Cytokines and bacterial infections

During the recent 10–15 years a growing amount of knowledge has been accumulated on the role of cytokines in the pathogenesis and resistance to infections caused by nonviral agents, including a wide range of bacteria. Cytokines can be major mediators of the pathogenic effect in some diseases, and represent important defense mechanisms in others. Detailed knowledge on the role of the growing number of recognised cytokines is important, because it may represent means to combat and to prevent diseases caused by such infections.     

Genomics and bacterial metabolism

The field of bacterial metabolism and physiology is arguably the oldest in microbiology. Much of our understanding of biological processes and molecular paradigms has its roots In early studies of prokaryotic physiology. After a period of declining interest in metabolic studies (prompted by the insurgence of molecular techniques), genomic technologies are revitalizing the study of bacterial metabolism and physiology. These new technologies bring a means to approach metabolic questions with a global perspective. When used in combination with classical and molecular techniques, emerging global technologies will make it feasible to understand the complex integration of metabolic processes that result in an efficient physiology. At the same time, without increased computational capabilities, the massive amounts of data generated by these technologies threaten to overwhelm, rather than facilitate, this work. For genomic technologies to reach their potential for increasing our understanding of bacterial metabolism, microbiologists must become more collaborative and multidisciplinary than at any time in our history.     

Tracking bacterial growth in liquid media and a new bacterial life model

By increasing viscosity of liquid media above 8.4 centipoise (cp) i.e. 0.084 g·cm~(-1)·S~(-1) individual growth and family formation of Escherichia coli was continuously observed in real-time for up to 6 h. The observations showed primarily unidirectional growth and reproduction of E. coli and suggested more than one reproduction in the observed portion of E. coli life span. A new bacterial life model is proposed: each bacterium has a stable cell polarity that ultimately transforms into two bacteria of different generations; the life cycle of a bacterium can contain more than one reproduction cycle; and the age of a bacterium should be defined by its experienced chronological time. This new bacterial life model differs from the dominant concepts of bacterial life but complies with all basic life principles based on direct observation of macroorganisms.     

Statistical sampling of bacterial strains and its use in bacterial diversity measurement

The cultural bacterial strains of two sediment samples, i.e., 260 strains, were submitted to numerical taxonomy to determine ecological profiles. From these profiles several calculations of bacterial diversity were done with increasing number of strains (between 10 and 130). Studying 20–30 strains was sufficient to obtain a diversity of bacterial community.Number of tests could be reduced from 62 to 30 without any influence on bacterial diversity. Similarity between studied tests was shown by using numerical taxonomy.     

Tracking bacterial growth in liquid media and a new bacterial life model

By increasing viscosity of liquid media above 8.4 centipoise (cp) i.e. 0.084 g· cm^-1 · s^-1, individual growth and family formation ofEscherichia coli was continuously observed in real-time for up to 6 h. The observations showed primarily unidirectional growth and reproduction ofE. coli and suggested more than one reproduction in the observed portion ofE. coli life span. A new bacterial life model is proposed: each bacterium has a stable cell polarity that ultimately transforms into two bacteria of different generations; the life cycle of a bacterium can contain more than one reproduction cycle; and the age of a bacterium should be defined by its experienced chronological time. This new bacterial life model differs from the dominant concepts of bacterial life but complies with all basic life principles based on direct observation of macroorganisms.     

FtsZ and bacterial cell division

In this review we describe proteins and supermolecular structures which take part in the division of bacterial cells. FtsZ, a eukaryotic tubulin homolog is a key cell division protein in most prokaryotes. FtsZ, as well as tubulin, is capable of binding and hydrolyzing GTP. The division of a bacterial cell begins with the forming of a so-called divisome. The basis of such a divisome is a contractile ring (Z ring) which encircles the cell about midcell. The Z-ring consists of a bundle of laterally bound protofilaments formed in result of FtsZ polymerization. Z-ring is rigidly bounded to the cytosolic side of the inner membrane with the participation of FtsA, ZipA, FtsW and many other divisome cell division proteins. The ring directs the process of cytokinesis transmitting constriction power to the membrane. The primary structures of the prokaryotic FtsZ family members significantly differ from eukaryotic tubulins except for the sites of GTP binding. There is a high degree of structural homology between these proteins in the region. FtsZ is one of the most conserved proteins in prokaryotes. However, ftsZ genes have not been found in several species of microorganisms with completely sequenced genomes. They include two species of mycoplasmas (Ureaplasma parvum and Mycoplasma mobile), Prostecobacter dejongeii, 10 species of chlamydia and 5 species of archaea. Consequently, these organisms divide without FtsZ participation. The genomes of U. parvum and M. mobile have many open reading frames which encode proteins with unknown functions. A comparison of the primary structures of these hypothetical proteins did not identify any known cell division proteins. We hypothesize that the process of cell division in these organisms should involve proteins similar to FtsZ in function and homologous to FtsZ or other cell division proteins in structure.     

Protonmotive force and bacterial sensing

The role of the proton gradient and external pH in the motility and chemotaxis of Bacillus subtilis was investigated. Presence of a substantial proton gradient is not necessary for motility or chemotaxis, as long as the electrical potential is sufficient to maintain motility. Changes in the proton gradient do, however, lead to changes in swimming behavior, and these changes are mediated by two processes. One is sensitive to external pH and probably operates through a pH receptor. The second is sensitive to changes in the proton gradient. When the level of the protonmotive force is high enough to maintain motiligy, changes in the components of the protonmotive force are sensed by the bacteria and lead to behavioral changes, but changes in the protonmotive force are not necessary for chemotaxis.     

Stress-inducible bacterial proteins and virulence

Different species of pathogenic bacteria, including Salmonella, Neisseria, Listeria and Francisella have been used to demonstrate relationship between the synthesis of stressor induced proteins by cells and the phenotypic manifestation of their virulence. The impact of such external factors as high temperature, low pH, osmolarity, substrate limitation, the content of active forms of oxygen, etc. is accompanied by the synthesis of different stressor induced proteins playing a complex role. Under unfavorable environmental conditions the synthesis of these proteins ensures the survival of the infective agents. Under conditions of a macroorganism synthesis of some stressor induced proteins promotes the survival of infective agents and their resistance to the action of humoral and cell-mediated protective factors of the host. As is known, the expression of virulence genes is not constitutive. The expression of these genes greatly depends on environmental conditions and its induction is determined by extra- or intracellular location of the infective agent. Several systems of the regulation of bacterial pathogenicity factors have been described that are relatively not numerous, conservative and respond to external signals. The relevance of a number of stressor induced proteins of bacteria to virulence associated factors is discussed.     

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.     

Antimicrobial use and bacterial resistance

The current epidemic of bacterial resistance is attributed, in part, to the overuse of antibiotics. Recent studies have documented increases in resistance with over-use of particular antibiotics and improvements in susceptibility when antibiotic use is controlled. The most effective means of improving use of antibiotics is unknown. Comprehensive management programs directed by multi-disciplinary teams, computer-assisted decision-making, and antibiotic cycling have been beneficial in controlling antibiotic use, decreasing costs without impacting patient outcomes, and possibly decreasing resistance.