Rikki N. Hvorup

Asymmetry in the structure of the ABC transporter-binding protein complex BtuCD-BtuF.

BtuCD is an adenosine triphosphate–binding cassette (ABC) transporter that translocates vitamin B12 from the periplasmic binding protein BtuF into the cytoplasm of Escherichia coli. The 2.6 angstrom crystal structure of a complex BtuCD-F reveals substantial conformational changes as compared with the previously reported structures of BtuCD and BtuF. The lobes of BtuF are spread apart, and B12 is displaced from the binding pocket. The transmembrane BtuC subunits reveal two distinct conformations, and the translocation pathway is closed to both sides of the membrane. Electron paramagnetic resonance spectra of spin-labeled cysteine mutants reconstituted in proteoliposomes are consistent with the conformation of BtuCD-F that was observed in the crystal structure. A comparison with BtuCD and the homologous HI1470/71 protein suggests that the structure of BtuCD-F may reflect a posttranslocation intermediate.

The tripartite tricarboxylate transporter (TTT) family

Extracytoplasmic solute binding receptors are constituents of primary and secondary active transport systems. Previous studies have shown that the constituents of two such families (ABC and TRAP-T) occur in bacteria and archaea and have undergone minimal shuffling of constituents between systems during evolutionary history. We here show that a third family of binding receptor-dependent transporters, the tripartite tricarboxylate transporter (TTT) family, the prototype of which is the TctABC system of Salmonella typhimurium, occurs in many bacteria but not in archaea or eukaryotes. Phylogenetic analyses suggest that these systems have evolved from a primordial tripartite system with only two out of 39 possible examples of shuffling of constituents between systems. The occurrence of TctA homologues in many bacteria and archaea that apparently lack corresponding TctB and TctC homologues suggests that the appearance of tripartite systems was a relatively recent evolutionary invention that occurred after the divergence of archaea and eukaryotes from bacteria.

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.

Bioinformatic Analyses of the Bacterial L-Ascorbate Phosphotransferase System Permease Family

The tripartite L-ascorbate permease of Escherichia coli is the first functionally characterized member of a large family of enzyme II complexes (SgaTBA, encoding enzymes IIC, IIB and IIA) of the bacterial phosphotransferase system (PTS). We here report bioinformatic analyses of these proteins. Forty-five homologous systems from a wide variety of bacteria were identified, but no homologues were found in archaea or eukaryotes. These systems fell into five structural types: (1) IIC, IIB and IIA are encoded by distinct genes; (2) IIC and IIB are encoded by distinct genes, but the IIA-encoding gene is absent; (3) IIC and IIB are encoded by a fused gene, but IIA is a distinct gene product; (4) IIA and IIB are fused, but IIC is encoded by a distinct gene, and (5) IIC and IIB are encoded by distinct genes, but IIA is fused to a transcriptional regulator. Phylogenetic analyses revealed that gene fusion/splicing events have occurred repeatedly during the evolutionary divergence of family members, although no evidence for shuffling of constituents between systems was obtained. The SgaTBA family proved to be distantly related to the GatCBA family of PTS permeases, and this family was also analyzed. In contrast to the SgaTBA family, no gene splicing/fusion has occurred during the evolutionary divergence of GatCBA family members as each domain is always encoded by a distinct gene. However, GatC homologues were identified in organisms that lack other PTS proteins, suggesting a transport mechanism not coupled to substrate phosphorylation. Topological analyses suggest that in contrast to all other PTS permeases, IIC proteins of the Sga and Gat families exhibit 12 transmembrane α-helical segments and are distantly related to secondary carriers. Like many secondary carriers, GatC (IIC) homologues could be shown to have arisen by an ancient intragenic duplication event. These results suggest that the Sga and Gat families of PTS permeases comprise a small superfamily in which the transmembrane IIC domains evolved independently of all other known PTS permeases.

Asymmetric states of vitamin B12 transporter BtuCD are not discriminated by its cognate substrate binding protein BtuF

BtuF, BtuD and BtuC physically interact by X‐ray crystallography (View interaction)

Web-Based Programs for the Display and Analysis of Transmembrane α-Helices in Aligned Protein Sequences

We developed novel programs for displaying and analyzing the transmembrane α-helical segments (TMSs) in the aligned sequences of homologous integral membrane proteins. TMS_ALIGN predicts the positions of putative TMSs in multiply aligned protein sequences and graphically shows the TMSs in the alignment. TMS_SPLIT (1) predicts the positions of TMSs for each sequence; (2) allows a user to select proteins with a specified number of TMSs, and (3) splits the sequences into groups of TMSs of equal numbers. TMS_CUT works like TMS_SPLIT, but it can cut sequences with any combination of TMSs. The BASS program similarly allows comparison of protein repeat elements, equivalent to TMS_SPLIT plus IC, but it provides the comparison data expressed in BLAST E values. These programs, together with the IntraCompare program, facilitate the identification of repeat sequences in integral membrane proteins. They also facilitate the estimation of protein topology and the determination of evolutionary pathways.

In vitro folding and assembly of the Escherichia coli ATP-binding cassette transporter, BtuCD.

Studies on membrane protein folding have focused on monomeric α-helical proteins and a major challenge is to extend this work to larger oligomeric membrane proteins. Here, we study the Escherichia coli (E. coli) ATP-binding cassette (ABC) transporter that imports vitamin B12 (the BtuCD protein) and use it as a model system for investigating the folding and assembly of a tetrameric membrane protein complex. Our work takes advantage of the modular organization of BtuCD, which consists of two transmembrane protein subunits, BtuC, and two cytoplasmically located nucleotide-binding protein subunits, BtuD. We show that the BtuCD transporter can be re-assembled from both prefolded and partly unfolded, urea denatured BtuC and BtuD subunits. The in vitro re-assembly leads to a BtuCD complex with the correct, native, BtuC and BtuD subunit stoichiometry. The highest rates of ATP hydrolysis were achieved for BtuCD re-assembled from partly unfolded subunits. This supports the idea of cooperative folding and assembly of the constituent protein subunits of the BtuCD transporter. BtuCD folding also provides an opportunity to investigate how a protein that contains both membrane-bound and aqueous subunits coordinates the folding requirements of the hydrophobic and hydrophilic subunits.

Dependency of sugar transport and phosphorylation by the phosphoenolpyruvate-dependent phosphotransferase system on membranous phosphatidylethanolamine in Escherichia coli : studies with a pssA mutant lacking phosphatidylserine synthase

An isogenic pair of Escherichia coli strains lacking (pssA) and possessing (wild-type) the enzyme phosphatidylserine synthase was used to estimate the effects of the total lack of phosphatidylethanolamine (PE), the major phospholipid in E. coli membranes, on the activities of several sugar permeases (enzymes II) of the phosphoenolpyruvate:sugar phosphotransferase system (PTS). The mutant exhibits greatly elevated levels of phosphatidylglycerol (PG), a lipid that has been reported to stimulate the in vitro activities of several PTS permeases. The activities, thermal stabilities, and detergent sensitivities of three PTS permeases, the glucose enzyme II (IIGlc), the mannose enzyme II (IIMan) and the mannitol enzyme II (IIMtl), were characterized. Western blot analyses revealed that the protein levels of IIGlc were not appreciably altered by the loss of PE. In the pssA mutant, IIGlc and IIMan activities were depressed both in vivo and in vitro, with the in vivo transport activities being depressed much more than the in vitro phosphorylation activities. IIMtl also exhibited depressed transport activity in vivo but showed normal phosphorylation activities in vitro. IIMan and IIGlc exhibited greater thermal lability in the pssA mutant membranes than in the wild-type membranes, but IIMtl showed enhanced thermal stability. All three enzymes were activated by exposure to TritonX100 (0.4%) or deoxycholate (0.2%) and inhibited by SDS (0.1%), but IIMtl was the least affected. IIMan and, to a lesser degree, IIGlc were more sensitive to detergent treatments in the pssA mutant membranes than in the wild-type membranes while IIMtl showed no differential effect. The results suggest that all three PTS permeases exhibit strong phospholipid dependencies for transport activity in vivo but much weaker and differential dependencies for phosphorylation activities in vitro, with IIMan exhibiting the greatest and IIMtl the least dependency. The effects of lipid composition on thermal sensitivities and detergent activation responses paralleled the effects on in vitro phosphorylation activities. These results together with those previously published suggest that, while the in vivo transport activities of all PTS enzymes II require an appropriate anionic to zwitterionic phospholipid balance, the in vitro phosphorylation activities of these same enzymes show much weaker and differential dependencies. Alteration of the phospholipid composition of the membrane thus allows functional dissection of transport from the phosphorylation activities of PTS enzyme complexes.

An Automated Program to Screen Databases for Members of Protein Families

We have developed a program, ScreenTransporter (ST), to screen for potential members of recognized transporter families. This program uses Blastpgp as the engine to search a nonredundant database, NRDB90, based on an adjustable E-value cut-off as well as adjustable protein size criteria. Additional parameters can be integrated in later versions. ST is convenient for easily obtaining nonredundant members of transporter families starting from several homologous query sequences. The program can be applied to any protein family.