Physical and genetic characterization of the melibiose operon and identification of the gene products in Escherichia coli

We have identified hybrid plasmids carrying the melibiose operon of Escherichia coli in a colony bank of Clarke and Carbon (Tsuchiya, T., Ottina, K., Moriyama, Y., Newman, M., and Wilson, T. H. (1982) J. Biol. Chem. 257, 5125-5128). Using one of the plasmids as a starting material, the DNA fragments containing the melibiose operon were recloned in a vector pBR322. Restriction maps were prepared, and several DNA segments were subcloned into pBR322. Genetic complementation tests and recombination analyses using those plasmids and melA- and melB- mutants as well as biochemical analyses of mel mutants transformed with those plasmids enabled us to determine the physical location of promoter, melA, and melB on the DNA segment. The size of the melAB region was about 3,000 base pairs. Gene products were identified using maxicells harboring plasmids carrying the melibiose operon. The apparent molecular weight of the alpha-galactosidase (coded by melA) was about 50,000 and that of the melibiose carrier (coded by melB) was about 31,000, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The melibiose carrier was also identified as a 30,000-dalton protein in reconstituted proteoliposomes which possessed melibiose transport activity.     

Isolation and functional reconstitution of soluble melibiose permease from Escherichia coli

By use of techniques described recently for lac permease [Roepe, P.D., & Kaback, H.R. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 6087], the melibiose permease from Escherichia coli, another polytopic integral plasma membrane protein, has been purified in a metastable soluble form after overexpression of the melB gene via the T7 RNA polymerase system. As demonstrated with lac permease, soluble melibiose permease is dissociated from the membrane with 5.0 M urea and appears to remain soluble in phosphate buffer at neutral pH after removal of urea by dialysis, although the protein aggregates in a time- and concentration-dependent fashion. Moreover, soluble melibiose permease behaves as a monomer during purification by size exclusion chromatography in the presence of urea. Circular dichroism of purified soluble melibiose permease reveals that the protein is highly helical in potassium phosphate buffer and that secondary structure is disrupted in 5.0 M urea. Finally, purified melibiose permease can be reconstituted into proteoliposomes, and the preparations catalyze membrane potential driven H+/melibiose or Na+/methyl 1-thio-beta,D-galactopyranoside symport. The results provide further support for the notion that hydrophobic transmembrane proteins may be able to assume a nondenatured conformation in aqueous solution and extend the implication that the approach described may represent a general method for rapid isolation and reconstitution of this class of membrane proteins.     

A cryptic melibiose transporter gene possessing a frameshift from Citrobacter freundii

Wild-type Citrobacter freundii cannot grow on melibiose as a sole source of carbon. The melibiose transporter gene melB was cloned from a C. freundii mutant M4 that could utilize melibiose as a sole carbon source. Although the cloned melB gene is closely similar to the melB genes of other bacteria, it is cryptic because of a frameshift mutation. Site-directed mutagenesis was used to construct a functional melB gene by deleting one nucleotide, resulting in the production of an active melibiose transporter. The active MelB transporter could utilize Na(+) and H(+) as coupling cations to melibiose transport. The amino acid sequence of the C. freundii MelB was found to be most similar to those of Salmonella typhimurium and Escherichia coli MelB. These facts are consistent with the phylogenetic relationship of bacteria and the cation coupling properties of the melibiose transporters.     

Structural analysis of genes participating in melibiose fermentation and isocitrate lyase production in Yersinia pestis strains of main and non main subspecies

Comparative analysis of nucleotide sequences of genes participating in melibiose fermentation and isocitrate lyase production was conducted in 90 natural Yersinia pestis strains of main and non main subspecies. It was ascertained that the lack of the ability to utilize disaccharide melibiose in strains of the main subspecies is caused by integration of the insertion sequence IS285 at 73 bp from the beginning of the structural gene melB that encodes the transport protein galactoside permease. In contrast, strains of non main subspecies (caucasica, altaica, and ulegeica) contain the intact gene melB and are capable of fermenting melibiose. Differences in the manifestation of the other differential trait, production of isocitrate lyase, are connected with the presence of mutation (insertion of two nucleotides +CC) in the regulatory gene iclR encoding repressor protein of the acetate operon, which is the reason for constitutive synthesis of this enzyme. Strains of non main subspecies do not contain mutations in gene iclR, and this correlates in these strains with their capacity for inducible synthesis of isocitrate lyase.     

Biochemical and genetic analysis of Streptococcus mutans alpha-galactosidase.

The aga gene coding for alpha-galactosidase in Streptococcus mutans was detected in a recombinant gene library constructed in phage lambda. The gene was subcloned into plasmid vectors and shown to specify a novel protein of Mr 80,000. Characterization of alpha-galactosidase from S. mutans and from recombinant Escherichia coli expressing aga indicated that the enzyme functions as a tetramer. The amino acid composition of the alpha-galactosidase, deduced from nucleotide sequencing of aga, gave a predicted Mr of 82,022 and revealed regions of homology to alpha-galactosidases encoded by the E. coli Raf plasmids and by Bacillus stearothermophilus. Inactivation of the aga gene in S. mutans resulted in loss of all alpha-galactosidase activity and abolished the ability to ferment melibiose; alpha-glucosidase activity was also lost, due to an indirect effect on the dexB gene.     

Metabolic pathway for the utilization of L-arginine, L-ornithine, agmatine, and putrescine as nitrogen sources in Escherichia coli K-12

The structural genes (melB) for the melibiose carrier of five mutants of Escherichia coli showing altered cation specificity for melibiose transport were cloned. The mutations were mapped in a 248-base-pair DNA fragment by a recombinational assay by using the mutants transformed with hybrid plasmids carrying various portions of the wild-type melB gene. The nucleotide sequences of the corresponding DNA fragments derived from mutated melB genes were determined, and the amino acid sequences of the carrier were deduced. Proline 122 was replaced with serine in the melibiose carrier of all five mutants (which were isolated independently). We conclude that this amino acid replacement caused the alteration in cation specificity (loss of coupling to H+) of the melibiose carrier.     

Primary structure and characteristics of the melibiose carrier of Klebsiella pneumoniae.

The melB gene coding for the melibiose carrier of Klebsiella pneumoniae was cloned and sequenced. There were two potential translation initiation sites. It was predicted that the melibiose carrier consists of 471 (or 467) amino acid residues. Seventy-eight percent of the 471 amino acids were identical to the Escherichia coli melibiose carrier. Sugar transport characteristics were studied using an E. coli mel- mutant expressing cloned K. pneumoniae melB gene. Accumulation of melibiose via the K. pneumoniae melibiose carrier was not stimulated by adding NaCl or LiCl which stimulates melibiose accumulation via the E. coli melibiose carrier. Lactose was accumulated only in the presence of LiCl. TMG (methyl-1-thio-beta-D-galactopyranoside) was accumulated in the absence of added NaCl or LiCl. The accumulation was stimulated by LiCl but not by NaCl. Rapid H+ uptake was observed when melibiose or TMG was added to cell suspensions. These results suggest that the preferred cation couplings via K. pneumoniae melibiose carrier are H(+)-melibiose, Li(+)-lactose, and H+/Li(+)-TMG. This coupling spectrum is quite different from that of the E. coli melibiose carrier. It is of special interest that the K. pneumoniae melibiose carrier seems to be lacking the ability to recognize Na+ which is a preferred coupling cation of the E. coli melibiose carrier for all known sugar substrates. Further investigation of these two carriers may give us insight into the Na+ recognition site.     

Production of recombinant alpha-galactosidases in Thermus thermophilus

A Thermus thermophilus selector strain for production of thermostable and thermoactive alpha-galactosidase was constructed. For this purpose, the native alpha-galactosidase gene (agaT) of T. thermophilus TH125 was inactivated to prevent background activity. In our first attempt, insertional mutagenesis of agaT by using a cassette carrying a kanamycin resistance gene led to bacterial inability to utilize melibiose (alpha-galactoside) and galactose as sole carbohydrate sources due to a polar effect of the insertional inactivation. A Gal(+) phenotype was assumed to be essential for growth on melibiose. In a Gal(-) background, accumulation of galactose or its metabolite derivatives produced from melibiose hydrolysis could interfere with the growth of the host strain harboring recombinant alpha-galactosidase. Moreover, the AgaT(-) strain had to be Km(s) for establishment of the plasmids containing alpha-galactosidase genes and the kanamycin resistance marker. Therefore, a suitable selector strain (AgaT(-) Gal(+) Km(s)) was generated by applying integration mutagenesis in combination with phenotypic selection. To produce heterologous alpha-galactosidase in T. thermophilus, the isogenes agaA and agaB of Bacillus stearothermophilus KVE36 were cloned into an Escherichia coli-Thermus shuttle vector. The region containing the E. coli plasmid sequence (pUC-derived vector) was deleted before transformation of T. thermophilus with the recombinant plasmids. As a result, transformation efficiency and plasmid stability were improved. However, growth on minimal agar medium containing melibiose was achieved only following random selection of the clones carrying a plasmid-based mutation that had promoted a higher copy number and greater stability of the plasmid.     

Biochemical studies of melibiose metabolism in wild type and mel mutant strains of Salmonella typhimurium

I identified two enzyme activities, alpha-galactosidase and a galactoside permease, required for melibiose metabolism by Salmonella typhimurium. These activities are very low under normal growth conditions, but their production can be induced by melibiose and gratuitously by melibiitol. Melibiose induction is severely inhibited by glucose, but the glucose effect can be countered by 3', 5' cyclic adenosine monophosphate. I isolated two phenotypic classes of mutants not able to utilize melibiose as a carbon source. One class, Car(-), is deficient in the phosphotransferase system. The other, Mel, lacks either alpha-galactosidase, galactoside permease, or both functions.     

Analysis of melibiose mutants deficient in alpha-galactosidase and thiomethylgalactoside permease II in Escherichia coli K-12

Three types of mutants (mel(-)) unable to metabolize the alpha-d-galactoside, melibiose, were derived from Escherichia coli K-12. One type lacked alpha-galactosidase; another lacked a specific transport system, termed thiomethylgalactoside (TMG) permease II; and the third lacked both of these functions. The mutational sites were genetically mapped by recombination frequency with different markers and by determination of chromosomal transfer in interrupted-mating experiments. All three mel(-) mutant types mapped in a cluster near to the metA marker on the E. coli chromosome and were cotransducible. Induction studies revealed that the three alpha-d-galactosides, melibiose, melibiitol, and galactinol, induced alpha-galactosidase and TMG permease II coordinately; d-galactose also induced them but only in a galactokinaseless mutant. These data suggest that alpha-galactosidase and TMG permease II may be components of a common operon.     

Purification and analysis of the structure of alpha-galactosidase from Escherichia coli

Alpha-Galactosidase, the product of the melA gene, was purified from a strain of Escherichia coli harboring a plasmid carrying melA, which over-produced the alpha-galactosidase. An apparent molecular weight was determined to be 50 kDa. The amino acid composition of this enzyme was determined. The result indicates that this enzyme is a hydrophilic and acidic protein. We have subjected the purified enzyme to 20 cycles of N-terminal sequence analysis. This verified the translation start site of the melA gene and the predicted N-terminal sequence.     

Nucleotide sequence of the melA gene, coding for alpha-galactosidase in Escherichia coli K-12.

Melibiose uptake and hydrolysis in E.coli is performed by the MelB and MelA proteins, respectively. We report the cloning and sequencing of the melA gene. The nucleotide sequence data showed that melA codes for a 450 amino acid long protein with a molecular weight of 50.6 kd. The sequence data also supported the assumption that the mel locus forms an operon with melA in proximal position. A comparison of MelA with alpha-galactosidase proteins from yeast and human origin showed that these proteins have only limited homology, the yeast and human proteins being more related. However, regions common to all three proteins were found indicating sequences that might comprise the active site of alpha-galactosidase.     

Nucleotide sequence of the melB gene and characteristics of deduced amino acid sequence of the melibiose carrier in Escherichia coli

The nucleotide sequence of the melB gene coding for the melibiose carrier in Escherichia coli has been determined. The melibiose carrier is predicted to consist of 469 amino acid residues, resulting in a protein with a molecular weight of 52,029. The predicted carrier protein is highly hydrophobic (70% nonpolar amino acid residues). The hydropathic profile suggests that there are 10 long hydrophobic segments in the primary structure of the carrier protein. Most of them seem to traverse the membrane. Although the hydropathic profile of the melibiose carrier is similar to that of the lactose carrier as a whole, homology in the primary structure between the two carriers is very low. Furthermore, no homology in the nucleotide sequence is found in the structural genes for the two carriers. However, the nucleotide sequences of the intergenic regions are very similar between the melibiose operon and the lactose operon. There is a typical intercistronic regulatory sequence in the 3'-flanking region of the melB as well as in that of the lacY, which suggests the presence of another gene downstream of the melB.     

Identification and mapping of a second proline permease Salmonella typhimurium

In this paper we demonstrate the existence of a second proline permease, gene proP, in Salmonella typhimurium. Uptake assays demonstrate that this second proline permease has 5 to 10% the uptake rate of the putP permease, the cell's major proline permease, when assayed at 20 microM proline. Genetic mapping by Hfr and P22-mediated genetic crosses placed the second proline permease gene at 92 min on the S. typhimurium genetic map, near the genes for melibiose utilization. F'-mediated complementation tests indicated that Escherichia coli also has the proP gene.     

Alpha-galactosidases from the larval midgut of Tenebrio molitor (Coleoptera) and Spodoptera frugiperda (Lepidoptera)

There are three midgut alpha-galactosidases (TG1, TG2, TG3) from Tenebrio molitor larvae that are partially resolved by ion-exchange chromatography. The enzymes have approximately the same pH optimum (5.0), pl value (4.6) and Mr value (46000-49000) as determined by gel filtration or native electrophoresis run in polyacrylamide gels with different concentrations. Substrate specificities and functions were proposed for the major T. molitor midgut alpha-galactosidases (TG2 and TG3) based on chromatographic, carbodiimide inactivation, Tris inhibition, and on substrate competition data. Thus, TG2 would hydrolyse alpha-1,6-galactosaccharides, exemplified by raffinose, whereas TG3 would act on melibiose and apparently also on digalactosyldiglyceride, the most important compound in the thylacoid membranes of chloroplasts. Most galactoside digestion should occur in the lumen of the first two thirds of T. molitor larval midguts, since alpha-galactosidase activity predominates there. Spodoptera frugiperda larvae have three midgut alpha-galactosidases (SG1, SG2, SG3) partially resolved by ion-exchange chromatography. The enzymes have similar pH optimum (5.8), pl value (7.2) and Mr value (46000-52000), and at least the major alpha-galactosidase must have an active carboxyl group in the active site. Based on data similar to those described for T. molitor, SG1 and SG3 should hydrolyse melibiose and SG3 should digest raffinose and, perhaps, also digalactosyldiglyceride. The midgut distribution of alpha-galactosidase activity supports the proposal that alpha-galactosidase digestion occurs at the surface of anterior midgut cells in Spodoptera frugiperda larvae.     

Active-site-directed photolabeling of the melibiose permease of Escherichia coli

Covalent photolabeling of the melibiose permease (MelB) of Escherichia coli has been undertaken with the sugar analogue [(3)H]-p-azidophenyl alpha-D-galactopyranoside ([(3)H]-alpha-PAPG) with the purpose of identifying the domains forming the MelB sugar-binding site. We show that alpha-PAPG is a high-affinity substrate of MelB (K(d) = 1 x 10(-)(6) M). Its binding to or transport by MelB is Na-dependent and is competitively prevented by melibiose or by the high-affinity ligand p-nitrophenyl alpha-D-galactopyranoside (alpha-NPG). Membrane vesicles containing overexpressed histidine-tagged recombinant MelB were photolabeled in the presence of [(3)H]-alpha-PAPG by irradiation with UV light (lambda = 250 nm). Eighty-five percent of the radioactivity covalently associated with the vesicles was incorporated in a polypeptide corresponding to MelB monomer. MelB labeling was completely prevented by an excess of melibiose or alpha-NPG during the assay. Radioactivity analysis of CNBr cleavage or limited proteolysis products of the purified [(3)H]-alpha-PAPG-labeled transporter suggests that several domains of MelB are targets for labeling. One of the labeled CNBr cleavage products is a peptide with an apparent molecular mass of 5.5 kDa. It is shown that (i) its amino acid sequence is that of the Asp124-Met181 domain of MelB (7.5 kDa), which includes the cytoplasmic loop 4-5 connecting helices IV and V, the hydrophobic helix V, and the outer loop connecting helices V-VI, and (ii) that Arg141 in loop 4-5 is the only labeled amino acid of this peptide. Labeling of loop 4-5 provides independent evidence that this specific domain plays a significant role in MelB transport. Comparison with the well-characterized equivalent domain of LacY suggests that sugar transporters with similar structure and substrate specificity may have conserved domains involved in sugar recognition.