Sequence determinants in the lamB gene of Escherichia coli influencing the binding and pore selectivity of maltoporin

Maltoporin (LamB protein) is a malto-oligosaccharide-selective pore protein in the outer membrane of Escherichia coli. The genetic basis of binding and transport specificity was investigated through cloning, mapping and sequencing lamB genes from seven independent mutants with various changes in maltodextrin binding affinities; these mutants were unchanged in binding phage lambda. Single amino acid substitutions specifically resulting in maltodextrin affinity changes were as follows: Arg8----His in two independent mutants resulted in much reduced affinity for all ligands and a smaller pore no longer selective for maltodextrins. A Trp74----Arg substitution resulted in a lower affinity for starch, a slight increase in maltose affinity but no striking pore changes. An Arg82----Ser resulted in lowered maltodextrin affinity, but increased affinity for sucrose in both binding and pore function. A Tyr118----Phe resulted in a higher affinity for both starch and maltose, a slightly larger pore and increased transport of maltohexaose by the pores. Asp121----Gly in two independent isolates resulted in a higher affinity for large dextrins and a marginally larger pore. These results suggest that the maltodextrin-selective functions reside in the N-terminal sequence of maltoporin and are separate from the phage lambda binding domains.     

Identification of a new porin, RafY, encoded by raffinose plasmid pRSD2 of Escherichia coli.

The conjugative plasmid pRSD2 carries a raf operon that encodes a peripheral raffinose metabolic pathway in enterobacteria. In addition to the previously known raf genes, we identified another gene, rafY, which in Escherichia coli codes for an outer membrane protein (molecular mass, 53 kDa) similar in function to the known glycoporins LamB (maltoporin) and ScrY (sucrose porin). Sequence comparisons with LamB and ScrY revealed no significant similarities; however, both lamB and scrY mutants are functionally complemented by RafY. Expressed from the tac promoter, RafY significantly increases the uptake rates for maltose, sucrose, and raffinose at low substrate concentrations; in particular it shifts the apparent K(m) for raffinose transport from 2 mM to 130 microM. Moreover, RafY permits diffusion of the tetrasaccharide stachyose and of maltodextrins up to maltoheptaose through the outer membrane of E. coli. A comparison of all three glycoporins in regard to their substrate selectivity revealed that both ScrY and RafY have a broad substrate range which includes alpha-galactosides while LamB seems to be restricted to malto-oligosaccharides. It supports growth only on maltodextrins but not, like the others, on raffinose and stachyose.     

Affinity engineering of maltoporin: variants with enhanced affinity for particular ligands

Affinity-chromatographic selection on immobilized starch was used to selectively enhance the affinity of the maltodextrin-specific pore protein ( maltoporin , LamB protein, or lambda receptor protein) in the outer membrane of E. coli. Selection strategies were established for rare bacteria in large populations producing maltoporin variants with enhanced affinities for both starch and maltose, for starch but not maltose and for maltose but not starch. Three classes of lamB mutants with up to eight-fold increase in affinity for particular ligands were isolated. These mutants provide a unique range of modifications in the specificity of a transport protein.     

Genetic evidence that outer membrane binding of starch is required for starch utilization by Bacteroides thetaiotaomicron

Mutagenesis of Bacteroides thetaiotaomicron with the transposon Tn4351 produced five classes of mutants that were not able to grow on amylose or amylopectin. These classes of mutants differed in their ability to grow on maltoheptaose (G7) and in the level of starch-degrading enzymes produced when bacteria were grown on maltose. All of the mutants were deficient in starch binding. Since one class of mutants retained normal levels of starch-degrading enzymes, this indicates that binding of the starch molecule by a cell surface receptor is necessary for starch utilization by B. thetaiotaomicron. Analysis of a starch-negative mutant that grew on G7 indicated that B. thetaiotaomicron possessed two starch-binding components or sites. One component (site A), apparently missing in this mutant, had an absolute preference for larger starch oligomers, whereas the other component (site M) also had a high affinity for maltodextrins (G4 through G7). Mutants not able to grow on maltodextrins (greater than G4) probably lacked both of these binding components. Only one class of mutants did not grow normally on maltose, but instead had a 4- to 5-h lag on maltose and a slower growth rate than the wild type. This class of mutants did not produce any of the starch-degrading enzymes or bind starch, even when growing on maltose. Such a phenotype probably resulted from transposon inactivation of a central regulatory gene or a gene encoding an enzyme that produces the inducer. The fact that both the degradative enzymes and the starch-binding activity were affected in this mutant indicates that genes encoding the cell surface starch-binding site are under the same regulatory control as genes encoding the enzymes.     

Investigation of the selectivity of maltoporin channels using mutant LamB proteins: mutations changing the maltodextrin binding site.

Wild-type and seven mutant maltoporins were purified and their channel-forming activities studied after reconstitution into black lipid membranes. The proteins were assayed for alterations at the maltodextrin binding site by measuring the sugar-dependent blockage of ion flux through these channels. Some substitutions (R8H, W74R) caused reduced channel affinity for all maltodextrins without changing single channel conductivities. The channel with a GlySer insertion after residue 9 was also poorly blocked by sugars but unique to this protein, the channel showed a striking, almost exponential increase of affinity with increasing maltodextrin chain length. In mutants with AspPro insertions after residues 79 and 183, there was an increase in affinity for glucose and maltose but not longer maltodextrins. The additional negative charge in the AspPro insertion mutants increased the cation selectivity of maltoporin channels, as did the decrease in positive charge resulting from the R8H substitution. A mutant with a W120C substitution also showed an increased affinity for glucose and maltose but reduced affinity for longer maltosaccharides. In contrast, a Y118F substitution resulted in an 8-fold increase in maltotriose affinity, but lesser improvements for other sugars. These results are interpreted to reflect changes in subsites contributing to an extended binding site within the channel, which in turn determines the overall sugar affinity of maltoporin.     

Sucrose transport through maltoporin mutants of Escherichia coli.

Maltoporin (LamB) and sucrose porin (ScrY) reside in the bacterial outer membrane and facilitate the passive diffusion of maltodextrins and sucrose, respectively. To gain further insight into the determinants of solute specificity, LamB mutants were designed to allow translocation of sucrose, which hardly translocates through wild-type LamB. Three LamB mutants were studied. (a) Based on sequence and structure alignment of LamB with ScrY, two LamB triple mutants were generated (R109D, Y118D,D121F; R109N,Y118D,D121F) to mimic the ScrY constriction. The crystal structure of the first of these mutants was determined to be 3.2 A and showed an increased ScrY-like cross-section except for D109 that protrudes into the channel. (b) Based on this crystal structure a double mutant was generated by truncation of the two residues that obstruct the channel most in LamB (R109A,Y118A). Analysis of liposome swelling and in vivo sugar uptake demonstrated substantial sucrose permeation through all mutants with the double alanine mutant performing best. The triple mutants did not show a well-defined binding site as indicated by sugar-induced ion current noise analysis, which can be explained by remaining steric interference as deduced from the crystal structure. Binding, however, was observed for the double mutant that had the obstructing residues truncated to alanines.     

A mutant form of maltose-binding protein of Escherichia coli deficient in its interaction with the bacteriophage lambda receptor protein.

In one malE mutant known to be deficient in the transport of maltose and maltodextrins across the outer membrane, the altered MalE protein was shown to be defective in its interaction with the phage lambda receptor, or LamB protein, of the outer membrane.     

Distribution of mannosamine and mannosaminuronic acid among cell walls of Bacillus species

Some Escherichia coli K-12 lamB mutants, those producing reduced amounts of LamB protein (one-tenth the wild type amount), grow normally on dextrins but transport maltose when present at a concentration of 1 microM at about one-tenth the normal rate. lamB Dex- mutants were found as derivatives of these strains. These Dex- mutants are considerably impaired in the transport of maltose at low concentrations (below 10 microM), and they have a structurally altered LamB protein which is impaired in its interaction with phages lambda and K10 but still interacts with a lambda host range mutant lambda hh*. The Dex- mutants are double lamB mutants carrying one mutation, already present in the parental strains, that reduces LamB synthesis and a second that alters LamB structure. The secondary mutations, present in different independent Dex- mutants, are clustered in the same region of the lamB gene. Dex+ revertants were isolated and analyzed: when the altered LamB protein is made in wild-type amount, due to a reversion of the first mutation, the phenotype reverts to Dex+. However, these Dex+ revertants are still very significantly impaired in maltose transport at low concentrations (below 10 microM).     

Lambda Receptor in the Outer Membrane of Escherichia coli as a Binding Protein for Maltodextrins and Starch Polysaccharides

The starch polysaccharides amylose and amylopectin are not utilized by Escherichia coli, but are bound by the bacteria. The following evidence supports the view that the outer membrane lambda receptor protein, a component of the maltose/ maltodextrin transport system is responsible for the binding. (i) Amylose and amylopectin both inhibit the transport of maltose into E. coli. (ii) Both polysaccharides prevent binding of non-utilizable maltodextrins by the intact bacterium, a process previously shown to be dependent on components of the maltose transport system (T. Ferenci, Eur. J. Biochem., in press). (iii) A fluorescent amylopectin derivative, O-(fluoresceinyl thiocarbamoyl)-amylopectin, has been synthesized and shown to bind to E. coli in a reversible, saturable manner. Binding of O-(fluoresceinyl thiocarbamoyl)-amylopectin is absent in mutants lacking the lambda receptor, but mutations in any of the other components of the maltose transport system do not affect binding as long as lambda receptor is present. (iv) Using the inhibition of lambda receptor-dependent O-(fluoresceinyl thiocarbamoyl)-amylopectin binding as an assay, the affinities of the lambda receptor for maltodextrins and other sugars have been estimated. The affinity for dextrins increases with increasing degree of polymerization (K(d) for maltose, 14 mM; for maltotetraose, 0.3 mM; for maltodecaose, 0.075 mM). Maltose and some other di- and trisaccharides are inhibitory to amylopectin binding, but only at concentrations above 1 mM.     

Maltose and maltotriose can be formed endogenously in Escherichia coli from glucose and glucose-1-phosphate independently of enzymes of the maltose system.

The maltose system in Escherichia coli consists of cell envelope-associated proteins and enzymes that catalyze the uptake and utilization of maltose and alpha,1-4-linked maltodextrins. The presence of these sugars in the growth medium induces the maltose system (exogenous induction), even though only maltotriose has been identified in vitro as an inducer (O. Raibaud and E. Richet, J. Bacteriol., 169:3059-3061, 1987). Induction is dependent on MalT, the positive regulator protein of the system. In the presence of exogenous glucose, the maltose system is normally repressed because of catabolite repression and inducer exclusion brought about by the phosphotransferase-mediated vectorial phosphorylation of glucose. In contrast, the increase of free, unphosphorylated glucose in the cell induces the maltose system. A ptsG ptsM glk mutant which cannot grow on glucose can accumulate [14C]glucose via galactose permeases. In this strain, internal glucose is polymerized to maltose, maltotriose, and maltodextrins in which only the reducing glucose residue is labeled. This polymerization does not require maltose enzymes, since it still occurs in malT mutants. Formation of maltodextrins from external glucose as well as induction of the maltose system is absent in a mutant lacking phosphoglucomutase, and induction by external glucose could be regained by the addition of glucose-1-phosphate entering the cells via a constitutive glucose phosphate transport system. malQ mutants, which lack amylomaltase, are constitutive for the expression of the maltose genes. This constitutive nature is due to the formation of maltose and maltodextrins from the degradation of glycogen.     

Derepression of LamB protein facilitates outer membrane permeation of carbohydrates into Escherichia coli under conditions of nutrient stress.

The level of LamB protein in the outer membrane of Escherichia coli was derepressed in the absence of a known inducer (maltodextrins) under carbohydrate-limiting conditions in chemostats. LamB protein contributed to the ability of the bacteria to remove sugar from glucose-limited chemostats, and well-characterized lamB mutants with reduced stability constants for glucose were less growth competitive under glucose limitation than those with wild-type affinity. In turn, wild-type bacteria were less growth competitive than lamB mutants with enhanced sugar affinity. In contrast to an earlier report, we found that LamB- bacteria were less able to compete in carbohydrate-limited chemostats (with glucose, lactose, arabinose, or glycerol as the carbon and energy sources) when mixed with LamB+ bacteria. The transport Km for [14C]glucose was affected by the presence or affinity of LamB, but only in chemostat-grown bacteria, with their elevated LamB levels. The pattern of expression of LamB and the advantage it confers for growth on low concentrations of carbohydrates are consistent with a wider role in sugar permeation than simply maltosaccharide transport, and hence the well-known maltoporin activity of LamB is but one facet of its role as the general glycoporin of E. coli. A corollary of these findings is that OmpF/OmpC porins, present at high levels in carbon-limited bacteria, do not provide sufficient permeability to sugars or even glycerol to support high growth rates at low concentrations. Hence, the sugar-binding site of LamB protein is an important contributor to the permeability of the outer membrane to carbohydrates in habitats with low extracellular nutrient concentrations.     

ExbBD-dependent transport of maltodextrins through the novel MalA protein across the outer membrane of Caulobacter crescentus

Analysis of the genome sequence of Caulobacter crescentus predicts 67 TonB-dependent outer membrane proteins. To demonstrate that among them are proteins that transport nutrients other than chelated Fe(3+) and vitamin B(12)-the substrates hitherto known to be transported by TonB-dependent transporters-the outer membrane protein profile of cells grown on different substrates was determined by two-dimensional electrophoresis. Maltose induced the synthesis of a hitherto unknown 99.5-kDa protein, designated here as MalA, encoded by the cc2287 genomic locus. MalA mediated growth on maltodextrins and transported [(14)C]maltodextrins from [(14)C]maltose to [(14)C]maltopentaose. [(14)C]maltose transport showed biphasic kinetics, with a fast initial rate and a slower second rate. The initial transport had a K(d) of 0.2 microM, while the second transport had a K(d) of 5 microM. It is proposed that the fast rate reflects binding to MalA and the second rate reflects transport into the cells. Energy depletion of cells by 100 microM carbonyl cyanide 3-chlorophenylhydrazone abolished maltose binding and transport. Deletion of the malA gene diminished maltose transport to 1% of the wild-type malA strain and impaired transport of the larger maltodextrins. The malA mutant was unable to grow on maltodextrins larger than maltotetraose. Deletion of two C. crescentus genes homologous to the exbB exbD genes of Escherichia coli abolished [(14)C]maltodextrin binding and transport and growth on maltodextrins larger than maltotetraose. These mutants also showed impaired growth on Fe(3+)-rhodotorulate as the sole iron source, which provided evidence of energy-coupled transport. Unexpectedly, a deletion mutant of a tonB homolog transported maltose at the wild-type rate and grew on all maltodextrins tested. Since Fe(3+)-rhodotorulate served as an iron source for the tonB mutant, an additional gene encoding a protein with a TonB function is postulated. Permeation of maltose and maltotriose through the outer membrane of the C. crescentus malA mutant was slower than permeation through the outer membrane of an E. coli lamB mutant, which suggests a low porin activity in C. crescentus. The pores of the C. crescentus porins are slightly larger than those of E. coli K-12, since maltotetraose supported growth of the C. crescentus malA mutant but failed to support growth of the E. coli lamB mutant. The data are consistent with the proposal that binding of maltodextrins to MalA requires energy and MalA actively transports maltodextrins with K(d) values 1,000-fold smaller than those for the LamB porin and 100-fold larger than those for the vitamin B(12) and ferric siderophore outer membrane transporters. MalA is the first example of an outer membrane protein for which an ExbB/ExbD-dependent transport of a nutrient other than iron and vitamin B(12) has been demonstrated.     

Isolation and characterization of OmpC porin mutants with altered pore properties.

The LamB protein is normally required for the uptake of maltodextrins. Starting with a LamB- OmpF- strain, we have isolated mutants that will grow on maltodextrins. The mutation conferring the Dex+ phenotype in the majority of these mutants has been mapped to the ompC locus. These mutants, unlike LamB- OmpF- strains, grew on maltotriose and maltotetraose, but not on maltopentaose, and showed a significantly higher rate of [14C]maltose uptake than the parent strain did. In addition, these mutants showed increased sensitivity to certain beta-lactam antibiotics and sodium dodecyl sulfate, but did not exhibit an increase in sensitivity to other antibiotics and detergents. The nucleotide sequence of these mutants has been determined. In all cases, residue 74 (arginine) of the mature OmpC protein was affected. The results suggest that this region of the OmpC protein is involved in the pore domain and that the alterations lead to an increased pore size.     

Maltose transport and starch binding in phage-resistant point mutants of maltoporin. Functional and topological implications

The relationships between the bacteriophage lambda binding site, the starch binding site and the pore formed by maltoporin (LamB protein, lambda receptor protein) were investigated. Bacteria with single amino acid substitutions in the maltoporin sequence, which were previously shown to be strongly reduced in phage lambda sensitivity, were assayed for maltose- (and maltodextrin) selective pore functions. Maltose transport assays was performed at low substrate concentrations, under conditions where LamB is limiting for transport. It revealed three classes of mutants. Class A is composed of mutants with no effect on transport (substitutions at amino acid residues 154, 155, 259, 382 and 401); class B corresponds to mutants with a significant but variable reduction in transport (sites 148, 151, 152, 163, 164, 245, 247 and 250); class C is represented by a single mutant for which transport is almost completely abolished (site 18). Starch binding was assayed by two different methods that gave compatible results. In class A mutants, binding was normal, while no binding was observed in the class C mutant. Binding was impaired to various extents in category B mutants. There was a correlation between the level of impairment of starch binding and impairment of maltose transport, consistent with the notion that the residues influencing starch binding are inside, or in close proximity to, the pore. These results, together with previous data on starch-binding mutants that were not affected in phage binding (substitutions at residues 8, 74, 82, 118 and 121), suggest that the binding sites for starch and phage lambda overlap but are distinct. Mutations affecting transport and starch binding are located in the first third of the protein and in the region of residues 245 to 250. Mutations affecting phage adsorption are located mainly in the last two-thirds of the protein. The topological constraints suggested by the results with the available mutants altered in the lamB gene were used to propose a revised model of maltoporin folding across the outer membrane as well as to define the outlines of footprints of macromolecular binding sites (phage, starch and monoclonal antibodies) on the surface of the protein.     

Regulation and genetic enhancement of beta-amylase production in Clostridium thermosulfurogenes.

We studied the general mechanism for regulation of beta-amylase synthesis in Clostridium thermosulfurogenes. beta-Amylase was expressed at high levels only when the organism was grown on maltose or other carbohydrates containing maltose units. Three kinds of mutants altered in beta-amylase production were isolated by using nitrosoguanidine treatment, enrichment on 2-deoxyglucose, and selection of colonies with large clear zones on iodine-stained starch-glucose agar plates. beta-Amylase was produced only when maltose was added to cells growing on sucrose in wild-type and catabolite repression-resistant mutant strains, but the differential rate of enzyme synthesis in constitutive mutants was constant regardless of the presence of maltose. In carbon-limited chemostats of wild-type and catabolite repression-resistant mutant stains, beta-amylase was expressed on maltose but not on glucose or sucrose. beta-Amylase synthesis was immediately repressed by the addition of glucose. Therefore, we concluded that beta-amylase synthesis in C. thermosulfurogenes was inducible and subject to catabolite repression. The addition of cAMP did not eliminate the repressive effect of glucose. The mutants were generally characterized in terms of beta-amylase production, growth properties, fermentation product formation, and alterations in glucose isomerase and glucoamylase activities. A hyperproductive mutant produced eightfold more beta-amylase on starch medium than the wild type and more rapidly fermented starch to ethanol.     

Biochemical analysis of starch degradation by Ruminobacter amylophilus 70.

Ruminobacter amylophilus is an obligate anaerobe that uses only alpha-linked glucose molecules (i.e., maltose, maltodextrins, and starch) as a source of energy, making it an excellent model for the study of bacterial starch degradation. Constitutive amylase, amylopectinase, and pullulanase activities were found in intracellular and extracellular fractions of R. amylophilus. However, extracellular activities apparently resulted from cell lysis. Both soluble and membrane-bound polysaccharidase activities were detected. Most of the soluble polysaccharidase activity partitioned with the periplasmic cell fraction. No alpha-glucosidase or maltase activity was detected in either the cellular or extracellular fraction. In addition, intact cells of R. amylophilus bound U-14C-starch. This binding could be saturated and was constitutive and sensitive to proteinase K, indicating protein or protein complex mediation. Competition experiments showed that these starch-binding sites had equally high affinities for starch and maltodextrins larger than maltotriose. The sites had a reduced affinity for maltose and virtually no affinities for glucose and nonstarch polysaccharides. These findings suggest that R. amylophilus binds starch molecules to the cell surface as an initial step in transporting the molecule through the outer membrane and into the periplasmic space. Extracellular polysaccharides do not appear to be involved in starch degradation.     

Seasonal Variations in the Carbohydrates in the Xylem of Antiaris africana

The xylem of Antiaris africana contains sucrose, starch, glucose,fructose, maltose, and raffinose. Sucrose and starch are themost abundant carbohydrates. Glucose and fructose occur in relativelyequal amounts while maltose and raffinose are the least abundant.Raffinose disappears from the xylem during the dry season, justbefore leaf fall. The pattern of seasonal variation in the individualsugars and starch is similar. There is generally a peak at leaffall and a depletion of these reserves at new flush. Accumulationof carbohydrates during leaf fall occurs first in the youngestxylem (i.e. the 0–2-cm segment). The youngest xylem alsoaccumulates the greatest amount of reserve sugars and starch.The concentrations of the sugars decrease inwards until theybegin to rise after the 4–6-cm segment. There is, however,no such rise in the concentration of starch. The dry-mattercontents increase inwards from the youngest xylem until theylevel out after the 4–6-cm segment. There is a rapid fallin the sucrose and starch contents of felled A. africana. Sucrosedropped by about 65 per cent and starch by about 73 per centin the first 10 days after felling. The levels of other sugarsdecreased gradually except for glucose and fructose which initiallyrose and then fell. Glucose and maltose could still be detectedon the 68th day after felling.     

Identification of valine 177 as a mutation altering specificity for transport of sugars by the Escherichia coli lactose carrier. Enhanced specificity for sucrose and maltose

A mutant of the Escherichia coli lactose carrier has been selected (in an invertase-positive strain) based on its ability to grow on 6 mM sucrose in a manner dependent upon lactose carrier induction by isopropyl-1-thio-beta-D-galactopyranoside. The mutant was cloned, and DNA sequencing revealed a point mutation in lacY which changed alanine 177 to valine. The valine 177 mutation increased the transport rate for both [14C]sucrose and the maltose analog 4-nitrophenyl-alpha-maltoside. The potency for inhibition of beta-ONPG transport by several sugars containing the glucopyranosyl moiety (maltose, cellobiose, or palatinose) was increased significantly relative to the parental carrier. Similar experiments showed that the mutation did not affect the affinity for such commonly studied substrates as 4-nitrophenyl-alpha-D-galactopyranoside and beta-D-galactopyranosyl-1-thio-beta-D-galactopyranoside. These data indicate that gross structural alteration of the galactoside binding site cannot account for increased transport of sucrose and maltose by the valine 177 mutant. We conclude that effects of the valine 177 mutation are not limited strictly to changes in observed sugar affinity and that sugar-specific changes in turnover number may be an important determinant of the altered spectrum of sugar specificities exhibited by the Val-177 carrier. These phenomena may be related to the effect of this mutation on proton recognition (described in King, S.C., and Wilson, T.H. (1990) J. Biol. Chem. 265, 9645-9651).     

Effect of point mutations on the in-vitro pore properties of maltoporin, a protein of Escherichia coli outer membrane

Maltoporin (LamB protein), a protein of Escherichia coli outer membrane forms ionic channels with a selectivity for maltose and maltodextrins (Dargent et al., 1987). The effect of different point mutations on maltoporin pore properties was investigated in vitro with planar bilayers. The mutations belong to three classes in terms of selective maltose transport in vivo: class A (substitution at positions 259 and 382) does not affect maltose transport, class B (position 163 and 245) decreases maltose transport down to 20 to 30%, and class C (position 18) almost completely abolishes selective maltose transport. This in-vitro study reveals that class A does not affect the pore properties in contrast to class B substitutions. The class B maltoporins are still able to form channels but display some specific features and altered specificity for maltose and maltodextrins. The substitution (Gly18----Val) alters trimer stability and impedes pore function (class C mutant). Thus, there is a good correlation between the specific transport properties of the mutated maltoporins in vivo and their behavior in vitro. These data, in combination with the asymmetric orientation of the protein within the bilayer and topological considerations, indicate that residues 245 and 163 do not belong to the selectivity filter. Mutations at these sites cause hindrance at the mouth of the pore on the outer domain of maltoporin.     

Isolation and characterization of maltose non utilizing (mnu) mutants mapping outside the MAL1 locus in Saccharomyces cerevisiae

The MAL1 locus of Saccharomyces cerevisiae comprises three genes necessary for maltose utilization. They include regulatory, maltose transport and maltase genes designated MAL1R, MAL1T and MAL1S respectively. Using a MAL1 strain transformed with an episomal, multicopy plasmid carrying the MAL2 locus, five recessive and one dominant mutant unable to grow on maltose, but still retaining a functional MAL1 locus were isolated. All the mutants could use glycerol, ethanol, raffinose and sucrose as a sole carbon source; expression of the maltase and maltose permease genes was severely and coordinately reduced. Only the dominant mutant failed to accumulate the MAL1R mRNA.