Evolution of the bacterial phosphotransferase system: from carriers and enzymes to group translocators.

The bacterial phosphotransferase system (PTS) is a structurally and functionally complex system with a surprising evolutionary history. The substrate-recognizing protein constituents of the PTS (Enzymes II) derive from at least four independent sources. Some of the non-PTS precursor constituents have been identified, and evolutionary pathways taken have been proposed. Our analyses suggest that two of these independently evolving systems are still in transition, not yet having acquired the full-fledged characteristics of PTS Enzyme II complexes. The work described provides detailed insight into the process of catalytic protein evolution.

Sequence and phylogenetic analyses of 4 TMS junctional proteins of animals: connexins, innexins, claudins and occludins.

Connexins and probably innexins are the principal constituents of gap junctions, while claudins and occludins are principal tight junctional constituents. All have similar topologies with four alpha-helical transmembrane segments (TMSs), and all exhibit well-conserved extracytoplasmic cysteines that either are known to or potentially can form disulfide bridges. We have conducted sequence, topological and phylogenetic analyses of the proteins that comprise the connexin, innexin, claudin and occludin families. A multiple alignment of the sequences of each family was used to derive average hydropathy and similarity plots as well as phylogenetic trees. Analyses of the data generated led to the following evolutionary and functional suggestions: (1) In all four families, the most conserved regions of the proteins from each family are the four TMSs although the extracytoplasmic loops between TMSs 1 and 2, and TMSs 3 and 4 are usually well conserved. (2) The phylogenetic trees revealed sets of orthologues except for the innexins where phylogeny primarily reflects organismal source, probably due to a lack of relevant organismal sequence data. (3) The two halves of the connexins exhibit similarities suggesting that they were derived from a common origin by an internal gene duplication event. (4) Conserved cysteyl residues in the connexins and innexins may point to a similar extracellular structure involved in the docking of hemichannels to create intercellular communication channels. (5) We suggest a similar role in homomeric interactions for conserved extracellular residues in the claudins and occludins. The lack of sequence or motif similarity between the four different families indicates that, if they did evolve from a common ancestral gene, they have diverged considerably to fulfill separate, novel functions. We suggest that internal duplication was a general evolutionary strategy used to generate new families of channels and junctions with unique functions. These findings and suggestions should serve as guides for future studies concerning the structures, functions and evolutionary origins of junctional proteins.

Influence of threonine exporters on threonine production in Escherichia coli.

Threonine production in Escherichia coli threonine producer strains is enhanced by overexpression of the E. coli rhtB and rhtC genes or by heterologous overexpression of the gene encoding the Corynebacterium glutamicum threonine excretion carrier, thrE. Both E. coli genes give rise to a threonine-resistant phenotype when overexpressed, and they decrease the accumulation of radioactive metabolites derived from [(14)C] L-threonine. The evidence presented supports the conclusion that both RhtB and RhtC catalyze efflux of L-threonine and other structurally related neutral amino acids, but that the specificities of these two carriers differ substantially.

Phylogenetic and structural analyses of the oxa1 family of protein translocases.

Mitochondrial Oxa1p homologs have been shown to function in protein export and membrane insertion in bacteria, mitochondria and chloroplasts, but their mode of action, organismal distribution and evolutionary origins are poorly understood. All sequenced homologs of Oxa1p were retrieved from the databases and multiply aligned. All organisms with a fully sequenced genome possess at least one Oxa1p homolog showing that the family is truly ubiquitous. Most prokaryotes possess just one Oxa1p homolog, but several Gram-positive bacteria and one archaeon possess two, and eukaryotes may have as many as six. Although these proteins vary in length over a 5-fold range, they exhibit a common hydrophobic core region of about 200 residues. Multiple sequence alignments reveal conserved residues and provide the basis for structural and phylogenetic analyses that serve to characterize the Oxa1 family.

A web-based program (WHAT) for the simultaneous prediction of hydropathy, amphipathicity, secondary structure and transmembrane topology for a single protein sequence.

We designed a web-based program, WHAT, which uses a sliding window to determine and plot the hydropathy, amphipathicity, secondary structure and transmembrane topology along the length of any protein sequence. This method is based on programs designed by us for hydropathy and amphipathicity but on JNET and MEMSAT for secondary structure and transmembrane topology predictions, respectively. It has a user-friendly interface and a convenient input format. It is available at our website http://www.biology.ucsd.edu/~yzhai/biotools.html.

The drug/metabolite transporter superfamily.

Previous work defined several families of secondary active transporters, including the prokaryotic small multidrug resistance (SMR) and rhamnose transporter (RhaT) families as well as the eukaryotic organellar triose phosphate transporter (TPT) and nucleotide-sugar transporter (NST) families. We show that these families as well as several other previously unrecognized families of established or putative secondary active transporters comprise a large ubiquitous superfamily found in bacteria, archaea and eukaryotes. We have designated it the drug/metabolite transporter (DMT) superfamily (transporter classification number 2.A.7) and have shown that it consists of 14 phylogenetic families, five of which include no functionally well-characterized members. The largest family in the DMT superfamily, the drug/metabolite exporter (DME) family, consists of over 100 sequenced members, several of which have been implicated in metabolite export. Each DMT family consists of proteins with a distinctive topology: four, five, nine or 10 putative transmembrane alpha helical spanners (TMSs) per polypeptide chain. The five TMS proteins include an N-terminal TMS lacking the four TMS proteins. The full-length proteins of 10 putative TMSs apparently arose by intragenic duplication of an element encoding a primordial five-TMS polypeptide. Sequenced members of the 14 families are tabulated and phylogenetic trees for all the families are presented. Sequence and topological analyses allow structural and functional predictions.

Phylogeny of multidrug transporters.

We currently recognize five large ubiquitous superfamilies and one small eukaryotic-specific family in which cellular multidrug efflux pumps occur. One, the ABC superfamily, includes members that use ATP hydrolysis to drive drug efflux, but the MFS, RND, MATE and DMT superfamilies include members that are secondary carriers, functioning by drug:H(+)or drug:Na(+)antiport mechanisms. The small MET family seems to be restricted to endosomal membranes of eukaryotes, and only a single such system has been functionally characterized. In this review article, these families of drug transporters are discussed and evaluated from phylogenetic standpoints.

The complete phosphotransferase system in Escherichia coli.

We here tabulate and describe all currently recognized proteins of the phosphoenolpyruvate:sugar phosphotransferase system (PTS) and their homologues encoded within the genomes of sequenced E. coli strains. There are five recognized Enzyme I homologues and six recognized HPr homologues. A nitrogen-metabolic PTS phosphoryl transfer chain encoded within the rpoN and ptsP operons and a tri-domain regulatory PTS protein encoded within the dha (dihydroxyacetone catabolic) operon, probably serve regulatory roles exclusively. In addition to several additional putative regulatory proteins, there are 21 (and possibly 22) recognized Enzyme II complexes. Of the 21 Enzyme II complexes, 7 belong to the fructose (Fru) family, 7 belong to the glucose (Glc) family, and 7 belong to the other PTS permease families. All of these proteins are briefly described, and phylogenetic data for the major families are presented.

An evolutionary alternative system for aryl beta-glucosides assimilation in bacteria.

Some bacteria of the soil microflora or of the digestive systems of mammals can grow on aryl beta-glucosides as sole carbon sources. The bgl operon of E. coli is the paradigm for such a catabolic pathway. In Azospirillum irakense, the two adjacent genes salAB encode beta-glucosidases which are required for salicin assimilation. In this report, we analyse the sequence of salC, the last gene to be identified in the salCAB operon and investigate the phylogenetic origins of the sal and bgl genes. The results suggest an alternative model for the assimilation of aryl beta-glucosides in bacteria.

SMR-type multidrug resistance pumps.

Multidrug resistance (MDR) efflux pumps in pathogenic microorganisms nullify the effects of antimicrobial drugs used in medicine. We have conducted phylogenetic analyses showing that these efflux pumps are associated with five superfamilies of transport systems. One of these, the drug/metabolite transporter (DMT) superfamily includes a family of small multidrug resistance (SMR)-conferring proteins that are discussed in detail in this review. A single microorganism such as Bacillus subtilis may possess multiple homologs of this family, and these homologs are believed to form both homo-oligomeric or hetero-oligomeric pumps, some of which export cationic drugs. The characteristics of some of these systems and the genes that encode them are described, with emphasis on the eight homologs encoded within the B subtilis genome. Anomalies and unanswered questions that provide impetus for future studies are presented.

NMR structure of cysteinyl-phosphorylated enzyme IIB of the N,N'-diacetylchitobiose-specific phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli.

The determination by NMR of the solution structure of the phosphorylated enzyme IIB (P-IIB(Chb)) of the N,N'-diacetylchitobiose-specific phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli is presented. Most of the backbone and side-chain resonances were assigned using a variety of mostly heteronuclear NMR experiments. The remaining resonances were assigned with the help of the structure calculations.NOE-derived distance restraints were used in distance geometry calculations followed by molecular dynamics and simulated annealing protocols. In addition, combinations of ambiguous restraints were used to resolve ambiguities in the NOE assignments. By combining sets of ambiguous and unambiguous restraints into new ambiguous restraints, an error function was constructed that was less sensitive to information loss caused by assignment uncertainties. The final set of structures had a pairwise rmsd of 0.59 A and 1.16 A for the heavy atoms of the backbone and side-chains, respectively. Comparing the P-IIB(Chb) solution structure with the previously determined NMR and X-ray structures of the wild-type and the Cys10Ser mutant shows that significant differences between the structures are limited to the active-site region. The phosphoryl group at the active-site cysteine residue is surrounded by a loop formed by residues 10 through 16. NOE and chemical shift data suggest that the phosphoryl group makes hydrogen bonds with the backbone amide protons of residues 12 and 15. The binding mode of the phosphoryl group is very similar to that of the protein tyrosine phosphatases. The differences observed are in accordance with the presumption that IIB(Chb) has to be more resistant to hydrolysis than the protein tyrosine phosphatases. We propose a proton relay network by which a transfer occurs between the cysteine SH proton and the solvent via the hydroxyl group of Thr16.