Structural and phylogenetic analysis of the MotA and MotB families of bacterial flagellar motor proteins

Motility Increases the Numbers and Durations of Cell-Surface Engagements for Escherichia coli Flowing near Poly(ethylene glycol)-Functionalized Surfaces

Bacteria are keenly sensitive to properties of the surfaces they contact, regulating their ability to form biofilms and initiate infections. This study examines how the presence of flagella, interactions between the cell body and the surface, or motility itself guides the dynamic contact between bacterial cells and a surface in flow, potentially enabling cells to sense physicochemical and mechanical properties of surfaces. This work focuses on a poly(ethylene glycol) biomaterial coating, which does not retain cells. In a comparison of four Escherichia coli strains with different flagellar expressions and motilities, cells with substantial run-and-tumble swimming motility exhibited increased flux to the interface (3 times the calculated transport-limited rate which adequately described the non-motile cells), greater proportions of cells engaging in dynamic nanometer-scale surface associations, extended times of contact with the surface, increased probability of return to the surface after escape and, as evidenced by slow velocities during near-surface travel, closer cellular approach. All these metrics, reported here as distributions of cell populations, point to a greater ability of motile cells, compared with nonmotile cells, to interact more closely, forcefully, and for greater periods of time with interfaces in flow. With contact durations of individual cells exceeding 10 s in the window of observation and trends suggesting further interactions beyond the field of view, the dynamic contact of individual cells may approach the minute timescales reported for mechanosensing and other cell recognition pathways. Thus, despite cell translation and the dynamic nature of contact, flow past a surface, even one rendered non-cell arresting by use of an engineered coating, may produce a subpopulation of cells already upregulating virulence factors before they arrest on a downstream surface and formally initiate biofilm formation.

Escherichia coli Swimming back Toward Stiffer Polyetheylene Glycol Coatings, Increasing Contact in Flow

Bacterial swimming in flow near surfaces is critical to the spread of infection and device colonization. Understanding how material properties affect flagella- and motility-dependent bacteria-surface interactions is a first step in designing new medical devices that mitigate the risk of infection. We report that, on biomaterial coatings such as polyethylene glycol (PEG) hydrogels and end-tethered layers that prevent adhesive bacteria accumulation, the coating mechanics and hydration control the near-surface travel and dynamic surface contact of E. coli cells in gentle shear flow (order 10 s-1). Along relatively stiff (order 1 MPa) PEG hydrogels or end-tethered layers of PEG chains of similar polymer correlation length, run-and-tumble E. coli travel nanometrically close to the coating's surface in the flow direction in distinguishable runs or "engagements" that persist for several seconds, after which cells leave the interface. The duration of these engagements was greater along stiff hydrogels and end-tethered layers compared with softer, more-hydrated hydrogels. Swimming cells that left stiff hydrogels or end-tethered layers proceeded out to distances of a few microns and then returned to engage the surface again and again, while cells engaging the soft hydrogel tended not to return after leaving. As a result of differences in the duration of engagements and tendency to return to stiff hydrogel and end-tethered layers, swimming E. coli experienced 3 times the integrated dynamic surface contact with stiff coatings compared with softer hydrogels. The striking similarity of swimming behaviors near 16-nm-thick end-tethered layers and 100-μm-thick stiff hydrogels argues that only the outermost several nanometers of a highly hydrated coating influence cell travel. The range of material stiffnesses, cell-surface distance during travel, and time scales of travel compared with run-and-tumble time scales suggests the influence of the coating derives from its interactions with flagella and its potential to alter flagellar bundling. Given that restriction of flagellar rotation is known to trigger increased virulence, bacteria influenced by surfaces in one region may become predisposed to form a biofilm downstream.

The Structure of Treponema pallidum Tp0624 Reveals a Modular Assembly of Divergently Functionalized and Previously Uncharacterized Domains

Treponema pallidum subspecies pallidum is the causative agent of syphilis, a chronic, multistage, systemic infection that remains a major global health concern. The molecular mechanisms underlying T. pallidum pathogenesis are incompletely understood, partially due to the phylogenetic divergence of T. pallidum. One aspect of T. pallidum that differentiates it from conventional Gram-negative bacteria, and is believed to play an important role in pathogenesis, is its unusual cell envelope ultrastructure; in particular, the T. pallidum peptidoglycan layer is chemically distinct, thinner and more distal to the outer membrane. Established functional roles for peptidoglycan include contributing to the structural integrity of the cell envelope and stabilization of the flagellar motor complex, which are typically mediated by the OmpA domain-containing family of proteins. To gain insight into the molecular mechanisms that govern peptidoglycan binding and cell envelope biogenesis in T. pallidum we report here the structural characterization of the putative OmpA-like domain-containing protein, Tp0624. Analysis of the 1.70 Å resolution Tp0624 crystal structure reveals a multi-modular architecture comprised of three distinct domains including a C-terminal divergent OmpA-like domain, which we show is unable to bind the conventional peptidoglycan component diaminopimelic acid, and a previously uncharacterized tandem domain unit. Intriguingly, bioinformatic analysis indicates that the three domains together are found in all orthologs from pathogenic treponemes, but are not observed together in genera outside Treponema. These findings provide the first structural insight into a multi-modular treponemal protein containing an OmpA-like domain and its potential role in peptidoglycan coordination and stabilization of the T. pallidum cell envelope.

Crystallographic and molecular dynamics analysis of loop motions unmasking the peptidoglycan-binding site in stator protein MotB of flagellar motor

Background

The C-terminal domain of MotB (MotB-C) shows high sequence similarity to outer membrane protein A and related peptidoglycan (PG)-binding proteins. It is believed to anchor the power-generating MotA/MotB stator unit of the bacterial flagellar motor to the peptidoglycan layer of the cell wall. We previously reported the first crystal structure of this domain and made a puzzling observation that all conserved residues that are thought to be essential for PG recognition are buried and inaccessible in the crystal structure. In this study, we tested a hypothesis that peptidoglycan binding is preceded by, or accompanied by, some structural reorganization that exposes the key conserved residues.

Methodology/Principal Findings

We determined the structure of a new crystalline form (Form B) of Helicobacter pylori MotB-C. Comparisons with the existing Form A revealed conformational variations in the petal-like loops around the carbohydrate binding site near one end of the β-sheet. These variations are thought to reflect natural flexibility at this site required for insertion into the peptidoglycan mesh. In order to understand the nature of this flexibility we have performed molecular dynamics simulations of the MotB-C dimer. The results are consistent with the crystallographic data and provide evidence that the three loops move in a concerted fashion, exposing conserved MotB residues that have previously been implicated in binding of the peptide moiety of peptidoglycan.

Conclusion/Significance

Our structural analysis provides a new insight into the mechanism by which MotB inserts into the peptidoglycan mesh, thus anchoring the power-generating complex to the cell wall.

TransportDB: a relational database of cellular membrane transport systems

TransportDB (http://www.membranetransport.org) is a relational database designed for describing the predicted cellular membrane transport proteins in organisms whose complete genome sequences are available. For each organism, the complete set of membrane transport systems was identified and classified into different types and families according to putative membrane topology, protein family, bioenergetics and substrate specificities. Web pages were created to provide user-friendly interfaces to easily access, query and download the data. Additional features, such as a BLAST search tool against known transporter protein sequences, comparison of transport systems from different organisms and phylogenetic trees of individual transporter families are also provided. TransportDB will be regularly updated with data obtained from newly sequenced genomes.

Helicobacter pylori uses motility for initial colonization and to attain robust infection

Helicobacter pylori has been shown to require flagella for infection of the stomach. To analyze whether flagella themselves or motility is needed by these pathogens, we constructed flagellated nonmotile mutants. This was accomplished by using both an insertion mutant and an in-frame deletion of the motB gene. In vitro, these mutants retain flagella (Fla(+)) but are nonmotile (Mot(-)). By using FVB/N mice, we found that these mutants had reduced ability to infect mice in comparison to that of their isogenic wild-type counterparts. When these mutants were coinfected with wild type, we were unable to detect any motB mutant. Finally, by analyzing the 50% infectious dose, we found that motility is needed for initial colonization of the stomach mucosa. These results support a model in which motility is used for the initial colonization of the stomach and also to attain full infection levels.

Phylogenetic approaches to the identification and characterization of protein families and superfamilies

With the advent of megabase genome sequencing, the need for computational analyses increases exponentially. Sequencing errors must be corrected, encoded proteins must be identified, functions must be assigned to these proteins, and distant phylogenetic relationships must be recognized in order to maximize the yield of information obtainable from genome sequencing projects. Both the computer and the human brain have their limitations, but using them in combination, the biologist can vastly extend his or her analytic capabilities. Computer techniques can be used to estimate protein structure, function, biogenesis, and evolution. In this review, the application of available computer programs to several protein families, particularly transport, receptor, and transcriptional regulatory protein families, illustrate our current capabilities and limitations. Although some multidomain protein families are evolutionarily homogeneous, others have mosaic origins. Evidence concerning the nature and frequency of occurrence of domain shuffling, splicing, fusion, deletion, and duplication during evolution of specific protein families is evaluated. It is shown that specific families of enzymes, receptors, transport proteins, and transcriptional regulatory proteins share a common evolutionary origin, frequently diverging in function because of domain splicing and ligation. Some large families arose gradually over evolutionary time, whereas others developed suddenly, due to bursts of intragenic or intergenic (or both) duplication events occurring over relatively short periods of time. It is argued that energy coupling to transport was a late occurrence, superimposed on preexisting mechanisms of solute facilitation. It is also shown that several transport protein families have evolved independently of each other, employing different routes, at different times in evolutionary history, to give topologically similar transmembrane protein complexes.

Microbial genome analyses: global comparisons of transport capabilities based on phylogenies, bioenergetics and substrate specificities

We have conducted genome sequence analyses of seven prokaryotic microorganisms for which completely sequenced genomes are available (Escherichia coli, Haemophilus influenzae, Helicobacter pylori, Bacillus subtilis, Mycoplasma genitalium, Synechocystis PCC6803 and Methanococcus jannaschii). We report the distribution of encoded known and putative polytopic cytoplasmic membrane transport proteins within these genomes. Transport systems for each organism were classified according to (1) putative membrane topology, (2) protein family, (3) bioenergetics, and (4) substrate specificities. The overall transport capabilities of each organism were thereby estimated. Probable function was assigned to greater than 90% of the putative transport proteins identified. The results show the following: (1) Numbers of transport systems in eubacteria are approximately proportional to genome size and correspond to 9.7 to 10.8% of the total encoded genes except for H. pylori (5.4%), Synechocystis (4.7%) and M. jannaschii (3.5%) which exhibit substantially lower proportions. (2) The distribution of topological types is similar in all seven organisms. (3) Transport systems belonging to 67 families were identified within the genomes of these organisms, and about half of these families are also found in eukaryotes. (4) 12% of these families are found exclusively in Gram-negative bacteria, but none is found exclusively in Gram-positive bacteria, cyanobacteria or archaea. (5) Two superfamilies, the ATP-binding cassette (ABC) and major facilitator (MF) superfamilies account for nearly 50% of all transporters in each organism, but the relative representation of these two transporter types varies over a tenfold range, depending on the organism. (6) Secondary, pmf-dependent carriers are 1.5 to threefold more prevalent than primary ATP-dependent carriers in E. coli, H. influenzae, H. pylori and B. subtilis while primary carriers are about twofold more prevalent in M. genitalium and Synechocystis. M. jannaschii exhibits a slight preference for secondary carriers. (7) Bioenergetics of transport generally correlate with the primary forms of energy generated via available metabolic pathways but ecological niche and substrate availability may also be determining factors. (8) All organisms display a similar range of transport specificities with quantitative differences presumably reflective of disparate ecological niches. (9) M. jannaschii and Synechocystis have a two to threefold increased proportion of transporters for inorganic ions with a concomitant decrease in transporters for organic compounds. (10) 6 to 18% of all transporters in these bacteria probably function as drug export systems showing that these systems are prevalent in non-pathogenic as well as pathogenic organisms. (11) All seven prokaryotes examined encode proteins homologous to known channel proteins, but none of the channel types identified occurs in all of these organisms. (12) The phosphoenolpyruvate:sugar phosphotransferase system is prevalent in the large genome organisms, E. coli and B. subtilis, and is present in the small genome organisms, H. influenzae and M. genitalium, but is totally lacking in H. pylori, Synechocystis and M. jannaschii. Details of the information summarized in this article are available on our web sites, and this information will be periodically updated and corrected as new sequence and biochemical data become available.

Putative channel components for the fast-rotating sodium-driven flagellar motor of a marine bacterium

The polar flagellum of Vibrio alginolyticus rotates remarkably fast (up to 1,700 revolutions per second) by using a motor driven by sodium ions. Two genes, motX and motY, for the sodium-driven flagellar motor have been identified in marine bacteria, Vibrio parahaemolyticus and V. alginolyticus. They have no similarity to the genes for proton-driven motors, motA and motB, whose products constitute a proton channel. MotX was proposed to be a component of a sodium channel. Here we identified additional sodium motor genes, pomA and pomB, in V. alginolyticus. Unexpectedly, PomA and PomB have similarities to MotA and MotB, respectively, especially in the predicted transmembrane regions. These results suggest that PomA and PomB may be sodium-conducting channel components of the sodium-driven motor and that the motor part consists of the products of at least four genes, pomA, pomB, motX, and motY. Furthermore, swimming speed was controlled by the expression level of the pomA gene, suggesting that newly synthesized PomA proteins, which are components of a force-generating unit, were successively integrated into the defective motor complexes. These findings imply that Na+-driven flagellar motors may have similar structure and function as proton-driven motors, but with some interesting differences as well, and it is possible to compare and study the coupling mechanisms of the sodium and proton ion flux for the force generation.