The transmembrane domain provides nucleotide binding specificity to the bacterial conjugation protein TrwB

In order to understand the functional significance of the transmembrane domain of TrwB, an integral membrane protein involved in bacterial conjugation, the protein was purified in the native, and also as a truncated soluble form (TrwBΔN70). The intact protein (TrwB) binds preferentially purine over pyrimidine nucleotides, NTPs over NDPs, and ribo- over deoxyribonucleotides. In contrast, TrwBΔN70 binds uniformly all tested nucleotides. The transmembrane domain has the general effect of making the nucleotide binding site(s) less accessible, but more selective. This is in contrast to other membrane proteins in which most of the protein mass, including the catalytic domain, is outside the membrane, but whose activity is not modified by the presence or absence of the transmembrane segment.     

Deletion of a single helix from the transmembrane domain causes large changes in membrane insertion properties and secondary structure of the bacterial conjugation protein TrwB

TrwB is an essential protein in the conjugative transfer of plasmid R388. The protein consists of a bulky cytosolic domain containing the catalytic site, and a small transmembrane domain (TMD). Our previous studies support the idea that the TMD plays an essential role in the activity, structure and stability of the protein. We have prepared a mutant, TrwBΔN50 that lacks one of the two α-helices in the TMD. The mutant has been studied both in detergent suspension and reconstituted in lipid vesicles. Deletion of a single helix from the TMD is enough to increase markedly the affinity of TrwB for ATP. The deletion changes the secondary structure of the cytosolic domain, whose infrared spectroscopy (IR) spectra become similar to those of the mutant TrwBΔN70 lacking the whole TMD. Interestingly, when TrwBΔN50 is reconstituted into lipid membranes, the cytosolic domain orients itself towards the vesicle interior, opposite to what happens for wild-type TrwB. In addition, we analyze the secondary structure of the TMD and TMD-lacking mutant TrwBΔN70, and found that the sum IR spectrum of the two protein fragments is different from that of the native protein, indicating the irreversibility of changes caused in TrwB by deletion of the TMD.     

Structure of TrwB, a gatekeeper in bacterial conjugation.

Bacterial conjugation implies a trans-membrane passage of DNA, mediated by proteins encoded in conjugative plasmids. This results in a spread of genetic information, including antibiotic resistance acquisition by pathogens. Special cases of conjugation are trans-kingdom gene transfer from bacteria to plants or fungi, and even bacterial sporulation and cell division. One of the main actors in this process is an integral inner membrane DNA-binding protein, called TrwB in the E. coli R388 conjugative system. It is responsible for coupling the single-strand DNA to be transferred from the donor to the acceptor cell in its complex with other proteins, with a type IV secretion system making up the mating apparatus. The TrwB protomer consists of two domains: a nucleotide-binding domain of alpha/beta topology, similar to RecA and DNA ring helicases, and an all-alpha domain. The quaternary structure reveals an almost spherical homohexamer, strikingly similar to F(1)-ATPase. A central 20 A wide channel traverses the hexamer, thus connecting cytoplasm with periplasm.     

Purification and properties of TrwB,a hexameric,ATP-binding integral membrane protein essential for R388 plasmid conjugation

TrwB is an integral membrane protein linking the relaxosome to the DNA transport apparatus in plasmid R388 conjugation. Native TrwB has been purified in monomeric and hexameric forms, in the presence of dodecylmaltoside from overexpressing bacterial cells. A truncated protein (TrwBDeltaN70) that lacked the transmembrane domain could be purified only in the monomeric form. Electron microscopy images revealed the hexameric structure and were in fact superimposable to the previously published atomic structure for TrwBDeltaN70. In addition, the electron micrographs showed an appendix, approximately 25 A wide, corresponding to the transmembrane region of TrwB. TrwB was located in the bacterial inner membrane in agreement with its proposed coupling role. Purified TrwB hexamers and monomers bound tightly the fluorescent ATP analogue TNP-ATP. A mutant in the Walker A motif, TrwB-K136T, was equally purified and found to bind TNP-ATP with a similar affinity to that of the wild type. However, the TNP-ATP affinity of TrwBDeltaN70 was significantly reduced in comparison with the TrwB hexamers. Competition experiments in which ATP was used to displace TNP-ATP gave an estimate of ATP binding by TrwB (K(d)((ATP)) = 0.48 mm for hexamers). The transmembrane domain appears to be involved in TrwB protein hexamerization and also influences its nucleotide binding properties.     

Role of the coronavirus E viroporin protein transmembrane domain in virus assembly

Coronavirus envelope (E) proteins are small (approximately 75- to 110-amino-acid) membrane proteins that have a short hydrophilic amino terminus, a relatively long hydrophobic membrane domain, and a long hydrophilic carboxy-terminal domain. The protein is a minor virion structural component that plays an important, not fully understood role in virus production. It was recently demonstrated that the protein forms ion channels. We investigated the importance of the hydrophobic domain of the mouse hepatitis coronavirus (MHV) A59 E protein. Alanine scanning insertion mutagenesis was used to examine the effect of disruption of the domain on virus production in the context of the virus genome by using a MHV A59 infectious clone. Mutant viruses exhibited smaller plaque phenotypes, and virus production was significantly crippled. Analysis of recovered viruses suggested that the structure of the presumed alpha-helical structure and positioning of polar hydrophilic residues within the predicted transmembrane domain are important for virus production. Generation of viruses with restored wild-type helical pitch resulted in increased virus production, but some exhibited decreased virus release. Viruses with the restored helical pitch were more sensitive to treatment with the ion channel inhibitor hexamethylene amiloride than were the more crippled parental viruses with the single alanine insertions, suggesting that disruption of the transmembrane domain affects the functional activity of the protein. Overall the results indicate that the transmembrane domain plays a crucial role during biogenesis of virions.     

Modeling the transmembrane domain of bacterial chemoreceptors

Bacterial chemoreceptors signal across the membrane by conformational changes that traverse a four-helix transmembrane domain. High-resolution structures are available for the chemoreceptor periplasmic domain and part of the cytoplasmic domain but not for the transmembrane domain. Thus, we constructed molecular models of the transmembrane domains of chemoreceptors Trg and Tar, using coordinates of an unrelated four-helix coiled coil as a template and the X-ray structure of a chemoreceptor periplasmic domain to establish register and positioning. We tested the models using the extensive data for cross-linking propensities between cysteines introduced into adjacent transmembrane helices, and we found that many aspects of the models corresponded with experimental observations. The one striking disparity, the register of transmembrane helix 2 (TM2) relative to its partner transmembrane helix 1, could be corrected by sliding TM2 along its long axis toward the periplasm. The correction implied that axial sliding of TM2, the signaling movement indicated by a large body of data, was of greater magnitude than previously thought. The refined models were used to assess effects of inter-helical disulfides on the two ligand-induced conformational changes observed in alternative crystal structures of periplasmic domains: axial sliding within a subunit and subunit rotation. Analyses using a measure of disulfide potential energy provided strong support for the helical sliding model of transmembrane signaling but indicated that subunit rotation could be involved in other ligand-induced effects. Those analyses plus modeled distances between diagnostic cysteine pairs indicated a magnitude for TM2 sliding in transmembrane signaling of several angstroms.     

Characterization of ATP and DNA binding activities of TrwB, the coupling protein essential in plasmid R388 conjugation

TrwB is the conjugative coupling protein of plasmid R388. TrwBDeltaN70 contains the soluble domain of TrwB. It was constructed by deletion of trwB sequences containing TrwB N-proximal transmembrane segments. Purified TrwBDeltaN70 protein bound tightly the fluorescent ATP analogue TNP-ATP (K(s) = 8.7 microM) but did not show measurable ATPase or GTPase activity. A single ATP binding site was found per TrwB monomer. An intact ATP-binding site was essential for R388 conjugation, since a TrwB mutant with a single amino acid alteration in the ATP-binding signature (K136T) was transfer-deficient. TrwBDeltaN70 also bound DNA nonspecifically. DNA binding enhanced TrwC nic cleavage, providing the first evidence that directly links TrwB with conjugative DNA processing. Since DNA bound by TrwBDeltaN70 also showed increased negative superhelicity (as shown by increased sensitivity to topoisomerase I), nic cleavage enhancement was assumed to be a consequence of the increased single-stranded nature of DNA around nic. The mutant protein TrwB(K136T)DeltaN70 was indistinguishable from TrwBDeltaN70 with respect to the above properties, indicating that TrwB ATP binding activity is not required for them. The reported properties of TrwB suggest potential functions for conjugative coupling proteins, both as triggers of conjugative DNA processing and as motors in the transport process.     

Plasticity of the domain structure in FlgJ, a bacterial protein involved in flagellar rod formation

Bacterial flagellar rod structure is built across the peptidoglycan (PG) layer. A Salmonella enterica flagellar protein FlgJ is believed to consist of two functional domains, the N-terminal half acting as a scaffold or cap essential for rod assembly and the C-terminal half acting as a PG hydrolase (PGase) that makes a hole in the PG layer to facilitate rod penetration. In this study, molecular data analyses were conducted on FlgJ data sets sampled from a variety of bacterial species, and three types of FlgJ homologs were identified: (i) "canonical dual-domain" type found in beta- and gamma-proteobacteria that has a domain for one of the PGases, acetylmuramidase (Acm), at the C terminus, (ii) "non-canonical dual-domain" type found in the genus Desulfovibrio (delta-proteobacteria) that bears a domain for another PGase, M23/M37-family peptidase (Pep), at the C terminus and (iii) "single-domain" type found in phylogenetically diverged lineages that lacks the Acm or Pep domain. FlgJ phylogeny, together with the domain architecture, suggested that the single-domain type was the original form of FlgJ and the canonical dual-domain type had evolved from the single-domain type by fusion of the Acm domain to its C terminus in the common ancestor of beta- and gamma-proteobacteria. The non-canonical dual-domain type may have been formed by fusion of the Pep domain to the single-domain type in the ancestor of Desulfovibrio. In some lineages of gamma-proteobacteria, the Acm domain appeared to be lost secondarily from the dual-domain type FlgJ to yield again a single-domain type one. To rationalize the underlying mechanism that gave rise to the two different types of dual-domain FlgJ homologs, we propose a model assuming the lineage-specific co-option of flagellum-specific PGase from diverged housekeeping PGases in bacteria.     

Structure,function, and biogenesis of SecY,an integral membrane protein involved in protein export

TheE. coli secY (prlA) gene, located in the operator-distal part of thespec ribosomal protein operon, codes for an integral membrane protein, SecY. The phenotypes of temperature-sensitive and cold-sensitive mutations insecY suggest that the SecY protein plays an essential rolein vivo to facilitate protein translocation, whereas theprlA mutations in this gene suggest that SecY may interact with the signal sequence of translocating polypeptides. SecY contains most probably six cytoplasmic and five periplasmic domains, as well as 10 transmembrane segments. Such membrane-embedded structure may confer the SecY protein a translocator function, in which it provides a proteinaceous pathway for passage of secreted as well as membrane proteins. Results obtained byin vitro analyses of the translocation reactions, as well as some new phenotypes of thesecY mutants, are consistent with this notion. Possible interaction of SecY with other secretion and chaperone-like factors is also discussed.     

Beyond anchoring: the expanding role of the hendra virus fusion protein transmembrane domain in protein folding, stability, and function

While work with viral fusion proteins has demonstrated that the transmembrane domain (TMD) can affect protein folding, stability, and membrane fusion promotion, the mechanism(s) remains poorly understood. TMDs could play a role in fusion promotion through direct TMD-TMD interactions, and we have recently shown that isolated TMDs from three paramyxovirus fusion (F) proteins interact as trimers using sedimentation equilibrium (SE) analysis (E. C. Smith, et al., submitted for publication). Immediately N-terminal to the TMD is heptad repeat B (HRB), which plays critical roles in fusion. Interestingly, addition of HRB decreased the stability of the trimeric TMD-TMD interactions. This result, combined with previous findings that HRB forms a trimeric coiled coil in the prefusion form of the whole protein though HRB peptides fail to stably associate in isolation, suggests that the trimeric TMD-TMD interactions work in concert with elements in the F ectodomain head to stabilize a weak HRB interaction. Thus, changes in TMD-TMD interactions could be important in regulating F triggering and refolding. Alanine insertions between the TMD and HRB demonstrated that spacing between these two regions is important for protein stability while not affecting TMD-TMD interactions. Additional mutagenesis of the C-terminal end of the TMD suggests that β-branched residues within the TMD play a role in membrane fusion, potentially through modulation of TMD-TMD interactions. Our results support a model whereby the C-terminal end of the Hendra virus F TMD is an important regulator of TMD-TMD interactions and show that these interactions help hold HRB in place prior to the triggering of membrane fusion.     

Topology analysis of the SecY protein, an integral membrane protein involved in protein export in Escherichia coli.

The secY (prlA) gene product is an essential component of the Escherichia coli cytoplasmic membrane, and its function is required for the translocation of exocytoplasmic proteins across the membrane. We have analyzed the orientation of the SecY protein in the membrane by examining the hydropathic character of its amino acid sequence, by testing its susceptibility to proteases added to each side of the membrane, and by characterizing SecY-PhoA (alkaline phosphatase) hybrid proteins constructed by TnphoA transpositions. The orientation of the PhoA portion of the hybrid protein with respect to the membrane was inferred from its enzymatic activity as well as sensitivity to external proteases. The results suggest that SecY contains 10 transmembrane segments, five periplasmically exposed parts, and six cytoplasmic regions including the amino- and carboxyterminal regions.     

Ermelin, an endoplasmic reticulum transmembrane protein, contains the novel HELP domain conserved in eukaryotes

We have cloned a cDNA encoding a novel protein referred to as ermelin from mouse C2 skeletal muscle cells. This protein contained six hydrophobic amino acid stretches corresponding to transmembrane domains, two histidine-rich sequences, and a sequence homologous to the fusion peptides of certain fusion proteins. Ermelin also contained a novel modular sequence, designated as HELP domain, which was highly conserved among eukaryotes, from yeast to higher plants and animals. All these HELP domain-containing proteins, including mouse KE4, Drosophila Catsup, and Arabidopsis IAR1, possessed multipass transmembrane domains and histidine-rich sequences. Ermelin was predominantly expressed in brain and testis, and induced during neuronal differentiation of N1E-115 neuroblastoma cells but downregulated during myogenic differentiation of C2 cells. The mRNA was accumulated in hippocampus and cerebellum of brain and central areas of seminiferous tubules in testis. Epitope-tagging experiments located ermelin and KE4 to a network structure throughout the cytoplasm. Staining with the fluorescent dye DiOC(6)(3) identified this structure as the endoplasmic reticulum. These results suggest that at least some, if not all, of the HELP domain-containing proteins are multipass endoplasmic reticulum membrane proteins with functions conserved among eukaryotes.     

Role of the N-terminal domain of FliI ATPase in bacterial flagellar protein export

FliI, the ATPase involved in bacterial flagellar protein export, forms a complex with its regulator FliH in the cytoplasm and hexamerizes upon docking to the export gate composed of integral membrane proteins. The extreme N-terminal region of FliI is involved not only in its interaction with FliH but also in its oligomerization, but the regulatory mechanism of oligomerization remains unclear. Using in-frame 10-residue deletions within the 100 residues of the N-terminal domain, we demonstrate that the first 20 residues are required for FliH binding and that the conformation of the N-terminal domain is sensitive to the export function, even though the oligomerization and FliH-binding ability are retained and the ATPase activity is maintained in most of the deletion variants.     

AtAPOSTART1, an Arabidopsis thaliana PH-START domain protein involved in seed germination

The seed in the mature and dry state is metabolically inactive (quiescent) and is thus able to withstand extreme environmental conditions, such as drought and cold. Germination commences when the dry seed, shed from its parent plant, takes up water (imbibition) and ends when the root emerges through the seed coat. During seedling establishment, the reserves stored in the seed are metabolized, whereas the subsequent vegetative and reproductive growth is supported by photosynthesis. Here, we describe the functional characterization of the PH-START protein AtAPO1 (Arabidopsis thaliana APOSTART1), the putative homologue of PpAPO1 (Poa pratensis APOSTART1) in Arabidopsis thaliana. By using translational fusion of the AtAPO1 promoter to the uiaD gene and in situ hybridization analyses, we show that AtAPO1 is expressed in mature embryo sacs and developing embryos. The functional analysis of two at-apostart mutant alleles suggests that AtAPO1 is involved in the control of seed germination.     

Role of the transmembrane domain of marburg virus surface protein GP in assembly of the viral envelope

The major protein constituents of the filoviral envelope are the matrix protein VP40 and the surface transmembrane protein GP. While VP40 is recruited to the sites of budding via the late retrograde endosomal transport route, GP is suggested to be transported via the classical secretory pathway involving the endoplasmic reticulum, Golgi apparatus, and trans-Golgi network until it reaches the plasma membrane where most filoviral budding takes place. Since both transport routes target the plasma membrane, it was thought that GP and VP40 join there to form the viral envelope. However, it was recently shown that, upon coexpression of both proteins, GP is partially recruited into peripheral VP40-enriched multivesicular bodies, which contained markers of the late endosome. Accumulation of GP and VP40 in this compartment was presumed to play an important role in the formation of the filoviral envelope. Using a domain-swapping approach, we were able to show that the transmembrane domain of GP was essential and sufficient for (i) partial recruitment of chimeric glycoproteins into VP40-enriched multivesicular bodies and (ii) incorporation into virus-like particles (VLPs) that were released upon expression of VP40. Only those chimeric glycoproteins which were targeted to VP40-enriched endosomal multivesicular bodies were subsequently recruited into VLPs. These data show that the transmembrane domain of GP is critical for the mixing of VP40 and GP in multivesicular bodies and incorporation of GP into the viral envelope. Results further suggest that trapping of GP in the VP40-enriched late endosomal compartment is important for the formation of the viral envelope.     

A fijiviral nonstructural protein triggers cell death in plant and bacterial cells via its transmembrane domain

Southern rice black‐streaked dwarf virus (SRBSDV; Fijivirus, Reoviridae) has become a threat to cereal production in East Asia in recent years. Our previous cytopathologic studies have suggested that SRBSDV induces a process resembling programmed cell death in infected tissues that results in distinctive growth abnormalities. The viral product responsible for the cell death, however, remains unknown. Here P9‐2 protein, but not its RNA, was shown to induce cell death in Escherichia coli and plant cells when expressed either locally with a transient expression vector or systemically using a heterologous virus. Both computer prediction and fluorescent assays indicated that the viral nonstructural protein was targeted to the plasma membrane (PM) and further modification of its subcellular localization abolished its ability to induce cell death, indicating that its PM localization was required for the cell death induction. P9‐2 was predicted to harbour two transmembrane helices within its central hydrophobic domain. A series of mutation assays further showed that its central transmembrane hydrophobic domain was crucial for cell death induction and that its conserved F90, Y101, and L103 amino acid residues could play synergistic roles in maintaining its ability to induce cell death. Its homologues in other fijiviruses also induced cell death in plant and bacterial cells, implying that the fijiviral nonstructural protein may trigger cell death by targeting conserved cellular factors or via a highly conserved mechanism.     

The transmembrane domain of the DnaJ-like protein DjlA is a dimerisation domain

DjlA is a bitopic inner membrane protein, which belongs to the DnaJ co-chaperone family in Escherichia coli. Overproduction of DjlA leads to the synthesis of colanic acid, resulting in mucoidy, via the activation of the two-component regulatory system RcsC/B that controls the cps (capsular polysaccharide) operon. This induction requires both the co-chaperone activity of DjlA, in cooperation with DnaK and GrpE, and its unique transmembrane (TM) domain. Here, we show that the TM segment of DjlA acts as a dimerisation domain: when fused to the N-terminal DNA-binding domain of the lambda cI repressor protein, it can substitute for the native C-terminal dimerisation domain of cI, thus generating an active cI repressor. Replacing the TM domain of DjlA by other TM domains, with or without dimerising capacity, revealed that dimerisation is not sufficient for the induction of cps expression, indicating an additional sequence- or structurally specific role for the TM domain. Finally, the conserved glycines present in the TM domain of DjlA are essential for the induction of mucoidy, but not for dimerisation.