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Citation: Gurnani, M.; Chauhan, A.;

Ranjan, A.; Tuli, H.S.; Alkhanani,

M.F.; Haque, S.; Dhama, K.; Lal, R.;

Jindal, T. Filamentous

Thermosensitive Mutant Z: An

Appealing Target for Emerging

Pathogens and a Trek on Its Natural

Inhibitors. Biology 2022, 11, 624.

https://doi.org/10.3390/

biology11050624

Academic Editors: Amirata

Saei Dibavar, Roozbeh Eskandari and

Lucia Coppo

Received: 4 February 2022

Accepted: 1 April 2022

Published: 20 April 2022

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4.0/).

biology

Review

Filamentous Thermosensitive Mutant Z: An Appealing Target
for Emerging Pathogens and a Trek on Its Natural Inhibitors
Manisha Gurnani 1, Abhishek Chauhan 2,* , Anuj Ranjan 3,* , Hardeep Singh Tuli 4 , Mustfa F. Alkhanani 5,
Shafiul Haque 6,7 , Kuldeep Dhama 8 , Rup Lal 9 and Tanu Jindal 2

1 Amity Institute of Environmental Science, Amity University, Noida 201301, India;
manishagurnani10@gmail.com

2 Amity Institute of Environmental Toxicology, Safety and Management, Amity University, Noida 201303, India;
tjindal@amity.edu

3 Academy of Biology and Biotechnology, Southern Federal University, 344006 Rostov-on-Don, Russia
4 Department of Biotechnology, Maharishi Markandeshwar (Deemed to be University), Ambala 133207, India;

hardeep.biotech@gmail.com
5 Emergency Service Department, College of Applied Sciences, AlMaarefa University,

Riyadh 11597, Saudi Arabia; mkhanani@mcst.edu.sa
6 Research and Scientific Studies Unit, College of Nursing and Allied Health Sciences, Jazan University,

Jazan 45142, Saudi Arabia; shafiul.haque@hotmail.com
7 Faculty of Medicine, Görükle Campus, Bursa Uludağ University, Nilüfer, Bursa 16059, Turkey
8 Division of Pathology, ICAR—Indian Veterinary Research Institute, Bareilly 243122, India;

kdhama@rediffmail.com
9 Department of Zoology, University of Delhi, Delhi 110021, India; ruplal@gmail.com
* Correspondence: akchauhan@amity.edu (A.C.); andzhan@sfedu.ru (A.R.)

Simple Summary: Antimicrobial resistance (AMR) is a pressing issue worldwide that must be
addressed swiftly. It is driven by spontaneous evolution, bacterial mutation, and the dissemination
of resistant genes via horizontal gene transfer. Researchers are working on many novel targets, which
can become a pathway to inhibit harmful bacteria. Filamentous Thermosensitive mutant-Z (Fts-Z) is
one such bacterial target that has gained popularity amongst scientists due to its conserved nature
in bacteria and absence in eukaryotes. The aim of this work was to review the Fts-Z mechanism of
action along with current studies on natural inhibitors for Fts-Z.

Abstract: Antibiotic resistance is a major emerging issue in the health care sector, as highlighted
by the WHO. Filamentous Thermosensitive mutant Z (Fts-Z) is gaining significant attention in the
scientific community as a potential anti-bacterial target for fighting antibiotic resistance among
several pathogenic bacteria. The Fts-Z plays a key role in bacterial cell division by allowing Z ring
formation. Several in vitro and in silico experiments have demonstrated that inhibition of Fts-Z can
lead to filamentous growth of the cells, and finally, cell death occurs. Many natural compounds
that have successfully inhibited Fts-Z are also studied. This review article intended to highlight
the structural–functional aspect of Fts-Z that leads to Z-ring formation and its contribution to the
biochemistry and physiology of cells. The current trend of natural inhibitors of Fts-Z protein is
also covered.

Keywords: antimicrobials; cytokinesis; divisome; drug discovery; MRSA; VRE; Fts-Z assembly;
microtubules; cell division; anti-bacterial drugs

1. Introduction

The story of antibiotics began in the 1930s with the discovery of Penicillin, the first
antibiotic, by Alexander Fleming. The next 40 years were a “golden era”, and even the
current antibiotics are the outcome of research work done during that time [1]. In that
phase, the discovery of antibiotics was considered to be a sign of victory over bacterial

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Biology 2022, 11, 624 2 of 24

infections, but bacteria are developing resistance to several conventional antibiotics, and
this is posing a serious threat to the health care sector.

Our knowledge about microbes and their infection-causing tendencies has increased
exponentially due to the extensive development of techniques for their study throughout
the 20th century. This, in turn, has boosted our ability to prevent and treat infections and
achieve better public health. However, exploring the depths of infection-causing pathways
is still is a mystery that we need to solve [2].

The WHO has clearly emphasized the concern about antimicrobial resistance (AMR)
that is brought about by the misuse of antibiotics and deliberate consumption through poul-
try and meat [3]. A WHO report released in February 2017 emphasized making improved
antibiotics for some pathogens a priority and categorized them as ESKAPE pathogens
(E. faecium, S. aureus, K. pneumoniae, A. baumannii, P. aeruginosa, Enterobacter) [4–6]. These
pathogens are WHO AMR priority pathogens as they have developed resistance against
antibiotics such as β lactams [7–9], fluroquinolones [10–12], macrolides [13,14], tetracy-
clines [15,16], and even last line defense antibiotics like glycopeptides [17,18] and car-
bapenems [19–21]. They have also developed resistance against the clinically unfavorable
polymyxins through mutations in genetic material and/or through assessing the MGEs,
i.e., mobile genetic elements [22]. In the worst cases, AMR leads to the development of
“Superbugs”, which develop multi-drug resistance (MDR) in bacteria [23,24]. New Delhi
metallobeta-lactamase-1 (NDM-1) is another case of antibiotic resistance where, to date,
colistin and tigecycline are the only effective antibiotics against these superbugs [25].

Antibiotic-resistant bacteria have been classified into three classes, namely:

(I) Methicillin-resistant Staphylococcus aureus, popularly known as (MRSA), which ac-
counts for ~12,000 [7] deaths per year and a health care cost of ~USD 5 billion per
year [26]. Following MRSA, Vancomycin-resistant S. aureus (VRSA) is another chal-
lenge to tackle and has become a new problem in hospitals [27].

(II) Pan drug-resistant and Multidrug-resistant, popularly known as PDR and MDR
respectively, in Gram-negative bacterial strains of E. coli, K. pneumoniae, A. baumannii,
P. aeruginosa, pose the threat of untreatable infections [28]. The avenues for finding
novel antibiotics for these are limited due to their outer membrane, which prevents
the entry of some antibiotics, and efflux pumps expel many of the remainders [29–31].

(III) Multidrug-resistant and extensively drug-resistant strains of M. tuberculosis, also
called MDR-TB and XDR-TB, pose a threat to the developing world specifically. The
treatment requires a 2-year course of antibiotics and has serious side effects for patients.
XDR-TB is more difficult to cure and often fatal [32,33].

Many studies have been conducted in this area leading to the identification of novel
antibiotics, identification of new targets, and management of AMR diseases. The research
community is constantly working on the above strategy to explore the new unexplored
boundaries. New pharmacophores showing good affinity against any key bacterial recep-
tors are checked for future avenues, and their derivatives are also being worked upon [34].
The study of novel antibiotic compounds and new targets is the only way forward in health
care research. In this context, in silico discoveries of novel compounds have become most
popular. Currently, AMR has made it imperative to work on both ends of drug discovery;
therefore, the ligand-based approach and the receptor-based approach must go hand in
hand. The rigorous exploration for novel bacterial targets indicates bacterial divisome
machinery to be an interesting receptor against antimicrobial activity [35].

2. Antibiotics and Bacterial Divisome Proteins as Emerging Therapeutic Targets

The emerging antimicrobial drug resistant in pathogens have made it mandatory to
search for the new scaffolds both for drugs and targets on priority. From the past studies
it is evident that the existing set of antibiotics is a combination of small molecules and
through various synthetic techniques their effectivity has been increased by chemists and
druggists [36–41]. Figure 1 shows the known antibiotics and their target sites in pathogen
causing bacteria. Potential targets have been discovered with the help of genomic data of



Biology 2022, 11, 624 3 of 24

these pathogens [42]. Many lead molecules are under preclinical trials for one or the other
targets [43].

Biology 2022, 11, x FOR PEER REVIEW 3 of 23 
 

 

bacteria. Potential targets have been discovered with the help of genomic data of these path-
ogens [42]. Many lead molecules are under preclinical trials for one or the other targets [43].  

 
Figure 1. Antibiotics and their target sites in bacterial cells. This figure is adapted from: Bbosa et al., 
2014 and Mendes et al., 2019 [43,44]. 

Bacterial cell division is being considered as the new antibiotic target and efforts are 
being made to identify compounds that either directly interact with the major divisome 
machinery or affect the structural integrity of Fts-Z by inhibiting its activity [35]. A few 
other targets from divisome machinery on which studies have already been done are Fts-
A [45], Fts-BLQ, Fts-N [46], Fts-K [47], Fts-Q [48] Fts-W [49]. Some of these studies include 
divisome proteins to be potent targets while others aim to understand the roles of these 
in division to find new targets against pathogens. The functions of some of the essential 
cell division proteins has been summarized in Table 1.  

Table 1. Summary of essential cell division protein (source: Seidel, Reyes et al., Geissler et al., Lock 
and Harry [47,50–52]). 

Protein Function Interacting Protein 

Fts-Z 
Cytoskeleton protein, Self-polymerizing GTPase which forms Z-ring/proto 

ring and recruitment of other proteins 
Fts-A, Zip-A, Fts-K 

Fts-A ATP binding protein which anchors and stabilizes Fts-Z filaments Fts-N, Fts-Z  
Zip-A Provides membrane anchorage for Fts-Z by bunding the filaments Fts-Z 

Fts-K 
DNA segregation at C terminal, stabilizing component and linker between 

early and late stages of division. 
Fts-A, Fts-I, Fts-L, Fts-Q, Fts-Z 

Fts-Q 
Periplasmic functional domain, Peptidoglycan synthesis, Complex formation 

with Fts-B and Fts-L 
Fts-B, Fts-I, Fts-L, Fts-N, Fts-W 

Fts-L Complex formation with Fts-B and Fts-Q, Peptidoglycan synthesis Fts-B, Fts-I, Fts-K, Fts-Q 
Fts-B Complex formation with Fts-L and Fts-Q, Peptidoglycan synthesis Fts-L, Fts-Q 
Fts-W Translocation of lipid precursors across membrane, Peptidoglycan synthesis Fts-I, Fts-L, Fts-N, Fts-Q, Fts-Z 
Fts-I Transpeptidase, Cross links peptidoglycan strains Fts-N, Fts-Q, Fts-W 

Figure 1. Antibiotics and their target sites in bacterial cells. This figure is adapted from: Bbosa et al., 2014
and Mendes et al., 2019 [43,44].

Bacterial cell division is being considered as the new antibiotic target and efforts are
being made to identify compounds that either directly interact with the major divisome
machinery or affect the structural integrity of Fts-Z by inhibiting its activity [35]. A few
other targets from divisome machinery on which studies have already been done are Fts-
A [45], Fts-BLQ, Fts-N [46], Fts-K [47], Fts-Q [48] Fts-W [49]. Some of these studies include
divisome proteins to be potent targets while others aim to understand the roles of these in
division to find new targets against pathogens. The functions of some of the essential cell
division proteins has been summarized in Table 1.

Table 1. Summary of essential cell division protein (source: Seidel, Reyes et al., Geissler et al., Lock
and Harry [47,50–52]).

Protein Function Interacting Protein

Fts-Z Cytoskeleton protein, Self-polymerizing GTPase which forms
Z-ring/proto ring and recruitment of other proteins Fts-A, Zip-A, Fts-K

Fts-A ATP binding protein which anchors and stabilizes Fts-Z filaments Fts-N, Fts-Z

Zip-A Provides membrane anchorage for Fts-Z by bunding the filaments Fts-Z

Fts-K DNA segregation at C terminal, stabilizing component and linker
between early and late stages of division. Fts-A, Fts-I, Fts-L, Fts-Q, Fts-Z

Fts-Q Periplasmic functional domain, Peptidoglycan synthesis, Complex
formation with Fts-B and Fts-L Fts-B, Fts-I, Fts-L, Fts-N, Fts-W

Fts-L Complex formation with Fts-B and Fts-Q, Peptidoglycan synthesis Fts-B, Fts-I, Fts-K, Fts-Q

Fts-B Complex formation with Fts-L and Fts-Q, Peptidoglycan synthesis Fts-L, Fts-Q

Fts-W Translocation of lipid precursors across membrane,
Peptidoglycan synthesis Fts-I, Fts-L, Fts-N, Fts-Q, Fts-Z

Fts-I Transpeptidase, Cross links peptidoglycan strains Fts-N, Fts-Q, Fts-W

Fts-N Triggers septation during peptidoglycan synthesis, Periplasmic
functional domain Fts-A, Fts-I, Fts-Q, Fts-W



Biology 2022, 11, 624 4 of 24

3. Fts-Z: An Appealing Antibacterial Target

Generally, bacteria undergo binary fission wherein, the divisome machinery coordi-
nates the entire process with varying constituents across the species. In Gram negative
bacteria the cell division process occurs in two phases: Early Divisome where the assembly
of the Z ring occurs and Late Divisome where remodeling of Peptidoglycan and Septation
occurs. Formation of the division site is the first step followed by elongation, septum
formation, then chromosome is divided and lastly at the division site two daughter nuclei
are formed [50,53,54]. The divisome complex comprises of more than 30 genes (including
the important ones—Fts A, Fts B, Fts I, Fts K, Fts L, Fts N, Fts Q, Fts W, Fts Z and Zip A)
of which Fts Z, a 40 kDa septal ring progenitor protein with 383 residues, is responsible
for proto ring formation. It is after this gene only that the splitting initiates [54–56]. For
this reason, it is extensively explored. It has been named so because its mutant causes
filamentation in E. coli cells at extreme temperatures, thus called “filamentous temperature
sensitive” [57–62]. It forms a dais for assembly and is the prime energy source for cell wall
constriction [63–69]. Fts-Z forms ring like constriction ‘the Z-ring’ (which is usually at the
midpoint of the rod lying perpendicular to the long cell axis in E. coli and B. subtilis), and
further downstream recruitment of ~13 other proteins take place which guides the location,
synthesis, and shape of division septum. Many molecular mechanisms such as Zap and
Min proteins, work together to govern Z ring placement [70]. Tethering of the membrane
is mediated by Fts-A (along with Zip A in Gram-positive and Sep F in Gram-negative
microbes). This complex of Fts-Z along with Fts-A (Sep F/Zip A) is a ‘proto-ring’. Fts-Z
driven constriction has been defined by two well-known models: the sliding model and
the bending model. The first model is dependent on the treadmilling of Fts-Z monomers
causing the sliding of filaments against each other and the tightening of the ring occurs by
overlapping filaments. The bending model is based on conformations change in protomers
during GTP hydrolysis which induces a curvature in filaments. This happens only when
Fts-Z is attached to the membrane so that a force is exerted on the membrane allowing
invagination when peptidoglycan remodeling enzymes are present [47,71].

Due to its conserved nature amongst nearly all prokaryotes, and absence in the eu-
karyotes, it is being considered to be an appealing target for forming antibiotics and thus
the molecules which can inhibit its activity will eventually disrupt the bacterial viability
of pathogens. Figure 2 shows how polymerization occurs in normal Fts-Z ring formation
and also the way Fts-Z molecules depolymerize in the presence of inhibitors. The mech-
anism of action of Fts-Z inhibitors can be: (a) through Fts-Z assembly inhibition [72–74];
(b) through entire Z-ring inhibition as done by berberine [48], cinnamaldehyde [75];
(c) through stimulating or discontinuing Fts-Z polymerization to disturb cytokinesis as
done by taxanes [76,77], Mci-Z [78] etc.; (d) elevating or hindering GTPase activity to ob-
struct cytokinesis as done by curcumin [53], benzimidazoles; Fts-Z delocalization through
point foci formation as done by certain synthetic compounds [79]. These all will cause the
cell to elongate into a filamentous structure and eventually will result in cell death [80].



Biology 2022, 11, 624 5 of 24
Biology 2022, 11, x FOR PEER REVIEW 5 of 23 
 

 

 
Figure 2. Polymerization and Depolymerization of Fts-Z ring in the presence and absence of inhib-
itors (yellow pentagon). 

Structural and Functional Aspect of Fts-Z 
The Fts-Z protein is broadly characterized into 5 portions: 2 conserved globular sub-

domains, N-terminal starting from residue 13 to residue 178 and C-terminal starting from 
residue 209 to 314, connected to each other by a central helix (α-H7 starting from residue 
179 to 202) and a synergy loop (T7) which connects α-H7 and H8., (Figure 3A) [81]. The 
N-terminal subunit and the C-terminal linker which is quite unstructured and least con-
served, the C terminal tail responsible for interacting/contacting between Fts-Z and other 
auxiliary proteins for the formation of protofilaments of Z-ring and the C-terminal varia-
ble which makes lateral contacts if the modulatory proteins are not present at the site [82]. 
N-terminal has nucleotide binding motif with parallel beta sheets connected to α helices 
called “Rossmann fold”. Thus, the binding cavity of this protein is formed by the conju-
gation point between the two monomer units and GTP hydrolyses rely on their assembly, 
which is further dependent on the binding of Mg++ ion and monovalent cations [57] . 

 
Figure 3. (A) Fts-Z protein from S. aureus (PDB ID—6RVQ) in ribbons bound to GDP (in brown 
CPK). The T7 loop is in pink and α-H7 helix is in green color. After the T7 loop starts the H8 helix. 
(B) Tubulin protein from Homo sapiens (PDB ID—6BR1) in ribbons showing alpha and beta subunits 
bound to GTP (in pink CPK) and GDP (in brown CPK) respectively. Note: Blue colored portion is 

Figure 2. Polymerization and Depolymerization of Fts-Z ring in the presence and absence of inhibitors
(yellow pentagon).

Structural and Functional Aspect of Fts-Z

The Fts-Z protein is broadly characterized into 5 portions: 2 conserved globular
subdomains, N-terminal starting from residue 13 to residue 178 and C-terminal starting
from residue 209 to 314, connected to each other by a central helix (α-H7 starting from
residue 179 to 202) and a synergy loop (T7) which connects α-H7 and H8., (Figure 3A) [81].
The N-terminal subunit and the C-terminal linker which is quite unstructured and least
conserved, the C terminal tail responsible for interacting/contacting between Fts-Z and
other auxiliary proteins for the formation of protofilaments of Z-ring and the C-terminal
variable which makes lateral contacts if the modulatory proteins are not present at the
site [82]. N-terminal has nucleotide binding motif with parallel beta sheets connected
to α helices called “Rossmann fold”. Thus, the binding cavity of this protein is formed
by the conjugation point between the two monomer units and GTP hydrolyses rely on
their assembly, which is further dependent on the binding of Mg++ ion and monovalent
cations [57].

Certain studies indicate the structural homology of this crucial protein with human
tubulin protein, sharing a common ancestry although significant differences between
amino-acid sequences were reported. Both the proteins tether and hydrolyze GTP and
polymerize into a GTP dependent fashion which is another point where biochemical
similarity is revealed [83,84]. Sequence motifs of Fts-Z like GGGTGTG, are also monograms
of alpha-, beta- and gamma- tubulins and are connected to GTP binding ability. Another
important motif, G-box, a seven amino acid sequence (SAG)GGTG(SAT)G was also found
to be conserved in the tubulin family from different species [59]. Studies of the archaeal
group gave indications that Fts-Z might have evolved to tubulin [60]. The variation in the
structure was reported at the hydrophobic cleft which is at H7 where the N terminus is
connected to the C terminus [85,86]. This hydrophobic cleft is absent in eukaryotic protein
which is shown in Figure 3B.



Biology 2022, 11, 624 6 of 24

Biology 2022, 11, x FOR PEER REVIEW 5 of 23 
 

 

 
Figure 2. Polymerization and Depolymerization of Fts-Z ring in the presence and absence of inhib-
itors (yellow pentagon). 

Structural and Functional Aspect of Fts-Z 
The Fts-Z protein is broadly characterized into 5 portions: 2 conserved globular sub-

domains, N-terminal starting from residue 13 to residue 178 and C-terminal starting from 
residue 209 to 314, connected to each other by a central helix (α-H7 starting from residue 
179 to 202) and a synergy loop (T7) which connects α-H7 and H8., (Figure 3A) [81]. The 
N-terminal subunit and the C-terminal linker which is quite unstructured and least con-
served, the C terminal tail responsible for interacting/contacting between Fts-Z and other 
auxiliary proteins for the formation of protofilaments of Z-ring and the C-terminal varia-
ble which makes lateral contacts if the modulatory proteins are not present at the site [82]. 
N-terminal has nucleotide binding motif with parallel beta sheets connected to α helices 
called “Rossmann fold”. Thus, the binding cavity of this protein is formed by the conju-
gation point between the two monomer units and GTP hydrolyses rely on their assembly, 
which is further dependent on the binding of Mg++ ion and monovalent cations [57] . 

 
Figure 3. (A) Fts-Z protein from S. aureus (PDB ID—6RVQ) in ribbons bound to GDP (in brown 
CPK). The T7 loop is in pink and α-H7 helix is in green color. After the T7 loop starts the H8 helix. 
(B) Tubulin protein from Homo sapiens (PDB ID—6BR1) in ribbons showing alpha and beta subunits 
bound to GTP (in pink CPK) and GDP (in brown CPK) respectively. Note: Blue colored portion is 

Figure 3. (A) Fts-Z protein from S. aureus (PDB ID—6RVQ) in ribbons bound to GDP (in brown
CPK). The T7 loop is in pink and α-H7 helix is in green color. After the T7 loop starts the H8 helix.
(B) Tubulin protein from Homo sapiens (PDB ID—6BR1) in ribbons showing alpha and beta subunits
bound to GTP (in pink CPK) and GDP (in brown CPK) respectively. Note: Blue colored portion is the
N-terminal and the green portion is the C-terminal. The figure was visualized in BIOVIA Discovery
studio visualizer v21.1.

4. Fts-Z Inhibition: A Strategy to Combat AMR

Fts-Z is being explored as potent target for inhibiting emerging microbes due to its
central role in Z-ring formation and conserved nature in nearly all bacterial species and
absence in higher eukaryotes. Its absence in bacteria induces filamentation and cell death
occurs [85].

Research work is being carried out to screen phytocompounds and other natural
compounds using in-vitro and in-silico techniques. Some of the natural compounds such
as berberine [87], curcumin [88], cinnamaldehyde [89], plumbagin [90], viriditoxin [91],
dichamanetins [92], coumarins [93], Chrysophaentins [94] and some phenylpropanoids [95]
and some have recently been investigated for Fts-Z inhibitors and antimicrobial properties.
A few potential inhibitors of Fts-Z are discussed below (Figure 4).

Biology 2022, 11, x FOR PEER REVIEW 6 of 23 
 

 

the N-terminal and the green portion is the C-terminal. The figure was visualized in BIOVIA Dis-
covery studio visualizer v21.1. 

Certain studies indicate the structural homology of this crucial protein with human 
tubulin protein, sharing a common ancestry although significant differences between 
amino-acid sequences were reported. Both the proteins tether and hydrolyze GTP and pol-
ymerize into a GTP dependent fashion which is another point where biochemical similarity 
is revealed [83,84]. Sequence motifs of Fts-Z like GGGTGTG, are also monograms of alpha-
, beta- and gamma- tubulins and are connected to GTP binding ability. Another important 
motif, G-box, a seven amino acid sequence (SAG)GGTG(SAT)G was also found to be con-
served in the tubulin family from different species [59]. Studies of the archaeal group gave 
indications that Fts-Z might have evolved to tubulin [60]. The variation in the structure was 
reported at the hydrophobic cleft which is at H7 where the N terminus is connected to the 
C terminus [85,86]. This hydrophobic cleft is absent in eukaryotic protein which is shown in 
Figure 3B. 

4. Fts-Z Inhibition: A Strategy to Combat AMR 
Fts-Z is being explored as potent target for inhibiting emerging microbes due to its central 

role in Z-ring formation and conserved nature in nearly all bacterial species and absence in 
higher eukaryotes. Its absence in bacteria induces filamentation and cell death occurs [85].  

Research work is being carried out to screen phytocompounds and other natural 
compounds using in-vitro and in-silico techniques. Some of the natural compounds such 
as berberine [87], curcumin [88], cinnamaldehyde [89], plumbagin [90], viriditoxin [91], 
dichamanetins [92], coumarins [93], Chrysophaentins [94] and some phenylpropanoids 
[95] and some have recently been investigated for Fts-Z inhibitors and antimicrobial prop-
erties. A few potential inhibitors of Fts-Z are discussed below (Figure 4).  

 
Figure 4. Fts-Z natural inhibitors. 

4.1. Berberine and Derivatives 
Berberine (IUPAC: 16,17-dimethoxy-5,7-dioxa-13-azoniapentacy-clo[11.8.0.02,10.04,8.015,20] 

henicosa-1(13),2,4(8),9,14,16,18,20-octaene), a benzyl isoquinoline alkaloid (Figure 5) from the 
Berberis plant, show a mild antibacterial activity and Fts- Z inhibition. Sun et al. in their work, 
studied the active site in S. aureus for Fts-Z (PDB ID—4DXD) binding through in-silico tech-
nique and the found interdomain region participating actively in the docking comparable to 

Figure 4. Fts-Z natural inhibitors.

4.1. Berberine and Derivatives

Berberine (IUPAC: 16,17-dimethoxy-5,7-dioxa-13-azoniapentacy-clo [11.8.0.02,10.04,8.015,20]
henicosa-1(13),2,4(8),9,14,16,18,20-octaene), a benzyl isoquinoline alkaloid (Figure 5) from



Biology 2022, 11, 624 7 of 24

the Berberis plant, show a mild antibacterial activity and Fts- Z inhibition. Sun et al. in
their work, studied the active site in S. aureus for Fts-Z (PDB ID—4DXD) binding through
in-silico technique and the found interdomain region participating actively in the docking
comparable to that of PC190723 [61]. The planar structure of the compound is best suited
for interaction with the C-terminus beta sheet of Fts-Z protein. Further they designed and
synthesized 9-phenoxyalkyl substituted derivatives of berberine (Figure 6) and found a
compound that has a high potent activity which was further verified through in-vitro an-
timicrobial susceptibility assay and GTPase activity assay. Dasgupta and colleagues, a few
years earlier had reported the inhibitory activity of berberine through In-vitro isothermal
colorimetry (ITC) and STD NMR spectroscopy [75]. The studies indicated the overlap of
the binding site of berberine with the GTP binding pocket in the Fts-Z protein. Berberine
also had low toxicity rates and some other side effects like that of bilirubin -induced brain
damage causing jaundice in infants and expecting mothers [87,96,97].

Biology 2022, 11, x FOR PEER REVIEW 7 of 23 
 

 

that of PC190723 [61]. The planar structure of the compound is best suited for interaction with 
the C-terminus beta sheet of Fts-Z protein. Further they designed and synthesized 9-phenox-
yalkyl substituted derivatives of berberine (Figure 6) and found a compound that has a high 
potent activity which was further verified through in-vitro antimicrobial susceptibility assay 
and GTPase activity assay. Dasgupta and colleagues, a few years earlier had reported the in-
hibitory activity of berberine through In-vitro isothermal colorimetry (ITC) and STD NMR 
spectroscopy [75]. The studies indicated the overlap of the binding site of berberine with the 
GTP binding pocket in the Fts-Z protein. Berberine also had low toxicity rates and some other 
side effects like that of bilirubin -induced brain damage causing jaundice in infants and ex-
pecting mothers [87,96,97].  

 
Figure 5. Berberine structure; Mol. Formula—C20H18NO4+; Mol. Wt.—336.4; Experimental details—
berberine-dependent Fts-Z assembly observed (IC50 = 10.0 ± 2.5 µM); Fts-Z GTPase activity observed 
(IC50 = 16.01 ± 5.0 µM), ITC results—dissociation constant (KD = 0.023) entropy driven [61]. Source: 
PubChem-CID 2353. 

 
Figure 6. Berberine chloride derivative; Mol. Formula—C20H18ClNO4; Mol. Wt.—371.8; Experi-
mental details—Inhibited MRSA ATCC 29247 (MIC = 2 µg mL−1), ATCC 700221 (MIC = 4 µg mL−1), 
E. coli (MIC = 32 µg mL−1), K. pneumoniae (MIC = 64 µg mL−1); showed GTPase (IC50 between 37.8 and 
63.7 µM). In-silico studies done on PDB-4DXD (interacting residues were Ile197, Leu200, Val203, 
Leu209, Met226, Leu261, Val297 and Ile311) [61]. Source: PubChem-CID 12456. 

4.2. Sanguinarine 
Sanguinarine (IUPAC: 24-methyl-5,7,18,20-tetraoxa-24-azoniahexacyclo 

[11.11.0.02,10.04,8.014,22.017,21] tetracosa-1(24),2,4(8),9,11,13,15,17(21),22-nonaene) is a benzo-
phenanthridine alkaloid from rhizome of Sanguinaria canadensis is found to inhibit cytoki-
nesis in bacteria. It inhibits the E. coli Fts-Z assembly by perturbing the Z ring and was 
also found to inhibit B. subtilis cell growth without affecting nucleoid segregation at an 
IC50 of 3µM. This interaction was investigated through in-vitro size exclusion chromatog-
raphy and fluoroscent probing. Mutational studies were also conducted by the group  
(Figure 7A) [90]. A representative compound 21 had 2 fold higher GTPase activity as com-
pared to sanguinarine for which a patent was also filed [98]. Liu and coworkers designed 
and synthesized sequence of novel 5-methyl-2-phenylphenanthridium (Figure 7B) deriv-
atives by simplifying the skeleton of sanguinarine. These had an exceptionally elevated 
anti-bacterial activity against an array of 10 antibiotic sensitive and resistant strains. MIC 
values for S. aureus ATCC25923, S. epidermis, S. pyogenes PS and PR, B. subtilis ATCC9372, 
B. pumilus ATCC63202 were ranged from 0.06 to 8 and 0.25–16 µg mL−1 respectively and 
for E. coli ATCC 25922 and P. aeruginosa ATCC27853 it was more than 64 µg mL−1 [89].  

Figure 5. Berberine structure; Mol. Formula—C20H18NO4
+; Mol. Wt.—336.4; Experimental details—

berberine-dependent Fts-Z assembly observed (IC50 = 10.0 ± 2.5 µM); Fts-Z GTPase activity observed
(IC50 = 16.01 ± 5.0 µM), ITC results—dissociation constant (KD = 0.023) entropy driven [61]. Source:
PubChem-CID 2353.

Biology 2022, 11, x FOR PEER REVIEW 7 of 23 
 

 

that of PC190723 [61]. The planar structure of the compound is best suited for interaction with 
the C-terminus beta sheet of Fts-Z protein. Further they designed and synthesized 9-phenox-
yalkyl substituted derivatives of berberine (Figure 6) and found a compound that has a high 
potent activity which was further verified through in-vitro antimicrobial susceptibility assay 
and GTPase activity assay. Dasgupta and colleagues, a few years earlier had reported the in-
hibitory activity of berberine through In-vitro isothermal colorimetry (ITC) and STD NMR 
spectroscopy [75]. The studies indicated the overlap of the binding site of berberine with the 
GTP binding pocket in the Fts-Z protein. Berberine also had low toxicity rates and some other 
side effects like that of bilirubin -induced brain damage causing jaundice in infants and ex-
pecting mothers [87,96,97].  

 
Figure 5. Berberine structure; Mol. Formula—C20H18NO4+; Mol. Wt.—336.4; Experimental details—
berberine-dependent Fts-Z assembly observed (IC50 = 10.0 ± 2.5 µM); Fts-Z GTPase activity observed 
(IC50 = 16.01 ± 5.0 µM), ITC results—dissociation constant (KD = 0.023) entropy driven [61]. Source: 
PubChem-CID 2353. 

 
Figure 6. Berberine chloride derivative; Mol. Formula—C20H18ClNO4; Mol. Wt.—371.8; Experi-
mental details—Inhibited MRSA ATCC 29247 (MIC = 2 µg mL−1), ATCC 700221 (MIC = 4 µg mL−1), 
E. coli (MIC = 32 µg mL−1), K. pneumoniae (MIC = 64 µg mL−1); showed GTPase (IC50 between 37.8 and 
63.7 µM). In-silico studies done on PDB-4DXD (interacting residues were Ile197, Leu200, Val203, 
Leu209, Met226, Leu261, Val297 and Ile311) [61]. Source: PubChem-CID 12456. 

4.2. Sanguinarine 
Sanguinarine (IUPAC: 24-methyl-5,7,18,20-tetraoxa-24-azoniahexacyclo 

[11.11.0.02,10.04,8.014,22.017,21] tetracosa-1(24),2,4(8),9,11,13,15,17(21),22-nonaene) is a benzo-
phenanthridine alkaloid from rhizome of Sanguinaria canadensis is found to inhibit cytoki-
nesis in bacteria. It inhibits the E. coli Fts-Z assembly by perturbing the Z ring and was 
also found to inhibit B. subtilis cell growth without affecting nucleoid segregation at an 
IC50 of 3µM. This interaction was investigated through in-vitro size exclusion chromatog-
raphy and fluoroscent probing. Mutational studies were also conducted by the group  
(Figure 7A) [90]. A representative compound 21 had 2 fold higher GTPase activity as com-
pared to sanguinarine for which a patent was also filed [98]. Liu and coworkers designed 
and synthesized sequence of novel 5-methyl-2-phenylphenanthridium (Figure 7B) deriv-
atives by simplifying the skeleton of sanguinarine. These had an exceptionally elevated 
anti-bacterial activity against an array of 10 antibiotic sensitive and resistant strains. MIC 
values for S. aureus ATCC25923, S. epidermis, S. pyogenes PS and PR, B. subtilis ATCC9372, 
B. pumilus ATCC63202 were ranged from 0.06 to 8 and 0.25–16 µg mL−1 respectively and 
for E. coli ATCC 25922 and P. aeruginosa ATCC27853 it was more than 64 µg mL−1 [89].  

Figure 6. Berberine chloride derivative; Mol. Formula—C20H18ClNO4; Mol. Wt.—371.8; Experimen-
tal details—Inhibited MRSA ATCC 29247 (MIC = 2 µg mL−1), ATCC 700221 (MIC = 4 µg mL−1),
E. coli (MIC = 32 µg mL−1), K. pneumoniae (MIC = 64 µg mL−1); showed GTPase (IC50 between 37.8
and 63.7 µM). In-silico studies done on PDB-4DXD (interacting residues were Ile197, Leu200, Val203,
Leu209, Met226, Leu261, Val297 and Ile311) [61]. Source: PubChem-CID 12456.

4.2. Sanguinarine

Sanguinarine (IUPAC: 24-methyl-5,7,18,20-tetraoxa-24-azoniahexacy-clo [11.11.0.02,10.
04,8.014,22.017,21] tetracosa-1(24),2,4(8),9,11,13,15,17(21),22-nonaene) is a benzophenanthri-
dine alkaloid from rhizome of Sanguinaria canadensis is found to inhibit cytokinesis in



Biology 2022, 11, 624 8 of 24

bacteria. It inhibits the E. coli Fts-Z assembly by perturbing the Z ring and was also found
to inhibit B. subtilis cell growth without affecting nucleoid segregation at an IC50 of 3µM.
This interaction was investigated through in-vitro size exclusion chromatography and
fluoroscent probing. Mutational studies were also conducted by the group (Figure 7A) [90].
A representative compound 21 had 2 fold higher GTPase activity as compared to sanguinar-
ine for which a patent was also filed [98]. Liu and coworkers designed and synthesized
sequence of novel 5-methyl-2-phenylphenanthridium (Figure 7B) derivatives by simpli-
fying the skeleton of sanguinarine. These had an exceptionally elevated anti-bacterial
activity against an array of 10 antibiotic sensitive and resistant strains. MIC values for S.
aureus ATCC25923, S. epidermis, S. pyogenes PS and PR, B. subtilis ATCC9372, B. pumilus
ATCC63202 were ranged from 0.06 to 8 and 0.25–16 µg mL−1 respectively and for E. coli
ATCC 25922 and P. aeruginosa ATCC27853 it was more than 64 µg mL−1 [89].

Biology 2022, 11, x FOR PEER REVIEW 8 of 23 
 

 

 
Figure 7. (A) Sanguinarine; Mol. Formula—C20H14NO4+; Mol. Wt.—332.3; Experimental details—
Dissociation constant (KD) = 18–20 µM; IC50 = 3 ± 1 µM for B. subtilis 168, 14 ± 2.3 µM for E. coli BL21 
[89]. (B) 5-methyl-2-phenylphenanthridium derivative of Sanguinarine [97]. Source: PubChem-CID 
5154; PMID-29657101. 

4.3. Cinnamaldehyde and Derivatives 
Cinnamaldehyde (IUPAC: (E)-3-phenylprop-2-enal), (Figure 8) a plant derived prod-

uct from spices (stem bark of Cinnamomum cassia) has shown an array of potential medic-
inal properties. It has been reported to possess inhibitory activity against yeasts, filamen-
tous molds and many bacteria through various pathways including inhibition of cell wall 
biosynthesis, changing of membrane structure and integrity and inhibiting GTPase activ-
ity [63]. Domadia and coworkers reported in-vitro, in-silico and in-vivo activity of cin-
namaldehyde to perturb Z ring morphology and GTP hydrolysis with an affinity of 1.0 ± 
0.2 µ/M [76]. Molecular modeling results were in concordance with STD-NMR results 
showing binding at the T7 loop in the C-terminal region. The results of MSA (multiple 
sequence alignment) also showed some of the residues- R202, V208, N263, G295, N263 to 
be highly conserved among Fts-Z. Xin and coworkers worked on derivatives of cinnamal-
dehyde where they found that substitution in the benzene ring at ortho or para position 
of cinnamaldehyde, by small groups increased the activity of compounds so synthesized 
against different microbes. They further stated that 2-methyl benzimidazoyl moiety was 
had a better efficiency against all strains, they tested and gave three compounds (marked 
as 3, 8, 10 in [94]) which had MIC of 4 µg mL−1 in two compounds and 10 µg mL−1 against 
S. aureus (ATCC 25923). Two compounds (marked as 4, 10 in [64]) gave MIC (4 µg 
mL−1)values 32 times better than the reference drugs used.  

 
Figure 8. Cinnamaldehyde structure. Mol. Formula—C9H8O; Mol. Wt.—132.16; Experimental de-
tails—inhibits E. coli (MIC = 1000 mgL−1), B. subtilis (MIC = 500 mgL−1), MSRA (MIC = 250 mgL−1), 
GTPase inhibition (IC50 = 5.81 ± 2.2 µM). In-silico docking (PDB ID—1FSZ), interacting residue were 
V208, R202, N263, G295, S297 [89]. Source PubChem: CID 637511. 

In 2015, another group of researchers took this study one step further by synthesizing 
cinnamaldehyde derivatives and reported comparable activity of them wherein some pos-
sessed cell division inhibition properties in S. aureus between 0.25–4 µg mL−1. They found good 

Figure 7. (A) Sanguinarine; Mol. Formula—C20H14NO4
+; Mol. Wt.—332.3; Experimental details—

Dissociation constant (KD) = 18–20 µM; IC50 = 3 ± 1 µM for B. subtilis 168, 14 ± 2.3 µM for E. coli
BL21 [89]. (B) 5-methyl-2-phenylphenanthridium derivative of Sanguinarine [97]. Source: PubChem-
CID 5154; PMID-29657101.

4.3. Cinnamaldehyde and Derivatives

Cinnamaldehyde (IUPAC: (E)-3-phenylprop-2-enal), (Figure 8) a plant derived product
from spices (stem bark of Cinnamomum cassia) has shown an array of potential medicinal
properties. It has been reported to possess inhibitory activity against yeasts, filamentous
molds and many bacteria through various pathways including inhibition of cell wall biosyn-
thesis, changing of membrane structure and integrity and inhibiting GTPase activity [63].
Domadia and coworkers reported in-vitro, in-silico and in-vivo activity of cinnamaldehyde
to perturb Z ring morphology and GTP hydrolysis with an affinity of 1.0 ± 0.2 µ/M [76].
Molecular modeling results were in concordance with STD-NMR results showing binding
at the T7 loop in the C-terminal region. The results of MSA (multiple sequence alignment)
also showed some of the residues- R202, V208, N263, G295, N263 to be highly conserved
among Fts-Z. Xin and coworkers worked on derivatives of cinnamaldehyde where they
found that substitution in the benzene ring at ortho or para position of cinnamaldehyde, by
small groups increased the activity of compounds so synthesized against different microbes.
They further stated that 2-methyl benzimidazoyl moiety was had a better efficiency against
all strains, they tested and gave three compounds (marked as 3, 8, 10 in [94]) which had
MIC of 4 µg mL−1 in two compounds and 10 µg mL−1 against S. aureus (ATCC 25923). Two
compounds (marked as 4, 10 in [64]) gave MIC (4 µg mL−1)values 32 times better than the
reference drugs used.



Biology 2022, 11, 624 9 of 24

Biology 2022, 11, x FOR PEER REVIEW 8 of 23 
 

 

 
Figure 7. (A) Sanguinarine; Mol. Formula—C20H14NO4+; Mol. Wt.—332.3; Experimental details—
Dissociation constant (KD) = 18–20 µM; IC50 = 3 ± 1 µM for B. subtilis 168, 14 ± 2.3 µM for E. coli BL21 
[89]. (B) 5-methyl-2-phenylphenanthridium derivative of Sanguinarine [97]. Source: PubChem-CID 
5154; PMID-29657101. 

4.3. Cinnamaldehyde and Derivatives 
Cinnamaldehyde (IUPAC: (E)-3-phenylprop-2-enal), (Figure 8) a plant derived prod-

uct from spices (stem bark of Cinnamomum cassia) has shown an array of potential medic-
inal properties. It has been reported to possess inhibitory activity against yeasts, filamen-
tous molds and many bacteria through various pathways including inhibition of cell wall 
biosynthesis, changing of membrane structure and integrity and inhibiting GTPase activ-
ity [63]. Domadia and coworkers reported in-vitro, in-silico and in-vivo activity of cin-
namaldehyde to perturb Z ring morphology and GTP hydrolysis with an affinity of 1.0 ± 
0.2 µ/M [76]. Molecular modeling results were in concordance with STD-NMR results 
showing binding at the T7 loop in the C-terminal region. The results of MSA (multiple 
sequence alignment) also showed some of the residues- R202, V208, N263, G295, N263 to 
be highly conserved among Fts-Z. Xin and coworkers worked on derivatives of cinnamal-
dehyde where they found that substitution in the benzene ring at ortho or para position 
of cinnamaldehyde, by small groups increased the activity of compounds so synthesized 
against different microbes. They further stated that 2-methyl benzimidazoyl moiety was 
had a better efficiency against all strains, they tested and gave three compounds (marked 
as 3, 8, 10 in [94]) which had MIC of 4 µg mL−1 in two compounds and 10 µg mL−1 against 
S. aureus (ATCC 25923). Two compounds (marked as 4, 10 in [64]) gave MIC (4 µg 
mL−1)values 32 times better than the reference drugs used.  

 
Figure 8. Cinnamaldehyde structure. Mol. Formula—C9H8O; Mol. Wt.—132.16; Experimental de-
tails—inhibits E. coli (MIC = 1000 mgL−1), B. subtilis (MIC = 500 mgL−1), MSRA (MIC = 250 mgL−1), 
GTPase inhibition (IC50 = 5.81 ± 2.2 µM). In-silico docking (PDB ID—1FSZ), interacting residue were 
V208, R202, N263, G295, S297 [89]. Source PubChem: CID 637511. 

In 2015, another group of researchers took this study one step further by synthesizing 
cinnamaldehyde derivatives and reported comparable activity of them wherein some pos-
sessed cell division inhibition properties in S. aureus between 0.25–4 µg mL−1. They found good 

Figure 8. Cinnamaldehyde structure. Mol. Formula—C9H8O; Mol. Wt.—132.16; Exper-
imental details—inhibits E. coli (MIC = 1000 mgL−1), B. subtilis (MIC = 500 mgL−1), MSRA
(MIC = 250 mgL−1), GTPase inhibition (IC50 = 5.81 ± 2.2 µM). In-silico docking (PDB ID—1FSZ),
interacting residue were V208, R202, N263, G295, S297 [89]. Source PubChem: CID 637511.

In 2015, another group of researchers took this study one step further by synthesizing
cinnamaldehyde derivatives and reported comparable activity of them wherein some
possessed cell division inhibition properties in S. aureus between 0.25–4 µg mL−1. They
found good activity when 2-methylbenzimidazolyl substitution was at the first position
and 2,4-dichlorophenyl was at the third position. Polymerization inhibition and GTPase
activity of S. aureus Fts-Z were shown in dose-dependent manner through biological assays
of compounds [94].

4.4. Chrysophaentins

Chrysophaentins are group of anti-infectives obtained from marine sources, chrys-
ophyte alga, Chryosphaeum taylori, including 8 phytochemicals (A-H), showed the in-
hibitory activity for MRSA, VREF (vancomycin-resistant E. faecium) and S. aureus [93].
Of these, Chrysophaentin A (IUPAC: (9E,25E)-4,10,20,26-tetrachloro-2,18-dioxapentacy-clo
[2 6.2.2.13,7.119,23.012,17]tetratriaconta-1(30),3,5,7(34),9,12(17),13,15,19,21,23(33),25,28,31-
tetradecaene-6,14,16,22,30,31-hexol), (Figure 9) showed the most potent antibacterial ac-
tivity and also inhibited GTPase activity in E. coli which was attributed to the presence
of hydroxyl group. Also, Chrysophaentins A had 12-fold higher MIC50 as compared to
Chrysophaentins D, due to the presence of chlorine at chains A and C. Another compound
hemi-Chrysophaentins(Figure 10) was synthesized and reported to have a reaction system
of Chrysophaentins A [67].

Biology 2022, 11, x FOR PEER REVIEW 9 of 23 
 

 

activity when 2-methylbenzimidazolyl substitution was at the first position and 2,4-dichloro-
phenyl was at the third position. Polymerization inhibition and GTPase activity of S. aureus 
Fts-Z were shown in dose-dependent manner through biological assays of compounds [94]. 

4.4. Chrysophaentins  
Chrysophaentins are group of anti-infectives obtained from marine sources, chryso-

phyte alga, Chryosphaeum taylori, including 8 phytochemicals (A-H), showed the inhibi-
tory activity for MRSA, VREF (vancomycin-resistant E. faecium) and S. aureus [93]. Of 
these, Chrysophaentin A (IUPAC: (9E,25E)-4,10,20,26-tetrachloro-2,18-dioxapentacyclo[2 
6.2.2.13,7.119,23.012,17]tetratriaconta-1(30),3,5,7(34),9,12(17),13,15,19,21,23(33),25,28,31-
tetradecaene-6,14,16,22,30,31-hexol), (Figure 9) showed the most potent antibacterial ac-
tivity and also inhibited GTPase activity in E. coli which was attributed to the presence of 
hydroxyl group. Also, Chrysophaentins A had 12-fold higher MIC50 as compared to 
Chrysophaentins D, due to the presence of chlorine at chains A and C. Another compound 
hemi-Chrysophaentins(Figure 10) was synthesized and reported to have a reaction system 
of Chrysophaentins A [67]. 

 
Figure 9. Chrysophaentin A Structure. Mol. Formula—C32H24Cl4O8; Mol. Wt.—678.3; Experimental 
details—GTPase activity (IC50 = 6.7 ± 1.7 µg mL−1); MIC50 = 1.8 ± 0.6 µg mL−1, 1.5 ± 0.7 µg mL−1, and 
1.3 ± 0.4 µg mL−1 against SA, MRSA, and multi drug resistant SA (MDR-SA), respectively; and 3.8 ± 
1.9 µg mL−1 and 2.9 ± 0.8 µg mL−1 toward E. faecium and VREF; In-silico docking on homology mod-
elled E.coli, placed compound in GTP binding site (residues Gly20, Asn24, Asn 43, Ala 70, Thr 108, 
Arg 142 formed H-bond) [93]. Source: PubChem-CID 46872004. 

 
Figure 10. Hemichrysophaentin Structure; Mol. Formula—C18H18Cl2O4; Mol. Wt.—369.2 [93]. 
Source: PubChem-60164930. 

4.5. Coumarins 
Coumarins (IUPAC: chromen-2-one), (Figure 11) are 1,2-benzopyrone derivatives 

were derived from different plants with a proven Fts-Z inhibition activity. They have a 
2H-chromen-2-one composed of lactone and aromatic ring, along with 2 oxygen atoms 
forming bonds with enzyme residues and thus are responsible for pharmacological prop-
erties. The aromatic ring also plays role in destabilizing enzymes by forming hydrophobic 

Figure 9. Chrysophaentin A Structure. Mol. Formula—C32H24Cl4O8; Mol. Wt.—678.3; Experimental
details—GTPase activity (IC50 = 6.7 ± 1.7 µg mL−1); MIC50 = 1.8 ± 0.6 µg mL−1, 1.5 ± 0.7 µg mL−1,
and 1.3 ± 0.4 µg mL−1 against SA, MRSA, and multi drug resistant SA (MDR-SA), respectively; and
3.8± 1.9 µg mL−1 and 2.9± 0.8 µg mL−1 toward E. faecium and VREF; In-silico docking on homology
modelled E.coli, placed compound in GTP binding site (residues Gly20, Asn24, Asn 43, Ala 70, Thr
108, Arg 142 formed H-bond) [93]. Source: PubChem-CID 46872004.



Biology 2022, 11, 624 10 of 24

Biology 2022, 11, x FOR PEER REVIEW 9 of 23 
 

 

activity when 2-methylbenzimidazolyl substitution was at the first position and 2,4-dichloro-
phenyl was at the third position. Polymerization inhibition and GTPase activity of S. aureus 
Fts-Z were shown in dose-dependent manner through biological assays of compounds [94]. 

4.4. Chrysophaentins  
Chrysophaentins are group of anti-infectives obtained from marine sources, chryso-

phyte alga, Chryosphaeum taylori, including 8 phytochemicals (A-H), showed the inhibi-
tory activity for MRSA, VREF (vancomycin-resistant E. faecium) and S. aureus [93]. Of 
these, Chrysophaentin A (IUPAC: (9E,25E)-4,10,20,26-tetrachloro-2,18-dioxapentacyclo[2 
6.2.2.13,7.119,23.012,17]tetratriaconta-1(30),3,5,7(34),9,12(17),13,15,19,21,23(33),25,28,31-
tetradecaene-6,14,16,22,30,31-hexol), (Figure 9) showed the most potent antibacterial ac-
tivity and also inhibited GTPase activity in E. coli which was attributed to the presence of 
hydroxyl group. Also, Chrysophaentins A had 12-fold higher MIC50 as compared to 
Chrysophaentins D, due to the presence of chlorine at chains A and C. Another compound 
hemi-Chrysophaentins(Figure 10) was synthesized and reported to have a reaction system 
of Chrysophaentins A [67]. 

 
Figure 9. Chrysophaentin A Structure. Mol. Formula—C32H24Cl4O8; Mol. Wt.—678.3; Experimental 
details—GTPase activity (IC50 = 6.7 ± 1.7 µg mL−1); MIC50 = 1.8 ± 0.6 µg mL−1, 1.5 ± 0.7 µg mL−1, and 
1.3 ± 0.4 µg mL−1 against SA, MRSA, and multi drug resistant SA (MDR-SA), respectively; and 3.8 ± 
1.9 µg mL−1 and 2.9 ± 0.8 µg mL−1 toward E. faecium and VREF; In-silico docking on homology mod-
elled E.coli, placed compound in GTP binding site (residues Gly20, Asn24, Asn 43, Ala 70, Thr 108, 
Arg 142 formed H-bond) [93]. Source: PubChem-CID 46872004. 

 
Figure 10. Hemichrysophaentin Structure; Mol. Formula—C18H18Cl2O4; Mol. Wt.—369.2 [93]. 
Source: PubChem-60164930. 

4.5. Coumarins 
Coumarins (IUPAC: chromen-2-one), (Figure 11) are 1,2-benzopyrone derivatives 

were derived from different plants with a proven Fts-Z inhibition activity. They have a 
2H-chromen-2-one composed of lactone and aromatic ring, along with 2 oxygen atoms 
forming bonds with enzyme residues and thus are responsible for pharmacological prop-
erties. The aromatic ring also plays role in destabilizing enzymes by forming hydrophobic 

Figure 10. Hemichrysophaentin Structure; Mol. Formula—C18H18Cl2O4; Mol. Wt.—369.2 [93].
Source: PubChem-60164930.

4.5. Coumarins

Coumarins (IUPAC: chromen-2-one), (Figure 11) are 1,2-benzopyrone derivatives were
derived from different plants with a proven Fts-Z inhibition activity. They have a 2H-
chromen-2-one composed of lactone and aromatic ring, along with 2 oxygen atoms forming
bonds with enzyme residues and thus are responsible for pharmacological properties. The
aromatic ring also plays role in destabilizing enzymes by forming hydrophobic bonds [69].
Ammoresinol, anthogenol, ostruthin, novobiocin, chartreusin and coumermycin are some
of the coumarins which also show anti-bacterial activity against many Gram-negative and
Gram-positive bacteria [99]. A study suggested that coumarins had potent activity against
M. tuberculosis (H37Rv) by inhibiting GTPase activity and polymerization of Fts-Z. Other
coumarins namely, Scopoletin (having IC50 of 41 µM for Fts-Z polymerization and 23 µM
for GTPase activity) and Daphnetin (IC50 of 73 µM for Fts-Z polymerization and 57 µM for
GTPase activity) have proven activity. In-silico studies performed on coumarins and Fts-Z
indicate that it binds in the T7 loop of Fts-Z [100–106].

Biology 2022, 11, x FOR PEER REVIEW 10 of 23 
 

 

bonds [69]. Ammoresinol, anthogenol, ostruthin, novobiocin, chartreusin and cou-
mermycin are some of the coumarins which also show anti-bacterial activity against many 
Gram-negative and Gram-positive bacteria [99]. A study suggested that coumarins had 
potent activity against M. tuberculosis (H37Rv) by inhibiting GTPase activity and polymer-
ization of Fts-Z. Other coumarins namely, Scopoletin (having IC50 of 41 µM for Fts-Z 
polymerization and 23 µM for GTPase activity) and Daphnetin (IC50 of 73 µM for Fts-Z 
polymerization and 57 µM for GTPase activity) have proven activity. In-silico studies per-
formed on coumarins and Fts-Z indicate that it binds in the T7 loop of Fts-Z [100–106]. 

 
Figure 11. Coumarin Structure. Mol. Formula—C9H6O2; Mol. Wt.—146.14; GTPase activity (IC50 = 
212 ± 4.12 µM); Fts-Z polymerization (IC50 = 200 ± 4.2 µM) [58]. Source: PubChem-323. 

4.6. Curcumin 
Curcumin (IUPAC: 1,7-bis(4-hydroxy-3-methoxyphenyl)-1,6-heptadiene-3,5-di-

one/diferuloyl methane), (Figure 12) is a chromophore in rhizomes of the plant Curcuma 
longa (turmeric). It is a polyphenolic compound, possessing a wide spectrum of biological 
activities and is traditionally used in as a household remedy for curing various diseases, as 
spice and as a food preservative in South East Asian countries including India [88]. The 
presence of two ortho methoxylated phenols having conjugate linking with beta-di-ketone 
function makes it an appealing target for the drug industry. Rai and coworkers, revealed 
the inhibitory action of curcumin to polymerize Fts-Z in B. subtilis wherein Z-ring formation 
was perturbed and GTPase activity was enhanced [107]. Roy and colleagues found putative 
curcumin binding sites in E. coli Fts-Z and B. subtilis Fts-Z forming bonds in the GTP binding 
pocket through the computational docking technique [108]. Some of the research groups are 
working on the nano-formulation of curcumin to increase its stability in in-vitro and in-vivo 
setups. The major drawback of curcumin is its poor aqueous solubility and bioavailability 
[92]. 

 
Figure 12. Curcumin Structure; Mol. Formula—C21H20O6; Mol. Wt.—368.4; Experimental details—
inhibited B. subtilis 168 (IC50 = 17 ± 3 µM), E. coli K12 MG1655 (IC50 = 58 ± 5 µM); dissociation constant 
(KD) = 7.3 ± 1.8 µM [108]. Source: PubChem-CID 969516. 

4.7. Dichamanetin and Derivatives 
Dichamanetin (Figure 13A) is a natural polyphenolic compound obtained/isolated 

from Uvariachamae and 2‴-hydroxy-5″-benxzylisouvarinol-B (Figure 13B) is another nat-
ural polyphenolic compound from Xylopia afticana found by two independent researchers 
[109]. Dichamanetin and derivatives are structurally similar to Zantrins Z1, and have anti-
bacterial activity against many Gram-positive microbes (S. aureus, B. subtilis, M. smegmatis 
and E. coli) comparable to Zantrin. Urgaonkar and colleagues examined the impact of 

Figure 11. Coumarin Structure. Mol. Formula—C9H6O2; Mol. Wt.—146.14; GTPase activity
(IC50 = 212 ± 4.12 µM); Fts-Z polymerization (IC50 = 200 ± 4.2 µM) [58]. Source: PubChem-323.

4.6. Curcumin

Curcumin (IUPAC: 1,7-bis(4-hydroxy-3-methoxyphenyl)-1,6-heptadiene-3,5-dione/
diferuloyl methane), (Figure 12) is a chromophore in rhizomes of the plant Curcuma longa
(turmeric). It is a polyphenolic compound, possessing a wide spectrum of biological
activities and is traditionally used in as a household remedy for curing various diseases, as
spice and as a food preservative in South East Asian countries including India [88]. The
presence of two ortho methoxylated phenols having conjugate linking with beta-di-ketone
function makes it an appealing target for the drug industry. Rai and coworkers, revealed
the inhibitory action of curcumin to polymerize Fts-Z in B. subtilis wherein Z-ring formation
was perturbed and GTPase activity was enhanced [107]. Roy and colleagues found putative
curcumin binding sites in E. coli Fts-Z and B. subtilis Fts-Z forming bonds in the GTP
binding pocket through the computational docking technique [108]. Some of the research
groups are working on the nano-formulation of curcumin to increase its stability in in-vitro



Biology 2022, 11, 624 11 of 24

and in-vivo setups. The major drawback of curcumin is its poor aqueous solubility and
bioavailability [92].

Biology 2022, 11, x FOR PEER REVIEW 10 of 23 
 

 

bonds [69]. Ammoresinol, anthogenol, ostruthin, novobiocin, chartreusin and cou-
mermycin are some of the coumarins which also show anti-bacterial activity against many 
Gram-negative and Gram-positive bacteria [99]. A study suggested that coumarins had 
potent activity against M. tuberculosis (H37Rv) by inhibiting GTPase activity and polymer-
ization of Fts-Z. Other coumarins namely, Scopoletin (having IC50 of 41 µM for Fts-Z 
polymerization and 23 µM for GTPase activity) and Daphnetin (IC50 of 73 µM for Fts-Z 
polymerization and 57 µM for GTPase activity) have proven activity. In-silico studies per-
formed on coumarins and Fts-Z indicate that it binds in the T7 loop of Fts-Z [100–106]. 

 
Figure 11. Coumarin Structure. Mol. Formula—C9H6O2; Mol. Wt.—146.14; GTPase activity (IC50 = 
212 ± 4.12 µM); Fts-Z polymerization (IC50 = 200 ± 4.2 µM) [58]. Source: PubChem-323. 

4.6. Curcumin 
Curcumin (IUPAC: 1,7-bis(4-hydroxy-3-methoxyphenyl)-1,6-heptadiene-3,5-di-

one/diferuloyl methane), (Figure 12) is a chromophore in rhizomes of the plant Curcuma 
longa (turmeric). It is a polyphenolic compound, possessing a wide spectrum of biological 
activities and is traditionally used in as a household remedy for curing various diseases, as 
spice and as a food preservative in South East Asian countries including India [88]. The 
presence of two ortho methoxylated phenols having conjugate linking with beta-di-ketone 
function makes it an appealing target for the drug industry. Rai and coworkers, revealed 
the inhibitory action of curcumin to polymerize Fts-Z in B. subtilis wherein Z-ring formation 
was perturbed and GTPase activity was enhanced [107]. Roy and colleagues found putative 
curcumin binding sites in E. coli Fts-Z and B. subtilis Fts-Z forming bonds in the GTP binding 
pocket through the computational docking technique [108]. Some of the research groups are 
working on the nano-formulation of curcumin to increase its stability in in-vitro and in-vivo 
setups. The major drawback of curcumin is its poor aqueous solubility and bioavailability 
[92]. 

 
Figure 12. Curcumin Structure; Mol. Formula—C21H20O6; Mol. Wt.—368.4; Experimental details—
inhibited B. subtilis 168 (IC50 = 17 ± 3 µM), E. coli K12 MG1655 (IC50 = 58 ± 5 µM); dissociation constant 
(KD) = 7.3 ± 1.8 µM [108]. Source: PubChem-CID 969516. 

4.7. Dichamanetin and Derivatives 
Dichamanetin (Figure 13A) is a natural polyphenolic compound obtained/isolated 

from Uvariachamae and 2‴-hydroxy-5″-benxzylisouvarinol-B (Figure 13B) is another nat-
ural polyphenolic compound from Xylopia afticana found by two independent researchers 
[109]. Dichamanetin and derivatives are structurally similar to Zantrins Z1, and have anti-
bacterial activity against many Gram-positive microbes (S. aureus, B. subtilis, M. smegmatis 
and E. coli) comparable to Zantrin. Urgaonkar and colleagues examined the impact of 

Figure 12. Curcumin Structure; Mol. Formula—C21H20O6; Mol. Wt.—368.4; Experimental details—
inhibited B. subtilis 168 (IC50 = 17 ± 3 µM), E. coli K12 MG1655 (IC50 = 58 ± 5 µM); dissociation
constant (KD) = 7.3 ± 1.8 µM [108]. Source: PubChem-CID 969516.

4.7. Dichamanetin and Derivatives

Dichamanetin (Figure 13A) is a natural polyphenolic compound obtained/isolated
from Uvariachamae and 2′′′-hydroxy-5′′-benxzylisouvarinol-B (Figure 13B) is another
natural polyphenolic compound from Xylopia afticana found by two independent re-
searchers [109]. Dichamanetin and derivatives are structurally similar to Zantrins Z1,
and have anti-bacterial activity against many Gram-positive microbes (S. aureus, B. subtilis,
M. smegmatis and E. coli) comparable to Zantrin. Urgaonkar and colleagues examined
the impact of dichamanetin on E. coli Fts-Z GTPase activity and found that the inhibition
IC50 values were 12.5 µM and 8.3 µM, respectively [109].

Biology 2022, 11, x FOR PEER REVIEW 11 of 23 
 

 

dichamanetin on E. coli Fts-Z GTPase activity and found that the inhibition IC50 values 
were 12.5 µM and 8.3 µM, respectively [109]. 

  
(A) (B) 

Figure 13. (A) Dichamanetin Structure; Mol. Formula—C29H24O6; Mol. Wt.—468.5; Experimental de-
tails—GTPase inhibition in E.coli (IC50 = 12.5 ± 0.5 µM) [109]. (B) 2‴-hydroxy-5″-benxzylisouvarinol-
B [109]. Source: PubChem-CID 181193. 

4.8. Doxorubicin 
Doxorubicin, (IUPAC: (7S,9S)-7-[(2R,4S,5S,6S)-4-amino-5-hydroxy-6-methyloxan-2-

yl]oxy-6,9,11-trihydroxy-9-(2-hydroxyacetyl)-4-methoxy-8,10-dihydro-7H-tetracene-5,12-
dione) (Figure 14) an anthracycline antibiotic derived from the actinobacterium Strepto-
myces peucetius, has been found as a powerful Fts-Z inhibitor that inhibits E. coli growth 
by disrupting Fts-Z functions [110]. It was identified as a small molecule targeting Fts-Z 
and suppressing bacterial division utilizing an independent computational, biochemical, 
and microbiological method from a drug library authorized by the US FDA. The fluores-
cence-binding experiment indicated that it interacts significantly with Fts-Z without 
changing membrane structure or nucleoid segregation in microbes. The effects were visi-
ble on both GTPase activity and Fts-Z assembly. 

 
Figure 14. Structure of Doxorubicin; Mol. Formula—C27H29NO11; Mol. Wt.—543.5; Experimental de-
tails—Antibacterial activity against E. coli BL21, B. subtilis (MIC—20 µM, 10 µM respectively); Dis-
sociation constant (KD 120 ± 61 nM) [110]. Source: PubChem-CID 31703. 

4.9. Phenylpropanoids 
Phenylpropanoids are phytochemicals produced primarily due to stress including 

wounding, UV irradiation, pollutants, infections, and several other environmental factors 
to protect them against pathogens and predators. This defensive characteristic can be at-
tributed to their free radical hunting and antioxidant properties [111]. Studies clearly in-
dicate the use of these phytochemicals for the production of anti-bacterial agents [111]. 
Hemaiswarya and coworkers studied the effect of 8 phenylpropanoids (chlorogenic acid, 
caffeic acid, 2,4,5-trimethoxycinnamic acid, cinnamic acid and p-coumaric acid) (Figure 
15A–E), against E. coli Fts-Z through both in-silico and in-vitro techniques [111]. Among 
them chlorogenic acid which is an ester of quinic aid and caffeic acid was found to have 
the highest IC50 value of 69.55 ± 3.6 µM, caffeic acid, cinnamic acid, p-coumaric acid fol-

Figure 13. (A) Dichamanetin Structure; Mol. Formula—C29H24O6; Mol. Wt.—468.5; Experi-
mental details—GTPase inhibition in E.coli (IC50 = 12.5 ± 0.5 µM) [109]. (B) 2′′′-hydroxy-5′′-
benxzylisouvarinol-B [109]. Source: PubChem-CID 181193.

4.8. Doxorubicin

Doxorubicin, (IUPAC: (7S,9S)-7-[(2R,4S,5S,6S)-4-amino-5-hydroxy-6-methyloxan-2-
yl]oxy-6,9,11-trihydroxy-9-(2-hydroxyacetyl)-4-methoxy-8,10-dihydro-7H-tetracene-5,12-dione)
(Figure 14) an anthracycline antibiotic derived from the actinobacterium Streptomyces



Biology 2022, 11, 624 12 of 24

peucetius, has been found as a powerful Fts-Z inhibitor that inhibits E. coli growth by dis-
rupting Fts-Z functions [110]. It was identified as a small molecule targeting Fts-Z and
suppressing bacterial division utilizing an independent computational, biochemical, and
microbiological method from a drug library authorized by the US FDA. The fluorescence-
binding experiment indicated that it interacts significantly with Fts-Z without changing
membrane structure or nucleoid segregation in microbes. The effects were visible on both
GTPase activity and Fts-Z assembly.

Biology 2022, 11, x FOR PEER REVIEW 11 of 23 
 

 

dichamanetin on E. coli Fts-Z GTPase activity and found that the inhibition IC50 values 
were 12.5 µM and 8.3 µM, respectively [109]. 

  
(A) (B) 

Figure 13. (A) Dichamanetin Structure; Mol. Formula—C29H24O6; Mol. Wt.—468.5; Experimental de-
tails—GTPase inhibition in E.coli (IC50 = 12.5 ± 0.5 µM) [109]. (B) 2‴-hydroxy-5″-benxzylisouvarinol-
B [109]. Source: PubChem-CID 181193. 

4.8. Doxorubicin 
Doxorubicin, (IUPAC: (7S,9S)-7-[(2R,4S,5S,6S)-4-amino-5-hydroxy-6-methyloxan-2-

yl]oxy-6,9,11-trihydroxy-9-(2-hydroxyacetyl)-4-methoxy-8,10-dihydro-7H-tetracene-5,12-
dione) (Figure 14) an anthracycline antibiotic derived from the actinobacterium Strepto-
myces peucetius, has been found as a powerful Fts-Z inhibitor that inhibits E. coli growth 
by disrupting Fts-Z functions [110]. It was identified as a small molecule targeting Fts-Z 
and suppressing bacterial division utilizing an independent computational, biochemical, 
and microbiological method from a drug library authorized by the US FDA. The fluores-
cence-binding experiment indicated that it interacts significantly with Fts-Z without 
changing membrane structure or nucleoid segregation in microbes. The effects were visi-
ble on both GTPase activity and Fts-Z assembly. 

 
Figure 14. Structure of Doxorubicin; Mol. Formula—C27H29NO11; Mol. Wt.—543.5; Experimental de-
tails—Antibacterial activity against E. coli BL21, B. subtilis (MIC—20 µM, 10 µM respectively); Dis-
sociation constant (KD 120 ± 61 nM) [110]. Source: PubChem-CID 31703. 

4.9. Phenylpropanoids 
Phenylpropanoids are phytochemicals produced primarily due to stress including 

wounding, UV irradiation, pollutants, infections, and several other environmental factors 
to protect them against pathogens and predators. This defensive characteristic can be at-
tributed to their free radical hunting and antioxidant properties [111]. Studies clearly in-
dicate the use of these phytochemicals for the production of anti-bacterial agents [111]. 
Hemaiswarya and coworkers studied the effect of 8 phenylpropanoids (chlorogenic acid, 
caffeic acid, 2,4,5-trimethoxycinnamic acid, cinnamic acid and p-coumaric acid) (Figure 
15A–E), against E. coli Fts-Z through both in-silico and in-vitro techniques [111]. Among 
them chlorogenic acid which is an ester of quinic aid and caffeic acid was found to have 
the highest IC50 value of 69.55 ± 3.6 µM, caffeic acid, cinnamic acid, p-coumaric acid fol-

Figure 14. Structure of Doxorubicin; Mol. Formula—C27H29NO11; Mol. Wt.—543.5; Experimental
details—Antibacterial activity against E. coli BL21, B. subtilis (MIC—20 µM, 10 µM respectively);
Dissociation constant (KD 120 ± 61 nM) [110]. Source: PubChem-CID 31703.

4.9. Phenylpropanoids

Phenylpropanoids are phytochemicals produced primarily due to stress including
wounding, UV irradiation, pollutants, infections, and several other environmental factors
to protect them against pathogens and predators. This defensive characteristic can be
attributed to their free radical hunting and antioxidant properties [111]. Studies clearly
indicate the use of these phytochemicals for the production of anti-bacterial agents [111].
Hemaiswarya and coworkers studied the effect of 8 phenylpropanoids (chlorogenic acid,
caffeic acid, 2,4,5-trimethoxycinnamic acid, cinnamic acid and p-coumaric acid) (Figure 15A–E),
against E. coli Fts-Z through both in-silico and in-vitro techniques [111]. Among them
chlorogenic acid which is an ester of quinic aid and caffeic acid was found to have the high-
est IC50 value of 69.55 ± 3.6 µM, caffeic acid, cinnamic acid, p-coumaric acid followed with
105.96 ± 6.3 µM, 238.91 ± 7.1 µM, 189.53 ± 3.7 µM, respectively. 2,4,5-trimethoxy cinnamic
acid, 3,4-dimethoxy cinnamic acid and eugenol were the least potent (IC50 < 250 µM.). Light
scattering experiments and circular dichroism studies supported the results. The in-silico
studies indicated that the binding of phenylpropanoids happens not less than a residue in
the T7 loop which is considered to be most important in the Fts-Z structure. Some other
compounds which have inhibitory effects against Fts-Z were phenyl acrylamide [111,112],
vanillin derivative 3a and 4u which have been tested against S. aureus, S. pyogenes and M.
tuberculosis [112–114]

Biology 2022, 11, x FOR PEER REVIEW 12 of 23 
 

 

lowed with 105.96 ± 6.3 µM, 238.91 ± 7.1 µM, 189.53 ± 3.7 µM, respectively. 2,4,5-tri-
methoxy cinnamic acid, 3,4-dimethoxy cinnamic acid and eugenol were the least potent 
(IC50 < 250 µM.). Light scattering experiments and circular dichroism studies supported 
the results. The in-silico studies indicated that the binding of phenylpropanoids happens 
not less than a residue in the T7 loop which is considered to be most important in the Fts-
Z structure. Some other compounds which have inhibitory effects against Fts-Z were phe-
nyl acrylamide [111,112], vanillin derivative 3a and 4u which have been tested against S. 
aureus, S. pyogenes and M. tuberculosis [112–114] 

 
Figure 15. Phenylpropanoids group inhibiting Fts-Z: (A) Chlorogenic acid; (B) p-Coumaric acid; (C) 
Caffeic acid; (D) 2,4,5-Trimethoxycinnamic acid.; (E) Cinnamic acid. Source: PubChem. 

4.10. Plumbagin 
Plumbagin (IUPAC: 5-hydroxy-2-methylnaphthalene-1,4-dione), (Figure 16) is a 

phytochemical from the roots of the Plumbago zeylanica plant [90]. It is a secondary naph-
thoquinone derivative known to exhibit a variety of biological activities such as cell pro-
liferation in mammals [115], fungus [116] and bacterial cells [117]. The antimicrobial prop-
erties do not affect E.coli, S. typhimurium [118]. Acharya and coworkers, through their ex-
vivo experiment demonstrated the binding of plumbagin with cellular microtubules in 
the colchicine cavity, cell viability experiments gave the IC50 value of 14.6 µm [119]. The 
structural similarity of Fts-Z with that of tubulin has caused many scientists to work on 
this and plumbagin was found to inhibit Fts-Z in B. subtilis 168 in a dose dependent man-
ner. Further in-silico studies showed the possible binding site located at residues D199 
and V307 [120]. 

 
Figure 16. Plumbagin Structure. Mol. Formula—C11H8O3; Mol. Wt.—188.18; Dissociation constant 
(KD) 20.7 ± 5.6 µM [115]. Source: PubChem-10205. 

4.11. Totarol 
Totarol, a diterpene phenolic phytocompound, (IUPAC: (4bS,8aS)-4b,8,8-trimethyl-

1-propan-2-yl-5,6,7,8a,9,10-hexahydrophenanthren-2-ol) (Figure 17), is obtained from a 
conifer (Podocarpus totara) and showed activity against M. tuberculosis and B. subtilis 
[121,122]. Although totarol was shown to have high anti-bacterial action against a variety 
of Gram-positive bacteria, it had no effect on Gram-negative bacteria and no antifungal 
properties as well. The experiments done indicated that totarol did not disrupt the B. sub-
tilis membrane or nucleoid segregation, it only affected the functioning of the Z-ring. 

Figure 15. Phenylpropanoids group inhibiting Fts-Z: (A) Chlorogenic acid; (B) p-Coumaric acid;
(C) Caffeic acid; (D) 2,4,5-Trimethoxycinnamic acid.; (E) Cinnamic acid. Source: PubChem.



Biology 2022, 11, 624 13 of 24

4.10. Plumbagin

Plumbagin (IUPAC: 5-hydroxy-2-methylnaphthalene-1,4-dione), (Figure 16) is a phy-
tochemical from the roots of the Plumbago zeylanica plant [90]. It is a secondary naphtho-
quinone derivative known to exhibit a variety of biological activities such as cell prolifera-
tion in mammals [115], fungus [116] and bacterial cells [117]. The antimicrobial properties
do not affect E.coli, S. typhimurium [118]. Acharya and coworkers, through their ex-vivo
experiment demonstrated the binding of plumbagin with cellular microtubules in the
colchicine cavity, cell viability experiments gave the IC50 value of 14.6 µm [119]. The
structural similarity of Fts-Z with that of tubulin has caused many scientists to work on this
and plumbagin was found to inhibit Fts-Z in B. subtilis 168 in a dose dependent manner.
Further in-silico studies showed the possible binding site located at residues D199 and
V307 [120].

Biology 2022, 11, x FOR PEER REVIEW 12 of 23 
 

 

lowed with 105.96 ± 6.3 µM, 238.91 ± 7.1 µM, 189.53 ± 3.7 µM, respectively. 2,4,5-tri-
methoxy cinnamic acid, 3,4-dimethoxy cinnamic acid and eugenol were the least potent 
(IC50 < 250 µM.). Light scattering experiments and circular dichroism studies supported 
the results. The in-silico studies indicated that the binding of phenylpropanoids happens 
not less than a residue in the T7 loop which is considered to be most important in the Fts-
Z structure. Some other compounds which have inhibitory effects against Fts-Z were phe-
nyl acrylamide [111,112], vanillin derivative 3a and 4u which have been tested against S. 
aureus, S. pyogenes and M. tuberculosis [112–114] 

 
Figure 15. Phenylpropanoids group inhibiting Fts-Z: (A) Chlorogenic acid; (B) p-Coumaric acid; (C) 
Caffeic acid; (D) 2,4,5-Trimethoxycinnamic acid.; (E) Cinnamic acid. Source: PubChem. 

4.10. Plumbagin 
Plumbagin (IUPAC: 5-hydroxy-2-methylnaphthalene-1,4-dione), (Figure 16) is a 

phytochemical from the roots of the Plumbago zeylanica plant [90]. It is a secondary naph-
thoquinone derivative known to exhibit a variety of biological activities such as cell pro-
liferation in mammals [115], fungus [116] and bacterial cells [117]. The antimicrobial prop-
erties do not affect E.coli, S. typhimurium [118]. Acharya and coworkers, through their ex-
vivo experiment demonstrated the binding of plumbagin with cellular microtubules in 
the colchicine cavity, cell viability experiments gave the IC50 value of 14.6 µm [119]. The 
structural similarity of Fts-Z with that of tubulin has caused many scientists to work on 
this and plumbagin was found to inhibit Fts-Z in B. subtilis 168 in a dose dependent man-
ner. Further in-silico studies showed the possible binding site located at residues D199 
and V307 [120]. 

 
Figure 16. Plumbagin Structure. Mol. Formula—C11H8O3; Mol. Wt.—188.18; Dissociation constant 
(KD) 20.7 ± 5.6 µM [115]. Source: PubChem-10205. 

4.11. Totarol 
Totarol, a diterpene phenolic phytocompound, (IUPAC: (4bS,8aS)-4b,8,8-trimethyl-

1-propan-2-yl-5,6,7,8a,9,10-hexahydrophenanthren-2-ol) (Figure 17), is obtained from a 
conifer (Podocarpus totara) and showed activity against M. tuberculosis and B. subtilis 
[121,122]. Although totarol was shown to have high anti-bacterial action against a variety 
of Gram-positive bacteria, it had no effect on Gram-negative bacteria and no antifungal 
properties as well. The experiments done indicated that totarol did not disrupt the B. sub-
tilis membrane or nucleoid segregation, it only affected the functioning of the Z-ring. 

Figure 16. Plumbagin Structure. Mol. Formula—C11H8O3; Mol. Wt.—188.18; Dissociation constant
(KD) 20.7 ± 5.6 µM [115]. Source: PubChem-10205.

4.11. Totarol

Totarol, a diterpene phenolic phytocompound, (IUPAC: (4bS,8aS)-4b,8,8-trimethyl-
1-propan-2-yl-5,6,7,8a,9,10-hexahydrophenanthren-2-ol) (Figure 17), is obtained from a
conifer (Podocarpus totara) and showed activity against M. tuberculosis and B. subtilis [121,122].
Although totarol was shown to have high anti-bacterial action against a variety of Gram-
positive bacteria, it had no effect on Gram-negative bacteria and no antifungal properties as
well. The experiments done indicated that totarol did not disrupt the B. subtilis membrane
or nucleoid segregation, it only affected the functioning of the Z-ring.

Biology 2022, 11, x FOR PEER REVIEW 13 of 23 
 

 

 
Figure 17. Totarol structure, Mol. Formula—C20H30O; Mol. Wt.—286.5; Experimental Details—MIC 
against B. subtilis = 2 µM, S. aureus = 5.4 µM, M. tuberculosis = 16 µg mL−1; Dissociation constant KD = 
11 ± 2.3 µM [121]. Source: PubChem-CID 92783. 

4.12. Viriditoxin 

Viriditoxin (IUPAC: methyl 2-[(3S)-6-[(3S)-9,10-dihydroxy-7-methoxy-3-(2-methoxy-
2-oxoethyl)-1-oxo-3,4-dihydrobenzo[g]isochromen-6-yl]-9,10-dihydroxy-7-methoxy-1-
oxo-3,4-dihydrobenzo[g]isochromen-3-yl]acetate), (Figure 18) a cytotoxic compound ob-
tained from fungus Aspergillus sp. (MF6890) was found to inhibit the bacterial Fts-Z 
polymerization by Wang and co-workers in 2003 [14]. The IC50 values for E. coli GTPase 
activity were 7.0 µg mL−1, for polymerization were 8.2 µg mL−1 and found to elongate B. 
subtilis cells. Another group of researchers isolated this compound from the fungus Paeci-
lomyces variotii derived from jellyfish and found that viriditoxin stabilized microtubule 
polymers in SK-OV-3 cells and exhibited antimitotic and antimetastatic potential. 

 
Figure 18. Viriditoxin Structure. Mol. Formula—C34H30O14; Mol. Wt.—662.6; inhibited Fts-Z 
polymerization (IC50 = 8.2 µgmL−1), GTPase inhibition (IC50 = 7.0 µgmL−1) [14]. Source: PubChem-
53343291. 

Viriditoxin is also effective against a wide range of drug-resistant Gram-positive in-
fections, including S. aureus (MIC 4–8 µg mL−1), and E. faecium (MIC 2–16 µg mL−1). Induc-
ing Fts-Z expression in bacterial cells may increase the MIC value, suggesting that viridi-
toxin targets Fts-Z in these bacterial strains. Viriditoxin can induce B. subtilis cells to elon-
gate, according to morphological research [94]. 

4.13. Recent Reports 
Three compounds Seltsamiayu, Galinsogisoliyu and 1H-2-Benzopyran-1-one,6,8-di-

hydroxy-3-(2-hydroxypropyl) from Seltsamia galinsogisoli Tianyuan Zhang & Yixuan 
Zhang, sp. nov. MB 820393, showed antimicrobial activity for S. aureus with MIC value of 
75, 25, 32 µg mL−1 respectively and the in-silico docking showed a binding affinity of −109, 
−125, −113 kcal mol−1 respectively for Fts-Z protein of S. aureus (PDB ID—3VOB) [123]. 
Another research on Dysosma versipellis showed that the 4’-demethylepipodophyllo-
toxin compound had GTPase activity for Fts-Z of Xanthomonas oryzae pv. oryzae (Xoo), 
a plant vascular pathogen with an EC50 value of 38.7 mgL−1 yielding to filamentous cell 
growth as observed through transmission electron microscope and fluorescence micro-
scopic imaging. The in-silico docking showed strong interactions at residues Asp 38, Arg 

Figure 17. Totarol structure, Mol. Formula—C20H30O; Mol. Wt.—286.5; Experimental Details—MIC
against B. subtilis = 2 µM, S. aureus = 5.4 µM, M. tuberculosis = 16 µg mL−1; Dissociation constant
KD = 11 ± 2.3 µM [121]. Source: PubChem-CID 92783.

4.12. Viriditoxin

Viriditoxin (IUPAC: methyl 2-[(3S)-6-[(3S)-9,10-dihydroxy-7-methoxy-3-(2-methoxy-2-
oxoethyl)-1-oxo-3,4-dihydrobenzo[g]isochromen-6-yl]-9,10-dihydroxy-7-methoxy-1-oxo-3,4-
dihydrobenzo[g]isochromen-3-yl]acetate), (Figure 18) a cytotoxic compound obtained from
fungus Aspergillus sp. (MF6890) was found to inhibit the bacterial Fts-Z polymerization



Biology 2022, 11, 624 14 of 24

by Wang and co-workers in 2003 [14]. The IC50 values for E. coli GTPase activity were
7.0 µg mL−1, for polymerization were 8.2 µg mL−1 and found to elongate B. subtilis cells.
Another group of researchers isolated this compound from the fungus Paecilomyces vari-
otii derived from jellyfish and found that viriditoxin stabilized microtubule polymers in
SK-OV-3 cells and exhibited antimitotic and antimetastatic potential.

Biology 2022, 11, x FOR PEER REVIEW 13 of 23 
 

 

 
Figure 17. Totarol structure, Mol. Formula—C20H30O; Mol. Wt.—286.5; Experimental Details—MIC 
against B. subtilis = 2 µM, S. aureus = 5.4 µM, M. tuberculosis = 16 µg mL−1; Dissociation constant KD = 
11 ± 2.3 µM [121]. Source: PubChem-CID 92783. 

4.12. Viriditoxin 

Viriditoxin (IUPAC: methyl 2-[(3S)-6-[(3S)-9,10-dihydroxy-7-methoxy-3-(2-methoxy-
2-oxoethyl)-1-oxo-3,4-dihydrobenzo[g]isochromen-6-yl]-9,10-dihydroxy-7-methoxy-1-
oxo-3,4-dihydrobenzo[g]isochromen-3-yl]acetate), (Figure 18) a cytotoxic compound ob-
tained from fungus Aspergillus sp. (MF6890) was found to inhibit the bacterial Fts-Z 
polymerization by Wang and co-workers in 2003 [14]. The IC50 values for E. coli GTPase 
activity were 7.0 µg mL−1, for polymerization were 8.2 µg mL−1 and found to elongate B. 
subtilis cells. Another group of researchers isolated this compound from the fungus Paeci-
lomyces variotii derived from jellyfish and found that viriditoxin stabilized microtubule 
polymers in SK-OV-3 cells and exhibited antimitotic and antimetastatic potential. 

 
Figure 18. Viriditoxin Structure. Mol. Formula—C34H30O14; Mol. Wt.—662.6; inhibited Fts-Z 
polymerization (IC50 = 8.2 µgmL−1), GTPase inhibition (IC50 = 7.0 µgmL−1) [14]. Source: PubChem-
53343291. 

Viriditoxin is also effective against a wide range of drug-resistant Gram-positive in-
fections, including S. aureus (MIC 4–8 µg mL−1), and E. faecium (MIC 2–16 µg mL−1). Induc-
ing Fts-Z expression in bacterial cells may increase the MIC value, suggesting that viridi-
toxin targets Fts-Z in these bacterial strains. Viriditoxin can induce B. subtilis cells to elon-
gate, according to morphological research [94]. 

4.13. Recent Reports 
Three compounds Seltsamiayu, Galinsogisoliyu and 1H-2-Benzopyran-1-one,6,8-di-

hydroxy-3-(2-hydroxypropyl) from Seltsamia galinsogisoli Tianyuan Zhang & Yixuan 
Zhang, sp. nov. MB 820393, showed antimicrobial activity for S. aureus with MIC value of 
75, 25, 32 µg mL−1 respectively and the in-silico docking showed a binding affinity of −109, 
−125, −113 kcal mol−1 respectively for Fts-Z protein of S. aureus (PDB ID—3VOB) [123]. 
Another research on Dysosma versipellis showed that the 4’-demethylepipodophyllo-
toxin compound had GTPase activity for Fts-Z of Xanthomonas oryzae pv. oryzae (Xoo), 
a plant vascular pathogen with an EC50 value of 38.7 mgL−1 yielding to filamentous cell 
growth as observed through transmission electron microscope and fluorescence micro-
scopic imaging. The in-silico docking showed strong interactions at residues Asp 38, Arg 

Figure 18. Viriditoxin Structure. Mol. Formula—C34H30O14; Mol. Wt.—662.6; inhib-
ited Fts-Z polymerization (IC50 = 8.2 µgmL−1), GTPase inhibition (IC50 = 7.0 µgmL−1) [14].
Source: PubChem-53343291.

Viriditoxin is also effective against a wide range of drug-resistant Gram-positive
infections, including S. aureus (MIC 4–8 µg mL−1), and E. faecium (MIC 2–16 µg mL−1).
Inducing Fts-Z expression in bacterial cells may increase the MIC value, suggesting that
viriditoxin targets Fts-Z in these bacterial strains. Viriditoxin can induce B. subtilis cells to
elongate, according to morphological research [94].

4.13. Recent Reports

Three compounds Seltsamiayu, Galinsogisoliyu and 1H-2-Benzopyran-1-one,6,8-dihydroxy-
3-(2-hydroxypropyl) from Seltsamia galinsogisoli Tianyuan Zhang & Yixuan Zhang, sp.
nov. MB 820393, showed antimicrobial activity for S. aureus with MIC value of 75, 25,
32 µg mL−1 respectively and the in-silico docking showed a binding affinity of −109,
−125, −113 kcal mol−1 respectively for Fts-Z protein of S. aureus (PDB ID—3VOB) [123].
Another research on Dysosma versipellis showed that the 4’-demethylepipodophyllotoxin
compound had GTPase activity for Fts-Z of Xanthomonas oryzae pv. oryzae (Xoo), a plant
vascular pathogen with an EC50 value of 38.7 mgL−1 yielding to filamentous cell growth as
observed through transmission electron microscope and fluorescence microscopic imaging.
The in-silico docking showed strong interactions at residues Asp 38, Arg 205 of Fts-Z
protein of Xoo and the results were further strengthened with in-vivo bioassays which
showed good curative and protective activities [124]. Another natural anthraquinone
dye purpurin was also found to exhibit Fts-Z assembly perturbation in concentration
dependent manner, by a group of researchers. In their in-vitro experiment the dissociation
constant was 11 µM. It was found to bind near the nucleotide binding site and reduced
GTP hydrolysis [125,126]. Naturally occurring indole alkaloids are yet another group of
interest to target Fts-Z protein as studies indicate the presence of protein and enzyme
inhibition potential in them. One such bis-indole containing alkaloid 34 from Chaetomium
sp. SYP-F7950 of Panax notoginseng, an endophytic fungus showed anti-bacterial activity for
S. aureus, B. subtilis, E. faecium and had MIC value of 0.12–3.6 µg mL−1 which was far better
than vancomycin (MIC: 1.5–10 µg/mL) [127]. Another study targets Fts-Z protein through
a cyanobacterial compound using in-silico and in-vitro methods and Alpha dimorphecolic
acid was shown to have good anti-bacterial activity with a MIC of 512 µg mL−1 [128]. Some
other synthetic molecules which have Fts-Z inhibition caliber are in Table 2.



Biology 2022, 11, 624 15 of 24

Table 2. Synthetic and semi-synthetic inhibitors over natural inhibitors.

Compound Target Organism Action Mechanism Assay Used MIC/IC50 Ref.

Zantrin Broad range

Z1, Z2, Z4 destabilize
Fts-Z assembly; Z5

hyper stabilize Fts-Z
assembly.

Real time enzyme
coupled fluorescent

GTPase assay.

E. coli = 4–25 µM
M. tuberculosis =

30–70 µM
[129]

Amikacin E. coli Z-ring perturbation Cell elongation 4 µg mL−1 [130]

A-189 E. coli, S. aureus
GTPase inhibition

and Z-ring assembly
inhibition

Anucleate cell blue
assay. 16 µg mL−1 [131]

GTP analogue E. coli, S. aureus GTPase inhibition
Spectrophotometric
coupled enzymatic

assay
MeOGTP-IC50 = 15 µM [132]

PC190723 B. subtilis, S. aureus
(MRSA)

Binds H7 loop
affecting GTPase
activity causing

Z-ring mis
localization

Whole cell-based
assay leading to

filamentous
phenotype

0.5 µg mL−1 [133]

SRI-3072 M. tuberculosis
Inhibition of Fts-Z

polymerization and
GTPase activity

Antimicrobial assay 19 µM [134]

Taxanes M. tuberculosis
Stabilizes Fts-Z

against
depolymerization

Real-time PCR based
assay, Cell

filamentation
1.25−2.5 µM [76]

2-carbamoyl
pteridine M. tuberculosis

GTPase activity
inhibition and Fts-Z

polymerization

GTPase activity and
Fts-Z polymerization

through in vitro
technique

2 µg mL−1 [135]

534F6 derivatives E. coli Cell division
inhibition

Microorganisms
lacking MDR pumps

were used for
screening

>80 µM [136]

Bis indole methane
(2,2′-bisindole)

M. tuberculosis, M.
segmentis, H37Rv

strain
Cell division

inhibition

GTPase activity, Cell
proliferation,

Antimycobacterial
property

62.5 µg mL−1 [137]

5-Methyl-11-((3-(3-(4-
methylpyridine))-
propyl benzo[d]

thiazol-2(3H)-ylidene)
methyl)

benzofuro[3,2-b]
quinolin-5-ium

iodide)

B. subtilis, S. aureus,
E. coli

GTPase activity,
Polymerization of

Fts-Z

Cell based antibiotic
screening assay,

Biochemical assay,
Light scattering assay

0.5, 2, 4 µg mL−1

respectively
[138]

4.14. Natural Compounds over Synthetic Drugs: A Comparison

Natural products (NPs) have been an inexhaustible source of therapeutic drugs since
ancient times and numerous effective molecules have been synthesized to resemble the
activity of natural compounds [139]. Almost all natural compounds have specialized
biological functions for which they bind to receptors. These have pros and cons over
the synthetic molecules. When compared to synthetic compound libraries, they typically
have an increased molecular mass, more SP3 carbon and oxygen atoms but fewer nitrogen
and halogen atoms, more H-bond acceptors and donors, lower calculated octanol–water
partition coefficients (cLogP values, indicating higher hydrophilicity), and lesser molecular
flexibility. These distinctions can be beneficial; for example, the increased rigidity of NPs
can be beneficial in drug development for protein–protein interactions [140,141]. The
improved methods of extracting, screening and profiling have given researchers powerful
tools in the hands of researchers to explore NPs in more advanced ways.

Antibiotics are being used to cure human, veterinary and plant diseases and increase
the growth and life expectancy but research suggest the long term usage of antibiotics
increases negative effects on the treated organisms [142]. There are more than 250 chemical



Biology 2022, 11, 624 16 of 24

substances registered to be used in different countries for humans and farm animals [143].
Antibiotics given to animals in food or water to increase their growth and to protect
them from infections developing in them due to unhealthy living conditions. When
they are not completely metabolized in the body, they are discharged by the process of
adsorption/desorption into the environment as contaminants. They then enter the food
chain via manure application or grazing animals and accumulate in edible plant parts [144].
Some of them also ingested through meat into the human body [145]. Certain studies
show deleterious effects, delayed germination and post germinative development in plants
due to antibiotics [131]. The presence of antibiotics in soil, groundwater, poultry meat
and other plant and animal-based products and the side effects caused by antibiotics in
environment are staggering which has caused the scientific community and agencies to
reassess their use [146–153]. Thus, more efforts are being made to employ natural products
for fighting pathogens.

5. Discussion

Fts-Z is an important cytoskeleton protein that is currently being explored and targeted
by several natural and synthetic compounds in a number of pathogenic bacterial species.
Many bacterial cytoskeletal proteins such as MreB, ParM, and MamK, Min C and Zap
proteins similar to Fts-Z or with any new activities are also being investigated as potential
antibiotic discovery candidates [154]. The key cell division proteins targets are highly
conserved in most of the bacteria [65], however, there are a number of other proteins unique
to each genus are very promising [155]. Hence, inhibiting these could be an alternative
strategy for the discovery for characterization of novel antimicrobial drug targets.

Most antibiotics from the present generation primarily target either cell wall biosyn-
thesis or protein/nucleic acid synthesis [156]. Exploring and analyzing comprehensive data
on Fts-Z structure is also done in the recent years revealing its functional mechanisms [157].
Many successful studies has been conducted with natural inhibitors to target bacteria such
as S. aureus, E. coli, B. subtilis, VRE, M. tuberculosis. Though, several studies have been
conducted with both natural and synthetic inhibitors, in this review we have covered the
significant studies on the natural inhibitor of Fts-Z performed in recent years

Primarily, the natural compounds or their synthetic derivatives which exhibit a poten-
tial binding affinity with Fts-Z are being studied as a drug candidates [72–75]. Amongst
the presently known inhibitors, viriditoxin showed a broad spectrum of activity by in-
hibiting GTPase and polymerizing Fts-Z [123]. Other compounds that have also been
studied are sanguinarines [28,89], totarols [121,122], dichamanetins [107], 2′′′-hydroxy-
5′′-benzylisouvarinol-B [107], zantrins [129], curcumin [105], and cinnamaldehyde [94].
Some of the natural inhibitors show a strong activity through either GTPase inhibition or
polymerizing activity.

Such activities were tested for both Gram-positive and Gram-negative bacteria. Some
studies were performed using in-vitro techniques while others used in-silico and in-vivo
experiment. After such extensive research on this target, compounds like TXA 709, a
prodrug was studied in the phase I trials [59], thus increases the interest of scientists to
find a drug to target this crucial protein necessary for divisome machinery. Additionally, it
has recently been demonstrated that TXA707 acts synergistically with the third-generation
cephalosporin cefdinir against several multidrug-resistant S. aureus [158]. Thus, medicinal
chemists are working intensively on combinatorial therapies to increase the efficiency of
drugs along with broadening the drug spectrum against tuberculosis, HIV and cancer and
also to include Gram-negative microorganisms.

Another benzamide derivative PC190723 has selectively potent anti-staphylococcal
activity (MIC < 2.81 µg mL−1) and has sown a seed for further trials in this direction. Further
drugs are being worked on having similar structural scaffolding as of PC190723 [133].

In this regard, investigations on the combination of PC190723 prodrug (TXY436) with
an efflux-pump inhibitor (i.e., PAβN) revealed that the presence of sub-inhibitory con-
centrations of PAβN confers TXY436 with activity against Gram-negative strains (namely,



Biology 2022, 11, 624 17 of 24

E. coli, P. aeruginosa, and A. baumannii). It is envisaged that these impressive results, along
with the previously reported Fts-Z inhibitors [128], will pave the way for the creation of a
new class of anti-bacterial chemical entities that will inhibit bacterial cytokinesis and have
substantial therapeutic utility.

The natural inhibitors of Fts-Z showing comparable inhibition activities need to be
taken further for in-vivo and clinical trials as they would certainly be comparatively less
toxic than the synthetic compounds/inhibitors.

Research suggests the viability of Fts-Z as promising anti-bacterial target [13,49–51]. It
was suggested that an early generation of resistance might occur in new drugs, as happens
in other single-target inhibitors which although this can be prevented/avoided by tactical
and amenable use of combination therapy. Another point of concern is that most Fts-Z
inhibitors to date are broad-spectrum anti-bacterial which damage the host flora and fauna
and thus should be put off if feasible [35,100]. In addition to this, these broad spectrum
antibiotics aid the bacterial stress response, elevating the chance of bypassing the host’s
innate immune response [51–53]. There is also need to check if bacterial cells regain normal
division pattern once the inhibitor is removed using the fragmentation of the filament
technique [54].

Another important point of concern is that Fts-Z is homologous to tubulin, although
without any homology in amino acid sequence yet there is a need for critical evaluation of
its impact on the function of tubulin in hosts [55,56]. Some studies also showed that for suc-
cessful inhibition of beta lactams, well-functioning cell division machinery mandatory [57].
We need to keep the above mentioned points and related works in mind while developing
Fts-Z inhibitors for the clinical trials.

6. Conclusions

Targeting bacterial divisome protein Fts-Z is emerging as a promising strategy for the
identification of new antibiotic compounds as well as to deal with AMR. Several studies re-
ported that Fts-Z inhibitors could provide scaffolds and pharmacophores for the further de-
velopment of novel anti-bacterial agents. In the pursuit of novel anti-bacterial compounds,
targeting natural products are gaining significant attention as synthetic compounds are lead-
ing to development of several antibiotic resistant strains of bacteria. Natural compounds
are always the safest substitute in terms of toxicity, environmental persistence and effects
on non-target organisms. A few potential compounds discussed in this review are believed
to be promising, however, how these inhibitors performed in the future research; will set
the fine course for the anti-bacterial drug development using the natural compounds.

Author Contributions: Conceptualization, A.C. and A.R.; writing—original draft preparation, M.G.;
writing—review and editing, A.C., A.R., H.S.T. and K.D.; supervision, T.J. and R.L.; project adminis-
tration, T.J.; funding acquisition, M.F.A. and S.H. All authors have read and agreed to the published
version of the manuscript.

Funding: This work was supported by the AlMaarefa University, Riyadh, Saudi Arabia, (grant
number-TUMA-2021-53).

Institutional Review Board Statement: Not applicable.

Informed Consent Statement: Not applicable.

Data Availability Statement: Not applicable.

Acknowledgments: The authors are grateful to the founder president of Amity University Ashok K.
Chauhan for motivating, providing all facilities, and constant support.

Conflicts of Interest: The authors declare no conflict of interest.



Biology 2022, 11, 624 18 of 24

Abbreviations

AMR Anti Microbial Resistance
ATCC American Type Culture Collection
ESKAPE Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii,

Pseudomonas aeruginosa, and Enterobacter species
GTP Guanosine-5’-triphosphate
MRSA Methicillin-resistant Staphylococcus aureus
MGEs Mobile Genetic Elements
NDM New Delhi Metallo beta-lactamase-I
MDR Multi Drug Resistance
PDR Pan drug-resistant
VRSA Vancomycin-resistant Staphylococcus aureus
WHO World Health Organization
NP Natural Products
VRE Vancomycin-Resistant Enterococci

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