Ping Z. Ding

Sodium-substrate cotransport in bacteria

A variety of sodium-substrate cotransport systems are known in bacteria. Sodium enters the cell down an electrochemical concentration gradient. There is obligatory coupling between the entry of the ion and the entry of substrate with a stoichiometry (in the cases studied) of 1:1. Thus, the downhill movement of sodium ion into the cell leads to the accumulation of substrate within the cell. The melibiose carrier of Escherichia coli is perhaps the most carefully studied of the sodium cotransport systems in bacteria. This carrier is of special interest because it can also use protons or lithium ions for cotransport. Other sodium cotransport carriers that have been studied recently are for proline, glutamate, serine-threonine, citrate and branched chain amino acids.

The melibiose carrier of Escherichia coli: cysteine substitutions for individual residues in helix XI.

Abstract. The melibiose carrier from Escherichia coli is a sugar-cation cotransport system. Previously evidence was obtained that this integral membrane protein consists of 12 transmembrane helices. Starting with the cysteine-less melibiose carrier, cysteine has been substituted individually for amino acids 374–396, which includes all of the residues in the proposed helix XI. The carriers with cysteine substitutions were studied for their transport activity and the effect of the water soluble sulfhydryl reagent p-chloromercuribenzenesulfonic acid (PCMBS). Studies were carried out on both intact cells and inside out vesicles. Cysteine substitution caused loss of transport activity in seven of the mutants (K377C, G379C, A383C, F385C, L391C, G395C and Y396C). PCMBS produced more than 50% inhibition in six of the mutants (S380C, A381C, A384C, F387C, A388C and L391C). Preincubation of the cells with melibiose protected five of these residues from the inhibitory action of PCMBS. It was concluded that the residues whose cysteine derivatives were inhibited by PCMBS probably faced the aqueous channel.

Cysteine Substitutions for Individual Residues in Helix VI of the Melibiose Carrier of Escherichia coli

Abstract. The melibiose carrier of Escherichia coli is a cytoplasmic membrane protein that mediates the cotransport of galactosides with H+, Na+, or Li+. In this study we used cysteine-scanning mutagenesis to try to gain information about the position of transmembrane helix VI in the three-dimensional structure of the melibiose carrier. We constructed 23 individual cysteine substitutions in helix VI and an adjacent loop of the carrier. The resulting melibiose carriers retained 22–100% of their ability to transport melibiose. We tested the effect of the hydrophilic sulfhydryl reagent p-chloromercuri-benzenesulfonic acid (PCMBS) on the cysteine-substitution mutants and we found that there was no inhibition of melibiose transport in any of the mutants. We suggest that helix VI is imbedded in phospholipid and does not face the aqueous channel through which melibiose passes.

Sugar recognition mutants of the melibiose carrier of Escherichia coli: possible structural information concerning the arrangement of membrane-bound helices and sugar/cation recognition site.

Melibiose carrier mutants, isolated by growing cells on melibiose plus the non-metabolizable competitive inhibitor thiomethyl-beta-galactoside (TMG), were studied to determine sugar and cation recognition abnormalities. Most of the mutants show good transport of melibiose but have lost the recognition of TMG. In addition, most mutants show little or no transport of lactose. Cation recognition is also affected as all of these mutants have lost the ability to transport protons with melibiose. The amino acids causing these mutations were determined by sequencing the melB gene on the plasmid. The mutations were located on helices I, IV, VII, X and XI. We propose that these five helices are in proximity with each other and that they line the sugar/cation transport channel.

An investigation of cysteine mutants on the cytoplasmic loop X/XI in the melibiose transporter of Escherichia coli by using thiol reagents: implication of structural conservation of charged residues.

The melibiose transporter (Mel B) of Escherichia coli is a cation-coupled (H(+), Li(+), and Na(+)) membrane protein (MW 50 kDa) consisting of 12 transmembrane helices that are connected by periplasmic and cytoplasmic loops, with both the C- and N-ends located on the cytoplasmic side of the membrane. Previous investigations on the largest cytoplasmic loop X/XI indicated that it is a functional re-entrant loop. In this communication, the cysteine mutants on loop X/XI were studied with charged thiol reagents MTSES, MTSET, and IAA for both the inhibition patterns and charge replacement/function rescue of inactive mutants in which the original charged residues were replaced by neutral cysteines. Strong inhibitions were observed in T373C and V376C by both MTSES and MTSET, consistent with previous results of PCMBS inhibition. The thiol reagents failed to recover the activities of inactive mutants D351C, D354C, and R363C and to inhibit active mutants E357C, K359C, and E365C to any significant extent, suggesting a structural conservation at D351, D354, and R363 and tolerance of structural variations at E357, K359, and E365. The results are consistent with previous observation of structural conservation of functionally charged residues in the transmembrane domains and extend to a loop the contention that in the melibiose transporter functionally important charged residues are structurally conserved.

The proximity between helix I and helix XI in the melibiose carrier of Escherichia coli as determined by cross-linking

The melibiose carrier of Escherichia coli is a transmembrane protein that comprises 12 transmembrane helices connected by periplasmic and cytoplasmic loops, with both the N- and C-termini located on the cytoplasmic side. Our previous studies of second-site revertants suggested proximity between several helices, including helices XI and I. In this study, we constructed six double cysteine mutants, each having one cysteine in helix I and the other in helix XI: three mutants, K18C/S380C, D19C/S380C, and F20C/S380C, have their cysteine pairs near the cytoplasmic side of the carrier, and the other three, T34C/G395C, D35C/G395C, and V36C/G395C, have their cysteine pairs near the periplasmic side. In the absence of substrate, disulfide formations catalyzed by iodine and copper-(1,10-phenanthroline)(3) indicate that helix I and helix XI are in immediate proximity to each other on the periplasmic side but not on the cytoplasmic side, as shown by protease cleavage analyses. We infer that the two helices are tilted with respect to each other, with the periplasmic sides in close proximity.