Beta-barrel Outer Membrane Research Articles

A new multi-epitope DNA vaccine against Helicobacter Pylori infection in a BALB/c mouse model

BackgroundHelicobacter Pylori (H. Pylori) is a pathogen that may invade the human stomach. This bacterial strain is now causing widespread concern and considerable health issues worldwide. In contrast to antibiotic treatment, which may lead to drug resistance, vaccination therapy is emerging as a possible immunotherapy option for H. Pylori. DNA vaccines are a potential option to traditional vaccines among vaccine research methods. Furthermore, the multiepitope DNA vaccination may induce a broader immune response to suppress H. Pylori infection. MethodsFour target antigenic proteins (outer membrane beta-barrel, outer membrane beta, HofA, and hcp beta-lactamase-like protein) were used to identify epitopes. The best B and T cell epitopes were selected to induce humoral and cellular immune responses and were connected using the HEYGAEALERAG and GGGS linkers. The peptide's physicochemical characteristics, secondary and tertiary structures, antigenicity, and allergenicity were evaluated utilizing several bioinformatics tools. The multiepitope peptide was successfully inserted into the pcDNA3.1 expression vector. The immunological responses of both the vaccinated and control groups were evaluated by measuring cytokines and antibodies. ResultsBased on the data, the multiepitope peptide consists of 278 amino acid residues and has an average molecular weight (MW) of 28643.61 Da. The peptide residues were mainly situated within the preferred and permitted areas of the Ramachandran plot, accounting for 92.86% of the total. The VaxiJen server has calculated that the multiepitope peptide has an antigenicity score of 1.0067. BALB/c mice vaccinated with the DNA vaccine produced significantly higher levels of specific IgG antibodies (p<0.05). The vaccinated mice exhibited a TH1-type cellular immune response characterized by the generation of IFN-γ and a longer length of life compared to the control animals (p<0.05). In addition, the vaccination group exhibited a substantial increase in the expression level of IFN-γ and IL-1β genes compared to the control group (p<0.05). ConclusionsThe results demonstrated that the multiepitope DNA vaccine elicited significant humoral and cellular responses, and increased survival time in BALB/c mice, indicating that selecting potential epitopes may be a viable technique for developing multiepitope-based vaccines. This can help to introduce effective vaccines.

Structural bioinformatics studies of bacterial outer membrane beta-barrel transporters and their AlphaFold2 predicted water-soluble QTY variants.

Beta-barrel outer membrane proteins (OMP) are integral components of Gram-negative bacteria, eukaryotic mitochondria, and chloroplasts. They play essential roles in various cellular processes including nutrient transport, membrane stability, host-pathogen interactions, antibiotic resistance and more. The advent of AlphaFold2 for accurate protein structure predictions transformed structural bioinformatic studies. We previously used a QTY code to convert hydrophobic alpha-helices to hydrophilic alpha-helices in over 50 membrane proteins with all alpha-helices. The QTY code systematically replaces hydrophobic leucine (L), isoleucine (I), valine (V), and phenylalanine (F) with hydrophilic glutamine (Q), threonine (T), and tyrosine (Y). We here present a structural bioinformatic analysis of five outer membrane beta-barrel proteins with known molecular structures, including a) BamA, b) Omp85 (also called Sam50), c) FecA, d) Tsx, and e) OmpC. We superposed the structures of five native beta-barrel outer membrane proteins and their AlphaFold2-predicted corresponding QTY variant structures. The superposed structures of OMPs and their QTY variants exhibit remarkable structural similarity, as evidenced by residue mean square distance (RMSD) values between 0.206Å to 0.414Å despite the replacement of at least 22% (Transmembrane variation) of the amino acids in the transmembrane regions. We also show that native outer membrane proteins and QTY variants have different hydrophobicity patches. Our study provides important insights into the differences between hydrophobic and hydrophilic beta-barrels and validates the QTY code for studying beta-barrel membrane proteins and perhaps other hydrophobic aggregated proteins. Our findings demonstrate that the QTY code can be used as a simple tool for designing hydrophobic proteins in various biological contexts.

BAM folds OMPs using a budding mechanism.

In Gram-negative bacteria, the biogenesis of beta-barrel outer membrane proteins (OMPs) is mediated by the beta-barrel assembly machinery (BAM). The mechanism employed by BAM is complex and so far is not fully resolved. Here, we report the structures of BAM in nanodiscs, where we observe an outward-open state. Mutations in the barrel domain of BamA reveal that plasticity in BAM is essential, particularly along the lateral seam of the barrel domain, which is further supported by molecular dynamics simulations that show conformational dynamics in BAM are modulated by the accessory proteins. We also report a series of cryo-EM structures detailing the near complete folding of EspP by BAM, which reveals EspP threading from the underside of BAM and sequentially incorporating into the barrel domain of BamA. Together, our studies provide a complete view of OMP biogenesis by BAM, overwhelmingly supporting that OMPs are folded using the budding mechanism.

The mitosome of the anaerobic parasitic protist Entamoeba histolytica: A peculiar and minimalist mitochondrion-related organelle.

The simplest class of mitochondrion-related organelles (MROs) is the mitosome, an organelle present in a few anaerobic protozoan parasites such as Entamoeba histolytica, Giardia intestinalis, and Cryptosporidium parvum. E. histolytica causes amoebiasis in humans, deemed as one of the important, yet neglected tropical infections in the world. Much of the enigma of the E. histolytica mitosome circles around the obvious lack of a majority of known mitochondrial components and functions exhibited in other organisms. The identification of enzymes responsible for sulfate activation (AS, IPP, and APSK) and a number of lineage-specific proteins such as the outer membrane beta-barrel protein (MBOMP30), and transmembrane domain-containing proteins that bind to various organellar proteins (ETMP1, ETMP30, EHI_170120, and EHI_099350) showcased the remarkable divergence of this organelle compared to the other MROs of anaerobic protozoa. Here, we summarize the findings regarding the biology of the mitosomes in E. histolytica, from their discovery up to the present understanding of its roles and interactions. We also include current advances and future perspectives on the biology, biochemistry, and evolution of the mitosomes of E. histolytica.

Gram-negative outer-membrane proteins with multiple β-barrel domains

Outer-membrane beta barrels (OMBBs) are found in the outer membrane of gram-negative bacteria and eukaryotic organelles. OMBBs fold as antiparallel β-sheets that close onto themselves, forming pores that traverse the membrane. Currently known structures include only one barrel, of 8 to 36 strands, per chain. The lack of multi-OMBB chains is surprising, as most OMBBs form oligomers, and some function only in this state. Using a combination of sensitive sequence comparison methods and coevolutionary analysis tools, we identify many proteins combining multiple beta barrels within a single chain; combinations that include eight-stranded barrels prevail. These multibarrels seem to be the result of independent, lineage-specific fusion and amplification events. The absence of multibarrels that are universally conserved in bacteria with an outer membrane, coupled with their frequent de novo genesis, suggests that their functions are not essential but rather beneficial in specific environments. Adjacent barrels of complementary function within the same chain may allow for functions beyond those of the individual barrels.

High-Resolution Studies of Proteins in Natural Membranes by Solid-State NMR.

Membrane proteins are vital for cell function and thus represent important drug targets. Solid-state Nuclear Magnetic Resonance (ssNMR) spectroscopy offers a unique access to probe the structure and dynamics of such proteins in biological membranes of increasing complexity. Here, we present modern solid-state NMR spectroscopy as a tool to study structure and dynamics of proteins in natural lipid membranes and at atomic scale. Such spectroscopic studies profit from the use of high-sensitivity ssNMR methods, i.e., proton-(1H)-detected ssNMR and DNP (Dynamic Nuclear Polarization) supported ssNMR. Using bacterial outer membrane beta-barrel protein BamA and the ion channel KcsA, we present methods to prepare isotope-labeled membrane proteins and to derive structural and motional information by ssNMR.

PURIFICATION, CHARACTERIZATION AND EXPRESSION, OF RECOMBINANT OUTER MEMBRANE PROTEIN A (OMP A) OF ACINETOBACTER BAUMANNII LI311

Acinetobacter baumannii is a known hospital aquired pathogenic bacterium that increasingly resists antibiotics treatment. In order to characterize and produce a soluble OmpA protein that can be used to develop Acinetobacter vaccine, polymerase chain reaction (PCR) was used to produce the ompA gene, of A. baumannii strain LI311, which was cloned into the histidin taged pET19b expression plasmid. Immobilized metal affinity chromatography (IMAC) was utilized to purify the recombinant protein, and amino acid sequences for OmpA protein homologs were attained from the National Center for Biotechnology Information (NCBI) protein resource then analyzed using the blast tool and Jalview program. Protein topology prediction was done using NCBI tools and PRED-TMBB2. Analysis of amino acid sequence of OmpA of A. baumannii strain LI311 showed that it has homologies to other clinical Acinetobacter spices , including: A. pittii , A.nosocomialis , A.seifertii, A. calcoaceticus, and A. ursingii with identity percentages of 100%, 100%, 96%, 92%, and 91%. Protein topology prediction revealed two conserved domains belonging to OmpA family protein ,which are beta-barrel domain outer membrane protein (OMP_b-brl) and OmpA-C-like domain, and it is a 10-βeta -stranded transmembrane Outer Membrane Protein with a signal peptide at residues 1–22A. A recombinant Histidine tagged- OmpA (39.31kDa )was successfully expressed and purified in this study. In conclusion, OmpA protein of A.baumannii strain LI31 is highly conserved across clinical species of Acinetobacter, and the soluble recombinant OmpA created in this study can be used to develop a putative vaccine that may prevent infections caused by the clinical species of Acinetobacter.

Differences between predicted outer membrane proteins of genotype 1 and 2\u2009Mannheimia haemolytica

BackgroundMannheimia haemolytica strains isolated from North American cattle have been classified into two genotypes (1 and 2). Although members of both genotypes have been isolated from the upper and lower respiratory tracts of cattle with or without bovine respiratory disease (BRD), genotype 2 strains are much more frequently isolated from diseased lungs than genotype 1 strains. The mechanisms behind the increased association of genotype 2 M. haemolytica with BRD are not fully understood. To address that, and to search for interventions against genotype 2 M. haemolytica, complete, closed chromosome assemblies for 35 genotype 1 and 34 genotype 2 strains were generated and compared. Searches were conducted for the pan genome, core genes shared between the genotypes, and for genes specific to either genotype. Additionally, genes encoding outer membrane proteins (OMPs) specific to genotype 2 M. haemolytica were identified, and the diversity of their protein isoforms was characterized with predominantly unassembled, short-read genomic sequences for up to 1075 additional strains.ResultsThe pan genome of the 69 sequenced M. haemolytica strains consisted of 3111 genes, of which 1880 comprised a shared core between the genotypes. A core of 112 and 179 genes or gene variants were specific to genotype 1 and 2, respectively. Seven genes encoding predicted OMPs; a peptidase S6, a ligand-gated channel, an autotransporter outer membrane beta-barrel domain-containing protein (AOMB-BD-CP), a porin, and three different trimeric autotransporter adhesins were specific to genotype 2 as their genotype 1 homologs were either pseudogenes, or not detected. The AOMB-BD-CP gene, however, appeared to be truncated across all examined genotype 2 strains and to likely encode dysfunctional protein. Homologous gene sequences from additional M. haemolytica strains confirmed the specificity of the remaining six genotype 2 OMP genes and revealed they encoded low isoform diversity at the population level.ConclusionGenotype 2 M. haemolytica possess genes encoding conserved OMPs not found intact in more commensally prone genotype 1 strains. Some of the genotype 2 specific genes identified in this study are likely to have important biological roles in the pathogenicity of genotype 2 M. haemolytica, which is the primary bacterial cause of BRD.

PoreDesigner for tuning solute selectivity in a robust and highly permeable outer membrane pore

Monodispersed angstrom-size pores embedded in a suitable matrix are promising for highly selective membrane-based separations. They can provide substantial energy savings in water treatment and small molecule bioseparations. Such pores present as membrane proteins (chiefly aquaporin-based) are commonplace in biological membranes but difficult to implement in synthetic industrial membranes and have modest selectivity without tunable selectivity. Here we present PoreDesigner, a design workflow to redesign the robust beta-barrel Outer Membrane Protein F as a scaffold to access three specific pore designs that exclude solutes larger than sucrose (>360 Da), glucose (>180 Da), and salt (>58 Da) respectively. PoreDesigner also enables us to design any specified pore size (spanning 3–10 Å), engineer its pore profile, and chemistry. These redesigned pores may be ideal for conducting sub-nm aqueous separations with permeabilities exceeding those of classical biological water channels, aquaporins, by more than an order of magnitude at over 10 billion water molecules per channel per second.

Assembling Functional Proteins on Gold-Glass Surfaces

The generation of functional surfaces using biological molecules is of great interest for cell culture and diagnostic applications. Control of protein orientation is difficult but advantageous in many cases to retain activity. The results from simple adsorption methods can be extremely variable and often result in denatured or inactive proteins. The industrial sponsor of this work, Orla Protein Technologies, utilise gold-thiol chemistry and the self-assembling nature of a beta-barrel outer membrane protein (OMP) from E. coli to create reproducible protein arrays on gold surfaces. The E. coli OMP is a robust protein scaffold that can be engineered to display a wide variety of functional motifs or domains such as, cell adhesion proteins, single chain antibodies or antigens. Sputter coating is often used to achieve thin and even gold surfaces suitable for most uses but the method requires expensive equipment and specialist training and the layers are poorly transparent, limiting their use in cell biology and microscopy. This has led our group to develop a simple, flexible method for depositing high densities of gold nanoparticles on to glass substrates. These are cheap to produce using inexpensive equipment and all steps are carried out at room temperature without harsh solvents. Moving to a gold-glass platform enables the more flexible use of microscopy and spectroscopic techniques in cell culture and biosensing applications. Characterisation of the new surfaces by electron microscopy, fluorescence microscopy and neutron reflection reveals well-ordered fields of nanoparticles coated in a functional protein layer. Further analysis of functionalised nanoparticles in solution has been carried out using UV-Visible spectroscopy, dynamic light scattering, small angle neutron scattering and electron microscopy. This shows several proteins bound to the nanoparticle surface through a gold-thiol bond. Functional motifs are displayed away from the surface and retain the ability to bind specifically to antigens in the solution. These new surface topologies open new avenues for applications of self assembling protein layers.

Mechanistic Insights into Outer Membrane Protein Folding

The beta-barrel outer membrane proteins (OMPs) of Gram-negative bacteria are essential for cell viability and survival, but the molecular mechanisms of their biogenesis remain poorly understood. OMPs are synthesised in the cytoplasm, translocated across the inner membrane and transported across the periplasm by the molecular chaperones Skp or SurA, before being inserted into the OM by the essential beta-barrel assembly machinery (BAM) complex (a 203 kDa heteropentameric membrane protein complex). The mechanisms by which Skp and SurA recognise OMPs and successfully deliver their cargos to BAM remain poorly understood. Questions about these mechanisms are especially interesting since the periplasm is devoid of ATP, and it is completely unknown how substrate binding and release are controlled and coordinated. Moreover, whilst several structures of the BAM complex have been solved recently, how OMPs are delivered to BAM from Skp/SurA and folded into the crowded outer membrane remain mysterious. We have been exploiting a range of biophysical methods to gain new insights into the mechanisms of OMP folding and assembly, and its assistance by chaperones and BAM. In this lecture I will describe our recent results using a variety of OMPs of different sizes combined with analysis using fluorescence kinetic assays, cryo-EM and non-covalent mass spectrometry. The results have revealed a new mechanism of Skp action and new insights into how BAM facilitates OMP folding into the bacterial outer membrane.

Cell Surface Exposure.

Surface-exposed proteins of Gram-negative bacteria are represented by integral outer membrane beta-barrel proteins and lipoproteins. No computational methods exist for predicting surface-exposed lipoproteins, and therefore lipoprotein topology must be experimentally tested. This chapter describes three distinct but complementary methods for the detection of surface-exposed proteins: cell surface protein labeling, accessibility to extracellular protease and antibodies.

PRED-TMBB2: improved topology prediction and detection of beta-barrel outer membrane proteins.

The PRED-TMBB method is based on Hidden Markov Models and is capable of predicting the topology of beta-barrel outer membrane proteins and discriminate them from water-soluble ones. Here, we present an updated version of the method, PRED-TMBB2, with several newly developed features that improve its performance. The inclusion of a properly defined end state allows for better modeling of the beta-barrel domain, while different emission probabilities for the adjacent residues in strands are used to incorporate knowledge concerning the asymmetric amino acid distribution occurring there. Furthermore, the training was performed using newly developed algorithms in order to optimize the labels of the training sequences. Moreover, the method is retrained on a larger, non-redundant dataset which includes recently solved structures, and a newly developed decoding method was added to the already available options. Finally, the method now allows the incorporation of evolutionary information in the form of multiple sequence alignments. The results of a strict cross-validation procedure show that PRED-TMBB2 with homology information performs significantly better compared to other available prediction methods. It yields 76% in correct topology predictions and outperforms the best available predictor by 7%, with an overall SOV of 0.9. Regarding detection of beta-barrel proteins, PRED-TMBB2, using just the query sequence as input, achieves an MCC value of 0.92, outperforming even predictors designed for this task and are much slower. The method, along with all datasets used, is freely available for academic users at http://www.compgen.org/tools/PRED-TMBB2 CONTACT: pbagos@compgen.org.

A combined kinetic push and thermodynamic pull as driving forces for outer membrane protein sorting and folding in bacteria.

In vitro folding studies of outer membrane beta-barrels have been invaluable in revealing the lipid effects on folding rates and efficiencies as well as folding free energies. Here, the biophysical results are summarized, and these kinetic and thermodynamic findings are considered in terms of the requirements for folding in the context of the cellular environment. Because the periplasm lacks an external energy source the only driving forces for sorting and folding available within this compartment are binding or folding free energies and their associated rates. These values define functions for periplasmic chaperones and suggest a biophysical mechanism for the BAM complex.

Aqueous, Unfolded OmpA Forms Amyloid-Like Fibrils upon Self-Association.

Unfolded outer membrane beta-barrel proteins have been shown to self-associate in the absence of lipid bilayers. We previously investigated the formation of high molecular weight species by OmpA, with both the transmembrane domain alone and the full-length protein, and discovered that the oligomeric form contains non-native β-sheet structure. We have further probed the conformation of self-associated OmpA by monitoring binding to Thioflavin T, a dye that is known to bind the cross-β a structure inherent in amyloid fibrils, and by observing the species by electron microscopy. The significant increase in fluorescence indicative of Thioflavin T binding and the appearance of fibrillar species by electron microscopy verify that the protein forms amyloid-like fibril structures upon oligomerization. These results are also consistent with our previous kinetic analysis of OmpA self-association that revealed a nucleated growth polymerization mechanism, which is frequently observed in amyloid formation. The discovery of OmpA’s ability to form amyloid-like fibrils provides a new model protein with which to study fibrillization, and implicates periplasmic chaperone proteins as capable of inhibiting fibril formation.

Charge Asymmetry in Outer Membrane Proteins

Outer membrane proteins are the proteins found in the outer membranes of bacteria, mitochondria and chloroplasts. These proteins adopt a beta barrel structure. There are thousands of outer membrane beta barrels reported in genomic databases with approximately 2-3% of the genes in gram-negative bacteria encoding these proteins. Of the non-redundant outer membrane protein structures in the Protein Data Bank, half have been solved over the past 5 years. This influx of information provides new opportunities for understanding the chemistry of these proteins.Using a structural bioinformatics approach, we have determined a strong asymmetry in the charge distribution of these proteins. For the outward-facing amino acids of the beta barrel within regions of similar amino acid density for both membrane leaflets, the external side of the membrane contains more than three times the number of charged amino acids as the internal side of the membrane. Moreover, the lipid bilayer of the outer membrane is asymmetric, and the overall preference for amino acid types to be in the external leaflet of the membrane correlates roughly with the hydrophobicity of the membrane lipids. This preference is demonstrably related to the difference in lipid composition of the external and internal leaflets of the membrane. The charge asymmetry of proteins in the outer membrane has important implications for how we understand the mechanism of outer membrane protein insertion.

Structure and Function of the β-Barrel Assembly Machine and its Associated Chaperones

Membrane insertion of beta-barrel Outer Membrane Proteins (OMPs) is essential for Gram-Negative bacteria and requires the coordinated action of both periplasmic chaperones and the outer membrane complex known as beta-Barrel Assembly Machinery (BAM). BamA, a beta-barrel OMP itself, is the central component of BAM, which also has four associated lipoproteins: BamB, C, D and E. BamA and BamD are essential for viability and appear to be present in all bacteria with an outer membrane. In the current model, periplasmic chaperones prevent OMP aggregation in the periplasm and deliver their cargo to the BAM complex for insertion into the outer membrane. We have determined the crystal structure of the periplasmic chaperone Skp. With NMR and crosslinking experiments we show that Skp binds the transmembrane domain of OmpA, a model beta-barrel OMP, in its cavity maintaining it in an unfolded state while protecting it from aggregation. Interestingly, the periplasmic, non-membrane domain of OmpA is allowed to fold to its native conformation explaining the specific importance of Skp on the OMP biogenesis pathway. We also present high-resolution structures of the lipoproteins BamB, C and D as well as the periplasmic domain of BamA, which contains five POTRA motifs thought to organize the BAM complex and associate with nascent OMPs en route to insertion in the outer membrane. In addition, we report the first structure of a complex between BamB and a POTRA3-5 fragment of BamA that begins to illuminate the BAM complex architecture. Using complementary Small Angle X-ray Scattering and NMR we show that the BamA POTRA domain undergoes conformational transitions, which functional experiments show are crucial for its role in OMP folding and insertion.

The role of BamA in the biogenesis of beta-barrel membrane proteins

Beta-barrel membrane proteins are essential for nutrient import, signaling, motility, and survival. In Gram-negative bacteria, the beta-barrel assembly machinery (BAM) complex is responsible for the biogenesis of beta-barrel outer membrane proteins (OMPs), with homologous complexes found in mitochondria and chloroplasts. Despite their essential roles, exactly how these OMPs are formed remains unknown. The BAM complex consists of a central and essential component called BamA (an OMP itself) and four lipoproteins called BamB-E. While the structure of the lipoproteins have been reported, the structure of full length BamA has been elusive. Recently though, we described the structure of BamA from two species of bacteria: Neisseria gonorrhoeae and Haemophilus ducreyi. BamA consists of a large periplasmic domain attached to a 16-strand transmembrane beta-barrel domain. Together, our crystal structures and molecule dynamics (MD) simulations revealed several structural features which gave clues to the mechanism by which BamA catalyzes beta-barrel assembly. The first is that the interior cavity is accessible in one BamA structure and conformationally closed in the other. Second, an exterior rim of the beta-barrel has a distinctly narrowed hydrophobic surface, locally destabilizing the outer membrane. Third, the beta-barrel can undergo lateral opening, suggesting a route from the interior cavity in BamA into the outer membrane. And fourth, a surface exposed exit pore positioned above the lateral opening site which may play a role in the biogenesis of extracellular loops. In this presentation, the crystal structures and MD simulations of BamA will be presented along with our work looking at the role of these four structural features in the role of BamA within the BAM complex.

Identification of a molecular signature unique to metal-reducingGammaproteobacteria

Functional genes required for microbial (dissimilatory) metal reduction display high sequence divergence, which limits their utility as molecular biomarkers for tracking the presence and activity of metal-reducing bacteria in natural and engineered systems. In the present study, homologs of the outer membrane beta-barrel protein MtrB of metal-reducing Gammaproteobacteria were found to contain a unique N-terminal CXXC motif that was missing from MtrB homologs of nonmetal-reducing Gammaproteobacteria and metal- and nonmetal-reducing bacteria outside the Gammaproteobacteria. To determine whether the N-terminal CXXC motif of MtrB was required for dissimilatory metal reduction, each cysteine in the CXXC motif of the representative metal-reducing gammaproteobacterium Shewanella oneidensis was replaced with alanine, and the resulting site-directed mutants were tested for metal reduction activity. Anaerobic growth experiments demonstrated that the first, but not the second, conserved cysteine was required for metal reduction by S.oneidensis. The ability to predict metal reduction by Gammaproteobacteria with unknown metal reduction capability was confirmed with Vibrio parahaemolyticus, a pathogen whose genome encodes an MtrB homolog with an N-terminal CXXC motif. MtrB homologs with an N-terminal CXXC motif may thus represent a molecular signature unique to metal-reducing members of the Gammaproteobacteria.

Charge asymmetry in the proteins of the outer membrane

Outer membrane beta-barrels (OMBBs) are the proteins found in the outer membrane of bacteria, mitochondria and chloroplasts. There are thousands of beta-barrels reported in genomic databases with ∼2-3% of the genes in gram-negative bacteria encoding these proteins. These proteins have a wide variety of biological functions including active and passive transport, cell adhesion, catalysis and structural anchoring. Of the non-redundant OMBB structures in the Protein Data Bank, half have been solved during the past 5 years. This influx of information provides new opportunities for understanding the chemistry of these proteins. The distribution of charges in proteins in the outer membrane has implications for how the mechanism of outer membrane protein insertion is understood. Understanding the distribution of charges might also assist in organism selection for the heterologous expression of mitochondrial OMBBs. We find a strong asymmetry in the charge distribution of these proteins. For the outward-facing residues of the beta-barrel within regions of similar amino acid density for both membrane leaflets, the external side of the outer membrane contains almost three times the number of charged residues as the internal side of the outer membrane. Moreover, the lipid bilayer of the outer membrane is asymmetric, and the overall preference for amino acid types to be in the external leaflet of the membrane correlates roughly with the hydrophobicity of the membrane lipids. This preference is demonstrably related to the difference in lipid composition of the external and internal leaflets of the membrane.