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FtsA is a bacterial protein that is related to
FtsA, like actin and its homologs, is an ATPase. While the exact catalytic mechanism of FtsA is not fully understood, 
FtsA binds directly to the conserved C-terminal domain of FtsZ. This FtsA-FtsZ interaction is likely involved in regulating FtsZ polymer dynamics. In vitro, ''E. coli'' FtsA disassembles FtsZ polymers in the presence of ATP, both in solution, as FtsA* and on supported lipid bilayers. ''E. coli'' FtsA itself does not assemble into detectable structures except when on membranes, where it forms dodecameric minirings that often pack in clusters and bind to single FtsZ protofilaments. In contrast, FtsA* forms arcs on lipid membranes but rarely closed minirings, supporting genetic evidence that this mutant has a weaker FtsA-FtsA interface. When bound to the membrane, FtsA*-like mutants, which also can form double-stranded filaments, enhance close lateral interactions between FtsZ protofilaments, in contrast to FtsA, which keeps FtsZ protofilaments apart. As FtsZ protofilament bundling may be important for promoting septum formation, a switch from an FtsA-like to an FtsA*-like conformation during cell cycle progression may serve to turn on septum synthesis enzymes (FtsWI) as well as condense FtsZ polymers, setting up a positive feedback loop. In support of this model, the cytoplasmic domain of FtsN, which activates FtsWI in ''E. coli'' and interacts directly with the 1C subdomain of FtsA, switches FtsA from the miniring form to the double stranded filament form on lipid surfaces in vitro. These double filaments of ''E. coli'' FtsA are antiparallel, indicating that they themselves do not treadmill like FtsZ filaments.
Although E. coli FtsA has been the most extensively studied, more is becoming understood about FtsA proteins from other species. FtsA from ''Streptococcus pneumoniae'' forms helical filaments in the presence of ATP, but no interactions with FtsZ in vitro have been reported yet. FtsA colocalizes with FtsZ in ''S. pneumoniae'', but also is required for FtsZ ring localization, in contrast to ''E. coli'' where FtsZ rings remain localized upon inactivation of FtsA. FtsA from ''Staphylococcus aureus'' forms actin-like filaments similar to those of FtsA from ''Thermotoga maritima''. In addition, ''S. aureus'' FtsA enhances the GTPase activity of FtsZ. In a liposome system, FtsA* stimulates FtsZ to form rings that can divide liposomes, mimicking cytokinesis in vitro.
actin
Actin is a family of globular multi-functional proteins that form microfilaments in the cytoskeleton, and the thin filaments in muscle fibrils. It is found in essentially all eukaryotic cells, where it may be present at a concentration of ...
by overall structural similarity and in its ATP binding pocket. It is involved in bacterial cell division
Cell division is the process by which a parent cell (biology), cell divides into two daughter cells. Cell division usually occurs as part of a larger cell cycle in which the cell grows and replicates its chromosome(s) before dividing. In eukar ...
, where it serves to tether the cytokinetic ring formed by FtsZ
FtsZ is a protein encoded by the ''ftsZ'' gene that assembles into a ring at the future site of bacterial cell division (also called the Z ring). FtsZ is a prokaryotic homologue of the eukaryotic protein tubulin. The initials FtsZ mean "Filame ...
to the cytoplasmic membrane prior to division.
Along with other bacterial actin homologs such as MreB
MreB is a protein found in bacteria that has been identified as a homologue of actin, as indicated by similarities in tertiary structure and conservation of active site peptide sequence. The conservation of protein structure suggests the commo ...
, ParM
ParM is a prokaryotic actin homologue which provides the force to drive copies of the R1 plasmid to opposite ends of rod shaped bacteria before cytokinesis.
ParM is a monomer that is encoded in the DNA of the R1 plasmid and manufactured by the ho ...
, and MamK, these proteins suggest that eukaryotic
The eukaryotes ( ) constitute the Domain (biology), domain of Eukaryota or Eukarya, organisms whose Cell (biology), cells have a membrane-bound cell nucleus, nucleus. All animals, plants, Fungus, fungi, seaweeds, and many unicellular organisms ...
actin has a common ancestry. Like the other bacterial actins, FtsA binds ATP and can form actin-like filaments. The FtsA-FtsA interface has been defined by structural as well as genetic analysis. Although present in many diverse Gram-positive
In bacteriology, gram-positive bacteria are bacteria that give a positive result in the Gram stain test, which is traditionally used to quickly classify bacteria into two broad categories according to their type of cell wall.
The Gram stain is ...
and Gram-negative
Gram-negative bacteria are bacteria that, unlike gram-positive bacteria, do not retain the crystal violet stain used in the Gram staining method of bacterial differentiation. Their defining characteristic is that their cell envelope consists ...
species, FtsA is absent in actinobacteria and cyanobacteria
Cyanobacteria ( ) are a group of autotrophic gram-negative bacteria that can obtain biological energy via oxygenic photosynthesis. The name "cyanobacteria" () refers to their bluish green (cyan) color, which forms the basis of cyanobacteri ...
. FtsA also is structurally similar to PilM, a type IV pilus
A pilus (Latin for 'hair'; : pili) is a hair-like cell-surface appendage found on many bacteria and archaea. The terms ''pilus'' and '' fimbria'' (Latin for 'fringe'; plural: ''fimbriae'') can be used interchangeably, although some researchers ...
ATPase
ATPases (, Adenosine 5'-TriPhosphatase, adenylpyrophosphatase, ATP monophosphatase, triphosphatase, ATP hydrolase, adenosine triphosphatase) are a class of enzymes that catalyze the decomposition of ATP into ADP and a free phosphate ion or ...
.
Function
FtsA is required for propercytokinesis
Cytokinesis () is the part of the cell division process and part of mitosis during which the cytoplasm of a single eukaryotic cell divides into two daughter cells. Cytoplasmic division begins during or after the late stages of nuclear division ...
in bacteria such as ''Escherichia coli'', ''Caulobacter crescentus'', and ''Bacillus subtilis''. Originally isolated in a screen for ''E. coli'' cells that could divide at 30˚C but not at 40˚C, FtsA stands for "filamentous temperature sensitive A". Many thermosensitive alleles of ''E. coli ftsA'' exist, and all map in or near the ATP binding pocket. Suppressors that restore normal function map either to the binding pocket or to the FtsA-FtsA interface.
FtsA, like actin and its homologs, is an ATPase. While the exact catalytic mechanism of FtsA is not fully understood, glutamic acid
Glutamic acid (symbol Glu or E; known as glutamate in its anionic form) is an α- amino acid that is used by almost all living beings in the biosynthesis of proteins. It is a non-essential nutrient for humans, meaning that the human body can ...
Glu14 in the FtsA of ''Escherichia coli'' is indicated as a key residue involved in catalysis, as mutation of this residue impairs the enzyme's ability to hydrolyze
Hydrolysis (; ) is any chemical reaction in which a molecule of water breaks one or more chemical bonds. The term is used broadly for substitution, elimination, and solvation reactions in which water is the nucleophile.
Biological hydrolysis ...
ATP, in addition to halting phospholipid vesicle remodeling and Z-ring assembly ''in vivo.'' During cell division, FtsA self-polymerizes to form long, antiparallel double filaments that then localize to the cytokinetic ring formed by FtsZ (Z ring). This occurs via a conserved C-terminal amphipathic helix, forming an "A ring" in the process. Removal of this helix results in the formation of very long and stable polymer bundles of FtsA in the cell that do not function in cytokinesis. Another essential division protein, ZipA, also tethers the Z ring to the membrane and exhibits overlapping function with FtsA. FtsZ, FtsA and ZipA together are called the proto-ring because they are involved in a specific initial phase of cytokinesis. Another subdomain of FtsA (2B) is required for interactions with FtsZ, via the conserved C-terminus of FtsZ. Other FtsZ regulators including MinC and ZipA bind to the same C terminus of FtsZ. Finally, subdomain 1C, which is in a unique position relative to MreB and actin, is required for FtsA to recruit downstream cell division proteins such as FtsN.
Although FtsA is essential for viability in ''E. coli'', it can be deleted in ''B. subtilis''. ''B. subtilis'' cells lacking FtsA divide poorly but still survive. Another FtsZ-interacting protein, SepF (originally named YlmF; ), is able to replace FtsA in ''B. subtilis'', suggesting that SepF and FtsA have overlapping functions.
An allele of FtsA called FtsA* (R286W) is able to bypass the normal requirement for the ZipA in ''E. coli'' cytokinesis. FtsA* also causes cells to divide at a shorter cell length than normal, suggesting that FtsA may normally receive signals from the septum synthesis machinery to regulate when cytokinesis can proceed. Other FtsA*-like alleles have been found, and they mostly decrease FtsA-FtsA interactions. Oligomeric state of FtsA is likely important for regulating its activity, its ability to recruit the later cell division proteins and its ability to bind ATP. Other cell division proteins of ''E. coli'', including FtsN and the ABC transporter homologs FtsEX, seem to regulate septum constriction by signaling through FtsA, and the FtsQLB subcomplex is also involved in promoting FtsN-mediated septal constriction.
FtsA binds directly to the conserved C-terminal domain of FtsZ. This FtsA-FtsZ interaction is likely involved in regulating FtsZ polymer dynamics. In vitro, ''E. coli'' FtsA disassembles FtsZ polymers in the presence of ATP, both in solution, as FtsA* and on supported lipid bilayers. ''E. coli'' FtsA itself does not assemble into detectable structures except when on membranes, where it forms dodecameric minirings that often pack in clusters and bind to single FtsZ protofilaments. In contrast, FtsA* forms arcs on lipid membranes but rarely closed minirings, supporting genetic evidence that this mutant has a weaker FtsA-FtsA interface. When bound to the membrane, FtsA*-like mutants, which also can form double-stranded filaments, enhance close lateral interactions between FtsZ protofilaments, in contrast to FtsA, which keeps FtsZ protofilaments apart. As FtsZ protofilament bundling may be important for promoting septum formation, a switch from an FtsA-like to an FtsA*-like conformation during cell cycle progression may serve to turn on septum synthesis enzymes (FtsWI) as well as condense FtsZ polymers, setting up a positive feedback loop. In support of this model, the cytoplasmic domain of FtsN, which activates FtsWI in ''E. coli'' and interacts directly with the 1C subdomain of FtsA, switches FtsA from the miniring form to the double stranded filament form on lipid surfaces in vitro. These double filaments of ''E. coli'' FtsA are antiparallel, indicating that they themselves do not treadmill like FtsZ filaments.
Although E. coli FtsA has been the most extensively studied, more is becoming understood about FtsA proteins from other species. FtsA from ''Streptococcus pneumoniae'' forms helical filaments in the presence of ATP, but no interactions with FtsZ in vitro have been reported yet. FtsA colocalizes with FtsZ in ''S. pneumoniae'', but also is required for FtsZ ring localization, in contrast to ''E. coli'' where FtsZ rings remain localized upon inactivation of FtsA. FtsA from ''Staphylococcus aureus'' forms actin-like filaments similar to those of FtsA from ''Thermotoga maritima''. In addition, ''S. aureus'' FtsA enhances the GTPase activity of FtsZ. In a liposome system, FtsA* stimulates FtsZ to form rings that can divide liposomes, mimicking cytokinesis in vitro.
Structure
Several crystal structures for FtsA are known, including a structure for ''E. coli'' FtsA. Compared to MreB and eukaryotic actin, the subdomains are rearranged, and the 1B domain is swapped out for the SHS2 "1C" insert.References
{{reflist Bacterial proteins Cytoskeleton