Purification and Characterization of Escherichia coli MreB Protein

The actin homolog MreB is required in rod-shaped bacteria for maintenance of cell shape and is intimately connected to the holoenzyme that synthesizes the peptidoglycan layer. The protein has been reported variously to exist in helical loops under the cell surface, to rotate, and to move in patches in both directions around the cell surface. Studies of the Escherichia coli protein in vitro have been hampered by its tendency to aggregate. Here we report the purification and characterization of native E. coli MreB. The protein requires ATP hydrolysis for polymerization, forms bundles with a left-hand twist that can be as long as 4 μm, forms sheets in the presence of calcium, and has a critical concentration for polymerization of 1.5 μm.     

Dynamic Localization of MreB in Vibrio parahaemolyticus and in the Ectopic Host Bacterium Escherichia coli

MreB, a homolog of eukaryotic actin, participates in morphogenesis, cell division, cell polarity, and chromosome segregation in prokaryotes. In this study, a yellow fluorescent protein conjugate (YFP-MreB_Vp) was generated to investigate the behavior of MreB in merodiploid strain SC9 of the enteropathogen Vibrio parahaemolyticus. Under normal growth conditions, YFP-MreB_Vp formed helical filaments with a pitch of 0.64 ± 0.09 μm in about 85% of exponential-phase cells, and different clusters, relaxed coils, and ring configurations were observed in a small proportion of the cells. Overexpression of YFP-MreB_Vp substantially altered the structure of the MreB cytoskeleton and resulted in swollen and pleomorphic cells. Disturbing the activities of penicillin-binding proteins or adding magnesium suppressed the morphological distortions. These results indicate that mislocalization of cell wall-synthesizing machinery was responsible for morphological abnormality. By expressing YFP-MreB_Vp in the ectopic host bacterium Escherichia coli, shrinkage, fragmentation, and annealing of MreB_Vp filaments were directly observed. This work revealed the dynamic pattern of the localization of YFP-MreB_Vp in V. parahaemolyticus and its relationship to cell morphogenesis, and the YFP-MreB_Vp-E. coli system may be used to investigate the dynamic spatial structures of the MreB cytoskeleton in vivo.     

De novo morphogenesis in L‐forms via geometric control of cell growth

In virtually all bacteria, the cell wall is crucial for mechanical integrity and for determining cell shape. Escherichia coli's rod‐like shape is maintained via the spatiotemporal patterning of cell‐wall synthesis by the actin homologue MreB. Here, we transiently inhibited cell‐wall synthesis in E. coli to generate cell‐wall‐deficient, spherical L‐forms, and found that they robustly reverted to a rod‐like shape within several generations after inhibition cessation. The chemical composition of the cell wall remained essentially unchanged during this process, as indicated by liquid chromatography. Throughout reversion, MreB localized to inwardly curved regions of the cell, and fluorescent cell wall labelling revealed that MreB targets synthesis to those regions. When exposed to the MreB inhibitor A22, reverting cells regrew a cell wall but failed to recover a rod‐like shape. Our results suggest that MreB provides the geometric measure that allows E. coli to actively establish and regulate its morphology.     

MreB-Dependent Organization of the E.?coli Cytoplasmic Membrane Controls Membrane Protein Diffusion

The functional organization of prokaryotic cell membranes, which is essential for many cellular processes, has been challenging to analyze due to the small size and nonflat geometry of bacterial cells. Here, we use single-molecule fluorescence microscopy and three-dimensional quantitative analyses in live Escherichia coli to demonstrate that its cytoplasmic membrane contains microdomains with distinct physical properties. We show that the stability of these microdomains depends on the integrity of the MreB cytoskeletal network underneath the membrane. We explore how the interplay between cytoskeleton and membrane affects trans-membrane protein (TMP) diffusion and reveal that the mobility of the TMPs tested is subdiffusive, most likely caused by confinement of TMP mobility by the submembranous MreB network. Our findings demonstrate that the dynamic architecture of prokaryotic cell membranes is controlled by the MreB cytoskeleton and regulates the mobility of TMPs.     

Reconstruction of mreB Expression in Staphylococcus aureus via a Collection of New Integrative Plasmids

Protein localization has been traditionally explored in unicellular organisms, whose ease of genetic manipulation facilitates molecular characterization. The two rod-shaped bacterial models Escherichia coli and Bacillus subtilis have been prominently used for this purpose and have displaced other bacteria whose challenges for genetic manipulation have complicated any study of cell biology. Among these bacteria is the spherical pathogenic bacterium Staphylococcus aureus. In this report, we present a new molecular toolbox that facilitates gene deletion in staphylococci in a 1-step recombination process and additional vectors that facilitate the insertion of diverse reporter fusions into newly identified neutral loci of the S. aureus chromosome. Insertion of the reporters does not add any antibiotic resistance genes to the chromosomes of the resultant strains, thereby making them amenable for further genetic manipulations. We used this toolbox to reconstitute the expression of mreB in S. aureus, a gene that encodes an actin-like cytoskeletal protein which is absent in coccal cells and is presumably lost during the course of speciation. We observed that in S. aureus, MreB is organized in discrete structures in association with the membrane, leading to an unusual redistribution of the cell wall material. The production of MreB also caused cell enlargement, but it did not revert staphylococcal shape. We present interactions of MreB with key staphylococcal cell wall-related proteins. This work facilitates the use S. aureus as a model system in exploring diverse aspects of cellular microbiology.     

Division‐site localization of RodZ is required for efficient Z ring formation in Escherichia coli

Bacteria such as Escherichia coli must coordinate cell elongation and cell division. Elongation is regulated by an elongasome complex containing MreB actin and the transmembrane protein RodZ, which regulates assembly of MreB, whereas division is regulated by a divisome complex containing FtsZ tubulin. These complexes were previously thought to function separately. However, MreB has been shown to directly interact with FtsZ to switch to cell division from cell elongation, indicating that these complexes collaborate to regulate both processes. Here, we investigated the role of RodZ in the regulation of cell division. RodZ localized to the division site in an FtsZ‐dependent manner. We also found that division‐site localization of MreB was dependent on RodZ. Formation of a Z ring was delayed by deletion of rodZ, suggesting that division‐site localization of RodZ facilitated the formation or stabilization of the Z ring during early cell division. Thus, RodZ functions to regulate MreB assembly during cell elongation and facilitates the formation of the Z ring during cell division in E. coli.     

Studying Biomolecule Localization by Engineering Bacterial Cell Wall Curvature

In this article we describe two techniques for exploring the relationship between bacterial cell shape and the intracellular organization of proteins. First, we created microchannels in a layer of agarose to reshape live bacterial cells and predictably control their mean cell wall curvature, and quantified the influence of curvature on the localization and distribution of proteins in vivo. Second, we used agarose microchambers to reshape bacteria whose cell wall had been chemically and enzymatically removed. By combining microstructures with different geometries and fluorescence microscopy, we determined the relationship between bacterial shape and the localization for two different membrane-associated proteins: i) the cell-shape related protein MreB of Escherichia coli, which is positioned along the long axis of the rod-shaped cell; and ii) the negative curvature-sensing cell division protein DivIVA of Bacillus subtilis, which is positioned primarily at cell division sites. Our studies of intracellular organization in live cells of E. coli and B. subtilis demonstrate that MreB is largely excluded from areas of high negative curvature, whereas DivIVA localizes preferentially to regions of high negative curvature. These studies highlight a unique approach for studying the relationship between cell shape and intracellular organization in intact, live bacteria.     

A Highlights from MBoC Selection: Motion of variable-length MreB filaments at the bacterial cell membrane influences cell morphology

The maintenance of rod-cell shape in many bacteria depends on actin-like MreB proteins and several membrane proteins that interact with MreB. Using superresolution microscopy, we show that at 50-nm resolution, Bacillus subtilis MreB forms filamentous structures of length up to 3.4 μm underneath the cell membrane, which run at angles diverging up to 40° relative to the cell circumference. MreB from Escherichia coli forms at least 1.4-μm-long filaments. MreB filaments move along various tracks with a maximal speed of 85 nm/s, and the loss of ATPase activity leads to the formation of extended and static filaments. Suboptimal growth conditions lead to formation of patch-like structures rather than extended filaments. Coexpression of wild-type MreB with MreB mutated in the subunit interface leads to formation of shorter MreB filaments and a strong effect on cell shape, revealing a link between filament length and cell morphology. Thus MreB has an extended-filament architecture with the potential to position membrane proteins over long distances, whose localization in turn may affect the shape of the cell wall.     

Leptospira interrogans Enolase Is Secreted Extracellularly and Interacts with Plasminogen

Leptospira interrogans is the agent for leptospirosis, an important zoonosis in humans and animals across the globe. Surface proteins of invading pathogens, such as L. interrogans, are thought to be responsible for successful microbial persistence in vivo via interaction with specific host components. In particular, a number of invasive infectious agents exploit host proteolytic pathways, such as one involving plasminogen (Pg), which aid in efficient pathogen dissemination within the host. Here we show that L. interrogans serovar Lai binds host Pg and that the leptospiral gene product LA1951, annotated as enolase, is involved in this interaction. Interestingly, unlike in related pathogenic Spirochetes, such as Borrelia burgdorferi, LA1951 is not readily detectable in the L. interrogans outer membrane. We show that the antigen is indeed secreted extracellularly; however, it can reassociate with the pathogen surface, where it displays Pg-binding and measurable enzymatic activity. Hamsters infected with L. interrogans also develop readily detectable antibody responses against enolase. Taken together, our results suggest that the L. interrogans enolase has evolved to play a role in pathogen interaction with host molecules, which may contribute to the pathogenesis of leptospirosis.     

Exclusion of assembled MreB by anionic phospholipids at cell poles confers cell polarity for bidirectional growth

Cell polarity determines the direction of cell growth in bacteria. MreB actin spatially regulates peptidoglycan synthesis to enable cells to elongate bidirectionally. MreB densely localizes in the cylindrical part of the rod cell and not in polar regions in Escherichia coli. When treated with A22, which inhibits MreB polymerization, rod‐shaped cells became round and MreB was diffusely distributed throughout the cytoplasmic membrane. A22 removal resulted in restoration of the rod shape. Initially, diffuse MreB started to re‐assemble, and MreB‐free zones were subsequently observed in the cytoplasmic membrane. These MreB‐free zones finally became cell poles, allowing the cells to elongate bidirectionally. When MreB was artificially located at the cell poles, an additional pole was created, indicating that artificial localization of MreB at the cell pole induced local peptidoglycan synthesis. It was found that the anionic phospholipids (aPLs), phosphatidylglycerol and cardiolipin, which were enriched in cell poles preferentially interact with monomeric MreB compared with assembled MreB in vitro. MreB tended to localize to cell poles in cells lacking both aPLs, resulting in production of Y‐shaped cells. Their findings indicated that aPLs exclude assembled MreB from cell poles to establish cell polarity, thereby allowing cells to elongate in a particular direction.     

Mutations in cell elongation genes mreB,mrdA and mrdB suppress the shape defect of RodZ‐deficient cells

RodZ interacts with MreB and both factors are required to maintain the rod shape of Escherichia coli. The assembly of MreB into filaments regulates the subcellular arrangement of a group of enzymes that synthesizes the peptidoglycan (PG) layer. However, it is still unknown how polymerization of MreB determines the rod shape of bacterial cells. Regulatory factor(s) are likely to be involved in controlling the function and dynamics of MreB. We isolated suppressor mutations to partially recover the rod shape in rodZ deletion mutants and found that some of the suppressor mutations occurred in mreB. All of the mreB mutations were in or in the vicinity of domain IA of MreB. Those mreB mutations changed the property of MreB filaments in vivo. In addition, suppressor mutations were found in the periplasmic regions in PBP2 and RodA, encoded by mrdA and mrdB genes. Similar to MreB and RodZ, PBP2 and RodA are pivotal to the cell wall elongation process. Thus, we found that mutations in domain IA of MreB and in the periplasmic domain of PBP2 and RodA can restore growth and rod shape to ΔrodZ cells, possibly by changing the requirements of MreB in the process.     

Antimicrobial peptide magainin 2-induced rupture of single giant unilamellar vesicles comprising E. coli polar lipids

Most antimicrobial peptides (AMPs) damage the cell membrane of bacterial cells and induce rapid leakage of the internal cell contents, which is a main cause of their bactericidal activity. One of the AMPs, magainin 2 (Mag), forms nanopores in giant unilamellar vesicles (GUVs) comprising phosphatidylcholine (PC) and phosphatidylglycerol (PG), inducing leakage of fluorescent probes. In this study, to elucidate the Mag-induced pore formation in lipid bilayer region in E. coli cell membrane, we examined the interaction of Mag with single GUVs comprising E. coli polar lipids (E. coli-lipid-GUVs). First, we investigated the Mag-induced leakage of a fluorescent probe AF488 from single E. coli-lipid-GUVs, and found that Mag caused rupture of GUVs, inducing rapid AF488 leakage. The rate constant of Mag-induced GUV rupture increased with the Mag concentration. Using fluorescence microscopy with a time resolution of 5 ms, we revealed the GUV rupture process: first, a small micropore was observed in the GUV membrane, then the pore radius increased within 50 ms without changing the GUV diameter, the thickness of the membrane at the pore rim concomitantly increased, and eventually membrane aggregates were formed. Mag bound to only the outer monolayer of the GUV before GUV rupture, which increased the area of the GUV bilayer. We also examined the physical properties of E. coli-lipid-GUVs themselves. We found that the rate constant of the constant tension-induced rupture of E. coli-lipid-GUVs was higher than that of PG/PC-GUVs. Based on these results, we discussed the Mag-induced rupture of E. coli-lipid-GUVs and its mechanism.     

The Helical MreB Cytoskeleton in Escherichia coli MC1000/pLE7 Is an Artifact of the N-Terminal Yellow Fluorescent Protein Tag

Based on fluorescence microscopy, the actin homolog MreB has been thought to form extended helices surrounding the cytoplasm of rod-shaped bacterial cells. The presence of these and other putative helices has come to dominate models of bacterial cell shape regulation, chromosome segregation, polarity, and motility. Here we use electron cryotomography to show that MreB does in fact form extended helices and filaments in Escherichia coli when yellow fluorescent protein (YFP) is fused to its N terminus but native (untagged) MreB expressed to the same levels does not. In contrast, mCherry fused to an internal loop (MreB-RFP^SW) does not induce helices. The helices are therefore an artifact of the placement of the fluorescent protein tag. YFP-MreB helices were also clearly distinguishable from the punctate, “patchy” localization patterns of MreB-RFP^SW, even by standard light microscopy. The many interpretations in the literature of such punctate patterns as helices should therefore be reconsidered.     

Biosynthesis of poly(3-hydroxybutyrate-co-3-hydroxyvalerate) from glucose with elevated 3-hydroxyvalerate fraction via combined citramalate and threonine pathway in Escherichia coli

The biosynthesis of polyhydroxyalkanoate copolymers in Escherichia coli from unrelated carbon sources becomes attractive nowadays. We previously developed a poly(hydroxybutyrate-co-hydroxyvalerte) (PHBV) biosynthetic pathway from an unrelated carbon source via threonine metabolic route in E. coli (Chen et al., Appl Environ Microbiol 77:4886-4893, 2011). In our study, a citramalate pathway was introduced in recombinant E. coli by cloning a cimA gene from Leptospira interrogans. By blocking the pyruvate and the propionyl-CoA catabolism and replacing the β-ketothiolase gene, the PHBV with 11.5 mol% 3HV fraction was synthesized. Further, the combination of citramalate pathway with the threonine biosynthesis pathway improved the 3HV fraction in PHBV copolymer to 25.4 mol% in recombinant E. coli.     

Crystal structures of <Emphasis Type="Italic">Leptospira interrogans</Emphasis> FAD-containing ferredoxin-NADP<Superscript>+</Superscript> reductase and its complex with NADP<Superscript>+</Superscript>

Background  

Ferredoxin-NADP(H) reductases (FNRs) are flavoenzymes that catalyze the electron transfer between NADP(H) and the proteins ferredoxin or flavodoxin. A number of structural features distinguish plant and bacterial FNRs, one of which is the mode of the cofactor FAD binding. Leptospira interrogans is a spirochaete parasitic bacterium capable of infecting humans and mammals in general. Leptospira interrogans FNR (LepFNR) displays low sequence identity with plant (34% with Zea mays) and bacterial (31% with Escherichia coli) FNRs. However, LepFNR contains all consensus sequences that define the plastidic class FNRs.     

Sublethal High Hydrostatic Pressure Treatment Reveals the Importance of Genes Coding Cytoskeletal Protein in Escherichia Coli Morphogenesis

We studied morphologic changes after sublethal high hydrostatic pressure treatment (HPT) of Escherichia coli K-12 strains in which genes related to the cytoskeleton, cell wall, and cell division had been deleted. Some long filamentous and swelling cells were observed in wild-type bacteria, while some spherical, branched, or collapsed cells were observed in deletion mutants. In particular, ΔzapA and ΔrodZ showed distinguished morphologies. ZapA supports FtsZ, a cytoskeletal protein, forming ring with ZapB. RodZ, a cytoskeletal protein, interacts with MreB, also a cytoskeletal protein, and both factors are necessary for maintaining the rod shape of the cell. These results showed that insufficient formation of FtsZ rings induced cell elongation and that insufficient formation of MreB induced a branched and collapsed cell shape. Therefore, the correct formation of the bacteria cytoskeleton by FtsZ rings and MreB is important for keeping normal cell shape during growth after HPT, and the polymerization of cytoskeletal proteins was a critical target of sublethal HPT. These results indicate that sublethal HPT induces bacterial cell morphologic change and provide important information on the role of genes involved in morphogenesis. Therefore, sublethal HPT may be a good tool for studying the morphogenesis of bacterial cells.     

Manipulating Each MreB of Bdellovibrio bacteriovorus Gives Diverse Morphological and Predatory Phenotypes

We studied the two mreB genes, encoding actinlike cytoskeletal elements, in the predatory bacterium Bdellovibrio bacteriovorus. This bacterium enters and replicates within other Gram-negative bacteria by attack-phase Bdellovibrio squeezing through prey outer membrane, residing and growing filamentously in the prey periplasm forming an infective “bdelloplast,” and septating after 4 h, once the prey contents are consumed. This lifestyle brings challenges to the Bdellovibrio cytoskeleton. Both mreB genes were essential for viable predatory growth, but C-terminal green fluorescent protein tagging each separately with monomeric teal-fluorescent protein (mTFP) gave two strains with phenotypic changes at different stages in predatory growth and development. MreB1-mTFP cells arrested growth early in bdelloplast formation, despite successful degradation of prey nucleoid. A large population of stalled bdelloplasts formed in predatory cultures and predation proceeded very slowly. A small proportion of bdelloplasts lysed after several days, liberating MreB1-mTFP attack-phase cells of wild-type morphology; this process was aided by subinhibitory concentrations of an MreB-specific inhibitor, A22. MreB2-mTFP, in contrast, was predatory at an almost wild-type rate but yielded attack-phase cells with diverse morphologies, including spherical, elongated, and branched, the first time such phenotypes have been described. Wild-type predatory rates were seen for all but spherical morphotypes, and septation of elongated morphotypes was achieved by the addition of A22.The predatory bacterium Bdellovibrio bacteriovorus shows novel filamentous growth within the periplasm of the Gram-negative prey bacterium on which it feeds. This study focuses on the cytoskeletal protein MreB and the role that two homologues of it play in B. bacteriovorus predatory or host-dependent (HD) growth. The HD B. bacteriovorus life cycle can be split into two phases: an attack phase and a growth phase (Fig. ​(Fig.1).1). The attack-phase B. bacteriovorus is a small free-swimming, highly motile cell within which replication has been arrested and which does not take up organic nutrients from the environment or grow extensively (24, 26). Once an attack-phase cell has collided with a suitable prey bacterium, B. bacteriovorus opens and squeezes through a small hole, formed in the outer membrane, using type IV pili to pull itself inside (7, 10). The B. bacteriovorus reseals the hole upon entering the periplasm. Once inside, the prey is killed rapidly within 15 min, and the prey cell wall is partially digested (35), forming a rounded structure called the bdelloplast (see Fig. ​Fig.11 and 4Ac and d). The HD B. bacteriovorus cell then enters the second, growth phase, part of the life cycle, (Fig. ​(Fig.1),1), whereby it grows filamentously while simultaneously coordinating the digestion and transportation of monomers from the prey cytoplasm. The mature growth-phase cell is multiploid and elongates typically 3 to 10 times the length of an attack-phase cell, its length being a reflection of the nutritional resources available in the prey (20). Once resources within the bdelloplast are depleted, the mature filament septates sequentially from one pole to form multiple progeny. These lyse the exhausted bdelloplast, mature into attack-phase cells, and repress growth once again (Fig. ​(Fig.1).1). B. bacteriovorus can be cultured slowly, without prey, as host-independent (HI) cells growing upon peptone-rich medium (30). In these conditions they grow pleiomorphically as mainly long filamentous or serpentine cells, from which some small attack-phase cells septate (30).Open in a separate windowFIG. 1.Schematic host-dependent (HD) predatory cycle for B. bacteriovorus on E. coli prey, showing the different phases of growth and inferred demands on the B. bacteriovorus cell cytoskeleton. References where the roles of the cytoskeleton in cell development have been proven for other bacteria are provided in parentheses. The status of the prey genome is both drawn from an earlier study (26) and confirmed by our work in the present study (see Fig. ​Fig.44).The predatory lifestyle of B. bacteriovorus presents a number of novel developmental challenges to the B. bacteriovorus cell and its cytoskeleton. It is not known how the attack-phase cells deform, allowing the B. bacteriovorus to squeeze through a pore it makes in the prey outer membrane that is narrower than the width of an attack-phase cell, as was imaged by Burnham et al. in the 1960s and more recently by Evans et al. (7, 10). It is also not known how the growth-phase filamentous cell within the bdelloplast is generated and remains resistant to division until terminal sequential septation begins, despite having multiple potential sites for septation along its length while elongating.The processes of cell elongation in rod-shaped bacteria are coordinated by an internal MreB cell cytoskeleton (9). MreB is a eukaryotic actin homologue and has been well studied in Escherichia coli, Bacillus subtilis, and Caulobacter crescentus (38). MreB monomers polymerize on ATP binding, forming helical structures in vivo that appear to associate with the cytoplasmic side of the bacterial cytoplasmic membrane (11, 18, 31). Bacterial two-hybrid experiments in Escherichia coli suggest that MreB forms a transmembrane complex with the two proteins MreC and MreD, each of which have been shown to form helical structures in vivo (21). A complex of MreBCD, together with the RodA protein, influences the shape of the peptidoglycan cell wall and thus the shape of the cell by positioning the peptidoglycan biosynthetic machinery so that its action is directionally specific (9, 19, 37). The MreB filament has also been shown to have roles in chromosome segregation, septation, and cell polarity (13, 14, 22, 37).Depletion of the MreB protein levels in E. coli and B. subtilis led to cells taking on a spherical morphology and eventual loss of viability since new peptidoglycan is not synthesized evenly along the cell wall (9, 36). Uneven incorporation of new peptidoglycan is potentially driven by the tubulin homologue FtsZ (4, 36). A similar phenotype is achieved by addition of the MreB inhibitor A22 that causes the reversible loss of MreB filament localization in vivo (14, 17). A22 was discovered in a chemical library being screened for the ability to generate anucleate minicells from E. coli (16, 17). It has been used extensively by others to examine MreB function in bacteria of many different genera. The addition of A22 to E. coli cells at 3.13 μg/ml leads to the breakdown of MreB filaments, spheroplasting and the generation of minicells (16). In B. subtilis, A22 at concentrations in excess of 100 μg/ml is required to generate spheroplasts; in C. crescentus 6-h incubations of A22 at 10 μg/ml are needed before any change to the cell shape can be observed—in this case cells take on a characteristic “lemon shape” (14, 16). Isolation and sequencing of A22-resistant mutants of C. crescentus, as well as biochemical evidence from purified MreB from Thermotoga maritima, revealed that A22 binds in the nucleotide binding pocket of MreB (3, 14). In vitro light scattering assays of MreB filamentation showed that A22 acted as a competitive inhibitor of ATP binding and was able in inhibit the formation of MreB filaments, presumably by sequestering and inactivating MreB monomers preventing their recycling (3). This study also demonstrated that in vitro A22 can have a role in stabilizing ADP-bound MreB (3).In the present study we investigated the functions of the two MreB homologues found in B. bacteriovorus, testing the role each has in predation and cell morphology by a combination of genetic approaches and A22 treatment. A reduction in function in both MreB proteins, achieved by C-terminal teal fluorescent protein (TFP) tagging, suggests that the MreB1 (Bd0211) protein was required in the growth-phase cell in bdelloplasts, whereas the MreB2 (Bd1737) protein is required later in the predatory process, for maintaining and allowing successful resolution of the growth-phase filament into short attack-phase vibroid cells.     

Pulmonary haemorrhage as the earliest sign of severe leptospirosis in hamster model challenged with Leptospira interrogans strain HP358

BackgroundSevere leptospirosis is challenging as it could evolve rapidly and potentially fatal if appropriate management is not performed. An understanding of the progression and pathophysiology of Leptospira infection is important to determine the early changes that could be potentially used to predict the severe occurrence of leptospirosis. This study aimed to understand the kinetics pathogenesis of Leptospira interrogans strain HP358 in the hamster model and identify the early parameters that could be used as biomarkers to predict severe leptospirosis.Methodology/Principal findingsMale Syrian hamsters were infected with Leptospira interrogans strain HP358 and euthanized after 24 hours, 3, 4, 5, 6 and 7 days post-infection. Blood, lungs, liver and kidneys were collected for leptospiral detection, haematology, serum biochemistry and differential expression of pro- and anti-inflammatory markers. Macroscopic and microscopic organ damages were investigated. Leptospira interrogans strain HP358 was highly pathogenic and killed hamsters within 6–7 days post-infection. Pulmonary haemorrhage and blood vessel congestion in organs were noticed as the earliest pathological changes. The damages in organs and changes in biochemistry value were preceded by changes in haematology and immune gene expression.Conclusion/SignificanceThis study deciphered haemorrhage as the earliest manifestation of severe leptospirosis and high levels of IL-1β, CXCL10/IP-10, CCL3/MIP-α, neutrophils and low levels of lymphocytes and platelets serve as a cumulative panel of biomarkers in severe leptospirosis.     

Dr-FtsA,an Actin Homologue in Deinococcus radiodurans Differentially Affects Dr-FtsZ and Ec-FtsZ Functions In Vitro

The Deinococcus radiodurans genome encodes homologues of divisome proteins including FtsZ and FtsA. FtsZ of this bacterium (Dr-FtsZ) has been recently characterized. In this paper, we study FtsA of D. radiodurans (Dr-FtsA) and its involvement in regulation of FtsZ function. Recombinant Dr-FtsA showed neither ATPase nor GTPase activity and its polymerization was ATP dependent. Interestingly, we observed that Dr-FtsA, when compared with E. coli FtsA (Ec-FtsA), has lower affinity for both Dr-FtsZ and Ec-FtsZ. Also, Dr-FtsA showed differential effects on GTPase activity and sedimentation characteristics of Dr-FtsZ and Ec-FtsZ. For instance, Dr-FtsA stimulated GTPase activity of Dr-FtsZ while GTPase activity of Ec-FtsZ was reduced in the presence of Dr-FtsA. Stimulation of GTPase activity of Dr-FtsZ by Dr-FtsA resulted in depolymerization of Dr-FtsZ. Dr-FtsA effects on GTPase activity and polymerization/depolymerisation characteristics of Dr-FtsZ did not change significantly in the presence of ATP. Recombinant E. coli expressing Dr-FtsA showed cell division inhibition in spite of in trans expression of Dr-FtsZ in these cells. These results suggested that Dr-FtsA, although it lacks ATPase activity, is still functional and differentially affects Dr-FtsZ and Ec-FtsZ function in vitro.