A bacterial actin unites to divide bacterial cells

EMBO J 31 10, 2249–2260 (2012); published online March302012Once thought to exist only in eukaryotic cells, the highly conserved bacterial cytoskeleton is now known to function analogously to its eukaryotic counterparts, particularly in cell shape and division. For instance, the actin-like MreB protein and its homologs are important to maintain cell shape in many rod-shaped bacteria, probably by organizing how peptidoglycan is synthesized. FtsZ, a tubulin homolog, forms a scaffold for the cytokinetic ring, or divisome, by GTP-dependent polymerization into protofilaments. In this issue of The EMBO Journal, Szwedziak et al (2012) reveal the first crystal structures of cell division protein FtsA polymerizing into actin-like filaments, along with in vivo evidence that this self-interaction is crucial for proper cell division.FtsA is an actin homolog required for cytokinesis in many bacterial species and has several key roles in cell division, including helping to tether FtsZ to the cytoplasmic membrane via a membrane-targeting sequence (MTS), recruiting other essential proteins to the divisome, and perhaps promoting divisome constriction (de Boer, 2010). Szwedziak et al (2012) recapitulate the FtsZ-FtsA-membrane association in vitro using liposomes with FtsZ and FtsA proteins from Thermotoga maritima. To get a closer look at the FtsA-FtsZ interface, the authors co-crystallize FtsA with the carboxy-terminal tail of FtsZ, which is known to interact with FtsA. Intriguingly, the crystal reveals an FtsA homodimer. Contrary to the previous bioinformatics model of FtsA self-interaction that proposed a 180° rotation between the two subunits (Carettoni et al, 2003), the FtsA-FtsA interface in the crystal structure shows no rotation, similar to F-actin. Szwedziak et al (2012) also show that FtsA can form longer, actin-like polymers in the presence of non-hydrolysable ATP or on lipid monolayers. These results are surprising because FtsA has a divergent subdomain architecture compared to other actin-family proteins (van den Ent and Löwe).A critical question now is whether FtsA needs to form polymers in vivo to function properly. Purified Streptococcus pneumoniae FtsA assembles into large polymers that are not like F-actin, and it remains unclear if these structures are relevant in vivo (Krupka et al, 2012). Wild-type FtsA proteins do not form detectable filaments in cells, but C-terminal truncations of FtsA that remove the MTS form polymers quite readily in cells when overproduced, although they are not functional (Pichoff and Lutkenhaus, 2007). Even so, starting with an MTS truncation derivative of FtsA to visualize in vivo polymers, Szwedziak et al (2012) design site-directed mutants of Bacillus subtilis FtsA based on the FtsA-FtsA interface of their crystals; these fail to assemble into polymers in vivo. Using a similar MTS truncation derivative, Pichoff et al (2012) created random mutations in Escherichia coli FtsA, and found that those mapping to the same interface found by Szwedziak et al (2012) also disrupted polymer formation. Together, these data suggest that these residues are needed for FtsA self-interaction. Perplexingly, when these mutants were subsequently tested for functionality in the context of full-length FtsA, the results were mixed. Pichoff et al (2012) showed that FtsA mutants deficient for self-interaction in E. coli have a gain-of-function phenotype, whereas Szwedziak et al (2012) report that analogous mutants in B. subtilis FtsA suffer a loss of function. These results support the idea that FtsA self-association is related to its activity (Shiomi and Margolin, 2007), yet understanding how self-interaction regulates FtsA function clearly requires further study.The ability of eukaryotic cytoskeletal proteins to form long polymers is essential to their function, but the physiological relevance of long polymer formation by bacterial cytoskeletal proteins is now a topic of debate (Figure 1). For example, it has been hypothesized that FtsZ protofilaments wrap around the entire circumference of the cell to form the cytokinetic ring. However, recent studies using photoactivated localization microscopy (PALM) and electron cryotomography reveal a different model in which FtsZ forms a series of very short polymers that overlap to encompass the diameter of the cell (Li et al, 2007; Fu et al, 2010). MreB was also originally thought to form long-range helical polymers extending the length of the cell, but recent data obtained with more sophisticated microscopic techniques suggest that MreB is distributed in patches that move circumferentially and independently (White and Gober, 2012). It is not yet clear which of these models represents the true cellular architecture of MreB, although it is likely that some degree of MreB polymerization is still needed for function. It is notable that other bacterial homologs of actin and tubulin used for generating scaffolds or partitioning plasmid DNA, but not for essential cellular processes such as cell division and growth, tend to form long polymers that extend throughout the cell (Pogliano, 2008). The continued combined use of microscopic, biochemical, and genetic methods, as demonstrated by Szwedziak et al (2012) will enhance future understanding of ancestral tubulin and actin proteins in prokaryotes.Open in a separate windowFigure 1Bacterial actin and tubulin filaments involved in cell growth and division. (A) MreB (purple) has long been thought of as a spiral filament twisting along the cell length to control cell shape. Likewise, FtsZ protofilaments (blue) were once thought to wrap around the cell midpoint to organize the divisome. (B) Recent work using high-resolution microscopy has revealed that long cytoskeletal filaments are more likely to be short patches of polymers. The present work by Szwedziak et al (2012) has added FtsA actin-like filaments (green) to the model of possible divisome architecture.     

Beta-lactamases and bacterial resistance to antibiotics

The efficiency of β-lactam antibiotics, which are among our most useful chemotherapeutic weapons, is continuously challenged by the emergence of resistant bacterial strains. This is most often due to the production of β-lactamases by the resistant cells. These enzymes inactivate the antibiotics by hydrolysing the β-lactam amide bond. The elucidation of the structures of some β-lactamases by X-ray crystallography has provided precious insights into their catalytic mechanisms and revealed unsuspected similarities with the DD-transpeptidases, the bacterial enzymes which constitute the lethal targets of β-lactams. Despite numerous kinetic, structural and site-directed mutagenesis studies, we have not completely succeeded in explaining the diversity of the specificity profiles of β-lactamases and their surprising catalytic power. The solutions to these problems represent the cornerstones on which better antibiotics can be designed, hopefully on a rational basis.     

Plasmids and bacterial resistance to biocides

Plasmid-encoded fu1 bacterial resistance to antibiotics and to anions and cations (including important mercurial and silver compounds) has been widely studied. Plasmid-mediated resistance to organic cationic agents which are important biocides has been described for chlorhexidine and quaternary ammonium compounds (and also for the less important acridines, diamidines and ethidium bromide) in antibiotic-resistant Staphylococcus aureus and Staph. epidermidis strains. Plasmids may also encode reduced biocide susceptibility of Gram-negative bacteria, but intrinsic resistance is likely to be of greater significance. Antibiotic resistance and biocide resistance may be linked but this is not always found clinically.     

Characterizing bacterial resistance to preservatives and disinfectants

Bacterial resistance to preservatives and disinfectants is a problem with serious economic and health consequences. Understanding the basis of resistance may lead to strategies or chemistries capable of reversing or subverting the mechanism. A collection of bacterial isolates resistant to dimethoxydimethyl hydantoin, glutaraldehyde, methylchloroisothiazolone/methylisothiazolone, and benzisothiazolone, as well as combination preservatives, has been gathered. In addition, a perusal of the literature also reveals reports of resistance to quaternary ammonium compounds, biguanides, iodophors, and peroxides, suggesting no particular chemistry is immune to resistance development. The majority of isolates in the collection are members of the genera Pseudomonas and Burkholderia, along with several representatives of the genus Alcaligenes and Enterobacter. Characterization of their susceptibility to other preservatives and disinfectants revealed several patterns of cross-resistance. All isolates were resistant to biocides other than the selecting compound. Several isolates were cross-resistant to either a quaternary ammonium compound or hydrogen peroxide; one P. fluorescens isolate was cross-resistant to both disinfectants. The presence of cross-resistance among preservatives and disinfectants has serious implications for the ability to eradicate resistant microbes from contaminated surfaces or manufacturing processes using commonly accepted disinfectants.     

Contribution of bacterial outer membrane vesicles to innate bacterial defense

Background

Microorganisms produce cell-wall-degrading enzymes as part of their strategies for plant invasion/nutrition. Among these, pectin lyases (PNLs) catalyze the depolymerization of esterified pectin by a β-elimination mechanism. PNLs are grouped together with pectate lyases (PL) in Family 1 of the polysaccharide lyases, as they share a conserved structure in a parallel β-helix. The best-characterized fungal pectin lyases are obtained from saprophytic/opportunistic fungi in the genera Aspergillus and Penicillium and from some pathogens such as Colletotrichum gloeosporioides. The organism used in the present study, Colletotrichum lindemuthianum, is a phytopathogenic fungus that can be subdivided into different physiological races with different capacities to infect its host, Phaseolus vulgaris. These include the non-pathogenic and pathogenic strains known as races 0 and 1472, respectively.

Results

Here we report the isolation and sequence analysis of the Clpnl2 gene, which encodes the pectin lyase 2 of C. lindemuthianum, and its expression in pathogenic and non-pathogenic races of C. lindemuthianum grown on different carbon sources. In addition, we performed a phylogenetic analysis of the deduced amino acid sequence of Clpnl2 based on reported sequences of PNLs from other sources and compared the three-dimensional structure of Clpnl2, as predicted by homology modeling, with those of other organisms. Both analyses revealed an early separation of bacterial pectin lyases from those found in fungi and oomycetes. Furthermore, two groups could be distinguished among the enzymes from fungi and oomycetes: one comprising enzymes from mostly saprophytic/opportunistic fungi and the other formed mainly by enzymes from pathogenic fungi and oomycetes. Clpnl2 was found in the latter group and was grouped together with the pectin lyase from C. gloeosporioides.

Conclusions

The Clpnl2 gene of C. lindemuthianum shares the characteristic elements of genes coding for pectin lyases. A time-course analysis revealed significant differences between the two fungal races in terms of the expression of Clpnl2 encoding for pectin lyase 2. According to the results, pectin lyases from bacteria and fungi separated early during evolution. Likewise, the enzymes from fungi and oomycetes diverged in accordance with their differing lifestyles. It is possible that the diversity and nature of the assimilatory carbon substrates processed by these organisms played a determinant role in this phenomenon.     

Proteomic approaches to bacterial differentiation

Mass spectrometry-based proteomics has been used extensively to explore the proteomes of various organisms, and this technology is now being applied to the characterization of bacterial species. Predominantly, two methods emerge as leaders in this application. Intact protein profiling creates fingerprints of bacterial species which can be used for differentiation and tracking over time. Peptide-centric approaches, analyzed after enzymatic digestion, enable high-throughput proteome characterization in addition to species determination from the identification of peptides distinctive to a species. Highlighted herein is an application of a peptide-centric approach to the identification and quantitation of species-specific peptide identifiers using an in silico exploration and an experimental mass spectrometry-based method. The application to microbial communities is addressed with an in silico analysis of an artificial complex community of 25 microorganisms.     

Mechanisms of bacterial resistance and response to bile

Enteric bacteria are resistant to the bactericidal effects of intestinal bile, but these resistance mechanisms are not completely understood. It is becoming increasingly apparent that enteric bacteria have evolved to utilize bile as a signal for the temporal production of virulence factors and other adaptive mechanisms. A greater understanding of the resistance and response of bacteria to bile may assist the development of novel therapeutic, prevention, and diagnostic strategies to treat enteric and extraintestinal infections.     

Activation of nitrosomorpholine and nitrosopyrrolidine to bacterial mutagens

We have shown that nitrosomorpholine and nitrosopyrrolidine are metabolized by rat liver homogenates to mutagens active on Salmonella typhomurium. The resulting mutations seem to have been caused by base-pair substitutions and therefore are believed to be due to alkylations.     

Genetically engineered resistance to bacterial and fungal pathogens

In the past 10 years, different strategies have been used to produce transgenic plants that are less susceptible to diseases caused by phytopathogenic fungi and bacteria. Genes from different organisms, including bacteria, fungi and plants, have been successfully used to develop these strategies. Some strategies have been shown to be effective against different pathogens, whereas others are specific to a single pathogen or even to a single pathovar or race of a given pathogen. In this review, we present the strategies that have been employed to produce transgenic plants less susceptible to bacterial and fungal diseases and which constitute an important area of plant biotechnology.The authors are with the Departamento de Ingeniería Genética de Plantas. Centro de Investigación y de Estudios Avanzados del IPN-Unidad Irapuato, Km 9.6 del Libramiento Norte carretera Irapuato-León, Apdo Postal 629, Irapuato, Mexico.     

Production of sound waves by bacterial cells and the response of bacterial cells to sound

Bacterial cells enhance the proliferation of neighboring cells under stress conditions by emitting a physical signal. Continuous single sine sound waves produced by a speaker at frequencies of 6-10, 18-22, and 28-38 kHz promoted colony formation by Bacillus carboniphilus under non-permissive stress conditions of high KCl concentration and high temperature. Furthermore, sound waves emitted from cells of Bacillus subtilis at frequencies between 8 and 43 kHz with broad peaks at approximately 8.5, 19, 29, and 37 kHz were detected using a sensitive microphone system. The similarity between the frequency of the sound produced by B. subtilis and the frequencies that induced a response in B. carboniphilus and the previously observed growth-promoting effect of B. subtilis cells upon B. carboniphilus through iron barriers, suggest that the detected sound waves function as a growth-regulatory signal between cells.     

New method to study bacterial adhesion to meat

A new method was developed for the study of bacterial adhesion to meat surfaces. Thin slices of meat (40 microns thick) were inserted into a specially designed observation chamber. The meat slices were then exposed to a bacterial suspension (ca. 10(6) CFU.ml-1) to initiate adhesion (20 min of contact time) and subsequently rinsed to eliminate nonadherent bacteria. Because of the special chamber design, the disruptive force exerted on the bacteria during rinsing (shear stress) was uniform over the whole surface of the meat slices, was constant, and could be varied from 0 to 0.08 N.m-2. After being rinsed, the meat slices were stained with basic fuschin and observed under light microscopy to determine the number and distribution of adherent bacteria. This new method was used to study the adhesion of Acinetobacter strain LD2, a Lactobacillus sp., and Pseudomonas fluorescens to slices of beef fat and tendon. At 25 degrees C, most (greater than or equal to 99.9%) of the cells of the Lactobacillus sp. deposited on the meat were washed off the surface during rinsing (0.05 N.m-2), whereas a large number (ca. 10(5) CFU.cm-2) of Acinetobacter strain LD2 and P. fluorescens cells remained adherent. The extent of adhesion was similar on fat and tendon, and adherent bacteria were distributed evenly over the whole surface of the slices. This preliminary study indicates that the combined use of thin slices of meat and of the observation chamber provides us with the means to more accurately study bacterial adhesion to meat surfaces.     

Human adiponectin binds to bacterial lipopolysaccharide

Adiponectin has anti-inflammatory and anti-atherogenic properties in addition to its acknowledged roles in insulin sensitivity and energy homeostasis. These properties include the suppression of lipopolysaccharide [LPS]-mediated inflammatory events. We demonstrated that both recombinant and native adiponectin directly bind LPS derived from three different bacteria. The interaction occurred at pH 5.0-6.0 and was inhibited by the presence of Ca(2+) and Mg(2+), but enhanced by the sequestration of these cations. Maximal binding occurred at pH 6.0 in the presence of ethylenediaminetetraacetic acid. Lipid A and C1q were not inhibitory, although LPS, heparin, zymosan, and individual sugars all inhibited the reaction. Periodate-mediated deglycosylation of adiponectin, and reduction and alkylation also inhibited binding. Since adiponectin infiltrates into [relatively] acidic sites of inflammation, it may act as a scavenging anti-inflammatory agent in atherosclerosis and vascular damage where LPS [and other pro-inflammatory molecules] are present.