Background: Substrate-binding integral membrane proteins of ECF transporters are predicted to undergo reversible rotation during the transport cycle. Results: Capture and release of biotin by a nanodisc-embedded ECF transporter depended on ATP-induced subunit reorientations. Conclusion: ECF transporters mediate vitamin translocation by turning their substrate-specific components within the membrane. Significance: Individual steps of the transport cycle are highlighted by biochemical and biophysical techniques.
The energy-coupling factor (ECF) transporters are multi-subunit protein complexes that mediate uptake of transition-metal ions and vitamins in about 50% of the prokaryotes, including bacteria and archaea. Biological and structural studies have been focused on ECF transporters for vitamins, but the molecular mechanism by which ECF systems transport metal ions from the environment remains unknown. Here we report the first crystal structure of a NikM, TtNikM2, the substrate-binding component (S component) of an ECF-type nickel transporter from Thermoanaerobacter tengcongensis. In contrast to the structures of the vitamin-specific S proteins with six transmembrane segments (TSs), TtNikM2 possesses an additional TS at its N-terminal region, resulting in an extracellular N-terminus. The highly conserved N-terminal loop inserts into the center of TtNikM2 and occludes a region corresponding to the substrate-binding sites of the vitamin-specific S components. Nickel binds to NikM via its coordination to four nitrogen atoms, which are derived from Met1, His2 and His67 residues. These nitrogen atoms form an approximately square-planar geometry, similar to that of the metal ion-binding sites in the amino-terminal Cu2+- and Ni2+-binding (ATCUN) motif. Replacements of residues in NikM contributing to nickel coordination compromised the Ni-transport activity. Furthermore, systematic quantum chemical investigation indicated that this geometry enables NikM to also selectively recognize Co2+. Indeed, the structure of TtNikM2 containing a bound Co2+ ion has almost no conformational change compared to the structure that contains a nickel ion. Together, our data reveal an evolutionarily conserved mechanism underlying the metal selectivity of EcfS proteins, and provide insights into the ion-translocation process mediated by ECF transporters.
Energy-coupling factor (ECF) transporters form a large group of vitamin uptake systems in prokaryotes. They are composed of highly diverse, substrate-specific, transmembrane proteins (S units), a ubiquitous transmembrane protein (T unit), and homoor hetero-oligomeric ABC ATPases. Biotin transporters represent a special case of ECF-type systems. The majority of the biotinspecific S units (BioY) is known or predicted to interact with T units and ABC ATPases. About one-third of BioY proteins, however, are encoded in organisms lacking any recognizable T unit. This finding raises the question of whether these BioYs function as transporters in a solitary state, a feature ascribed to certain BioYs in the past. To address this question in living cells, an Escherichia coli K-12 derivative deficient in biotin synthesis and devoid of its endogenous high-affinity biotin transporter was constructed as a reference strain. This organism is particularly suited for this purpose because components of ECF transporters do not naturally occur in E. coli K-12. The double mutant was viable in media containing either high levels of biotin or a precursor of the downstream biosynthetic path. Importantly, it was nonviable on trace levels of biotin. Eight solitary bioY genes of proteobacterial origin were individually expressed in the reference strain. Each of the BioYs conferred biotin uptake activity on the recombinants, which was inferred from uptake assays with [ 3 H]biotin and growth of the cells on trace levels of biotin. The results underscore that solitary BioY transports biotin across the cytoplasmic membrane.
Energy-coupling factor (ECF) transporters form a distinct group of ABC-type micronutrient importers in prokaryotes that do not contain extracytoplasmic, soluble substrate-binding proteins. Instead, they consist of a transmembrane substrate-specific S component that interacts with a module composed of a moderately conserved transmembrane (T) component and ABC ATPases. The majority of S components is considered to act as high-affinity binding proteins that strictly depend on their cognate T and ATPase units for transport activity. For a fraction of biotin-specific S units, however, transport activity was demonstrated in their solitary state. Here, we compared the activities of nickel- and cobalt-specific ECF transporters in the presence and absence of their T and ATPase units. Accumulation assays with radioactive metal ions showed that the truncated transporters led to approx. 25% of cell-bound radioactivity compared to the holotransporters. Activity of urease, an intracellular nickel-dependent enzyme, was used as a reporter and clearly indicated that the cell-bound radioactivity correlates with the cytoplasmic metal concentration. The results demonstrate that S units of metal transporters not only bind their substrates on the cell surface but mediate transport across the membrane, a finding of general importance on the way to understand the mechanism of ECF transporters.
The mechanism of energy-coupling factor (ECF) transporters, a special type of ATP-binding-cassette importers for micronutrients in prokaryotes, is a matter of controversial discussion. Among subclass II ECF transporters, a single ECF interacts with several substrate-binding integral membrane proteins (S units) for individual solutes. Release and catch of the S unit, previously observed experimentally for a subclass II system, was proposed as the mechanism of all ECF transporters. The BioMNY biotin transporter is a prototype of subclass I systems, among which the S unit is dedicated to a specific ECF. Here we simulated the transport cycle using purified BioMNY in detergent solution. BioMNY complexes were stable during all steps. ATP binding was a prerequisite for biotin capture and ATP hydrolysis for subsequent biotin release. The data demonstrate that S units of subclass I ECF transporters do not have to dissociate from holotransporter complexes for high-affinity substrate binding, indicating mechanistic differences between the two subclasses.
Biotin is an essential cofactor of carboxylase enzymes in all kingdoms of life. The vitamin is produced by many prokaryotes, certain fungi, and plants. Animals depend on biotin uptake from their diet and in humans lack of the vitamin is associated with serious disorders. Many aspects of biotin metabolism, uptake, and intracellular transport remain to be elucidated. In order to characterize the activity of novel biotin transporters by a sensitive assay, an Escherichia coli strain lacking both biotin synthesis and its endogenous high-affinity biotin importer was constructed. This strain requires artificially high biotin concentrations for growth. When only trace levels of biotin are available, it is viable only if equipped with a heterologous high-affinity biotin transporter. This feature was used to ascribe transport activity to members of the BioY protein family in previous work. Here we show that this strain together with its parent is also useful as a diagnostic tool for wide-concentration-range bioassays.
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