Haemophore-mediated bacterial haem transport: evidence for a common or overlapping site for haem-free and haem-loaded haemophore on its specific outer membrane receptor.

Bacterial extracellular haemophores also named HasA for haem acquisition system form an independent family of haemoproteins that take up haem from host haeme carriers and shuttle it to specific receptors (HasR). Haemophore receptors are required for the haemophore-dependent haem acquisition pathway and alone allow free or haemoglobin-bound haem uptake, but the synergy between the haemophore and its receptor greatly facilitates this uptake. The three-dimensional structure of the Serratia marcescens holo-haemophore (HasASM) has been determined previously and revealed that the haem iron atom is ligated by tyrosine 75 and histidine 32. The phenolate of tyrosine 75 is also tightly hydrogen bonded to the Ndelta atom of histidine 83. Alanine mutagenesis of these three HasASM residues was performed, and haem-binding constants of the wild-type protein, the three single mutant proteins, the three double mutant proteins and the triple mutant protein were compared by absorption spectrometry to probe the roles of H32, Y75 and H83 in haem binding. We show that one axial iron ligand is sufficient to ligate haem efficiently and that H83 may become an alternative iron ligand in the absence of Y75 or both H32 and Y75. All the single mutant proteins retained the ability to stimulate haemophore-dependent haem uptake in vivo. Thus, the residues H32, Y75 and H83 are not individually necessary for haem delivery to the receptor. The binding of haem-free and haem-loaded HasASM proteins to HasRSM-producing strains was studied. Both proteins bind to HasRSM with similar apparent Kd. The double mutant H32A-Y75A competitively inhibits binding to the receptor of both holo-HasASM and apo-HasASM, showing that there is a unique or overlapping site on HasRSM for the apo- and holo-haemophores. Thus, we propose a new mechanism for haem uptake, in which haem is exchanged between haem-loaded haemophores and unloaded haemophores bound to the receptor without swapping of haemophores on the receptor.

The ABC of ABCS: a phylogenetic and functional classification of ABC systems in living organisms.

ATP binding cassette (ABC) systems constitute one of the most abundant superfamilies of proteins. They are involved not only in the transport of a wide variety of substances, but also in many cellular processes and in their regulation. In this paper, we made a comparative analysis of the properties of ABC systems and we provide a phylogenetic and functional classification. This analysis will be helpful to accurately annotate ABC systems discovered during the sequencing of the genome of living organisms and to identify the partners of the ABC ATPases.

ATP modulates subunit-subunit interactions in an ATP-binding cassette transporter (MalFGK2) determined by site-directed chemical cross-linking.

The binding protein-dependent maltose transport system of enterobacteria (MalFGK(2)), a member of the ATP-binding cassette (ABC) transporter superfamily, is composed of two integral membrane proteins, MalF and MalG, and of two copies of an ATPase subunit, MalK, which hydrolyze ATP, thus energizing the translocation process. In addition, an extracellular (periplasmic) substrate-binding protein (MalE) is required for activity. Ligand translocation and ATP hydrolysis are dependent on a signaling mechanism originating from the binding protein and traveling through MalF/MalG. Thus, subunit-subunit interactions in the complex are crucial to the transport process but the chemical nature of residues involved is poorly understood. We have investigated the proximity of residues in a conserved sequence ("EAA" loop) of MalF and MalG to residues in a helical segment of the MalK subunits by means of site-directed chemical cross-linking. To this end, single cysteine residues were introduced into each subunit at several positions and the respective malF and malG alleles were individually co-expressed with each of the malK alleles. Membrane vesicles were prepared from those double mutants that contained a functional transporter in vivo and treated with Cu(1,10-phenanthroline)(2)SO(4) or bifunctional cross-linkers. The results suggest that residues Ala-85, Lys-106, Val-114, and Val-117 in the helical segment of MalK, to different extents, participate in constitution of asymmetric interaction sites with the EAA loops of MalF and MalG. Furthermore, both MalK monomers in the complex are in close contact to each other through Ala-85 and Lys-106. These interactions are strongly modulated by MgATP, indicating a structural rearrangement of the subunits during the transport cycle. These data are discussed with respect to current transport models.

Structure-function study of MalF protein by random mutagenesis.

MalF is one of the two integral inner membrane proteins of the maltose-maltodextrin transport system. To identify functional regions in this protein, we characterized a collection of malF mutants obtained by random mutagenesis. We analyzed their growth on maltose and maltodextrins, the steady-state levels and subcellular localization of the mutant proteins, and the subcellular localization of MalK. Only 2 of the 21 MalF mutant proteins allowed growth on maltose and maltodextrins. Most mutations resulting in immunodetectable proteins mapped to hydrophilic domains, indicating that insertions affecting transmembrane segments gave rise to unstable or lethal proteins. All MalF mutant proteins, even those C-terminally truncated or with large N-terminal deletions, were inserted into the cytoplasmic membrane. Having identified mutations leading to reduced steady-state level, to partial mislocation, and/or to misfolding, we were able to assign to some regions of MalF a role in the assembly of the MalFGK2 complex and/or in the transport mechanism.

Getting in or out: early segregation between importers and exporters in the evolution of ATP-binding cassette (ABC) transporters.

ATP-binding cassette (ABC) systems, also called traffic ATPases, are found in eukaryotes and prokaryotes and almost all participate in the transport of a wide variety of molecules. ABC systems are characterized by a highly conserved ATPase module called here the ABC module, involved in coupling transport to ATP hydrolysis. We have used the sequence of one of the first representatives of bacterial ABC transporters, the MalK protein, to collect 250 closely related sequences from a nonredundant protein sequence database. The sequences collected by this objective method are all known or putative ABC transporters. After having eliminated short protein sequences and duplicates, the 197 remaining sequences were subjected to a phylogenetic analysis based on a mutational similarity matrix. An unrooted tree for these modules was found to display two major branches, one grouping all collected uptake systems and the other all collected export systems. This remarkable disposition strongly suggests that the divergence between these two functionally different types of ABC systems occurred once in the history of these systems and probably before the differentiation of prokaryotes and eukaryotes. We discuss the implications of this finding and we propose a model accounting for the generation and the diversification of ABC systems.

In vitro interaction between components of the inner membrane complex of the maltose ABC transporter of Escherichia coli: modulation by ATP.

Interactions between domains of ATP-binding cassette (ABC) transporters are of great functional importance and yet are poorly understood. To gain further knowledge of these protein-protein interactions, we studied the inner membrane complex of the maltose transporter of Escherichia coli. We focused on interactions between the nucleotide-binding protein, MalK, and the transmembrane proteins, MalF and MalG. We incubated purified MalK with inverted membrane vesicles containing MalF and MalG. MalK bound specifically to MalF and MalG and reconstituted a functional complex. We used this approach and limited proteolysis with trypsin to show that binding and hydrolysis of ATP, inducing conformational changes in MalK, modulate its interaction with MalF and MalG. MalK in the reconstituted complex was less sensitive to protease added from the cytoplasmic side of the membrane, and one proteolytic cleavage site located in the middle of a putative helical domain of MalK was protected. These results suggest that the putative helical domain of the nucleotide-binding domains is involved, through its conformational changes, in the coupling between the transmembrane domains and ATP binding/hydrolysis at the nucleotide-binding domains.

Subunit interactions in ABC transporters: a conserved sequence in hydrophobic membrane proteins of periplasmic permeases defines an important site of interaction with the ATPase subunits.

The cytoplasmic membrane proteins of bacterial binding protein-dependent transporters belong to the superfamily of ABC transporters. The hydrophobic proteins display a conserved, at least 20 amino acid EAA---G---------I-LP region exposed in the cytosol, the EAA region. We mutagenized the EAA regions of MalF and MalG proteins of the Escherichia coli maltose transport system. Substitutions at the same positions in MalF and MalG have different phenotypes, indicating that EAA regions do not act symmetrically. Mutations in malG or malF that slightly affect or do not affect transport, determine a completely defective phenotype when present together. This suggests that EAA regions of MalF and MalG may interact during transport. Maltose-negative mutants fall into two categories with respect to the cellular localization of the MalK ATPase: in the first, MalK is membrane-bound, as in wild-type strains, while in the second, it is cytosolic, as in strains deleted in the malF and malG genes. From maltose-negative mutants of the two categories, we isolated suppressor mutations within malK that restore transport. They map mainly in the putative helical domain of MalK, suggesting that EAA regions may constitute a recognition site for the ABC ATPase helical domain.

Activity of protein MalE (maltose-binding protein) fused to cytoplasmic and periplasmic regions of an Escherichia coli inner membrane protein.

We analysed the properties of mature MBP (maltose-binding protein or MalE protein) fused to an integral cytoplasmic membrane protein of Escherichia coli. Fusion of MalE to the first MalG periplasmic loop enabled a strain defective in the malE gene to utilize maltose. In contrast, fusion of MalE to a cytoplasmic loop did not complement the malE delta 444 deletion. We obtained results highly correlated with those obtained by using alkaline phosphatase as a reporter for the topology of MalG. We discuss the possibility of genetically determining the topology of cytoplasmic membrane proteins by a method based on engineered fusions to MBP.

Heat shock induction by a misassembled cytoplasmic membrane protein complex in Escherichia coli.

We analysed the effects of the overproduction of parts or all of a multisubunit ATP-binding cassette (ABC) transporter, the MalFGK2 complex, involved in the uptake of maltose and maltodextrins in Escherichia coli. We found that production of the MalF protein alone was inducing the phtrA promoter, which is under the control of a recently discovered sigma factor, sigma24, involved in the response to extracytoplasmic stresses. The production level, stability and localization of MalF were not altered when produced without its partners, suggesting that the protein was correctly inserted in the membrane. Our results indicate that a large periplasmic loop located between the third and fourth transmembrane segment of MalF, the L3 loop, is responsible for phtrA induction: (i) deleted MalF proteins with no L3 loop or with a L3 loop lacking 120 amino acids do not induce the phtrA promoter; (ii) the export to the periplasm of the L3 loop alone or fused to MalE induces the phtrA promoter. Moreover, the proteolytic sensitivity of MalF is different when it is produced alone and when MalF and MalG are produced together, suggesting a change in the conformation and/or accessibility of MalF. These results suggest that some inner membrane proteins can be sensed outside the cytoplasm by a quality control apparatus or by the export machinery. Moreover, the observation of the phtrA induction by MalF could be a useful new tool for studying the insertion and assembly of the MalFGK2 complex.

Phylogenetic analyses of the ATP-binding constituents of bacterial extracytoplasmic receptor-dependent ABC-type nutrient uptake permeases.

Thirty-eight ATP-binding cassette (ABC) protein constituents of bacterial extracytoplasmic receptor-dependent nutrient uptake systems, including one homologous chloroplast protein were analysed for sequence conservation and phylogenetic relatedness. The proteins were generally found to cluster in accordance with the clustering patterns previously observed for the extracytoplasmic receptors and the transmembrane channel-forming constituents of these permeases. The results suggest that these transport systems evolved from a single primordial system with minimal shuffling of the three dissimilar protein constituents of the systems.

Bacterial binding protein-dependent permeases: characterization of distinctive signatures for functionally related integral cytoplasmic membrane proteins.

Bacterial binding protein-dependent transport systems belong to the superfamily of ABC transporters, which is widely distributed among living organisms. Their hydrophobic membrane proteins are the least characterized components. The primary structures of 61 integral membrane proteins from 35 uptake systems were compared in order to characterize a short conserved hydrophilic segment, with a consensus EAA---G---------I-LP, located approximately 100 residues from the C-terminus. Secondary structure predictions indicated that this conserved region might be formed by two amphipathic alpha-helices connected by a loop containing the invariant G residue. We classified the conserved motifs and found that membrane proteins from systems transporting structurally related substrates specifically display a greater number of identical residues in the conserved region. We determined a consensus for each class of membrane protein and showed that these can be considered as signatures.

Sequence relationships between integral inner membrane proteins of binding protein-dependent transport systems: evolution by recurrent gene duplications.

Periplasmic binding protein-dependent transport systems are composed of a periplasmic substrate-binding protein, a set of 2 (sometimes 1) very hydrophobic integral membrane proteins, and 1 (sometimes 2) hydrophilic peripheral membrane protein that binds and hydrolyzes ATP. These systems are members of the superfamily of ABC transporters. We performed a molecular phylogenetic analysis of the sequences of 70 hydrophobic membrane proteins of these transport systems in order to investigate their evolutionary history. Proteins were grouped into 8 clusters. Within each cluster, protein sequences displayed significant similarities, suggesting that they derive from a common ancestor. Most clusters contained proteins from systems transporting analogous substrates such as monosaccharides, oligopeptides, or hydrophobic amino acids, but this was not a general rule. Proteins from diverse bacteria are found within each cluster, suggesting that the ancestors of current clusters were present before the divergence of bacterial groups. The phylogenetic trees computed for hydrophobic membrane proteins of these permeases are similar to those described for the periplasmic substrate-binding proteins. This result suggests that the genetic regions encoding binding protein-dependent permeases evolved as whole units. Based on the results of the classification of the proteins and on the reconstructed phylogenetic trees, we propose an evolutionary scheme for periplasmic permeases. According to this model, it is probable that these transport systems derive from an ancestral system having only 1 hydrophobic membrane protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Membrane topology of MalG, an inner membrane protein from the maltose transport system of Escherichia coli.

In Escherichia coli, the binding protein-dependent transport system for maltose and maltodextrins is composed of five proteins--LamB, MalE, MalF, MalG and MalK--located in the three layers of the bacterial envelope. Proteins MalF and MalG are hydrophobic inner membrane components mediating the energy-dependent translocation of substrates into the cytoplasm. In this paper, we analyse the topology of the MalG protein by using methods based on the properties of fusions between malG and 'phoA, a truncated gene encoding alkaline phosphatase lacking its translation initiation and exportation signals. Fusions were obtained by using either phage lambda TnphoA or by constructing in vitro fusions located randomly within the malG gene. The deduced topological model suggests that MalG spans the membrane six times and has its amino- and carboxy-termini in the cytoplasm. These results will be helpful for the interpretation of the phenotypes of mutants in malG.

Sequence-function relationships in MalG, an inner membrane protein from the maltose transport system in Escherichia coli.

The malG gene encodes a hydrophobic cytoplasmic membrane protein which is required for the energy-dependent transport of maltose and maltodextrins in Escherichia coli. The MalG protein, together with MalF and MalK proteins, forms a multimeric complex in the membrane consisting of two MalK subunits for each MalF and MalG subunit. Fifteen mutations have been isolated in malG by random linker insertion mutagenesis. Two regions essential for maltose transport have been identified. In particular, a hydrophilic region containing the peptidic motif EAA---G---------I-LP, highly conserved among inner membrane proteins from binding protein-dependent transport systems, is essential for maltose transport. The results also show that several regions of MalG are not essential for function. A region (residues 30-50) encompassing the first predicted transmembrane segment and the first periplasmic loop in MalG may be modified extensively with little effect on maltose transport and no effect on the stability and the localization of the protein. A region located at the middle of the protein (residues 153-157) is not essential for the function of the protein. A region, essential for maltodextrin utilization but not for maltose transport, has been identified near the C-terminus of the protein.

Completion of the nucleotide sequence of the 'maltose B' region in Salmonella typhimurium: the high conservation of the malM gene suggests a selected physiological role for its product.

We have subcloned and sequenced the genes malF and malM of Salmonella typhimurium, thereby completing the determination of the nucleotide sequence of its 'maltose B' regulon. The malM gene, encoding a periplasmic protein of unknown function in Escherichia coli, is a highly conserved as genes encoding proteins of known function from the same region.

Are appR and katF the same Escherichia coli gene encoding a new sigma transcription initiation factor?

The phenotype of Escherichia coli appR pleiotropic mutants has been compared with that of mutants in the katF gene, which lies in the same region and controls expression of catalase HPII (katE) and exonuclease III (xth). All the described characters of appR mutants--reduced pH 2.5 acid phosphatase level, overexpression of alkaline phosphatase and ability of crp or cya mutants to utilize some CAP + cAMP-dependent carbon sources--were reproduced by a katF:: Tn10 insertion. In all cases, the wild-type phenotype was restored by the presence of a plasmid-borne katF+ gene. Conversely, spontaneous appR mutants were hypersensitive to H2O2 to the same degree as katF mutants. We conclude that the appR gene is identical to katF, which encodes a putative new sigma factor (Mulvey and Loewen, 1989).

The maltoporin of Salmonella typhimurium: sequence and folding model.

The sequence of the lamB gene from Salmonella typhimurium was determined. It encodes the precursor to the LamB protein from S. typhimurium (pre-LamBS.t.; 452 residues) which presents extensive homologies with the pre-LamB protein from Escherichia coli (pre-LamBE.c.; 446 residues). The first third of pre-LamBS.t. is the most conserved, with 4% changes and strict identity between the signal peptides. The last two-third contains five "variable" segments where more than 50% of the residues are changed with respect to LamBE.c.. The three first variable segments are 8 to 14 residues long and contain only substitutions, while the two more distal ones are 24 and 29 residues long and also include insertions and deletions. It is remarkable that the variable segments correspond essentially to regions predicted to be extramembranous loops on our 2D folding model for LamBE.c.; they alternate with conserved predicted transmembranous segments. Four of the variable regions were predicted to be cell-surface-exposed loops on the basis of genetic and immunological data, while one of them (region II) was predicted to be periplasmic on the sole basis of folding rules. The LamB protein from S. typhimurium can substitute for the LamB protein from E. coli for maltodextrins binding and transport, but not for infection by any of the known E. coli phages using LamBE.c. for adsorption. A tetrapeptide, RGDS, assumed to be responsible for mammalian cell aggregation by LamBE.c. is conserved in LamBS.t., suggesting that it could have a functional role. The conservation of the binding and transport activity can be accounted for by the conservation of the regions known to be directly involved, namely the first third of the protein and a region corresponding to 352 to 374 of LamBS.t.. The phage resistance can be attributed to the variability of the four cell-surface-exposed loops previously identified as essential for phage adsorption. These results, together with those obtained with polyclonal and monoclonal antibodies directed against known LamB regions, strongly support the folding model presented for LamBE.c. and the idea that it can essentially be extended to LamBS.t., except perhaps for a region between residues 155 and 245. We propose that the existence of variable regions is due essentially, and perhaps only, to the local lack of structural constraints in the protein. The intergenic region between lamB and the following gene, malM, comprises conserved segments, including one palindromic unit.