Identification of cyanobacterial cell division genes by comparative and mutational analyses

We performed comparative and mutational analyses to define more comprehensively the repertoire of genes involved in cyanobacterial cell division. Genes ftsE, ftsI, ftsQ, ftsW, and (previously recognized) ftsZ, minC, minD, minE and sulA were identified as homologues of cell division genes of Gram-negative and Gram-positive bacteria. Transposon mutagenesis of Synechococcus elongatus PCC 7942 identified five additional genes, cdv1, cdv2, cdv3, ftn6 and cikA, involved in cell division. cdv1 encodes a presumptive periplasmic peptidyl-prolyl cis-trans isomerase. cdv2 has similarity to ylmF which, like divIVA, lies within the Gram-positive bacterial ylm gene cluster whose members have functions associated with division. Conservation of other ylm genes in cyanobacteria suggests that cyanobacteria and Gram-positive bacteria share specific division proteins. Two ylm homologues are also found in algal and plant genomes. cdv3 has low but significant similarity to divIVA, suggesting that minE and cdv3 both mediate division-site determination in cyanobacteria. In contrast, Gram-positive bacteria lack minE, and (Gram-negative) proteobacteria lack divIVA. ftn6, of unknown function, and the circadian input kinase, cikA, are specific to cyanobacteria. In S. elongatus, unlike in other bacteria, FtsZ rings are formed at sites occupied by nucleoids. Thus, the division machinery of cyanobacteria differs in its composition and regulation from that of Gram-negative and Gram-positive bacteria.     

Hypothesis: membrane domains and hyperstructures control bacterial division

The mechanism responsible for creating the division site in the right place at the right time in bacteria is unknown. It has been attributed to the formation of proteolipid domains in the cytoplasmic membrane surrounding the nucleoids. We interpret the growing evidence for this hypothesis by invoking hyperstructures, which exist at a level of organization intermediate between macromolecules and genes. Non-equilibrium hyperstructures comprise the genes, mRNA proteins and lipids required for a particular function such as cell division, and assemble and disassemble according to the needs of the cell.     

Inhibition of cell division in hupA hupB mutant bacteria lacking HU protein.

Escherichia coli hupA hypB double mutants that lack HU protein have severe cellular defects in cell division, DNA folding, and DNA partitioning. Here we show that the sfiA11 mutation, which alters the SfiA cell division inhibitor, reduces filamentation and production of anucleate cells in AB1157 hupA hupB strains. However, lexA3(Ind-) and sfiB(ftsZ)114 mutations, which normally counteract the effect of the SfiA inhibitor, could not restore a normal morphology to hupA hupB mutant bacteria. The LexA repressor, which controls the expression of the sfiA gene, was present in hupA hupB mutant bacteria in concentrations half of those of the parent bacteria, but this decrease was independent of the specific cleavage of the LexA repressor by activated RecA protein. One possibility to account for the filamentous morphology of hupA hupB mutant bacteria is that the lack of HU protein alters the expression of specific genes, such as lexA and fts cell division genes.     

Harnessing Single Cell Sorting to Identify Cell Division Genes and Regulators in Bacteria

Cell division is an essential cellular process that requires an array of known and unknown proteins for its spatial and temporal regulation. Here we develop a novel, high-throughput screening method for the identification of bacterial cell division genes and regulators. The method combines the over-expression of a shotgun genomic expression library to perturb the cell division process with high-throughput flow cytometry sorting to screen many thousands of clones. Using this approach, we recovered clones with a filamentous morphology for the model bacterium, Escherichia coli. Genetic analysis revealed that our screen identified both known cell division genes, and genes that have not previously been identified to be involved in cell division. This novel screening strategy is applicable to a wide range of organisms, including pathogenic bacteria, where cell division genes and regulators are attractive drug targets for antibiotic development.     

结瘤因子的研究进展

结瘤因子是由根瘤菌产生的一类信号分子,它们在结瘤的起始阶段发挥着十分重要的作用。新近的研究结果证明结瘤因子大分子骨架上的不同侧链基团是决定细菌与宿主植物间相互识别的关键因素,根瘤菌细胞中一系列结瘤基因编码能够合成Lipo-chio-oligosaccharides(LCOs)的各种酶类,进而确定结瘤信号分子的特定结构。目前,一系列令人兴奋的实验结果表明：LCOs不仅可促进豆科作物的生物固氮作用,对一些非豆科作物的细胞分裂作用等同样具有刺激作用。对根瘤菌结瘤因子的研究显然有助于进一步了解细菌与植物的相互作用机理,并进而为农业生产为直接利益。本文在综述这方面的研究进展同时,还就瘤菌,豆科作用和结瘤信号分子之间的相互作用机理,以及根际促生细菌,水杨酸和结瘤信号分子之间的可能关系进行了理论分析。     

FtsZ-less cell division in archaea and bacteria

A dedicated cell division machinery is needed for efficient proliferation of an organism. The eukaryotic actin-myosin based mechanism and the bacterial FtsZ-dependent machinery have both been characterized in detail, and a third division mechanism, the Cdv system, was recently discovered in archaea from the Crenarchaeota phylum. Despite these findings, division mechanisms remain to be identified in, for example, organisms belonging to the bacterial PVC superphylum, bacteria with extremely reduced genomes, wall-less archaea and bacteria, and in archaea that carry out the division process without cell constriction. Cytokinesis mechanisms in these clades and individual taxa are likely to include adaptation of host functions to division of bacterial symbionts, transfer of bacterial division genes into the host genome, vesicle formation without a dedicated constriction machinery, cross-wall formation without invagination, as well as entirely novel division mechanisms.     

Cyanobacterial cell division: Genetics and comparative genomics of cyanobacterial cell division

Division of cyanobacteria serves as a model for studying division of plant chloroplasts. Analysis of mutants obtained by methods of “forward” and “reverse” genetics underlies effective strategy for studying genetics of cell division in these photoautotrophic prokaryotes. Comparative genomic analysis indicates that some cyanobacterial genes involved in the control of cell division have homologs among cyanobacteria, green algae, and higher plants, some others, only in bacteria, whereas the remaining genes are specific only for cyanobacteria.     

The analysis of cell division and cell wall synthesis genes reveals mutationally inactivated ftsQ and mraY in a protoplast-type L-form of Escherichia coli

Cell division and cell wall synthesis are tightly linked cellular processes for bacterial growth. A protoplast-type L-form Escherichia coli, strain LW1655F+, indicated that bacteria can divide without assembling a cell wall. However, the molecular basis of its phenotype remained unknown. To establish a first phenotype-genotype correlation, we analyzed its dcw locus, and other genes involved in division of E. coli. The analysis revealed defective ftsQ and mraY genes, truncated by a nonsense and a frame-shift mutation, respectively. Missense mutations were determined in the ftsA and ftsW products yielding amino-acid replacements at conserved positions. FtsQ and MraY, obviously nonfunctional in the L-form, are essential for cell division and cell wall synthesis, respectively, in all bacteria with a peptidoglycan-based cell wall. LW1655F+ is able to survive their loss-of-functions. This points to compensatory mechanisms for cell division in the absence of murein sacculus formation. Hence, this L-form represents an interesting model to investigate the plasticity of cell division in E. coli, and to demonstrate how concepts fundamental for bacterial life can be bypassed.     

Genes specifying cytokinin biosynthesis in prokaryotes

Cytokinins are plant hormones which have long been associated with cell division and plastid differentiation. Recently, they have been found to play a central role also in the growth of plant tumors. Certain phytopathogenic bacteria, notably Agrobacterium tumefaciens and Pseudomonas syringae pv. savastanoi, can incite tumors on dicotyledonous plants and such tumors exhibit growth which is characteristic of the presence of excess auxin and cytokinin. Genes specifying cytokinin biosynthesis have now been isolated from both sets of bacteria. The genes encode prenyl transferase responsible for cytokinin biosynthesis which, upon expression in E. coli,cause the production of the active cytokinin, zeatin. Expression of these genes in association with the plant is responsible for at least part of the tumor phenotype, although the molecular mechanisms of infection by these bacteria are apparently quite dissimilar. There is extensive homology between the cytokinin biosynthetic genes from the two sets of bacteria.     

Control of cell division by sex factor F in Escherichia coli. II. Identification of genes for inhibitor protein and trigger protein on the 42.84-43.6 F segment

The genetic structure of the 42.84-43.6 F (BamHI-PstI) segment of the F plasmid, which contains all the F DNA sequences necessary for coupling cell division of F+ bacteria with plasmid DNA replication, was analyzed by isolating a series of amber mutants. Two cistrons were found in this region and they were designated letA and letD (an abbreviation for lethal mutation). The letA and letD cistrons were mapped on the 42.84-43.35 F (BamHI- XmaI ) segment and the 43.07-43.6 F (HincII-PstI) segment, respectively, and are presumed to correspond to the first (43.04-43.26 F) and second (43.26-43.57 F) open reading frames, respectively, which were found in this region by nucleotide sequencing. The letD gene product acts to inhibit cell division of the host bacteria and to induce prophages in lysogenic bacteria, whereas the letA gene product acts to suppress the activity of the letD gene product. Taking into consideration the fact that the 42.84-43.6 F segment carries all the F plasmid genes necessary for coupling cell division with plasmid DNA replication, and that the expression of the genes is likely to be controlled by plasmid DNA replication, we constructed the following hypothesis. Before completion of plasmid DNA replication, LetD protein acts to prevent cell division of the host bacteria. When plasmid DNA replication is completed, synthesis of LetA protein (and also LetD protein) takes place and the LetA protein synthesized acts to suppress the activity of LetD protein and make the cell ready for cell division. Actual cell division will take place when replication of both chromosomal and plasmid DNA is completed and the termination protein of the chromosome and the LetA protein of F plasmid are both synthesized. When cell division takes place LetA protein is consumed, and as a result LetD protein becomes active and prevents cell division until the next round of DNA replication is completed.     

Cellular and molecular remodelling of a host cell for vertical transmission of bacterial symbionts

Various insects require intracellular bacteria that are restricted to specialized cells (bacteriocytes) and are transmitted vertically via the female ovary, but the transmission mechanisms are obscure. We hypothesized that, in the whitefly Bemisia tabaci, where intact bacteriocytes (and not isolated bacteria) are transferred to oocytes, the transmission mechanism would be evident as cellular and molecular differences between the nymph (pre-adult) and adult bacteriocytes. We demonstrate dramatic remodelling of bacteriocytes at the developmental transition from nymph to adulthood. This transition involves the loss of cell–cell adhesion, high division rates to constant cell size and onset of cell mobility, enabling the bacteriocytes to crawl to the ovaries. These changes are accompanied by cytoskeleton reorganization and changes in gene expression: genes functioning in cell–cell adhesion display reduced expression and genes involved in cell division, cell motility and endocytosis/exocytosis have elevated expression in adult bacteriocytes, relative to nymph bacteriocytes. This study demonstrates, for the first time, how developmentally orchestrated remodelling of gene expression and correlated changes in cell behaviour underpin the capacity of bacteriocytes to mediate the vertical transmission and persistence of the symbiotic bacteria on which the insect host depends.     

Visualization of a cytoskeleton-like FtsZ network in chloroplasts

It has been a long-standing dogma in life sciences that only eukaryotic organisms possess a cytoskeleton. Recently, this belief was questioned by the finding that the bacterial cell division protein FtsZ resembles tubulin in sequence and structure and, thus, may be the progenitor of this major eukaryotic cytoskeletal element. Here, we report two nuclear-encoded plant ftsZ genes which are highly conserved in coding sequence and intron structure. Both their encoded proteins are imported into plastids and there, like in bacteria, they act on the division process in a dose-dependent manner. Whereas in bacteria FtsZ only transiently polymerizes to a ring-like structure, in chloroplasts we identified persistent, highly organized filamentous scaffolds that are most likely involved in the maintenance of plastid integrity and in plastid division. As these networks resemble the eukaryotic cytoskeleton in form and function, we suggest the term "plastoskeleton" for this newly described subcellular structure.     

In situ activity of NAC11-7 roseobacters in coastal waters off the Chesapeake Bay based on ftsZ expression

Determining in situ growth rates for specific bacterioplankton is of critical importance to understanding their contributions to energy and matter flow in the Ocean. Quantifying expression of genes central to cell division is a plausible approach for obtaining these measurements. In order to test this approach's assumptions, a quantitative PCR assay targeting the cell division gene ftsZ in the ubiquitous NAC11-7 group of the Rhodobacterales order of marine bacteria was developed. ftsZ genes and their corresponding mRNAs were measured in diel in situ samples and in parallel on-deck incubations. Strong correlations between ftsZ expression and gene abundance (R-squared = 0.62) were observed in situ. Rapid changes in NAC11-7 ftsZ gene copies suggested that different populations from different water types were sampled with a significant positive correlation between ftsZ expression and water temperature (R-squared = 0.68, P < 0.001). An outlier to this trend occurred at a single time point (9:00), which was remarkably consistent with a concomitant peak in ftsZ expression in on-deck incubations, suggesting the possibility of synchronous population growth.     

htpR-like gene controls cell division and proteolysis in Pseudomonas aeruginosa

As shown in hybridization experiments, the genome of Pseudomonas aeruginosa cells contains a htpR-like gene which controls the expression of heat shock genes in cells of Escherichia coli. By means of specially constructed plasmids, the synthesis of htpR antisense RNA has been found to disturb cell division and proteolytic processes in P. aeruginosa, suggesting the functional relationship of htpR genes in E. coli and Pseudomonas bacteria.     

Structure, function and evolution of the mitochondrial division apparatus

Mitochondria are derived from free-living alpha-proteobacteria that were engulfed by eukaryotic host cells through the process of endosymbiosis, and therefore have their own DNA which is organized using basic proteins to form organelle nuclei (nucleoids). Mitochondria divide and are split amongst the daughter cells during cell proliferation. Their division can be separated into two main events: division of the mitochondrial nuclei and division of the matrix (the so-called mitochondrial division, or mitochondriokinesis). In this review, we first focus on the cytogenetical relationships between mitochondrial nuclear division and mitochondriokinesis. Mitochondriokinesis occurs after mitochondrial nuclear division, similar to bacterial cytokinesis. We then describe the fine structure and dynamics of the mitochondrial division ring (MD ring) as a basic morphological background for mitochondriokinesis. Electron microscopy studies first identified a small electron-dense MD ring in the cytoplasm at the constriction sites of dividing mitochondria in the slime mold Physarum polycephalum, and then two large MD rings (with outer cytoplasmic and inner matrix sides) in the red alga Cyanidioschyzon merolae. Now MD rings have been found in all eukaryotes. In the third section, we describe the relationships between the MD ring and the FtsZ ring descended from ancestral bacteria. Other than the GTPase, FtsZ, mitochondria have lost most of the proteins required for bacterial cytokinesis as a consequence of endosymbiosis. The FtsZ protein forms an electron transparent ring (FtsZ or Z ring) in the matrix inside the inner MD ring. For the fourth section, we describe the dynamic association between the outer MD ring with a ring composed of the eukaryote-specific GTPase dynamin. Recent studies have revealed that eukaryote-specific GTPase dynamins form an electron transparent ring between the outer membrane and the MD ring. Thus, mitochondriokinesis is thought to be controlled by a mitochondrial division (MD) apparatus including a dynamic trio, namely the FtsZ, MD and dynamin rings, which consist of a chimera of rings from bacteria and eukaryotes in primitive organisms. Since the genes for the MD ring and dynamin rings are not found in the prokaryotic genome, the host genomes may make these rings to actively control mitochondrial division. In the fifth part, we focus on the dynamic changes in the formation and disassembly of the FtsZ, MD and dynamin rings. FtsZ rings are digested during a later period of mitochondrial division and then finally the MD and dynamin ring apparatuses pinched off the daughter mitochondria, supporting the idea that the host genomes are responsible for the ultimate control of mitochondrial division. We discuss the evolution, from the original vesicle division (VD) apparatuses to VD apparatuses including classical dynamin rings and MD apparatuses. It is likely that the MD apparatuses involving the dynamic trio evolved into the plastid division (PD) apparatus in Bikonta, while in Opisthokonta, the MD apparatus was simplified during evolution and may have branched into the mitochondrial fusion apparatus. Finally, we describe the possibility of intact isolation of large MD/PD apparatuses, the identification of all their proteins and their related genes using C. merolae genome information and TOF-MS analyses. These results will assist in elucidating the universal mechanism and evolution of MD, PD and VD apparatuses.     

衣藻叶绿体分裂相关基因CrFtsZ3的克隆及其原核表达

FtsZ蛋白在原核细胞以及植物细胞叶绿体的分裂过程中发挥着重要作用。为了研究叶绿体分裂装置的进化 ,运用RT PCR方法从莱茵衣藻中克隆了叶绿体分裂相关基因CrFtsZ3。由于已经从衣藻细胞中克隆了一个ftsZ基因 ,所以CrFtsZ3的克隆表明衣藻中已经存在两类不同的 ftsZ基因 ,这说明 ftsZ基因的复制与分歧发生于绿藻的分化之前。序列分析结果显示 ,CrFtsZ3所编码的蛋白质具有FtsZ蛋白的典型模体。进一步的原核表达与定位分析表明CrFtsZ3 GFP融合蛋白沿着宿主菌体的纵轴方向有规律地聚集成荧光点或荧光带 ,并且CrFtsZ3蛋白过量表达明显干挠了宿主菌正常的细胞分裂过程 ,说明衣藻CrFtsZ3蛋白能够识别宿主细胞内的分裂位点并影响细胞分裂过程 ,从而初步验证了它的生物学功能