Directed evolution of cellobiose utilization in Escherichia coli K12

The cellobiose catabolic system of Escherichia coli K12 is being used to study the role of cryptic genes in evolution of new functions. Escherichia coli does not use beta-glucoside sugars; however, mutations in several loci can activate the cryptic bgl operon and permit growth on the beta-glucoside sugars arbutin and salicin. Such Bgl+ mutants do not use cellobiose, which is the most common beta-glucoside in nature. We have isolated a Cel+ (cellobiose-utilizing) mutant from a Bgl+ mutant of E. coli K12. The Cel+ mutant grows well on cellobiose, arbutin, and salicin. Genes for utilization of these beta-glucosides are located at 37.8 min on the E. coli map. The genes of the bgl operon are not involved in cellobiose utilization. Introduction of a deletion covering bgl does not affect the ability to utilize cellobiose, arbutin, or salicin, indicating that the new Cel+ genes provide all three functions. Spontaneous cellobiose negative mutants also become arbutin and salicin negative. Analysis of beta-glucoside positive revertants of these mutants indicates that there are separate loci for utilization of each of the beta-glucoside sugars. The genes are closely linked and may be activated from a single locus. A fourth gene at an unknown location increases the growth rate on cellobiose. The cel genes constitute a second cryptic system for beta-glucoside utilization in E. coli K12.      

Cryptic Genes for Cellobiose Utilization in Natural Isolates of Escherichia coli

The ECOR collection of natural Escherichia coli isolates was screened to determine the proportion of strains that carried functional, cryptic and nonfunctional genes for utilization of the three beta-glucoside sugars, arbutin, salicin and cellobiose. None of the 71 natural isolates utilized any of the beta-glucosides. Each strain was subjected to selection for utilization of each of the sugars. Only five of the isolates were incapable of yielding spontaneous beta-glucoside-utilizing mutants. Forty-five strains yielded cellobiose+ mutants, 62 yielded arbutin+ mutants, and 58 strains yielded salicin+ mutants. A subset of the mutants was screen by mRNA hybridization to determine whether they were expressing either the cel or the bgl beta-glucoside utilization operons of E. coli K12. Two cellobiose+ and two arbutin+-salicin+ strains failed to express either of these known operons. It is concluded that there are at least four gene clusters specifying beta-glucoside utilization functions in E. coli populations, and that all of these are normally cryptic. It is estimated that in any random isolate the probability of any particular cluster having been irreversibly inactivated by the accumulation of random mutations is about 0.5.     

A Fourth Escherichia Coli Gene System with the Potential to Evolve β-Glucoside Utilization

Escherichia coli K12 is being used to study the potential for adaptive evolution that is present in the genome of a single organism. Wild-type E. coli K12 do not utilize any of the beta-glucoside sugars arbutin, salicin or cellobiose. It has been shown that mutations at three cryptic loci allow utilization of these sugars. Mutations in the bgl operon allow inducible growth on arbutin and salicin while cel mutations allow constitutive utilization of cellobiose as well as arbutin and salicin. Mutations in a third cryptic locus, arbT, allow the transport of arbutin. A salicin+ arbutin+ cellobiose+ mutant has been isolated from a strain which is deleted for the both the bgl and cel operons. Because the mutant utilized salicin and cellobiose as well as arbutin, it is unlikely it is the result of a mutation in arbT. A second step mutant exhibited enhanced growth on salicin and a third step mutant showed better growth on cellobiose. A fourfold level of induction in response to arbutin and a twofold level of induction in response to salicin was observed when these mutants were assayed on the artificial substrate p-nitrophenyl-beta-D-glucoside. Although growth on cellobiose minimal medium can be detected after prolonged periods of time, these strains are severely inhibited by cellobiose in liquid medium. This system has been cloned and does not hybridize to either bgl or cel specific probes. We have designated this gene system the sac locus. The sac locus is a fourth set of genes with the potential for evolving to provide beta-glucoside utilization.     

Maintenance of the cellobiose utilization genes of Escherichia coli in a cryptic state

The genes for cellobiose utilization are normally cryptic in Escherichia coli. The cellobiose system was used as a model to understand the process by which silent genes are maintained in microbial populations. Previously reported was (1) the isolation of a mutant strain that expresses the cellobiose-utilization (Cel) genes and (2) that expression of those genes allows utilization of three beta- glucoside sugars: cellobiose, arbutin, and salicin. The Cel gene cluster has now been cloned from that mutant strain. In the course of locating the Cel genes within the cloned DNA segment, it was discovered that inactivation of the Cel-encoded hydrolase rendered the host strain sensitive to all three beta-glucosides as potent inhibitors. This sensitivity arises from the accumulation of the phosphorylated beta- glucosides. Because even the fully active genes conferred some degree of beta-glucoside sensitivity, the effects of cellobiose on a series of five Cel+ mutants of independent origin were investigated. Although each of those strains utilizes cellobiose as a sole carbon and energy source, cellobiose also acts as a potent inhibitor that reduces the growth rate on glycerol 2.5-16.5-fold. On the other hand, wild-type strains that cannot utilize cellobiose are not inhibited. The observation that the same compound can serve either as a nutrient or as an inhibitor suggests that, under most conditions in which cellobiose will be present together with other resources, there is a strong selective advantage to having the cryptic (Cel0) allele. In those environments in which cellobiose is the sole, or the best, resource, mutants that express the genes (Cel+) will have a strong selective advantage. It is suggested that temporal alternation between these two conditions is a major factor in the maintenance of these genes in E. coli populations. This alternation of environments and fitnesses was predicted by the model for cryptic-gene maintenance that was previously published.      

Characterization and Nucleotide Sequence of the Cryptic Cel Operon of Escherichia Coli K12

Wild-type Escherichia coli are not able to utilize beta-glucoside sugars because the genes for utilization of these sugars are cryptic. Spontaneous mutations in the cel operon allow its expression and enable the organism to ferment cellobiose, arbutin and salicin. In this report we describe the structure and nucleotide sequence of the cel operon. The cel operon consists of five genes: celA, whose function is unknown; celB and celC which encode phosphoenolpyruvate-dependent phosphotransferase system enzyme IIcel and enzyme IIIcel, respectively, for the transport and phosphorylation of beta-glucoside sugars; celD, which encodes a negative regulatory protein; and celF, which encodes a phospho-beta-glucosidase that acts on phosphorylated cellobiose, arbutin and salicin. The mutationally activated cel operon is induced in the presence of its substrates, and is repressed in their absence. A comparison of proteins encoded by the cel operon with functionally equivalent proteins of the bgl operon, another cryptic E. coli gene system responsible for the catabolism of beta-glucoside sugars, revealed no significant homology between these two systems despite common functional characteristics. The celD and celF encoded repressor and phospho-beta-glucosidase proteins are homologous to the melibiose regulatory protein and to the melA encoded alpha-galactosidase of E. coli, respectively. Furthermore, the celC encoded PEP-dependent phosphotransferase system enzyme IIIcel is strikingly homologous to an enzyme IIIlac of the Gram-positive organism Staphylococcus aureus. We conclude that the genes for these two enzyme IIIs diverged much more recently than did their hosts, indicating that E. coli and S. aureus have undergone relatively recent exchange of chromosomal genes.     

Cryptic Operon for β-Glucoside Metabolism in ESCHERICHIA COLI K12: Genetic Evidence for a Regulatory Protein

Escherichia coli K12 does not metabolize beta-glucosides such as arbutin and salicin because of lack of expression of the bglBSRC operon, which contains structural genes for transport (bglC) and hydrolysis (bglB) of phospho-beta-glucosides. Mutants carrying lesions in the cis-acting regulatory site bglR metabolize beta-glucosides as a consequence of expression of this cryptic operon (Prasad and Schaefler 1974). We isolated mutations promoting beta-glucoside metabolism that were unlinked to bglR; some of these mutations were shown to be amber. All of them were mapped at 27 min on the E. coli K12 linkage map and appeared to define a single gene, for which we propose the designation bglY. Utilization of beta-glucosides in bglY mutants appeared to be a consequence of expression of the bglBSRC operon, since bglB bglR and bglB bglY double mutants had the same phenotype. All bglY mutations analyzed were recessive to the wild-type bglY+ allele. Phospho-beta-glucosidase B and beta-glucoside transport activities are inducible in bglY mutants, as they are in bglR mutants. Metabolism of beta-glucosides in both bglR and bglY mutants required cyclic AMP. We propose that bglY encodes a protein acting as a repressor of the bglBSRC operon, active in both the presence and absence of beta-glucosides, whose recognition site would be within the bglR locus.     

Functional genes for cellobiose utilization in natural isolates of Escherichia coli.

The genes for utilization of cellobiose are normally cryptic in both laboratory strains and natural isolates of Escherichia coli. A survey of natural isolates of E. coli reveals that functional genes for cellobiose utilization, while rare, are present. The fraction of E. coli that utilized cellobiose ranged from less than 0.01% in human fecal samples to 7% in fecal samples obtained from horses. Samples obtained from sheep, cows, dogs, and pigs contained 0.1 to 0.5% cellobiose-positive E. coli. Neither the previously identified cel genes nor the bgl genes from E. coli K-12 were expressed during growth on cellobiose by any of the 14 naturally occurring Cel+ isolates that were tested. All of the naturally occurring Cel+ isolates possessed a cel operon, but all were deleted for the major portion of the bgl operon. The functional cel+ genes from these natural isolates differed from the mutationally activated cel+ genes obtained in earlier studies in that (i) the mutationally activated cel+ genes were temperature sensitive, while the functional genes were not, and (ii) transport of cellobiose was inducible in the strains carrying functional cel+ genes, while it was expressed constitutively in strains carrying mutationally activated genes.     

Analysis of the Erwinia chrysanthemi arb genes, which mediate metabolism of aromatic beta-glucosides.

Erwinia chrysanthemi is one of the few members of the family Enterobacteriaceae that is capable of metabolizing most of the naturally occurring beta-glucosides. We previously isolated the clb genes, which allow the use of the disaccharide cellobiose as well as the aromatic beta-glucosides arbutin and salicin. We report here the isolation of the arb genes, which permit fermentation of the aromatic beta-glucosides only. Establishment of a functional Arb system in Escherichia coli depended on the presence of the phosphotransferase system and on the activation by the cyclic AMP-cyclic AMP receptor protein complex. Strains carrying mini-Mu-induced LacZ fusions to the arb genes were used to analyze arb genes organization and function. Three arb genes (arbG, arbF, and arbB) were identified and organized in this order. Genetic and structural evidence allowed us to assign a phospho-beta-glucosidase and a permease activity to the ArbB and ArbF proteins, respectively. Several Lac+ arb-lacZ insertions were introduced into the E. chrysanthemi chromosome. Both ArbG- and ArbF- strains were unable to ferment the aromatic beta-glucosides, whereas ArbB- strains were impaired only in salicin fermentation. None of the mutations in the arb genes affected cellobiose metabolism. The expression of the arb genes was substrate inducible and required the ArbF permease and, possibly, the ArbG protein. Collectively, our results underline the resemblance between the naturally expressed E. chrysanthemi arbGFB and the cryptic E. coli bglGFB operons, yet the arbG gene product seemed unable to activate E. coli bgl operon expression.     

Inducible system for the utilization of beta-glucosides in Escherichia coli. II. Description of mutant types and genetic analysis

Two types of mutants obtained by treating beta-gl(+) cells with nitrosoguanidine are described. One type, beta-gl(+)c, is constitutive for the biosynthesis of the aryl beta-glucoside splitting enzyme(s) and for the beta-glucoside permease; the other (beta-gl(+)sal(-)) has lost the capacity to ferment salicin, but has retained the capacity to ferment arbutin and other aryl beta-glucosides. By two successive mutational steps, beta-gl(+)sal(-)c double mutants can be obtained. Determinations of the enzymatic splitting of salicin and p-nitrophenyl beta-glucoside by beta-gl(+)sal(-) cells and extracts showed that these mutants have lost the capacity to split salicin but do split p-nitrophenyl beta-glucoside; they possess the beta-glucoside permease, and in them salicin is a gratuitous inducer for enzyme and permease biosynthesis. Studies on a beta-gl(+) strain, which splits salicin as well as p-nitrophenyl beta-glucoside, have shown that the splitting of salicin is more temperature-sensitive than that of p-nitrophenyl beta-glucoside and other beta-glucosides. Other properties of the two activities are similar. Interrupted mating experiments and cotransduction with P1kc phage showed that the genetic determinants of the beta-glucoside system map between the pyrE and ile loci. Three distinct mutational sites were found and are presumed to have the following functions: beta-glA, a structural gene for an aryl beta-glucoside splitting enzyme; beta-glB, either the structural gene for the beta-glucoside-permease or a regulatory gene; and beta-glC, a regulatory gene (or site). Escherichia coli wild-type strains are of the genotype A(+) B(-) C(+). The beta-gl(+) mutation determining the ability to ferment beta-glucosides is considered to be a permease or regulatory mutation, and the resulting genotype is A(+) B(+) C(+). The beta-gl(+)sal(-) phenotype results from a mutation in the beta-glA gene (genotype A' B(+) C(+)), and the constitutive phenotype results from a mutation in the beta-glC gene, the genotypes A(+) B(+)C(a) and A' B(+)C(a) corresponding to the phenotypes beta-gl(+)c and beta-gl(+)sal(-)c.     

Growth of Azospirillum irakense KBC1 on the Aryl β-Glucoside Salicin Requires either salA or salB

The rhizosphere nitrogen-fixing bacterium Azospirillum irakense KBC1 is able to grow on pectin and beta-glucosides such as cellobiose, arbutin, and salicin. Two adjacent genes, salA and salB, conferring beta-glucosidase activity to Escherichia coli, have been identified in a cosmid library of A. irakense DNA. The SalA and SalB enzymes preferentially hydrolyzed aryl beta-glucosides. A Delta(salA-salB) A. irakense mutant was not able to grow on salicin but could still utilize arbutin, cellobiose, and glucose for growth. This mutant could be complemented by either salA or salB, suggesting functional redundancy of these genes in salicin utilization. In contrast to this functional homology, the SalA and SalB proteins, members of family 3 of the glycosyl hydrolases, show a low degree of amino acid similarity. Unlike SalA, the SalB protein exhibits an atypical truncated C-terminal region. We propose that SalA and SalB are representatives of the AB and AB' subfamilies, respectively, in glycosyl hydrolase family 3. This is the first genetic implication of this beta-glucosidase family in the utilization of beta-glucosides for microbial growth.     

The beta-glucoside genes of Klebsiella aerogenes: conservation and divergence in relation to the cryptic bgl genes of Escherichia coli

The ability to metabolize aromatic beta-glucosides such as salicin and arbutin varies among members of the Enterobacteriaceae. The ability of Escherichia coli to degrade salicin and arbutin appears to be cryptic, subject to activation of the bgl genes, whereas many members of the Klebsiella genus can metabolize these sugars. We have examined the genetic basis for beta-glucoside utilization in Klebsiella aerogenes. The Klebsiella equivalents of bglG, bglB and bglR have been cloned using the genome sequence database of Klebsiella pneumoniae. Nucleotide sequencing shows that the K. aerogenes bgl genes show substantial similarities to the E. coli counterparts. The K. aerogenes bgl genes in multiple copies can also complement E. coli mutants deficient in bglG encoding the antiterminator and bglB encoding the phospho-beta-glucosidase, suggesting that they are functional homologues. The regulatory region bglR of K. aerogenes shows a high degree of similarity of the sequences involved in BglG-mediated regulation. Interestingly, the regions corresponding to the negative elements present in the E. coli regulatory region show substantial divergence in K. aerogenes. The possible evolutionary implications of the results are discussed.     

Mutations that activate the silent bgl operon of Escherichia coli confer a growth advantage in stationary phase

Wild-type strains of Escherichia coli are unable to utilize aromatic beta-glucosides such as arbutin and salicin because the major genetic system that encodes the functions for their catabolism, the bgl operon, is silent and uninducible. We show that strains that carry an activated bgl operon exhibit a growth advantage over the wild type in stationary phase in the presence of the rpoS819 allele that causes attenuated rpoS regulon expression. Our results indicate a possible evolutionary advantage in retaining the silent bgl operon by wild-type bacteria.     

Taxonomic Investigations on Expressed and Cryptic Phospho-β-glucosidases in Enterobacteriaceae

In the Enterobacteriaceae, beta-glucosides are catabolized by a complex system formed of three permeases, with partly overlapping substrate specificities, and two hydrolytic enzymes, phospho-beta-glucosidase A and B, which hydrolyze only phosphorylated beta-glucosides. Some Enterobacteriaceae such as Klebsiella-Aerobacter (Enterobacter) possess the complete system; others possess only parts of it or may have a cryptic phospho-beta-glucosidase activity without permease activity. A screening test applied to strains belonging to several genera of Enterobacteriaceae showed that strains of Citrobacter, Hafnia, and Serratia exhibit a degree of similarity in phospho-beta-glucosidase activity and inducibility which could be useful in their taxonomic characterization; others, such as Aerobacter aerogenes, Erwinia, and Proteus vulgaris, are more heterologous. Owing to the presence of inducible phospho-beta-glucosidases A and B in Citrobacter, the fermentation of beta-methyl glucoside and the fermentation of arbutin in mixture with cellobiose could be of diagnostic value in the differentiation of Citrobacter from Salmonella. Wild-type strains of Escherichia coli, Shigella, and Salmonella are phenotypically similar in their inability to catabolize beta-glucosides, the presence of constitutive P-beta-glucosidase A, and the lack of beta-glucoside permeases I and II. Their beta-glucoside-fermenting mutants show, however, a phospho-beta-glucosidase and beta-glucoside permease activity which is characteristic for mutants from each genus. The differences in the phenotype of the mutants reflect probable differences in the presence of cryptic genes in the wild-type strains and could be of evolutionary significance.     

Nucleotide sequence, function, activation, and evolution of the cryptic asc operon of Escherichia coli K12.

The cryptic asc (previous called "SAC") operon of Escherichia coli K12 has been completely sequenced. It encodes a repressor (ascG); a PTS enzyme IIasc for the transport of arbutin, salicin, and cellobiose (ascF); and a phospho-beta-glucosidase that hydrolyzes the sugars which are phosphorylated during transport (ascB). ascG and ascFB are transcribed from divergent promoters. The cryptic operon is activated by the insertion of IS186 into the ascG (repressor) gene. The ascFB genes are paralogous to the cryptic bglFB genes, and ascG is paralogous to galR. The duplications that gave rise to these paralogous genes are estimated to have occurred approximately 320 Mya, a time that predates the divergence of E. coli and Salmonella typhimurium.     

Widespread distribution of deletions of the bgl operon in natural isolates of Escherichia coli

A deletion that includes the bgl (beta-glucoside utilization) operon of Escherichia coli was originally detected in several rarely occurring natural isolates that utilize cellobiose. Here I show that bgl deletions are present in 95% of the Cel+ isolates obtained from diverse sources. They are also present in 29% of the Cel- strains in two different collections of natural isolates of E. coli. At least three versions of bgl deletions are present in E. coli populations. In the most common version approximately 8 kb of DNA around the bgl region of E. coli K12 is replaced by a specific 6.5-kb DNA fragment. In another version a deletion of similar length is not replaced by the same sequence. A third version involves deletion of approximately 14 kb without the replacement fragment being present. The distribution of these deletions suggests that the version 1 deletion occurred very early in the history of E coli. It also appears likely that there is selection for bgl deletions in Cel+ strains of E. coli. The presence of the version 1 deletion within distantly related phylogenetic groups of E. coli provides evidence for recombination within natural populations of E coli.      

Cellobiose uptake in the hyperthermophilic archaeon Pyrococcus furiosus is mediated by an inducible, high-affinity ABC transporter

The hyperthermophilic archaeon Pyrococcus furiosus can utilize different beta-glucosides, like cellobiose and laminarin. Cellobiose uptake occurs with high affinity (K(m) = 175 nM) and involves an inducible binding protein-dependent transport system. The cellobiose binding protein (CbtA) was purified from P. furiosus membranes to homogeneity as a 70-kDa glycoprotein. CbtA not only binds cellobiose but also cellotriose, cellotetraose, cellopentaose, laminaribiose, laminaritriose, and sophorose. The cbtA gene was cloned and functionally expressed in Escherichia coli. cbtA belongs to a gene cluster that encodes a transporter that belongs to the Opp family of ABC transporters.     

Influence of gyrA mutation on expression of Erwinia chrysanthemi clb genes cloned in Escherichia coli.

Erwinia chrysanthemi clb genes cloned into Nals Escherichia coli allowed growth on cellobiose, arbutin, or salicin. In contrast, Nalr isogenic strains grew only on cellobiose. It is proposed that expression of cloned E. chrysanthemi clb genes is reduced by the E. coli chromosomal gyrA (Nalr) mutation, resulting in apparent segregation of the Clb and Arb Sal characters.     

Involvement of Streptococcus gordonii beta-glucoside metabolism systems in adhesion, biofilm formation, and in vivo gene expression

Streptococcus gordonii genes involved in beta-glucoside metabolism are induced in vivo on infected heart valves during experimental endocarditis and in vitro during biofilm formation on saliva-coated hydroxyapatite (sHA). To determine the roles of beta-glucoside metabolism systems in biofilm formation, the loci of these induced genes were analyzed. To confirm the function of genes in each locus, strains were constructed with gene inactivation, deletion, and/or reporter gene fusions. Four novel systems responsible for beta-glucoside metabolism were identified, including three phosphoenolpyruvate-dependent phosphotransferase systems (PTS) and a binding protein-dependent sugar uptake system for metabolizing multiple sugars, including beta-glucosides. Utilization of arbutin and esculin, aryl-beta-glucosides, was defective in some mutants. Esculin and oligochitosaccharides induced genes in one of the three beta-glucoside metabolism PTS and in four other genetic loci. Mutation of genes in any of the four systems affected in vitro adhesion to sHA, biofilm formation on plastic surfaces, and/or growth rate in liquid medium. Therefore, genes associated with beta-glucoside metabolism may regulate S. gordonii in vitro adhesion, biofilm formation, growth, and in vivo colonization.