The C-terminal part of the surface-associated protein MopE of the methanotroph Methylococcus capsulatus (Bath) is secreted into the growth medium

A protein with an apparent molecular mass of 46 kDa was detected as the major polypeptide in the culture medium of the biotechnologically important methanotrophic bacterium Methylococcus capsulatus (Bath). The protein cross-reacted with polyclonal antibodies raised against the outer-membrane-associated protein MopE. The antiserum was used to identify a positive clone from a lambda gt11 library. The nucleotide sequence determined for the clone demonstrated that MopE and the secreted protein are encoded by the same gene, and that the secreted protein represents an N-terminally truncated form of MopE. By using monospecific antibodies against MopE in immunogold electron microscopy, the protein was localized at the cell surface and cell periphery. The mopE gene was expressed in Escherichia coli. The MopE protein synthesized was found in the periplasmic space of E. coli. No protein with sequence similarity over the entire length of MopE was detected in the databases, but some sequence similarity to the copper-repressible CorA protein of the methanotroph Methylomicrobium albus (Berson and Lidstrom 1997) was observed for the C-terminal region of MopE.     

Structural and functional features of methanotrophs from hypersaline and alkaline lakes

Ten strains of aerobic methanotrophic bacteria represented by halophilic neutrophiles or halotolerant alkaliphiles were isolated from saline and alkaline lakes of southeast Siberia, Mongolia, Africa, and North America. Based on analysis of the nucleotide sequences of 16S rRNA gene and the pmoA gene encoding particulate methane monooxygenase, the isolates were classified as Methylomicrobium alcaliphilum, Methylomicrobium buryatense, and Methylobacter marinus. All strains of the genus Methylomicrobium were shown to synthesize glycoprotein S-layers located on the cell surface with hexagonal symmetry (p6) as a monolayer of cup-shaped structures or fine “inverted” conical structures and as plates consisting of protein subunits with inclined (p2) symmetry. During adaptation to the high salinity of the medium, isolated methanotrophs synthesize osmoprotectants: ectoine, sucrose, and glutamate. The ectC gene encoding ectoine synthase (EctC) was identified in six methanotrophic strains. Phylogenetic analysis of translated amino acid sequence of the ectC gene fragment suggests lateral transfer of the genes of ectoine synthesis as the most probable way for methanotrophs to acquire resistance to high external salinity.     

Primary characterization of dominant cell surface proteins of halotolerant methanotroph <Emphasis Type="Italic">Methylomicrobium alcaliphilum</Emphasis> 20Z

Cell surface-associated proteins with molecular masses of 27 and 80 kDa found in Methylomicrobium alcaliphilum were studied. The MEALZv2_1030034 and MEALZv2_1030035 genes encoding these proteins were identified in the partially annotated genome of the methanotroph. Polypeptides MEALZv2_1030034 and MEALZv2_1030035 showed high homology (>50% identity) with the surface proteins CorA and CorB of Methylomicrobium album BG8 expressed in conditions of low copper content in the growth medium. Electron microscopic analysis with antibodies revealed localization of the 27-kDa protein in the base of the cup-shaped structures of S-layers. The mutant with an insertion in the MEALZv2_1030034 gene lost the ability to grow on the medium with methane, but grew in the presence of 0.2% methanol. In this case, the cup-shaped structures of S-layers were not bound to the cell wall but occurred as regular aggregates in the intercellular space. The 80-kDa protein was found mainly in the periplasm, had a peroxide-degrading activity, and was classified as a di-heme cytochrome c peroxidase. The mutant deficient in the MEALZv2_1030035 gene grew on methane at a high rate and had higher activities of C₁ compound oxidation enzymes than did the parent strain. The role of the proteins MEALZv2_1030034 and MEALZv2_1030035 and distribution of their homologues in other methanotrophs are discussed.     

Cloning and characterization of corA, a gene encoding a copper-repressible polypeptide in the type I methanotroph, Methylomicrobium albus BG8

In an attempt to identify proteins involved in copper transport in the type I methanotroph Methylomicrobium albus BG8, copper-regulated polypeptides were examined. One major copper-repressible membrane polypeptide of approx. 28 500 Da was identified and designated CorA. The gene encoding this polypeptide was isolated and sequenced, and it shared a low identity with a calcium channel protein. An insertion mutation in corA of M. albus BG8 grew very poorly, suggesting that CorA is important for growth of this methanotroph. CorA may be involved in transport of copper and/or other divalent metals ions in M. albus BG8.     

The Methylococcus capsulatus (Bath) Secreted Protein, MopE*, Binds Both Reduced and Oxidized Copper

Under copper limiting growth conditions the methanotrophic bacterium Methylococcus capsulatus (Bath) secrets essentially only one protein, MopE*, to the medium. MopE* is a copper-binding protein whose structure has been determined by X-ray crystallography. The structure of MopE* revealed a unique high affinity copper binding site consisting of two histidine imidazoles and one kynurenine, the latter an oxidation product of Trp130. In this study, we demonstrate that the copper ion coordinated by this strong binding site is in the Cu(I) state when MopE* is isolated from the growth medium of M. capsulatus. The conclusion is based on X-ray Near Edge Absorption spectroscopy (XANES), and Electron Paramagnetic Resonance (EPR) studies. EPR analyses demonstrated that MopE*, in addition to the strong copper-binding site, also binds Cu(II) at two weaker binding sites. Both Cu(II) binding sites have properties typical of non-blue type II Cu (II) centres, and the strongest of the two Cu(II) sites is characterised by a relative high hyperfine coupling of copper (A_|| = 20 mT). Immobilized metal affinity chromatography binding studies suggests that residues in the N-terminal part of MopE* are involved in forming binding site(s) for Cu(II) ions. Our results support the hypothesis that MopE plays an important role in copper uptake, possibly making use of both its high (Cu(I) and low Cu(II) affinity properties.     

The Surface-Associated and Secreted MopE Protein of Methylococcus capsulatus (Bath) Responds to Changes in the Concentration of Copper in the Growth Medium

Expression of surface-associated and secreted protein MopE of the methanotrophic bacterium Methylococcus capsulatus (Bath) in response to the concentration of copper ions in the growth medium was investigated. The level of protein associated with the cells and secreted to the medium changed when the copper concentration in the medium varied and was highest in cells exposed to copper stress.     

Taxonomic Characterization of New Alkaliphilic and Alkalitolerant Methanotrophs from Soda Lakes of the Southeastern Transbaikal Region and description of Methylomicrobium buryatense sp.nov.

Five strains of obligate methanotrophic bacteria (4G, 5G, 6G, 7G and 5B) isolated from bottom sediments of Southeastern Transbaikal soda lakes (pH 9.5–10.5) are taxonomically described. These bacteria are aerobic, Gram-negative monotrichous rods having tightly packed cup-shaped structures on the outer cell wall surface (S-layers) and Type I intracytoplasmic membranes. All the isolates possess particulate methane monooxygenase (pMMO) and one strain (5G) also contains soluble methane monooxygenase (sMMO). They assimilate methane and methanol via the ribulose monophosphate pathway (RuMP). The isolates are alkalitolerant or facultatively alkaliphilic, able to grow at pH 10.5–11.0 and optimally at pH 8.5–9.5. These organisms are obligately dependent on the presence of sodium ions in the growth medium and tolerate up to 0.9–1.4 M NaCl or 1 M NaHCO₃. Although being mesophilic, all the isolates are resistant to heating (80 °C, 20 min), freezing and drying. Their cellular fatty acids profiles primarily consist of C_16:1. The major phospholipids are phosphatidylethanolamine and phosphatidylglycerol. The main quinone is Q-8. The DNA G+C content ranges from 49.2–51.5 mol%. Comparative 16S rDNA sequencing showed that the newly isolated methanotrophs are related to membres of the Methylomicrobium genus. However, they differ from the known members of this genus by DNA-DNA relatedness. Based on pheno- and genotypic characteristics, we propose a new species of the genus Methylomicrobium - Methylomicrobium buryatense sp. nov.     

The characteristics and comparative analysis of methanotrophs reveal genomic insights into Methylomicrobium sp. enriched from marine sediments

Methanotrophic bacteria are widespread and use methane as a sole carbon and energy source. They also play a crucial role in marine ecosystems by preventing the escape of methane into the atmosphere from diverse methane sources, such as methane seeps and hydrothermal vents. Despite their importance for methane carbon cycling, relatively few marine methanotrophic bacteria have been isolated and studied at the genomic level. Herein, we report the genome of a marine methanotrophic member of the genus Methylomicrobium, metagenome-assembled genome (MAG) wino1, which was obtained through enrichment using methane as the sole carbon source. Phylogenetic analysis based on 16S rRNA sequences and comparison of pmoA genes supported the close relationship of MAG-wino1 to the genus Methylomicrobium and it possessed a genome of 5.06 Mb encoding many specialized methanotrophic genes. A comparison of MAG-wino1 with the genomes of other strains (Methylomicrobium alcaliphilum 20Z^T and Methylomicrobium buryatense 5G) showed that genes (e.g. ectABC, ask, and mscLS) involved in the accumulation of compatible solutes required for survival in marine environments might be conserved. Methane utilization genes, including methanol dehydrogenase, and key enzymes related to ribulose monophosphate (RuMP) metabolism were identified. The wino1 genome harbored nitrogen fixation, urease, urea and nitrate transporter genes involved in the exploitation of nitrogen sources. Poly-β-hydroxybutyrate degradation and glycogen synthesis-related genes may facilitate survival under nutrient-limiting conditions. Additionally, genome analysis revealed three dominant taxa in the enrichment culture, methanotroph Methylomicrobium sp., methylotroph Methyloceanibacter sp., and non-methylotroph Labrenzia sp., which provided insights into microbial associations in marine sediments.     

Outer membrane proteins of Methylococcus capsulatus (Bath)

Membranes obtained from whole-cell lysates of Methylococcus capsulatus (Bath) were separated by Triton X-100 extraction. The resulting insoluble fraction was enriched in outer membranes as assessed by electron microscopy and by the content of β-hydroxy palmitic acid and particulate methane monooxygenase. Major proteins with molecular masses of approximately 27, 40, 46, 59, and 66 kDa were detected by SDS-PAGE of the Triton-X-100-insoluble membranes. MopA, MopB, MopC, MopD, and MopE (Methylococcus outer membrane protein) are proposed to designate these proteins. Several of the Mop proteins exhibited heat-modifiable properties in SDS-PAGE and were influenced by the presence of 2-mercaptoethanol in the sample buffer. The 46- and 59-kDa bands migrated as a single high-molecular-mass 95-kDa oligomer under mild denaturing conditions. When reconstituted into black lipid membranes, this oligomer was shown to serve as a channel with an estimated single-channel conductance of 1.4 nS in 1 M KCl. Received: 20 December 1996 / Accepted: 11 April 1997     

Immunodetection and immunolocalization of tryptophanins in oat (Avena sativa L.) seeds

Tryptophanins (TRPs) are low molecular weight, tryptophan-rich, basic proteins found in oat (Avena sativa L.) seeds. Like their counterpart puroindolines (PINs) from wheat (Triticum aestivum L.), TRPs are thought to be involved in flour softness as well as disease resistance against phytopathogenic fungi. PINs are known to be the major components of ‘friabilin’ associated with the surface of water washed starch grains and possess lipid binding properties. Two polyclonal antisera against puroindoline-a (PIN-a), and puroindoline-b (PIN-b) respectively; and a monoclonal antiserum raised against ‘friabilin’ were used as primary antibodies in immunoblotting experiments. All antisera detected immunoreactive polypeptides, with approximate relative masses of 15–16 kDa, in oat, wheat, and barley (Hordeum vulgare L.) seed extracts but not in rice (Oryza sativa L.), maize (Zea mays L.), bean (Phaseolus vulgaris L.), pea (Pisum sativum L.) and lentil (Lens culinaris Medic.) seed extracts. Immunoreactive polypeptides were detected in aqueous ethanol [52% (v/v) ethanol] seed extracts. Both anti-‘friabilin’ monoclonal and anti-PIN-b polyclonal antisera recognized 15 as well as 16 kDa tryptophanins in oat seeds from different cultivars. On the other hand, anti-PIN-a polyclonal antiserum strongly cross-reacted with 16 kDa TRP and weakly with 15 kDa TRP. Tryptophanins were found to be associated with the surface of starch grains in oat endosperm tissue using both fluorescence and confocal laser scanning microscopies with anti-‘friabilin’ monoclonal antiserum. SDS-PAGE and immunoblotting assays revealed a gradual synthesis of TRPs as early as milk stage in developing oat seeds. On the other hand, TRPs tend to undergo degradation during seed germination.     

Loss of cytosolic Mg2+ binding sites in the Thermotoga maritima CorA Mg2+ channel is not sufficient for channel opening

The CorA Mg²⁺ channel is a homopentamer with five-fold symmetry. Each monomer consists of a large cytoplasmic domain and two transmembrane helices connected via a short periplasmic loop. In the Thermotoga maritima CorA crystal structure, a Mg²⁺ is bound between D89 of one monomer and D253 of the adjacent monomer (M1 binding site). Release of Mg²⁺ from these sites has been hypothesized to cause opening of the channel. We generated mutants to disrupt Mg²⁺ interaction with the M1 site. Crystal structures of the D89K/D253K and D89R/D253R mutants, determined to 3.05 and 3.3?Å, respectively, showed no significant structural differences with the wild type structure despite absence of Mg²⁺ at the M1 sites. Both mutants still appear to be in the closed state. All three mutant CorA proteins exhibited transport of ⁶³Ni²⁺, indicating functionality. Thus, absence of Mg²⁺ from the M1 sites neither causes channel opening nor prevents function. We also provide evidence that the T. maritima CorA is a Mg²⁺ channel and not a Co²⁺ channel.     

Differential protein expression for geothermal Agrostis scabra and turf-type Agrostis stolonifera differing in heat tolerance

Heat stress is a major factor limiting the growth of cool-season grasses in warm climatic regions by affecting many physiological processes, including protein metabolism. Protein degradation often occurs with increasing temperatures, but certain specific proteins such as heat shock proteins (HSPs) may be induced or enhanced in their expression under supraoptimal temperatures. The objectives of this study were to determine the critical temperature that causes protein induction or degradation in two Agrostis grass species differing in heat tolerance and to compare protein profiles between the two species under different temperature regimes. Plants of heat-tolerant Agrostis scabra and two cultivars of heat-sensitive Agrostis stolonifera (‘L-93’ and ‘Penncross’) were exposed to constant day/night temperatures of 20, 30, 35, 40, or 45 °C for 14 d. Leaf photochemical efficiency (Fv/Fm), chlorophyll and carotenoid contents, and soluble protein content declined with increasing temperatures. The decreases were the least severe for A. scabra, intermediate for ‘L-93’, and the most severe for ‘Penncross’, indicating interspecific and intraspecific variations in heat tolerance in Agrostis species. Protein degradation was observed at 30–45 °C in both cultivars of A. stolonifera, and at 40–45 °C in A. scabra.HSPs were induced or enhanced at 35–45 °C in ‘L-93’ and A. scabra, and at 40–45 °C in ‘Penncross’. Immunoblotting also revealed stronger expressions of HSP60 and HSP70 in A. scabra or ‘L-93’ than in ‘Penncross’ at 35–45 °C after 3 d. The results suggested the superior heat tolerance of Agrostis grass species and cultivars could be attributed to the early induction of HSPs, particularly small molecular weight (23 kDa), at a lower level of heat stress and the maintenance of protein thermostability, particularly high-molecular weight proteins (83 kDa and large units of Rubisco).     

Structural and functional heterogeneity of single-stranded DNA-binding proteins from calf thymus

A new purification technique for ‘single-stranded DNA-binding proteins’ from calf thymus permits the demonstration of a considerable heterogeneity within these proteins. Several molecular species are obtained with M_r between 24·10³ and 30·10³ and pI values between 6 and 8, showing significant differences with regard to the following functional properties: (1) strength of binding to single-stranded DNA; (2) lowering of melting temperature of poly[d(A-T)]; (3) stimulation of DNA polymerase α on a poly[d(A-T)] template. Analysis of trypsin digestion products demonstrates that the different molecular species share extensive primary sequence homology. Experiments with antibodies show that the different molecular species are antigenically related and that a 31 kDa protein present in low amounts in our preparations is very cross-reactive.     

Lactobacillus slpA promotes ESC growth through the ERK1/2 pathway

Bacterial surface layers (S-layers) are cell envelope structures ubiquitously found in gram-negative and gram-positive bacteria, including Lactobacillus. S-layers play a role in the determination and maintenance of cell shape as virulence factors, mediate cell adhesion, and regulate immature dendritic and T cells. In this study, we sought to understand the involvement of MAPK serine/threonine kinases in alterations in Endometrial epithelial cells (ESC) growth induced by Lactobacillus crispatus (L. crispatus) slpA, an S-layer protein. We applied various concentrations of L. crispatus to cultured ESCs and observed growth and changes in the phosphorylation status of ERK1/2, JNK, and p38. Similar experiments were conducted using L. crispatus lacking and overexpressing slpA. We found that ESC growth was altered by slpA primarily via ERK1/2. Our findings suggest that L. crispatus slpA promotes ESC growth mainly through an ERK1/2-dependent pathway.     

Physical and genetic characterization of an outer-membrane protein (OmpM1) containing an N-terminal S-layer-like homology domain from the phylogenetically Gram-positive gut anaerobe Mitsuokella multacida

Thin sectioning and freeze-fracture-etch of the ovine ruminal isolate Mitsuokella multacida strain 46/5(2) revealed a Gram-negative envelope ultra-structure consisting of a peptidoglycan wall overlaid by an outer membrane. Sodium-dodecyl-sulfate-polyacrylamide gel electrophoretic (SDS-PAGE) analysis of whole cells, cell envelopes and Triton X-100 extracted envelopes in combination with thin-section and N-terminal sequence analyses demonstrated that the outer membrane contained two major proteins (45 and 43 kDa) sharing identical N-termini (A-A-N-P-F-S-D-V-P-A-D-H-W-A-Y-D). A gene encoding a protein with a predicted N-terminus identical to those of the 43 and 45 kDa outer-membrane proteins was cloned. The 1290 bp open reading frame encoded a 430 amino acid polypeptide with a predicted molecular mass of 47,492 Da. Cleavage of a predicted 23 amino acid leader sequence would yield a protein with a molecular mass of 45,232 Da. Mass spectroscopic analysis confirmed that the cloned gene (ompM1) encoded the 45 kDa outer-membrane protein. The N-terminus of the mature OmpM1 protein (residues 24–70) shared homology with surface-layer homology (SLH) domains found in a wide variety of regularly structured surface-layers (S-layers). However, the outer-membrane locale, resistance to denaturation by SDS and high temperatures and the finding that the C-terminal residue was a phenylalanine suggested that ompM1 encoded a porin. Threading analysis in combination with the identification of membrane spanning domains indicated that the C-terminal region of OmpM1 (residues 250–430) likely forms a 16-strand β-barrel and appears to be related to the unusual N-terminal SLH-domain-containing β-barrel-porins previously described in the cyanobacterium Synechococcus PCC6301.     

Identification of novel subunits of the TOM complex from Arabidopsis thaliana

The preprotein translocase of the outer mitochondrial membrane (also called TOM complex) from Arabidopsis thaliana was characterized by Blue-native gel electrophoresis (BN-PAGE) and Electrospray Tandem Mass Spectrometry (ESI-MS/MS). BN-PAGE allows to prepare a very stable 390 kDa complex that includes six different protein types: the 34 kDa translocation pore TOM40, the 21/23 kDa preprotein receptor TOM20, the small TOM component TOM7 and three further subunits of 10, 6.3 and 6.0 kDa. Primary structures of all TOM subunits were elucidated. The 10 kDa subunit represents a truncated version of the TOM22 preprotein receptor and the two 6 kDa proteins represent subunits possibly homologous to fungal TOM6 and TOM5, although sequence conservation is at the borderline of significance. TOM40, TOM7 and one or both of the 6 kDa subunits form a subcomplex of about 100 kDa. The six TOM proteins from Arabidopsis are encoded by 12 genes, at least 11 of which are expressed. While the subunit composition of the TOM complex from fungi, animals and plants is remarkably conserved, the domain structure of individual TOM proteins differs, e.g. acidic domains in TOM22 and the 6 kDa TOM subunits from Arabidopsis are absent. The domain structure of the Arabidopsis TOM complex does not support the so-called ‘acid chain hypothesis’, which explains the translocation of proteins across the outer mitochondrial membrane of mitochondria by the binding of preproteins to acidic protein domains within the TOM complex. Functional implications are discussed.     

Corallopyronin A for short-course anti-wolbachial,macrofilaricidal treatment of filarial infections

Current efforts to eliminate the neglected tropical diseases onchocerciasis and lymphatic filariasis, caused by the filarial nematodes Onchocerca volvulus and Wuchereria bancrofti or Brugia spp., respectively, are hampered by lack of a short-course macrofilaricidal–adult-worm killing–treatment. Anti-wolbachial antibiotics, e.g. doxycycline, target the essential Wolbachia endosymbionts of filariae and are a safe prototype adult-worm-sterilizing and macrofilaricidal regimen, in contrast to standard treatments with ivermectin or diethylcarbamazine, which mainly target the microfilariae. However, treatment regimens of 4–5 weeks necessary for doxycycline and contraindications limit its use. Therefore, we tested the preclinical anti-Wolbachia drug candidate Corallopyronin A (CorA) for in vivo efficacy during initial and chronic filarial infections in the Litomosoides sigmodontis rodent model. CorA treatment for 14 days beginning immediately after infection cleared >90% of Wolbachia endosymbionts from filariae and prevented development into adult worms. CorA treatment of patently infected microfilaremic gerbils for 14 days with 30 mg/kg twice a day (BID) achieved a sustained reduction of >99% of Wolbachia endosymbionts from adult filariae and microfilariae, followed by complete inhibition of filarial embryogenesis resulting in clearance of microfilariae. Combined treatment of CorA and albendazole, a drug currently co-administered during mass drug administrations and previously shown to enhance efficacy of anti-Wolbachia drugs, achieved microfilarial clearance after 7 days of treatment at a lower BID dose of 10 mg/kg CorA, a Human Equivalent Dose of 1.4 mg/kg. Importantly, this combination led to a significant reduction in the adult worm burden, which has not yet been published with other anti-Wolbachia candidates tested in this model. In summary, CorA is a preclinical candidate for filariasis, which significantly reduces treatment times required to achieve sustained Wolbachia depletion, clearance of microfilariae, and inhibition of embryogenesis. In combination with albendazole, CorA is robustly macrofilaricidal after 7 days of treatment and fulfills the Target Product Profile for a macrofilaricidal drug.     

Functional Similarity between Archaeal and Bacterial CorA Magnesium Transporters

The constitutively expressed CorA Mg²⁺ transporter is the major Mg²⁺ influx system of Salmonella typhimurium and Escherichia coli. Genomic sequence data indicated the presence of a homolog in the archaeal organism Methanococcus jannaschii. The putative M. jannaschii CorA was expressed in an Mg²⁺-transport-deficient strain of S. typhimurium to determine its functional characteristics. The archaeal CorA homolog is a functional Mg²⁺ uptake system when expressed in S. typhimurium and has properties which are highly similar to those of the normal CorA transporter of S. typhimurium despite having a low level of sequence identity with the protein and being expressed in a lipid membrane of quite different composition than normal. This implies that the overall function of the proteins is the same and further suggests that their structures are very similar.     

The rate and extent of phosphorylation of the two light-harvesting chlorophyll a/b binding protein complex (LHC-II) polypeptides in isolated spinach thylakoids

The level of phosphorylation of the 24 kDa and the 25 kDa light-harvesting chlorophyll a/b binding protein complex (LHC) II polypeptides in isolated spinach thylakoids has been determined by quantitative SDS-polyacrylamide gel electrophoresis. The time-course of phosphorylation, after correction for the molar abundance of these two polypeptides, shows that (a) the rate of phosphorylation of the 24 kDa polypeptide is at least 3-fold faster compared with the 25 kDa polypeptide, (b) the final extent of phosphorylation for both the polypeptides is very similar, and (c) the final extent of phosphorylation is typically between 0.15 and 0.25 mol phosphate per mol polypeptide. The low extent of phosphorylation is not simply a consequence of inactivation of the kinase and / or LHC II substrate or ATP depletion. These observations suggest that there are at least three different sub-populations of LHC II in isolated thylakoids: (i) phosphorylated ‘mobile’, (ii) phosphorylated ‘PS II-coupled’ and (iii) non-phosphorylated. Furthermore, the reported differences in the specific activity of phosphorylation for the ‘mobile’ and the ‘PS II-coupled’ LHC II sub-populations (Kyle, D.J. et al. (1984) Biochim. Biophys. Acta 765, 89–96) are no longer observed following correction for the non-phosphorylated LHC-II population.     

Surface Location of Individual Residues of SlpA Provides Insight into the Lactobacillus brevis S-Layer

Bacterial surface layer (S-layer) proteins are excellent candidates for in vivo and in vitro nanobiotechnological applications because of their ability to self-assemble into two-dimensional lattices that form the outermost layer of many Eubacteria and most Archaea species. Despite this potential, knowledge about their molecular architecture is limited. In this study, we investigated SlpA, the S-layer protein of the potentially probiotic bacterium Lactobacillus brevis ATCC 8287 by cysteine-scanning mutagenesis and chemical modification. We generated a series of 46 mutant proteins by replacing single amino acids with cysteine, which is not present in the wild-type protein. Most of the replaced amino acids were located in the self-assembly domain (residues 179 to 435) that likely faces the outer surface of the lattice. As revealed by electron microscopy, all the mutant proteins were able to form self-assembly products identical to that of the wild type, proving that this replacement does not dramatically alter the protein conformation. The surface accessibility of the sulfhydryl groups introduced was studied with two maleimide-containing marker molecules, TMM(PEG)₁₂ (molecular weight [MW], 2,360) and AlexaFluor488-maleimide (MW = 720), using both monomeric proteins in solution and proteins allowed to self-assemble on cell wall fragments. Using the acquired data and available domain information, we assigned the mutated residues into four groups according to their location in the protein monomer and lattice structure: outer surface of the lattice (9 residues), inner surface of the lattice (9), protein interior (12), and protein-protein interface/pore regions (16). This information is essential, e.g., in the development of therapeutic and other health-related applications of Lactobacillus S-layers.Bacterial surface layers (S-layers) are cell envelope structures ubiquitously found in gram-positive and gram-negative bacteria as well as in Archaea. S-layers are composed of identical (glyco)protein subunits with a molecular mass in the range of 40 to 200 kDa. The proteins self-assemble into two-dimensional crystalline structures with oblique (p1, p2), square (p4), or hexagonal (p3, p6) symmetry, covering the entire cell surface. The subunits are held together and attached to the underlying cell wall by noncovalent interactions and they have an intrinsic ability to spontaneously form regular layers in solution and on solid supports (24). S-layers have been shown to have roles in the determination and maintenance of cell shape as virulence factors, as mediators of cell adhesion, and as regulators of immature dendritic and T cells. Moreover, they can also function as a protective coat, molecular sieve, murein hydrolase, and ion trap (4, 8, 13, 17, 19, 25, 29).S-layer proteins have several properties that make them an attractive target for the development of nanobiotechnological applications both in vivo and in vitro. In particular, a high number of protein subunits are displayed at the bacterial cell surface. Moreover, the protein subunits are able to spontaneously self-assemble into a regularly arranged lattice structure both in solution and on solid supports (1, 27, 30, 31). However, despite the high prevalence of S-layers in nature, their molecular structure remains poorly elucidated. In particular, knowledge about the spatial organization of amino acid residues in S-layer proteins or the interactions between these residues and other subunits is limited. The poor solubility of protein assemblies and the absence of stoichiometrically defined oligomers have hindered attempts to apply nuclear magnetic resonance or hydrogen/deuterium exchange mass spectroscopy. In addition, the intrinsic property of S-layer proteins to form two-dimensional lattices has hampered efforts to obtain three-dimensional crystals required for X-ray crystallography (12, 31). To our knowledge, only part of the structure of one S-layer protein, SbsC of Geobacillus stearothermophilus, has been determined by X-ray crystallography (18). Since high-resolution, three-dimensional structural data are mostly lacking, traditional mutation-based techniques are presently the methods of choice. In cysteine-scanning mutagenesis (CSM), a series of mutant proteins is generated by replacing single residues with cysteine, which contains a sulfhydryl group amenable to further chemical modification. The spatial locations of amino acid residues within the S-layer protein SbsB of gram-positive thermophile G. stearothermophilus PV72/p2 have been analyzed by CSM. A total of 75 residues out of 920 were studied, identifying 23 residues located at the surface of protein monomers, five of those located on the outer surface of the protein lattice (10). These mutant proteins were subsequently analyzed by a cross-linking screen to assess residues accessible in monomeric form to the protein/protein interface and the inner surface of the lattice (12).In the genus Lactobacillus, S-layers have been found in several species. S-layer protein genes have been sequenced from L. brevis, L. helveticus, and L. acidophilus group organisms. Sequence similarity between Lactobacillus S-layer protein genes can be found only between closely related Lactobacillus species. Therefore, the primary sequences of Lactobacillus S-layer proteins show extensive variability, with the number of identical amino acids varying from 7 to 100% between different proteins. As a group, Lactobacillus S-layer proteins differ from those of most other bacteria in their smaller sizes (25 to 71 kDa) and higher calculated isoelectric point (pI) values (9.4 to 10.4) (1). The presence of two or more S-layer protein genes in the same strain is common in lactobacilli (5, 6, 11, 28, 35); however, only one S-layer protein gene, slpA, has so far been described to be present in the genome of L. brevis ATCC 8287. SlpA is a 435-amino-acid, 46-kDa S-layer protein that assembles into a lattice of oblique symmetry on the bacterial surface (2, 36). L. brevis ATCC 8287 has GRAS (generally recognized as safe) status and has been shown to possess probiotic properties (21), which make SlpA a very attractive subject, e.g., in the development of live oral vaccines. Moreover, a recent report using differential scanning calorimetry suggests that in comparison with other S-layer proteins, SlpA is resistant to high temperatures (21). This thermal stability could prove potentially useful in a variety of in vitro S-layer applications currently being planned or under development (27, 30, 31). Recently, SlpA was characterized to consist of an N-terminal cell wall binding domain (residues 1 to 178) and a C-terminal self-assembly domain (179 to 435) (3). For the development of applications that take advantage of these characteristics, further investigation of SlpA at the molecular level is essential.Herein, we use CSM and targeted chemical modification to assign 46 amino acid residues of SlpA to spatial locations in the protein monomer and in the lattice according to their surface accessibility. We focused mainly on the self-assembly domain, the region facing the outer surface of the protein lattice and thus most amenable to insertions and chemical modification. Two different marker molecules were used to modify cysteine-containing mutant proteins that were either in solution or attached to the cell wall. The results were subsequently evaluated taking advantage of the recent new information on SlpA domain boundaries (3). We were able to distinguish residues located in the outer and inner surfaces of the lattice, protein interior, and interface/pore regions. The information gathered here can be used in the development of further biotechnological and nanobiological applications, both in vitro and in vivo, that benefit from a thermostable S-layer protein from a GRAS bacterium with health-beneficial properties.