On the Evolution of New Metabolic Functions in Diploid Organisms

Evolution of lactose utilization via the ebg system of Escherichia coli requires both structural gene (ebgA) and regulatory gene (ebgR) mutations. Because evolution of new metabolic functions in diploids might be subject to constraints not present in haploid organisms, merodiploid strains carrying a wild-type and an evolved ebgA allele, or a wild-type and an evolved ebgR allele were constructed. I show that heterozygosity at ebgA does not significantly affect the selective advantage of the evolved ebgA allele; whereas heterozygosity at ebgR eliminates the selective advantage of the evolved ebgR allele. It is suggested that, in diploid organisms, evolution of new functions for systems under negative control would be very difficult.     

The ebg operon consists of at least two genes

The ebg operon of Escherichia coli includes a second gene designated ebgB. The ebgB gene product is a 79,000-molecular-weight protein and is expressed coordinately with the ebgA gene product, ebg beta-galactosidase. Insertion of the transposable elements Tn5 and Tn9 into ebgA eliminates the expression of ebgB, suggesting that ebgB is distal to ebgA. Ultraviolet light mapping confirms that gene order. The function of the ebgB gene product is unknown.     

Determining the evolutionary potential of a gene

In addition to information for current functions, the sequence of a gene includes potential information for the evolution of new functions. The wild-type ebgA (evolved beta-galactosidase) gene of Escherichia coli encodes a virtually inactive beta-galactosidase, but that gene has the potential to evolve sufficient activity to replace the lacZ gene for growth on the beta-galactoside sugars lactose and lactulose. Experimental evidence, which has suggested that the evolutionary potential of Ebg enzyme is limited o two specific amino acid replacements, is limited to examining the consequences of single base- substitutions. Thirteen beta-galactosidases homologous with the Ebg beta-galactosidase are widely dispersed, being found in gram-negative and gram-positive eubacteria and in a eukaryote. A comparison of Ebg beta-galactosidase with those 13 beta-galactosidases shows that Ebg is part of an ancient clade that diverged from the paralogous lacZ beta- galactosidase over 2 billion years ago. Ebg differs from other members of its clade at only 2 of the 15 active-site residues, and the two mutations required for full Ebg beta-galactosidase activity bring Ebg into conformity with the other members of its clade. We conclude that either these are the only acceptable amino acids at those positions, or all of the single-base-substitution replacements that must arise as intermediates on the way to other acceptable amino acids are so deleterious that they constitute a deep selective valley that has not been traversed in over 2 billion years. The evolutionary potential of Ebg is thus limited to those two replacements.      

Physiological studies of Escherichia coli strain MG1655: growth defects and apparent cross-regulation of gene expression

Escherichia coli strain MG1655 was chosen for sequencing because the few mutations it carries (ilvG rfb-50 rph-1) were considered innocuous. However, it has a number of growth defects. Internal pyrimidine starvation due to polarity of the rph-1 allele on pyrE was problematic in continuous culture. Moreover, the isolate of MG1655 obtained from the E. coli Genetic Stock Center also carries a large deletion around the fnr (fumarate-nitrate respiration) regulatory gene. Although studies on DNA microarrays revealed apparent cross-regulation of gene expression between galactose and lactose metabolism in the Stock Center isolate of MG1655, this was due to the occurrence of mutations that increased lacY expression and suppressed slow growth on galactose. The explanation for apparent cross-regulation between galactose and N-acetylglucosamine metabolism was similar. By contrast, cross-regulation between lactose and maltose metabolism appeared to be due to generation of internal maltosaccharides in lactose-grown cells and may be physiologically significant. Lactose is of restricted distribution: it is normally found together with maltosaccharides, which are starch degradation products, in the mammalian intestine. Strains designated MG1655 and obtained from other sources differed from the Stock Center isolate and each other in several respects. We confirmed that use of other E. coli strains with MG1655-based DNA microarrays works well, and hence these arrays can be used to study any strain of interest. The responses to nitrogen limitation of two urinary tract isolates and an intestinal commensal strain isolated recently from humans were remarkably similar to those of MG1655.     

Overexpression and functional analysis of cold-active beta-galactosidase from Arthrobacter psychrolactophilus strain F2

Cold-active beta-galactosidase from Arthrobacter psychrolactophilus strain F2 was overexpressed in Escherichia coli using the Cold expression system and the recombinant enzyme, rBglAp, was characterized. The purified rBglAp exhibited similar enzymatic properties to the native enzyme, e.g., (i) it had high activity at 0 degrees C, (ii) its optimum temperature and pH were 10 degrees C and 8.0, respectively, and (iii) it was possible to rapidly inactivate the rBglAp at 50 degrees C in 5 min. Moreover, rBglAp was able to hydrolyze both ONPG and lactose with K(m) values of 2.7 and 42.1mM, respectively, at 10 degrees C. One U of rBglAp could hydrolyze about 70% of the lactose in 1 ml of milk in 24h, and the enzyme produced trisaccharide from lactose. We conclude that rBglAp is a cold-active enzyme that is extremely heat labile and has significant potential application to the food industry.     

Lactose metabolism involving phospho-beta-galactosidase in Klebsiella.

Klebsiella strain RE1755A is a Lac- Gal- mutant which has lost both of its lac operons, but possesses a gene specifying beta-galactosidase III, an enzyme which hydrolyzes o-nitrophenyl-beta-D-galactopyranoside but does not hydrolyze lactose. Selective pressure was applied to isolate mutants able to utilize lactose. The lactose-utilizing mutants obtained were shown to possess an unaltered beta-galactosidase III. Lactose utilization was shown to result from a pleiotropic mutation which also (i) permits galactose utilization and (ii) prevents induction of beta-galactosidase III synthesis by lactose. Evidence is presented suggesting that a phospho-beta-galactosidase enzyme is involved in lactose metabolism.     

The effects of osmotic stress on survival and alkaline phosphatase activity of Aeromonas hydrophila

Abstract Lactococcus lactis MG5267 is a plasmid-free strain in which the lactose operon is integrated in the bacterial chromosome. The chromosomal lac G gene which encodes phospho-β-galactosidase was inactivated by a double cross-over integration event. Unexpectedly, the resultant mutant was shown to retain a Lac-positive phenotype. The lysin gene from Listeria monocytogenes bacteriophage LM-4 was subsequently integrated into the chromosome of this strain such that expression of the heterologous gene was mediated by the lactose operon promoter. Expression of the lysin gene was shown to be regulated by growth on lactose. This represents an important strategy for the controlled and stabilised expression of biotechnologically useful genes in L lactis .     

Lactose hydrolysis by immobilized β-galactosidase on nylon-6: A novel spin-basket reactor

Summary -D-galactosidase from Kluyveromyces lactis immobilized on nylon-6 microbeads was used to hydrolyze lactose in skim milk (containing 28.6% total solids), using a novel spin-basket reactor. More than 75% of lactose was hydrolyzed at 34°C within a short space-time (<7 min) without experiencing any plugging such as typically seen in packed columns.     

Lactose- and galactose-utilizing strains of poly(hydroxyalkanoic acid)-accumulating Alcaligenes eutrophus and Pseudomonas saccharophila obtained by recombinant DNA technology

Summary Transposon Tn 951-encoded -galactosidase was expressed in Pseudomonas saccharophila and enabled this bacterium to grow on lactose as sole carbon source. In contrast, -galactosidase was not expressed in Alcaligenes eutrophus even if the lacZ gene of Tn 951 was separated from the lacI gene. However, -galactosidase was expressed in A. eutrophus, if a DNA fragment, which was suspected to harbour the promoter of the A. eutrophus poly(3-hydroxybutyric acid)-synthetic genes, was ligated to the promoter probe vector pMC1403, which employs lac Z, Y as reporter genes. Plasmid pPL76, which harboured one of the promoter-lac fusions, enabled A. eutrophus not only to express -galactosidase but also to grow slowly on lactose (doubling time &#x003D; 25–30 h). Subsequently, the promoter-lac fusion was ligated to Tn5 in pSUP5011 and was inserted into the genome of A. eutrophus H16 and of the glucose-utilizing mutant H16-G⁺1 by applying the suicide plasmid technique. Two recombinant strains, H16-cPL and H16-G⁺1-cPL, which grow with a doubling time of 16–23 h on lactose, were investigated in detail. The cells only utilized the glucose residue of lactose as a carbon source for grouth and excreted galactose into the medium. Only after the Escherichia coli gal operon had been cloned in vector pVK101 and had been mobilized to H16-cPL or H16-G⁺1-cPL, was lactose completely utilized; no galactose was detected in the medium and the growth yields increased twofold. Depending on the orientation of the gal operon in pVK101, the expression of galactokinase seems to be dependent either on the promoter of aminoglycoside phosphotransferase gene (kan) or on the promoter of the tetR gene. Offprint requests to: A. Steinbüchel     

Population Dynamics of a Lac(-) Strain of Escherichia Coli during Selection for Lactose Utilization

During selection for lactose utilization, Lac(+) revertants of FC40, a Lac(-) strain of Escherichia coli, appear at a high rate. Yet, no Lac(+) revertants appear in the absence of lactose, or in its presence if the cells have another, unfulfilled requirement for growth. This study investigates more fully the population dynamics of FC40 when incubated in the absence of a carbon source or when undergoing selection for lactose utilization. In the absence of a carbon source, the viable cell numbers do not change over 6 days. When incubated in liquid lactose medium, Lac(-) cells do not undergo any measurable increase in numbers or in turbidity for at least 2 days. When FC40 is plated on lactose minimum medium in the presence of scavenger cells, the upper limit to the amount of growth of Lac(-) cells during 5 days is one doubling, and there is no evidence for turnover (i.e., a balance between growth and death). The presence of a minority population that could form microcolonies was not detected. The implications of these results, plus the fact that the appearance of Lac(+) revertants during lactose selection is nearly constant with time, are discussed in reference to several models that have been postulated to account for adaptive mutations.     

Construction of a lethal mutation in the synthesis of the major acidic phospholipids of Escherichia coli

In order to determine if the major acidic phospholipids of Escherichia coli are essential to the organism, we constructed a null allele (pgsA30) of the pgsA gene thus rendering the organism incapable of synthesizing phosphatidylglycerol or cardiolipin. In strains carrying the pgsA30 allele cell viability, synthesis of gene product and the ability to synthesize the two major acidic phospholipids were dependent on the presence of a functional copy of the pgsA gene carried on a plasmid which was temperature-sensitive for replication. Growth ceased at the temperature restrictive for plasmid replication when the acidic phospholipid content dropped to about 10% of wild type levels which is slightly higher than the level reported in cells carrying the pgsA3 allele in a genetic background derived from strain SD12; the latter cells, which are capable of synthesizing low levels of acidic phospholipids, were previously shown to have no abnormal growth phenotype (Miyazaki, C., Kuroda, M., Ohta, A., and Shibuya, I. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 7530-7534). The pgsA30 allele, unlike the pgsA3 allele, could not support growth in strain SD12. Neither allele could support growth in two other independently derived strains of E. coli. Therefore, there is a direct dependence of cell viability on a functional pgsA gene product. Strain SD12 appears to contain a suppressor which allows cells with a reduced capability to synthesize acidic phospholipid (pgsA3 allele) to grow, but cannot support growth in cells with a complete lack of synthetic capability (pgsA30 allele).     

Mutants of Salmonella typhimurium deficient in an endoprotease.

Three bands of hydrolytic activity toward the chromogenic protease substrate N-acetyl-DL-phenylalanine beta-naphthyl ester (NAPNE) can be observed after gel electrophoresis of crude extracts of Salmonella typhimurium or Escherichia coli. Mutants deficient in one of these three activities have been isolated using a staining procedure that identifies colonies that show reduced ability to hydrolyze NAPNE. These mutants lack the strongest of the three bands of activity. The Salmonella mutations (designated apeA) are all co-transducible with purE, and the order (pro)-apeA-Hfr K17 origin-purE has been established. Strains carrying apeA mutations have wild-type doubling times. None of the apeA mutants isolated gains an auxotrophic requirement as a result of loss of the apeA gene product. The rates and extents of protein degradation during starvation for a carbon source or during growth after exposure to the amino acid analogue canavanine do not seem to be affected by apeA mutations. Revertants of apeA mutations (selected by screening for clones that have regained the ability to hydrolyze NAPNE) frequently contain a new enzymatic activity not found in wild-type cells.     

Experimental Evolution of a New Enzymatic Function. II. Evolution of Multiple Functions for EBG Enzyme in E. COLI

The evolution of ebgo enzyme of Escherichia coli, an enzyme which is unable to hydrolyze lactose, lactulose, lactobionate, or galactose-arabinoside effectively, has been directed in successive steps so that the evolved enzyme is able to hydrolyze these galactosides effectively. I show that in order for a strain of E. coli with a lacZ deletion to evolve the ability to use lactobionate as a carbon source, a series of mutations must occur in the ebg genes, and that these mutations must be selected in a particular order. The ordered series of mutations constitutes an obligatory evolutionary pathway for the acquisition of a new function for ebgo enzyme. A comparison of newly evolved strains with parental strains shows that when ebg enzyme acquires a new function, its old functions often suffer; but that in several cases old functions are either unaffected or are improved. I conclude that divergence of functions catalyzed by an enzyme need not require gene duplication.     

Maltose-binding protein does not modulate the activity of maltoporin as a general porin in Escherichia coli.

Maltoporin (lambda receptor) is part of the maltose transport system in Escherichia coli and is necessary for the facilitated diffusion of maltose and maltodextrins across the outer membrane. Maltoporin also allows the diffusion of nonmaltodextrin substrates, albeit with less efficiency. The preference of maltoporin for maltodextrins in vivo is thought to be the result of an interaction of maltoporin with the maltose-binding protein, the malE gene product. In a recent report Heuzenroeder and Reeves (J. Bacteriol. 144:431-435, 1980) suggested that this interaction establishes a gating mechanism which inhibits the diffusion of nonmaltodextrin substrates, such as lactose. To reinvestigate this important conclusion, we constructed ompR malTc strains carrying either the malE+ gene, the nonpolar malE444 deletion, or the malE254 allele, which specifies an interaction-deficient maltose-binding protein. Lactose uptake was measured at different concentrations below the Km of this transport system and under conditions where transport was limited by the diffusion through maltoporin. We found no difference in the kinetics of lactose uptake irrespective of the malE allele. We conclude that the maltose-binding protein does not modulate the activity of maltoporin as a general outer membrane porin.     

Sequence of the ebgA gene of Escherichia coli: comparison with the lacZ gene

We have sequenced the ebgA (evolved beta-galactosidase) gene of Escherichia coli K12. The sequence shows 50% nucleotide identity with the E. coli lacZ gene, demonstrating that the two genes are related by descent from a common ancestral gene. Comparison of the two sequences suggests that the ebgA gene has recently been under selection. A significant excess of identical, rather than synonymous, codons used to encode identical amino acids at the same positions in the aligned sequences implies that some form of selection is operating directly at the DNA level. This selection is independent of, and in addition to, selection based on codon usage or on function of the gene products.