lac repressor-operator interaction. Analysis of the X86 repressor mutant

In vitro measurements show that the X86 repressor, which has an increased affinity for the lac operator as compared to wild-type repressor, also has an increased affinity for non-operator sites on Escherichia coli DNA. The rate constant of association of repressor and operator is decreased by E. coli DNA fivefold more for X86 repressor than for wild-type repressor. Low inducer concentrations increase the rate of association of X86 repressor and operator in the presence of E. coli DNA. In a partial equilibrium situation where part of the X86 repressor is bound to the operator, and part to either non-operator sites on E. coli DNA or to an O^c operator, the formation of complexes between X86 repressor and wild-type operator is favored by low inducer concentrations. Repression of the lac enzymes increases drastically in the X86 mutant in the absence of DNA synthesis in vivo. A new explanation for the in vivo characteristics of the X86 mutant is suggested.     

Contribution of an aspartate residue,D114, in the active site of clostridial glutamate dehydrogenase to the enzyme’s unusual pH dependence

Glutamate dehydrogenase from Clostridium symbiosum displays unusual kinetic behaviour at high pH when compared with other members of this enzyme family. Structural and sequence comparisons with GDHs from other organisms have indicated that the Asp residue at position 114 in the clostridial enzyme may account for these differences. By replacing this residue by Asn, a mutant protein has been created with altered functional properties at high pH. This mutant protein can be efficiently overexpressed in Escherichia coli, and several criteria, including mobility in non-denaturing electrophoresis, circular dichroism (CD) spectra and initial crystallisation studies, suggest a folding and an assembly comparable to those of the wild-type protein. The D114N mutant enzyme shows a higher optimum pH for activity than the wild-type enzyme, and both CD data and activity measurements show that the distinctive time-dependent reversible conformational inactivation seen at high pH in the wild-type enzyme is abolished in the mutant.     

Dimerisation mutants of Lac repressor. II. A single amino acid substitution, D278L, changes the specificity of dimerisation

Assembly of the lactose repressor tetramer involves two subunit interfaces, the C-terminal heptad repeats, and the monomer-monomer interface. Dimerisation between two monomers of Lac repressor of Escherichia coli lacking the two C-terminal heptad repeats occurs through the interactions between three alpha-helices of each monomer, which form a highly hydrophobic interface. Residues possibly involved in specific dimer formation are known from X-ray studies and from the phenotypes of more than 4000 single amino acid substitutions. During the examination of numerous mutants within the dimerisation interface of Lac repressor, we found that substitution of one amino acid, D278 to leucine, is sufficient to change the specificity of dimerisation. Analysis of this single substitution indicates that D278L mutant Lac repressor represses like wild-type. However, it no longer forms heterodimers with wild-type Lac repressor.     

Specificities of three tight-binding Lac repressors.

Tight binding mutants of Lac repressor exhibit complex repression phenomena. In this work, in vivo Lac operator binding of three such mutants of E. coli Lac repressor (X86: ser 61-leu, l12: pro 3-tyr and the double mutant l12X86: pro 3-tyr, ser 61-leu) was analyzed. Repression of beta-galactosidase synthesis controlled by ideal lac operator and its 27 symmetric operator variants containing each possible base-pair at each single half-operator position in the presence of the tight-binding Lac repressor mutants was determined. The average increase of repression with all operator variants was about 3 fold with the X86 mutant. It was about 4 fold with the l12 mutant and about 2 fold with the double mutant l12X86 as compared to wildtype Lac repressor. The X86 mutant showed the same increase of affinity to all operator variants, whereas the l12 and l12X86 mutants exhibited lower repression with some variants than with most others. These results suggest that the X86 mutant has gained no additional specificity. In contrast the l12 mutant and the l12X86 mutant exhibit a relaxed specificity for certain base pairs in positions 1 and 3 of lac operator. This suggests that the extreme N-terminus of Lac repressor may interact with the inner base-pairs in the minor groove.     

Heterogeneity of the two tryptophanyl residues in the lac repressor of Escherichia coli.

The wild-type lac repressor of Escherichia coli is a tetrameric protein which contains two tryptophanyl residues per subunit at positions 190 and 209. Solute perturbation studies of the tryptophan fluorescence of the repressor were performed using a polar but uncharged quencher, acrylamide, to prevent possible bias caused by ionic quenchers. The results indicate that the two tryptophan residues have different accessibilities to the quencher. In addition, contrary to a previous report, the accessibility of these tryptophan residues is not altered by isopropyl-β-d-thiogalactoside (IPTG) binding to the repressor. Similar studies with mutant lac repressor containing only a single tryptophan either at positions 190 or 209 suggest that tryptophan 209 is located in a region which is perturbed by inducer binding. That the two tryptophanyl residues have heterogeneous environments was further confirmed by nanosecond fluorescence spectroscopy which showed the wild-type lac repressor exhibiting two excited-state lifetimes, τ₁ = 5.3 ns and τ₂ = 10 ns. In the presence of 10^?3m IPTG, only a single lifetime of 6 ns was observed for the wild-type repressor suggesting that the inducer perturbs the tryptophan residue with the longer lifetime but not the one with the shorter lifetime. This is in accord with the observation that the mutant repressor containing only tryptophan 190 (the Tyr-209 repressor) has a single lifetime of 4.5 ns which is not altered by IPTG binding. The surprising finding that the mutant repressor which contains only tryptophan 209 (the Tyr-190 repressor) shows two excited-state lifetimes has been interpreted to indicate that the repressor either does not exhibit fourfold symmetry in its subunit arrangement or is present in two different conformational states.     

Specificity and Affinity of Lac Repressor for the Auxiliary Operators O2 and O3 Are Explained by the Structures of Their Protein-DNA Complexes

The structures of a dimeric mutant of the Lac repressor DNA-binding domain complexed with the auxiliary operators O2 and O3 have been determined using NMR spectroscopy and compared to the structures of the previously determined Lac-O1 and Lac-nonoperator complexes. Structural analysis of the Lac-O1 and Lac-O2 complexes shows highly similar structures with very similar numbers of specific and nonspecific contacts, in agreement with similar affinities for these two operators. The left monomer of the Lac repressor in the Lac-O3 complex retains most of these specific contacts. However, in the right half-site of the O3 operator, there is a significant loss of protein-DNA contacts, explaining the low affinity of the Lac repressor for the O3 operator. The binding mode in the right half-site resembles that of the nonspecific complex. In contrast to the Lac-nonoperator DNA complex where no hinge helices are formed, the stability of the hinge helices in the weak Lac-O3 complex is the same as in the Lac-O1 and Lac-O2 complexes, as judged from the results of hydrogen/deuterium experiments.     

Glycosylation of Phenolic Compounds by the Site-Mutated β-Galactosidase from Lactobacillus bulgaricus L3

β-Galactosidases can transfer the galactosyl from lactose or galactoside donors to various acceptors and thus are especially useful for the synthesis of important glycosides. However, these enzymes have limitations in the glycosylation of phenolic compounds that have many physiological functions. In this work, the β-galactosidase from Lactobacillus bulgaricus L3 was subjected to site-saturation mutagenesis at the W980 residue. The recombinant pET-21b plasmid carrying the enzyme gene was used as the template for mutation. The mutant plasmids were transformed into Escherichia coli cells for screening. One recombinant mutant, W980F, exhibited increased yield of glycoside when using hydroquinone as the screening acceptor. The enzyme was purified and the effects of the mutation on enzyme properties were determined in detail. It showed improved transglycosylation activity on novel phenolic acceptors besides hydroquinone. The yields of the glycosides produced from phenol, hydroquinone, and catechol were increased by 7.6% to 53.1%. Moreover, it generated 32.3% glycosides from the pyrogallol that could not be glycosylated by the wild-type enzyme. Chemical structures of these glycoside products were further determined by MS and NMR analysis. Thus, a series of novel phenolic galactosides were achieved by β-galactosidase for the first time. This was a breakthrough in the enzymatic galactosylation of the challenging phenolic compounds of great values.     

Derepression of Uridine Diphosphate-Glucose Pyrophosphorylase (galU) in capR(lon), capS, and capT Mutants and Studies on the galU Repressor

Mutation of the capR(lon), capS, or capT genes in Escherichia coli K-12 causes overproduction of capsular polysaccharide leading to a mucoid phenotype. Several of the enzymes involved in capsular polysaccharide synthesis are derepressed in cap mutants. Previously it was shown that uridine diphosphate-glucose (UDPG) pyrophosphorylase, an enzyme involved in the synthesis of three of the nucleotide sugar precursors of the capsule, is derepressed in capR mutants. The control of galU, the gene which codes for UDPG pyrophosphorylase, is described in this study. In addition, it has been found that the enzyme is also derepressed in capS and capT mutants. The effect of galU gene dosage in cap mutants and the wild-type strain (all lysogenic for 80) was studied by infecting them with the purified transducing phage 80dgalU. The level of UDPG pyrophosphorylase increased in proportion to the number of galU copies added. The rate of enzyme synthesis in the mutants was about sixfold higher than in the wild type per galU gene added for multiplicities of infection from one to twenty. Thus, all the galU copies added to the wild-type lysogen were repressed. We obtain greater than 20 galU copies per cell by infecting the nonlysogenic strain which allows multiplication of 80dgalU. With some number of galU copies greater than 20, the rate of UDPG pyrophosphorylase synthesis in the wild type approaches the mutant rate of synthesis. The results suggest that there may indeed be a galU repressor pool in the cell which can be completely titrated. This pool must be composed of more than 20 galU repressor molecules. Since the capR, capS, and capT gene products or combinations thereof are known to control other widely separated operons of the cell besides the galU gene, it is postulated that the galU repressor may be capable of binding other operators. This would account for the relatively large pool of galU repressors per cell.     

Direct identification of the amino acid changes in two mutant lac repressors.

Deletions extending into the trp operon at one terminus and the lacI control region at the other terminus have been examined. One of these, B116, ends within the trp leader sequence and eliminates the trp attenuator site, placing the synthesis of lac repressor under trp control. We have isolated and characterized the B116 repressor. The protein sequence of the aminoterminus of B116 shows that an additional 16 residues are added to the amino-terminal end of wild-type repressor. Moreover, a valine residue appears in place of methionine at position 17 (the original amino-terminal residue of the wild-type repressor). A comparison of the messenger RNA sequence of the trp leader region and of the I leader region demonstrates that the translation of the B116 repressor is initiated at an AUG codon within the trp leader sequence. The GUG initiation codon at the start point for translation of wild-type repressor is now read as valine, since it appears at an internal position (residue 17 of the altered repressor). The B116 repressor accumulates at levels as high as 1% of the soluble cell protein in trpR^? strains. The efficiency of the trp leader initiation codon in translation suggests that in wild-type strains this AUG is also active in directing protein synthesis, which would result in a polypeptide consisting of 14 amino acids. We have examined the physical properties of the B116 repressor, which shows a marked tendency to form higher aggregates. Other characteristics of B116 are also described.     

Mechanism of promoter repression by Lac repressor–DNA loops

The Escherichia coli lactose (lac) operon encodes the first genetic switch to be discovered, and lac remains a paradigm for studying negative and positive control of gene expression. Negative control is believed to involve competition of RNA polymerase and Lac repressor for overlapping binding sites. Contributions to the local Lac repressor concentration come from free repressor and repressor delivered to the operator from remote auxiliary operators by DNA looping. Long-standing questions persist concerning the actual role of DNA looping in the mechanism of promoter repression. Here, we use experiments in living bacteria to resolve four of these questions. We show that the distance dependence of repression enhancement is comparable for upstream and downstream auxiliary operators, confirming the hypothesis that repressor concentration increase is the principal mechanism of repression loops. We find that as few as four turns of DNA can be constrained in a stable loop by Lac repressor. We show that RNA polymerase is not trapped at repressed promoters. Finally, we show that constraining a promoter in a tight DNA loop is sufficient for repression even when promoter and operator do not overlap.     

A frameshift mutation that elongates the penicillinase protein of Bacillus licheniformis

A penicillinase mutant penP102, isolated after ICR (acridine mustard) mutagenesis of Bacillus licheniformis strain 749/C, retains about 50% of the wild-type penicillinase specific activity. The penicillinase produced by this mutant differs from the wild-type protein in its sensitivity to pH and its electrophoretic behaviour. The penP102 mutation appears to have several other phenotypic effects, including an increase in the efficiency of release of the extracellular form of the enzyme.The penP102 penicillinase has been purified and its amino acid sequence compared to that of the wild-type enzyme. The mutation has resulted in the replacement of the last three amino acids of the wild-type enzyme and the addition of 17 residues at the carboxy-terminus. Comparison of the wild-type and mutant amino acid sequences shows that the mutational event is a single nucleotide deletion from the codon for asparagine²⁶⁵. Consideration of the possible nucleotide sequence for the region beyond the carboxy-terminus of the wild-type protein shows that there are no possible termination codons until four and six triplets beyond the codon for the carboxy-terminal lysine, indicating that the carboxy-terminus of the wild-type extracellular penicillinase is generated by proteolytic cleavage of a larger precursor protein.     

Involvement of UDP-glucose pyrophosphorylase from Verticillium dahliae in cell morphogenesis,stress responses,and host infection

UDP-glucose pyrophosphorylase (UGP, EC 2.7.7.9) is an essential enzyme involved in carbohydrate metabolism. In Saccharomyces cerevisiae and other fungi, the UGP gene is indispensable for normal cell development, polysaccharide synthesis, and stress response. However, the function of the UGP homolog in plant pathogenic fungi has been rarely explored during pathogenesis. In this study, we characterize a UGP homolog named VdUGP from Verticillium dahliae, a soil-borne fungus that causes plant vascular wilt. In comparison with wild-type strain V07DF2 and complementation strains, the VdUGP knocked down mutant 24C9 exhibited sensitivity to sodium dodecyl sulfate (perturbing membrane integrity) and high sodium chloride concentration (high osmotic pressure stress). More than 25 % of the conidia of the mutant developed into short and swollen hypha and formed hyperbranching and compact colonies. The mutant exhibited decreased virulence on cotton and tobacco seedlings. Further investigation determined that the germination of the mutant spores was significantly delayed compared with the wild-type strain on the host roots. RNA-seq analysis revealed that a considerable number of genes encoding secreted proteins and carbohydrate-active enzymes were significantly downregulated in the mutant at an early stage of infection compared with those of the wild-type strain. RNA-seq data indicated that mutation affected many Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways both in the pathogen and in the inoculated plants at the infection stage. These alterations of the mutant in cultural phenotypes, virulence, and gene expression profiles clearly indicated that VdUGP played important roles in fungal cell morphogenesis, stress responses, and host infection.     

Functional Importance of Arginine 64 in Chlamydomonas reinhardtii Phosphoribulokinase

Phosphoribulokinase (EC 2.7.1.19) was investigated in wild-type Chlamydomonas reinhardtii and in mutant strains deficient in this enzyme activity. Immunoblot analysis revealed substantial amounts of phosphoribulokinase in mutant 12-2B but none in mutant F-60. The pH optimum of the wild-type enzyme was 8.0 and that of the 12-2B enzyme was 6.5. The mutant kinase possessed a K_m value for ribulose 5-phosphate of about 45 millimolar, nearly three orders of magnitude greater than the wild-type value of 56 micromolar. K_m values for ATP in the range of 36 to 72 micromolar were observed with both wild-type and mutant enzymes. The V_max of the wild-type enzyme was about 450 micromoles per minute per milligram of protein, and values for the mutant enzyme were 140 micromoles per minute per milligram at pH 6.5 and 36 micromoles per minute per milligram at pH 7.8. Thermal stabilities of the wild-type and mutant kinases were similar. Sequence analysis of the 12-2B phosphoribulokinase gene revealed a C to T transition that caused an arginine to cysteine change at position 64 of the enzyme. This arginine residue is conserved in phosphoribulokinases from vascular plants, algae, and photosynthetic bacteria and appears to function in binding ribulose 5-phosphate.     

Photoreactivating enzyme from Euglena and the control of its intracellular level

Photoreactivating (PR) enzyme activity has already been demonstrated by us in cell-free extracts of Euglena gracilis var. bacillaris Pringsheim using the Hemophilus transformation assay. This activity can also be detected in extracts using a direct non-biological assay for the photorepair of thymine dimers in DNA. PR enzyme is found in extracts of both wild-type cells and cells of an aplastidic mutant, W₃BUL, lacking detectable chloroplast DNA, indicating that the PR enzyme is neither coded nor translated exclusively in the chloroplast, but is probably coded in the nucleus and translated in the cytoplasm. Growing cultures of wild-type cells manifest a large increase in PR enzyme activity in vitro upon entering stationary phase. This correlates with the increased photoreactivability of chloroplast inheritance in vivo in stationary phase cells, previously found for Euglena, and suggests that a substantial part of the newly synthesized PR enzyme is available to repair plastid DNA. When dark-grown nondividing wild-type cells are exposed to light, there is a large increase in the specific activity of PR enzyme measured in vitro. This increase is prevented by cycloheximide but not by chloramphenicol or streptomycin, indicating that the enzyme is synthesized on 87s cytoplasmic ribosomes rather than 68s chloroplast ribosomes. Wavelengths of light effective for PR of chloroplast DNA in vivo are also effective for the light induction of PR enzyme. A brief illumination (45 min) of dark-grown nondividing wild-type cells triggers the synthesis of PR enzyme which continues in the absence of light. Growing cultures of W₃BUL also exhibit a preferential synthesis of PR enzyme in the staionary phase of growth, but the specific activity in vitro is consistently ten times higher than that of wild-type. Dark-grown non-dividing cultures of W₃BUL also show a cycloheximide-sensitive light induction of PR enzyme synthesis which, however, is dependent on the continued presence of light. The light induction of PR enzyme synthesis can be regarded as the induction of an enzyme by one of its substrates.     

Characterization of mutations in the penicillinase operon of Staphylococcus aureus

Summary Mutant penicillinase plasmids, in which penicillinase synthesis is not inducible by penicillin or a penicillin analogue, were examined by biochemical and genetic analyses. In five of the six mutants tested, penicillinase synthesis could be induced by growth in the presence of 5-methyltryptophan. It is known that the tryptophan analogue 5-methyltryptophan is readily incorporated into protein by S. aureus and that staphylococcal penicillinase lacks tryptophan. 5-methyltryptophan seems to induce penicillinase synthesis in wild-type plasmids by becoming incorporated into the repressor and thereby inactivating the operator binding function of the penicillinase repressor. Therefore, induction of penicillinase synthesis in the mutant plasmids by 5-methyltryptophan strongly suggests that the noninducible phenotype of these five plasmids is due to a mutation that inactivates the effector binding site of the penicillinase repressor (i.e., the five mutant plasmids carry an i^s genotype for the penicillinase repressor). This conclusion was supported by heterodiploid analysis. The mutant plasmid that did not respond to 5-methyltryptophan either produces an exceedingly low basal level of penicillinase or does not produce active enzyme. This plasmid seems to carry a mutation in the penicillinase structural gene or in the promoter for the structural gene. Thus, a genetic characterization of many mutations in the penicillinase operon can be accomplished easily and rapidly by biochemical analysis.Journal Paper No. J-7994 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa. Project No. 2029     

The rb Mutation of Peas Causes Structural and Regulatory Changes in ADP Glucose Pyrophosphorylase from Developing Embryos

A mutation at the rb locus of pea (Pisum sativum L.) alters the shape, reduces the starch content, and increases the lipid and sucrose contents of the seed. These effects are probably all consequences of a reduction of up to 40-fold in the maximum catalytic activity of ADP glucose pyrophosphorylase in the developing embryo of the mutant relative to the wild type. We have investigated how the mutation brings about this reduction in activity. The purified enzyme from mutant embryos has a specific activity about 10-fold lower than that from wild-type embryos, and it is much more sensitive to the effectors inorganic phosphate and 3-phosphoglycerate than the wild-type enzyme. Both wild-type and mutant enzymes consist of polypeptides of around 50 kilodaltons. One of the polypeptides of the purified wild-type enzyme is missing from the mutant enzyme. We deduce that in the wild-type embryo this protein may interact with other subunits to confer a high specific activity and a low susceptibility to effectors on the enzyme.     

Phantom,a cytochrome P450 enzyme essential for ecdysone biosynthesis,plays a critical role in the control of border cell migration in Drosophila

The border cells of Drosophila are a model system for coordinated cell migration. Ecdysone signaling has been shown to act as the timing signal to initiate the migration process. Here we find that mutations in phantom (phm), encoding an enzyme in the ecdysone biosynthesis pathway, block border cell migration when the entire follicular epithelium of an egg chamber is mutant, even when the associated germline cells (nurse cells and oocyte) are wild-type. Conversely, mutant germline cells survive and do not affect border cell migration, as long as the surrounding follicle cells are wild-type. Interestingly, even small patches of wild-type follicle cells in a mosaic epithelium are sufficient to allow the production of above-threshold levels of ecdysone to promote border cell migration. The same phenotype is observed with mutations in shade (shd), encoding the last enzyme in the pathway that converts ecdysone to the active 20-hydroxyecdysone. Administration of high 20-hydroxyecdysone titers in the medium can also rescue the border cell migration phenotype in cultured egg chambers with an entirely phm mutant follicular epithelium. These results indicate that in normal oogenesis, the follicle cell epithelium of each individual egg chamber must supply sufficient ecdysone precursors, leading ultimately to high enough levels of mature 20-hydroxyecdysone to the border cells to initiate their migration. Neither the germline, nor the neighboring egg chambers, nor the surrounding hemolymph appear to provide threshold amounts of 20-hydroxyecdysone to do so. This “egg chamber autonomous” ecdysone synthesis constitutes a useful way to regulate the individual maturation of the asynchronous egg chambers present in the Drosophila ovary.     

DNA-binding properties of a lac repressor mutant incapable of forming tetramers

The interaction of proteins bound to sites widely separated on the genome is a recurrent motif in both prokaryotic and eukaryotic regulatory systems. Lac repressor mediates the formation of "DNA loops" by the simultaneous interaction of a single protein tetramer with two DNA-binding sites. The DNA-binding properties of a Lac repressor mutant (LacIadi) deficient in the association of protein dimers to tetramers was investigated. The results of quantitative footprint and gel mobility-shift titrations suggest that the wild-type Lac repressor (LacI+) binds cooperatively to two operator sites separated by 11 helical turns on a linear DNA restriction fragment by the formation of a "looped complex." LacIadi binds to this two-site operator non-cooperatively and without formation of a looped complex. These results demonstrate that the dimer-tetramer association of LacI+ is directly responsible for its cooperative binding and its ability to mediate formation of a looped complex. The Iadi mutation disrupts the monomer-dimer as well as eliminating the dimer-tetramer association equilibria while the DNA binding affinity of LacIadi to a single site is unchanged relative to the wild-type protein. These results suggest that DNA binding and dimer-tetramer association are functionally unlinked. The similarity of the DNA-binding properties of LacIadi and Gal repressor, a protein believed to function by mediating the formation of a looped complex, are discussed.     

Deoxyribonucleic Acid Polymerase Activity in a Deoxyribonucleic Acid Polymerase I-Deficient Mutant of Bacillus subtilis Infected with Temperate Bacteriophage SPO2

Increased deoxyribonucleic acid (DNA) polymerase activity is found in soluble extracts from a polymerase I-negative mutant of Bacillus subtilis after infection with temperate phage SPO2, or after induction of SPO2 prophage in lysogenic derivatives of this mutant. No increased enzyme activity is found after SPO2 infection in the presence of chloramphenicol. Infection of the polymerase-negative mutant with the DNA-negative sus mutant SPO2 L244 gives no increased enzyme activity, whereas infection with DNA-negative sus mutant SPO2 J385 gives enzyme activities comparable to those found in wild-type infected cells. These findings suggest that SPO2 determines a DNA polymerase activity essential for synthesis of phage DNA.