FtsZ
FtsZ is a protein encoded by the ftsZ gene that assembles into a ring at the future site of the septum of bacterial cell division. This is a prokaryotic homologue to the eukaryotic protein tubulin. FtsZ has been named after "Filamenting temperature-sensitive mutant Z". The hypothesis was that cell division mutants of E. coli would grow as filaments due to the inability of the daughter cells to separate from one another.
History
Discovery of the bacterial cytoskeleton is fairly recent. FtsZ was the first protein of the prokaryotic cytoskeleton to be identified.
The gene was discovered in the 1950s by Y. Hirota (ja:廣田幸敬) and his colleagues in a screen for bacterial cell division mutants.[1] In 1991 it was shown by Erfei Bi and Joseph Lutkenhaus that FtsZ assembled into the Z-ring.
Nuclear-encoded FtsZ in the moss Physcomitrella patens is required for chloroplast division and was the first identified protein essential for organelle division.[2]
Function
During cell division, FtsZ is the first protein to move to the division site, and is essential for recruiting other proteins that produce a new cell wall between the dividing cells. FtsZ's role in cell division is analogous to that of actin in eukaryotic cell division, but, unlike the actin-myosin ring in eukaryotes, FtsZ has no known motor protein associated with it. The origin of the cytokinetic force, thus, remains unclear, but it is believed that the localized synthesis of new cell wall produces at least part of this force. In liposomes Osawa (2009) showed FtsZ is capable of exerting a contractile force with no other proteins present.[3]
Erickson (2009) proposed how the roles of tubulin-like proteins and actin-like proteins in cell division became reversed in an evolutionary mystery.[4] The use of the FtsZ ring in dividing chloroplasts and some mitochondria further establishes their prokaryotic ancestry. It is interesting to note that L-form bacteria that lack a cell wall do not require FtsZ for division, which implies that bacteria may have retained components of an ancestral mode of cell division.[5]
Much is known about the dynamic polymerization activities of tubulin and microtubules, but little is known about these activities in FtsZ. While it is known that single-stranded tubulin protofilaments form into 13 stranded microtubules, the multistranded structure of the FtsZ-containing Z-ring is not known. It is only speculated that the structure consists of overlapping protofilaments.
Recently, proteins similar to tubulin and FtsZ have been discovered in large plasmids found in Bacillus species. They are believed to function as components of segrosomes, which are multiprotein complexes that partition chromosomes/plasmids in bacteria. The plasmid homologs of tubulin/FtsZ seem to have conserved the ability to polymerize into filaments.
The contractile ring
FtsZ has the ability to bind to GTP and also exhibits a GTPase domain that allows it to hydrolyze GTP to GDP and a phosphate group. In vivo, FtsZ forms filaments with a repeating arrangement of subunits, all arranged head-to-tail.[6] These filaments form a ring around the longitudinal midpoint, or septum, of the cell. This ring is called the Z-ring.
The GTP hydrolyzing activity of the protein is not essential to the formation of filaments or division. Mutants lacking the GTPase domain form twisted and disordered septa.[7] These cells with irregular septa can still divide, although abnormally. It is unclear as to whether FtsZ actually provides the physical force that results in division or serves as a marker for other proteins to execute division.
If FtsZ does provide force that divides the cell, it may do so through the relative movement of subunits. Computer models and in vivo measurements suggest that single FtsZ filaments cannot sustain a length more than 30 subunits long. In this model, FtsZ scission force comes from the relative lateral movement of subunits.[8] Lines of FtsZ would line up together parallel and pull on each other creating a "cord" of many strings that tightens itself.
In other models, FtsZ does not provide the contractile force but provides the cell a spatial scaffold for other proteins to execute the division of the cell. This is akin to the creating of a temporary structure by construction workers to access hard-to-reach places of a building. The temporary structure allows unfettered access and ensures that the workers can reach all places. If the temporary structure is not correctly built, the workers will not be able to reach certain places, and the building will be deficient.
The scaffold theory is supported by information that shows that the formation of the ring and localization to the membrane requires the concerted action of a number of accessory proteins. ZipA or the actin homologue FtsA permit initial FtsZ localization to the membrane.[9] Following localization to the membrane, division proteins of the Fts family are recruited for ring assembly.[10] Many of these proteins, such as FtsW, FtsK, and FtsQ are involved in stabilization of the Z ring and may also be active participants in the scission event. The timing of Z-ring formation suggests the possibility of a spatial or temporal signal that permits the formation of FtsZ filaments.
Septal localization and intracellular signaling
The formation of the Z-ring closely coincides with cellular processes associated with replication. Z-ring formation coincides with the termination of genome replication in E. coli and 70% of chromosomal replication in B. subtilis.[11] The timing of Z-ring formation suggests the possibility of a spatial or temporal signal that permits the formation of FtsZ filaments. In Escherichia coli, at least two negative regulators of FtsZ assembly form a bipolar gradient, such that the critical concentration of FtsZ required for FtsZ assembly is lowest at mid-cell between the two segregating chromosomes. This type of regulation seems to occur in other species such as Bacillus subtilis and Caulobacter crescentus. However, other species including Streptococcus pneumoniae and Myxococcus xanthus seem to use positive regulators that stimulate FtsZ assembly at mid-cell.[12]
Communicating distress
FtsZ polymerization is also linked to stressors like DNA damage. DNA damage induces a variety of proteins to be manufactured, one of them called SulA.[13] SulA prevents the polymerization and GTPase activity of FtsZ. SulA accomplishes this task by binding to self-recognizing FtsZ sites. By sequestering FtsZ, the cell can directly link DNA damage to inhibiting cell division.[14]
Preventing DNA damage
Like SulA, there are other mechanisms that prevent cell division that would result in disrupted genetic information sent to daughter cells. So far, two proteins have been identified in E. coli and B. subtilis that prevent division over the nucleoid region: Noc and SlmA. Noc gene knockouts result in cells that divide without respect to the nucleoid region, resulting in its asymmetrical partitioning between the daughter cells. The mechanism is not well understood, but thought to involve sequestration of FtsZ, preventing polymerization over the nucleoid region.[15] SlmA, like SulA, has been observed to sequester FtsZ, preventing the formation of the polymerized Z Ring over the nucleoid region.[16]
References
- Chen JC, Weiss DS, Ghigo JM, Beckwith J (15 January 1999). "Septal Localization of FtsQ, an Essential Cell Division Protein in Escherichia coli". J. Bacteriol. 181 (2): 521–30. PMC 93406. PMID 9882666.
- Löwe J, Amos LA (January 1998). "Crystal structure of the bacterial cell-division protein FtsZ". Nature 391 (6663): 203–6. doi:10.1038/34472. PMID 9428770.
- Romberg L, Levin PA (2003). "Assembly dynamics of the bacterial cell division protein FTSZ: poised at the edge of stability". Annu. Rev. Microbiol. 57: 125–54. doi:10.1146/annurev.micro.57.012903.074300. PMID 14527275.
- Scheffers D, Driessen AJ (September 2001). "The polymerization mechanism of the bacterial cell division protein FtsZ". FEBS Lett. 506 (1): 6–10. doi:10.1016/S0014-5793(01)02855-1. PMID 11591361.
- van den Ent F, Amos L, Löwe J (December 2001). "Bacterial ancestry of actin and tubulin". Current Opinion in Microbiology 4 (6): 634–8. doi:10.1016/S1369-5274(01)00262-4. PMID 11731313.
- Mendieta J, Rico AI, López-Viñas E, Vicente M, Mingorance J, Gómez-Puertas P (May 2009). "Structural and Functional Model for Ionic (K+/Na+) and pH Dependence of GTPase Activity and Polymerization of FtsZ, the Prokaryotic Ortholog of Tubulin". Journal of Molecular Biology. 390 (1): 17–25. doi:10.1016/j.jmb.2009.05.018. PMID 19447111.
- Mingorance J, Rivas G, Vélez, M, Gómez-Puertas P, Vicente M (Aug 2011). "Strong FtsZ is with the force: mechanisms to constrict bacteria". Trends in Microbiology. 18 (8): 348–56. doi:10.1016/j.tim.2010.06.001. PMID 20598544.
- Rowlett, V, Margolin W (2015). "The Min system and other nucleoid-independent regulators of Z ring positioning.". Frontiers in Microbiology 6 (8): 478. doi:10.3389/fmicb.2015.00478. PMID 26029202.
- ↑ Ishikawa,Hajime;Kuroiwa,Tsuneyoshi;Nagata,Kazuhiro. (March 2005). 『細胞生物学事典』. 朝倉書店. pp. 159–160. ISBN 978-4-254-17118-1.
- ↑ R. Strepp, S. Scholz, S. Kruse, V. Speth, R. Reski (1998): Plant nuclear gene knockout reveals a role in plastid division for the homolog of the bacterial cell division protein FtsZ, an ancestral tubulin. Proceedings of the National Academy of Science USA 95: 4368–4373.
- ↑ Masaki Osawa, David E. Anderson, and Harold P. Erickson (2009). "Reconstitution of Contractile FtsZ Rings in Liposomes". Science 320 (7): 792–4. doi:10.1126/science.1154520. PMC 2645864. PMID 18420899.
- ↑ Erickson, Harold P. (2007). "Evolution of the cytoskeleton". BioEssays 29 (7): 668–77. doi:10.1002/bies.20601. PMC 2630885. PMID 17563102.
- ↑ Leaver M, Domínguez-Cuevas P, Coxhead JM, Daniel RA, Errington J (February 2009). "Life without a wall or division machine in Bacillus subtilis". Nature 457 (7231): 849–853. doi:10.1038/nature07742. PMID 19212404.
- ↑ Desai A, Mitchison TJ (1997). "Microtubule polymerization dynamics". Annu Rev Cell Dev Biol 13: 83–117. doi:10.1146/annurev.cellbio.13.1.83. PMID 9442869.
- ↑ Bi EF, Lutkenhaus J (1991). "FtsZ ring structure associated with division in Escherichia coli". Nature 354 (3–5): 161–164. doi:10.1038/354161a0. PMID 1944597.
- ↑ Lan G, Debrowsky TM, Daniels BR, Wirtz D, Sun SX. (2009). "Condensation of FtsZ can Drive Bacterial Cell Division". Proc. Natl. Acad. Sci. 106 (1): 121–126. doi:10.1073/pnas.0807963106. PMC 2629247. PMID 19116281.
- ↑ Pichoff S, Lutkenhaus J (2005). "Tethering the Z ring to the membrane through a conserved membrane targeting sequence in FtsA". Mol Microbiol 55 (6): 1722–1734. doi:10.1111/j.1365-2958.2005.04522.x. PMID 15752196.
- ↑ Buddelmeijer N, Beckwith J (2002). "Assembly of cell division proteins at the E. coli cell center". Current Opinion in Microbiology 5 (6): 553–557. doi:10.1016/S1369-5274(02)00374-0. PMID 12457697.
- ↑ Harry EJ (2001). "Coordinating DNA replication with cell division: lessons from outgrowing spores". Biochimie 83 (1).): 75–81. doi:10.1016/S0300-9084(00)01220-7. PMID 11254978.
- ↑ Rowlett V, Margolin W (2015). "The Min system and other nucleoid-independent regulators of Z ring positioning". Frontiers in Microbiology 13 (6): 478. doi:10.3389/fmicb.2015.004780. PMID 26029202.
- ↑ He AS, Rohatgi PR, Hersh MN, Rosenberg SM (2006). "Roles of E. coli double-strand-break-repair proteins in stress-induced mutation". DNA Repair 5 (2): 258–273. doi:10.1016/j.dnarep.2005.10.006. PMID 16310415.
- ↑ Mukherjee A, Lutkenhaus J (1998). "Dynamic assembly of FtsZ regulated by GTP hydrolysis". The EMBO Journal 17 (2): 462–469. doi:10.1093/emboj/17.2.462. PMC 1170397. PMID 9430638.
- ↑ Wu LJ, Errington J (2006). "Coordination of cell division and chromosome segregation by a nucleoid occlusion protein in Bacillus subtilis". Cell 117 (7): 915–925. doi:10.1016/j.cell.2004.06.002. PMID 15210112.
- ↑ Bernhardt TG, de Boer PA (2005). "SlmA, a nucleoid-associated, FtsZ-binding protein required for blocking septal ring assembly over chromosomes in E. coli". Mol Cell 18 (5): 555–564. doi:10.1016/j.molcel.2005.04.012. PMID 15916962.
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