FtsW is a dispensable cell division protein required for Z-ring stabilization during sporulation septation in Streptomyces coelicolor

The conserved rodA and ftsW genes encode polytopic membrane proteins that are essential for bacterial cell elongation and division, respectively, and each gene is invariably linked with a cognate class B high-molecular-weight penicillin-binding protein (HMW PBP) gene. Filamentous differentiating Streptomyces coelicolor possesses four such gene pairs. Whereas rodA, although not its cognate HMW PBP gene, is essential in these bacteria, mutation of SCO5302 or SCO2607 (sfr) caused no gross changes to growth and septation. In contrast, disruption of either ftsW or the cognate ftsI gene blocked the formation of sporulation septa in aerial hyphae. The inability of spiral polymers of FtsZ to reorganize into rings in aerial hyphae of these mutants indicates an early pivotal role of an FtsW-FtsI complex in cell division. Concerted assembly of the complete divisome was unnecessary for Z-ring stabilization in aerial hyphae as ftsQ mutants were found to be blocked at a later stage in cell division, during septum closure. Complete cross wall formation occurred in vegetative hyphae in all three fts mutants, indicating that the typical bacterial divisome functions specifically during nonessential sporulation septation, providing a unique opportunity to interrogate the function and dependencies of individual components of the divisome in vivo.     

SpoIIIE and a novel type of DNA translocase, SftA, couple chromosome segregation with cell division in Bacillus subtilis

Cell division must only occur once daughter chromosomes have been fully separated. However, the initiating event of bacterial cell division, assembly of the FtsZ ring, occurs while chromosome segregation is still ongoing. We show that a two-step DNA translocase system exists in Bacillus subtilis that couples chromosome segregation and cell division. The membrane-bound DNA translocase SpoIIIE assembled very late at the division septum, and only upon entrapment of DNA, while its orthologue, SftA (YtpST), assembled at each septum in B. subtilis soon after FtsZ. Lack of SftA resulted in a moderate segregation defect at a late stage in the cell cycle. Like the loss of SpoIIIE, the absence of SftA was deleterious for the cells during conditions of defective chromosome segregation, or after induction of DNA damage. Lack of both proteins exacerbated all phenotypes. SftA forms soluble hexamers in solution, binds to DNA and has DNA-dependent ATPase activity, which is essential for its function in vivo . Our data suggest that SftA aids in moving DNA away from the closing septum, while SpoIIIE translocates septum-entrapped DNA only when septum closure precedes complete segregation of chromosomes.     

Promiscuous targeting of Bacillus subtilis cell division protein DivIVA to division sites in Escherichia coli and fission yeast

The Bacillus subtilis divIVA gene encodes a coiled-coil protein that shows weak similarity to eukaryotic tropomyosins. The protein is targeted to the sites of cell division and mature cell poles where, in B.subtilis, it controls the site specificity of cell division. Although clear homologues of DivIVA are present only in Gram-positive bacteria, and its role in division site selection is not conserved in the Gram-negative bacterium, Escherichia coli, a DivIVA-green fluorescent protein (GFP) fusion was targeted accurately to division sites and retained at the cell pole in this organism. Remarkably, the same fusion protein was also targeted to nascent division sites and growth zones in the fission yeast Schizosaccharomyces pombe, mimicking the localization of the endogenous tropomyosin-like cell division protein Cdc8p, and F-actin. The results show that a targeting signal for division sites is conserved across the eukaryote-prokaryote divide.     

PKB/Akt:一个具有多种功能的蛋白激酶

蛋白激酶B(protein kinaseB,PKB)是细胞信号传导过程中的一个重要的中间体。在过去lO多年的研究中,发现它不仅参与调节细胞糖代谢、细胞增殖、细胞凋亡,而且与糖尿病和癌症的发生也有关。目前PKB的相关调控机制还未得到完全阐明。在此,作者谨就PKB的一些研究进展作一介绍。     

Repeated triggering of sporulation in Bacillus subtilis selects against a protein that affects the timing of cell division

Bacillus subtilis sporulation is a last-resort phenotypical adaptation in response to starvation. The regulatory network underlying this developmental pathway has been studied extensively. However, how sporulation initiation is concerted in relation to the environmental nutrient availability is poorly understood. In a fed-batch fermentation set-up, in which sporulation of ultraviolet (UV)-mutagenized B. subtilis is repeatedly triggered by periods of starvation, fitter strains with mutated tagE evolved. These mutants display altered timing of phenotypical differentiation. The substrate for the wall teichoic acid (WTA)-modifying enzyme TagE, UDP-glucose, has recently been shown to be an intracellular proxy for nutrient availability, and influences the timing of cell division. Here we suggest that UDP-glucose also influences timing of cellular differentiation.     

TG2, a novel extracellular protein with multiple functions

TG2 is multifunctional enzyme which can be secreted to the cell surface by an unknown mechanism where its Ca(2+)-dependent transamidase activity is implicated in a number of events important to cell behaviour. However, this activity may only be transient due to the oxidation of the enzyme in the extracellular environment including its reaction with NO probably accounting for its many other roles, which are transamidation independent. In this review, we discuss the novel roles of TG2 at the cell surface and in the ECM acting either as a transamidating enzyme or as an extracellular scaffold protein involved in cell adhesion. Such roles include its ability to act as an FN co-receptor for β integrins or in a heterocomplex with FN interacting with the cell surface heparan sulphate proteoglycan syndecan-4 leading to activation of PKCα. These different properties of TG2 involve this protein in various physiological processes, which if not regulated appropriately can also lead to its involvement in a number of diseases. These include metastatic cancer, tissue fibrosis and coeliac disease, thus increasing its attractiveness as both a therapeutic target and diagnostic marker.     

Molecular cloning of a Bacillus subtilis gene involved in cell division, sporulation, and exoenzyme secretion

The wild type div-341+ gene of Bacillus subtilis was cloned in a temperate phage rho 11, and was recloned in a smaller temperate phage phi 105. The resulting Div+ transducing phage carried a 3 kilobase Cfr13I digested chromosomal fragment which showed Div+ transforming activity and contained the whole div-341+ gene which is involved in cell division, sporulation, exoenzyme secretion, competent cell formation, and autolysis. A partial restriction map of the fragment was established. The merodiploid system of the div-341+ gene, wild type gene on the phage genome and mutant gene on the chromosome, resulted in the suppression of mutant phenotypes and indicated that the wild type div-341+ gene is dominant over mutant gene.     

The C. elegans F-box/WD-repeat protein LIN-23 functions to limit cell division during development

In multicellular eukaryotes, a complex program of developmental signals regulates cell growth and division by controlling the synthesis, activation and degradation of G(1) cell cycle regulators. Here we describe the lin-23 gene of Caenorhabditis elegans, which is required to restrain cell proliferation in response to developmental cues. In lin-23 null mutants, all postembryonic blast cells undergo extra divisions, creating supernumerary cells that can differentiate and function normally. In contrast to the inability to regulate the extent of blast cell division in lin-23 mutants, the timing of initial cell cycle entry of blast cells is not affected. lin-23 encodes an F-box/WD-repeat protein that is orthologous to the Saccharomyces cerevisiae gene MET30, the Drosophila melanogaster gene slmb and the human gene betaTRCP, all of which function as components of SCF ubiquitin-ligase complexes. Loss of function of the Drosophila slmb gene causes the growth of ectopic appendages in a non-cell autonomous manner. In contrast, lin-23 functions cell autonomously to negatively regulate cell cycle progression, thereby allowing cell cycle exit in response to developmental signals.     

ShyA, a membrane protein for proper septation of hyphae in Streptomyces

The life cycle of Streptomyces involves the formation of filamentous substrate and aerial hyphae. Following cessation of growth of an aerial hypha, multiple septation occurs at the tip to produce a chain of unigenomic spores. A gene, shyA, which influences several aspects of this growth, was isolated and partially characterized in Streptomyces coelicolor. The gene product is a representative of a well-conserved family of small actinomycete proteins. The shyA mutant sporulates normally but displays hyper septum formation and altered spore-chain morphology. Biochemical separation experiments and immunofluorescence staining demonstrated that the shyA gene product locates at cell membranes. Moreover, yeast two-hybrid screen and GST-pull-down assay showed that ShyA can interact with itself. Altogether, ShyA belongs to a new family of membrane-associated proteins which plays a role in morphological differentiation in actinomycetes.     

Characterization of YmgF, a 72-residue inner membrane protein that associates with the Escherichia coli cell division machinery

Formation of the Escherichia coli division septum is catalyzed by a number of essential proteins (named Fts) that assemble into a ring-like structure at the future division site. Many of these Fts proteins are intrinsic transmembrane proteins whose functions are largely unknown. In the present study, we attempted to identify a novel putative component(s) of the E. coli cell division machinery by searching for proteins that could interact with known Fts proteins. To do that, we used a bacterial two-hybrid system based on interaction-mediated reconstitution of a cyclic AMP (cAMP) signaling cascade to perform a library screening in order to find putative partners of E. coli cell division protein FtsL. Here we report the characterization of YmgF, a 72-residue integral membrane protein of unknown function that was found to associate with many E. coli cell division proteins and to localize to the E. coli division septum in an FtsZ-, FtsA-, FtsQ-, and FtsN-dependent manner. Although YmgF was previously shown to be not essential for cell viability, we found that when overexpressed, YmgF was able to overcome the thermosensitive phenotype of the ftsQ1(Ts) mutation and restore its viability under low-osmolarity conditions. Our results suggest that YmgF might be a novel component of the E. coli cell division machinery.     

Premature targeting of cell division proteins to midcell reveals hierarchies of protein interactions involved in divisome assembly

In order to divide, the bacterium Escherichia coli must assemble a set of at least 10 essential proteins at the nascent division site. These proteins localize to midcell according to a linear hierarchy, suggesting that cell division proteins are added to the nascent divisome in strict sequence. We previously described a method, 'premature targeting', which allows us to target a protein directly to the division site independently of other cell division proteins normally required for its localization at midcell. By systematically applying this method to probe the recruitment of and associations among late cell division proteins, we show that this linear assembly model is likely incorrect. Rather, we find that the assembly of most of the late proteins can occur independently of 'upstream' proteins. Further, most late proteins, when prematurely targeted to midcell, can back-recruit upstream proteins in the reverse of the predicted pathway. Together these observations indicate that the late proteins, with the notable exception of the last protein in the pathway, FtsN, are associated in a hierarchical set of protein complexes. Based on these observations we present a revised model for assembly of the E. coli division apparatus.     

A mechanism of division of a cell with an impermeable membrane

The case of a cell in which metabolites are produced and consumed within the cell, without leaving the cell, is considered. Conditions are given under which there may be an excess production at the center over that at the periphery, and this condition is stable with respect to displacement of the center. The resulting diffusion forces are considered, and an expression is developed for the Rate of elongation with time. The expression is very similar to that obtained by considering the flow of metabolites into and out of the cell.     

Impaired cell division and sporulation of a Bacillus subtilis strain with the ftsA gene deleted.

The ftsZ and ftsA genes of Bacillus subtilis are organized in a simple operon expressed from promoter sequences immediately upstream of ftsA. The promoter-distal ftsZ gene is an essential septation gene. In this report, it is shown that the promoter-proximal ftsA gene can be deleted in a previously constructed strain in which the essential gene, ftsZ, is under the control of the inducible spac promoter. Absence of the ftsA gene product resulted in a very filamentous morphology indicating an important role for ftsA in cell division. Also, growth was severely impaired, and viability and sporulation were reduced. The defective sporulation phenotype correlated with a deficiency in the processing of pro-sigma E to its active form.     

The glycogenic action of protein targeting to glycogen in hepatocytes involves multiple mechanisms including phosphorylase inactivation and glycogen synthase translocation

Expression of the glycogen-targeting protein PTG promotes glycogen synthase activation and glycogen storage in various cell types. In this study, we tested the contribution of phosphorylase inactivation to the glycogenic action of PTG in hepatocytes by using a selective inhibitor of phosphorylase (CP-91149) that causes dephosphorylation of phosphorylase a and sequential activation of glycogen synthase. Similar to CP-91194, graded expression of PTG caused a concentration-dependent inactivation of phosphorylase and activation of glycogen synthase. The latter was partially counter-acted by the expression of muscle phosphorylase and was not additive with the activation by CP-91149, indicating that it is in part secondary to the inactivation of phosphorylase. PTG expression caused greater stimulation of glycogen synthesis and translocation of glycogen synthase than CP-91149, and the translocation of synthase could not be explained by accumulation of glycogen, supporting an additional role for glycogen synthase translocation in the glycogenic action of PTG. The effects of PTG expression on glycogen synthase and glycogen synthesis were additive with the effects of glucokinase expression, confirming the complementary roles of depletion of phosphorylase a (a negative modulator) and elevated glucose 6-phosphate (a positive modulator) in potentiating the activation of glycogen synthase. PTG expression mimicked the inactivation of phosphorylase caused by high glucose and counteracted the activation caused by glucagon. The latter suggests a possible additional role for PTG on phosphorylase kinase inactivation.     

The receptor binding protein P2 of PRD1, a virus targeting antibiotic-resistant bacteria,has a novel fold suggesting multiple functions

Bacteriophage PRD1 is unusual, with an internal lipid membrane, but has striking resemblances to adenovirus that include receptor binding spikes. The PRD1 vertex complex contains P2, a 590 residue monomer that binds to receptors on antibiotic-resistant strains of E. coli and so is the functional counterpart to adenovirus fiber. P2 structures from two crystal forms, at 2.2 and 2.4 A resolution, reveal an elongated club-shaped molecule with a novel beta propeller "head" showing pseudo-6-fold symmetry. An extended loop with another novel fold forms a long "tail" containing a protruding proline-rich "fin." The head and fin structures are well suited to recognition and attachment, and the tail is likely to trigger the processes of vertex disassembly, membrane tube formation, and subsequent DNA injection.     

Oligomerization,membrane anchoring,and cellulose-binding characteristics of AbpS,a receptor-like Streptomyces protein

Streptomyces reticuli produces a 34.6-kDa surface-anchored protein (AbpS) whose surface-exposed N terminus binds strongly to Avicel, a dominantly crystalline type of cellulose. The generation of a large set of mutated abpS-genes and the subsequent analysis of the corresponding proteins in vitro as well as in vivo in a Streptomyces host allow the assignment of the following characteristics for AbpS. (i) Amino acid residues participating directly in the cellulose-interaction are located at the N terminus. (ii) As ascertained by cross-linking experiments, AbpS forms homotetramers in its soluble as well as cellulose-bound form. (iii) The intermolecular assembly of four AbpS molecules is governed by two domains (including amino acids 60-110 and 161-212). Both domains possess large portions of alpha-helical regions in which hydrophobic amino acids are located on one side as known from coiled-coil proteins. (iv) The C-terminal part of AbpS comprising 35 amino acids contains a transmembrane domain. Due to the surface-exposed N terminus of AbpS and the presence of transmembrane helix the C terminus has to be situated in the cytoplasm of the S. reticuli hyphae. Thus AbpS connects the interior of the mycelia with the extracellular space and binds cellulose using a unique cellulose-binding module.     

Acylation-dependent and-independent membrane targeting and distinct functions of small myristoylated proteins (SMPs) in Leishmania major

Trypanosomatid parasites express a number of mono- and diacylated proteins that are targeted to distinct regions of the plasma membrane including the cell body, the flagellum and the flagellar pocket. The extent to which the acylation status and other protein motifs regulate the targeting and/or retention of these proteins to the distinct membrane domains is poorly defined. We have previously described a family of small myristoylated proteins (SMPs) that are either monoacylated (myristoylated) or diacylated (myristoylated and palmitoylated) and targeted to distinct plasma membrane domains. Diacylated SMP-1 is a major constituent of the flagellar membrane, whereas monoacylated SMP-2 resides in the flagellar pocket in Leishmania major. Here, we show that a third SMP family member, monoacylated SMP-4, localizes predominantly to the pellicular membrane. Density gradient centrifugation of detergent-insoluble membranes indicated that SMP-4 was associated with detergent-insoluble domains but was not tightly associated with the subpellicular cytoskeleton. Based on the localisation of truncated SMP proteins, we conclude that the flagellum targeting of SMP-1 is primarily dependent on the dual-acylation motif. In contrast, the localisation of SMP-4 to the cell body membrane is dependent on N-terminal myristoylation and a C-terminal peptide subdomain with a predicted α-helical structure. Strikingly, a SMP-1 chimera containing the SMP-4 C-terminal extension was selectively trafficked to the distal tip of the flagellum and failed to complement the loss of native SMP-1 in a Δsmp1/2 double knockout strain. Collectively, these results suggest that dual acylation is sufficient to target some SMP proteins to the flagellum, while the unique C-terminal extensions of these proteins may confer additional membrane targeting signals that are important for both localisation and SMP function.