Purification, gene cloning, and gene disruption of the transcription elongation factor S-II in Saccharomyces cerevisiae.

Saccharomyces cerevisiae S-II was purified to near homogeneity as a protein stimulating RNA polymerase II. Four of seven lysyl endopeptidase-digested fragments of S-II were located in the PPR2 sequence reported previously. Analysis of a genomic clone of S-II revealed that S-II and PPR2 are the same protein consisting of 309 amino acid residues, and frame shifts were found in the sequence of PPR2 gene reported previously. Yeast S-II and mouse S-II showed high similarity in their amino acid sequences, especially in their amino-terminal and carboxyl-terminal regions. A gene disruption experiment showed that an S-II null mutant was not lethal under usual growth conditions, indicating that S-II is not essential for the growth of yeast.     

Involvement of surface cysteines in activity and multimer formation of thimet oligopeptidase

Thimet oligopeptidase is a metalloenzyme involved in regulating neuropeptide processing. Three cysteine residues (246, 248, 253) are known to be involved in thiol activation of the enzyme. In contrast to the wild-type enzyme, the triple mutant (C246S/C248S/C253S) displays increased activity in the absence of dithiothreitol. Dimers, purportedly formed through cysteines 246, 248 and 253, have been thought to be inactive. However, analysis of the triple mutant by native gel electrophoresis reveals the existence of dimers and multimers, implying that oligomer formation is mediated by other cysteines, probably on the surface, and that some of these forms are enzymatically active. Isolation and characterization of iodoacetate-modified monomers and dimers of the triple mutant revealed that, indeed, certain dimeric forms of the enzyme are still fully active, whereas others show reduced activity. Cysteine residues potentially involved in dimerization were identified by modeling of thimet oliogopeptidase to its homolog, neurolysin. Five mutants were constructed; all contained the triple mutation C246S/C248S/C253S and additional substitutions. Substitutions at C46 or C682 and C687 prevented multimer formation and inhibited dimer formation. The C46S mutant had enzymatic activity comparable to the parent triple mutant, whereas that of C682S/C687S was reduced. Thus, the location of intermolecular disulfide bonds, rather than their existence per se, is relevant to activity. Dimerization close to the N-terminus is detrimental to activity, whereas dimerization near the C-terminus has little effect. Altering disulfide bond formation is a potential regulatory factor in the cell owing to the varying oxidation states in subcellular compartments and the different compartmental locations and functions of the enzyme.     

Evidence for a proton transfer network and a required persulfide-bond-forming cysteine residue in Ni-containing carbon monoxide dehydrogenases

Carbon monoxide dehydrogenase from Moorella thermoacetica catalyzes the reversible oxidation of CO to CO(2) at a nickel-iron-sulfur active site called the C-cluster. Mutants of a proposed proton transfer pathway and of a cysteine residue recently found to form a persulfide bond with the C-cluster were characterized. Four semiconserved histidine residues were individually mutated to alanine. His116 and His122 were essential to catalysis, while His113 and His119 attenuated catalysis but were not essential. Significant activity was "rescued" by a double mutant where His116 was replaced by Ala and His was also introduced at position 115. The activity was also rescued in double mutants where His122 was replaced by Ala and His was simultaneously introduced at either position 121 or position 123. Activity was also rescued by replacing His with Cys at position 116. Mutation of conserved Lys587 near the C-cluster attenuated activity but did not eliminate it. Activity was virtually abolished in a double mutant where Lys587 and His113 were both changed to Ala. Mutations of conserved Asn284 also attenuated activity. These effects suggest the presence of a network of amino acid residues responsible for proton transfer rather than a single linear pathway. The Ser mutant of the persulfide-forming Cys316 was essentially inactive and displayed no electron paramagnetic resonance signals originating from the C-cluster. Electronic absorption and metal analysis suggest that the C-cluster is absent in this mutant. The persulfide bond appears to be essential for either the assembly or the stability of the C-cluster, and possibly for eliciting the redox chemistry of the C-cluster required for catalytic activity.     

A single amino acid substitution in rhodopsin (lysine 248----leucine) prevents activation of transducin

In structure-function studies on bovine rhodopsin by in vitro site-specific mutagenesis, we have prepared three mutants in the cytoplasmic loop between the putative transmembrane helices E and F. In each mutant, charged amino acid residues were replaced by neutral residues: mutant 1, Glu239----Gln; mutant 2, Lys248----Leu; and mutant 3, Glu247----Gln, Lys248----Leu, and Glu249----Gln. The mutant rhodopsin genes were expressed in monkey kidney (COS-1) cells. After the addition of 11-cis-retinal to the cells, the rhodopsin mutants were purified by immunoaffinity adsorption. Each mutant gave a wild-type rhodopsin visible absorption spectrum. The mutants were assayed for their ability to stimulate the GTPase activity of transducin in a light-dependent manner. While mutants 1 and 3 showed wild-type activity, mutant 2 (Lys248----Leu) was inactive.     

Lysine can replace arginine 67 in the mediation of covalent attachment of FAD to histidine 71 of 6-hydroxy-D-nicotine oxidase

The requirements for FAD-attachment to His71 of 6-hydroxy-D-nicotine oxidase (6-HDNO) were investigated by site-directed mutagenesis. The following amino acid replacements were introduced into the sequence Arg67-Ser68-Gly69-Gly70-His71 of the 6-HDNO-polypeptide: 1) Arg67 was replaced with Ala (A1 mutant); 2) Ser68 was replaced with Ala (A2 mutant); and 3) Arg67 was replaced with Lys (K mutant). The substitution in mutant A2 had no effect on flavinylation, measured as [14C]FAD incorporation into apo-6-HDNO. Replacement of Arg67 with Ala prevented, but replacement with Lys permitted the flavinylation of His71. Mutant A1 showed no 6-HDNO activity, whereas the replacement of Ser with Ala in mutant A2 had only a slight effect on 6-HDNO activity. The substitution of Lys for Arg67, however, reduced the specific 6-HDNO activity in extracts of Escherichia coli cells expressing the mutant polypeptide from 50.3 to 17.5 milliunits/mg protein. It is concluded that a basic amino acid residue (Arg67 or Lys67) is required to mediate the attachment of FAD to His71, and while Lys can substitute for Arg67 in this function, it can only partially replace Arg67 in the enzyme reaction mechanism of 6-HDNO.     

Mutation of a single MalK subunit severely impairs maltose transport activity in Escherichia coli.

The maltose transport system of Escherichia coli, a member of the ABC transport superfamily of proteins, consists of a periplasmic maltose binding protein and a membrane-associated translocation complex that contains two copies of the ATP-binding protein MalK. To examine the need for two nucleotide-binding domains in this transport complex, one of the two MalK subunits was inactivated by site-directed mutagenesis. Complexes with mutations in a single subunit were obtained by attaching a polyhistidine tag to the mutagenized version of MalK and by coexpressing both wild-type MalK and mutant (His)6MalK in the same cell. Hybrid complexes containing one mutant (His)6MalK subunit and one wild-type MalK subunit were separated from those containing two mutant (His)6MalK proteins based on differential affinities for a metal chelate column. Purified transport complexes were reconstituted into proteoliposome vesicles and assayed for maltose transport and ATPase activities. When a conserved lysine residue at position 42 that is involved in ATP binding was replaced with asparagine in both MalK subunits, maltose transport and ATPase activities were reduced to 1% of those of the wild type. When the mutation was present in only one of the two subunits, the complex had 6% of the wild-type activities. Replacement of a conserved histidine residue at position 192 in MalK with arginine generated similar results. It is clear from these results that two functional MalK proteins are required for transport activity and that the two nucleotide-binding domains do not function independently to catalyze transport.     

Purification and preparation of antibody to RNA polymerase II stimulatory factors from Ehrlich ascites tumor cells.

An improved method was developed for purification of the protein termed S-II that specifically stimulates RNA polymerase II of Ehrlich ascites tumor cells. The specific activity of the final preparation was 400 000 units/mg of protein, which is about 30-fold higher than that of the previous preparation [Sekimizu, K., et al. (1976) Biochemistry 15, 5064]. The final preparation gave a single band on both sodium dodecyl sulfate and nondenaturing gel electrophoresis, and the protein extracted from the band on nondenaturing gel had stimulatory activity. S-II is a basic protein with a molecular weight of 40 500. The fundamental characteristics of S-II determined with the previous preparation were confirmed with completely purified S-II. A specific antibody to S-II was prepared. This antibody inhibited only the stimulatory activity of S-II and did not affect the activity of RNA polymerase II itself. Thus, S-II is probably not a component of the multimeric proteins of RNA polymerase II.     

Metal-tetracycline/H+ antiporter of Escherichia coli encoded by a transposon Tn10. Histidine 257 plays an essential role in H+ translocation.

The transposon Tn10-encoded tetA gene product is a metal-tetracycline/proton antiporter (Yamaguchi, A., Udagawa, T., and Sawai, T. (1990) J. Biol. Chem. 265, 4809-4813). Its tetracycline transport activity was inhibited by a histidine-specific reagent, diethyl pyrocarbonate. Among five histidine residues in this antiporter, only His257 is located in the putative transmembrane helices. Thus, His257 was replaced by Glu or Asp. Inverted vesicles containing the Glu257 and Asp257 mutant proteins showed only 20 and 10% of the tetracycline uptake of wild-type vesicles, respectively. In contrast to wild-type vesicles, the mutant vesicles showed no tetracycline-dependent proton translocation, indicating that the mutant proteins had lost the tetracycline/H+ antiport activity. The significant 60Co2+ uptake without proton translocation by the mutant vesicles also confirmed that the mutant carriers act as uniporters of a metal-tetracycline complex. The metal-tetracycline uniport by the mutant proteins was not inhibited by diethyl pyrocarbonate, indicating that His257 is the only histidine residue essential for proton translocation. These mutant proteins conferred about half-level resistance to tetracycline, probably due to their catalyzing downhill efflux of a metal-tetracycline complex out of the cells.     

Replacement of the folC gene, encoding folylpolyglutamate synthetase-dihydrofolate synthetase in Escherichia coli, with genes mutagenized in vitro.

The folylpolyglutamate synthetase-dihydrofolate synthetase gene (folC) in Escherichia coli was deleted from the bacterial chromosome and replaced by a selectable Kmr marker. The deletion strain required a complementing gene expressing folylpolyglutamate synthetase encoded on a plasmid for viability, indicating that folC is an essential gene in E. coli. The complementing folC gene was cloned into the vector pPM103 (pSC101, temperature sensitive for replication), which segregated spontaneously at 42 degrees C in the absence of selection. This complementing plasmid was replaced in the folC deletion strain by compatible pUC plasmids containing folC genes with mutations generated in vitro, producing strains which express only mutant folylpolyglutamate synthetase. Mutant folC genes expressing insufficient enzyme activity could not complement the chromosomal deletion, resulting in retention of the pPM103 plasmid. Some mutant genes expressing low levels of enzyme activity replaced the complementing plasmid, but the strains produced were auxotrophic for products of folate-dependent pathways. The folylpolyglutamate synthetase gene from Lactobacillus casei, which may lack dihydrofolate synthetase activity, replaced the complementing plasmid, but the strain was auxotrophic for all folate end products.     

Probing suggested catalytic domains of glycosyltransferases by site-directed mutagenesis.

The plant enzyme arbutin synthase isolated from cell suspension cultures of Rauvolfia serpentina and heterologously expressed in Escherichia coli is a member of the NRD1beta family of glycosyltransferases. This enzyme was used to prove, by site-directed mutagenesis, suggested catalytic domains and reaction mechanisms proposed for enzyme-catalyzed glycosylation. Replacement of amino acids far from the NRD domain do not significantly affect arbutin synthase activity. Exchange of amino acids at the NRD site leads to a decrease of enzymatic activity, e.g. substitution of Glu368 by Asp. Glu368, which is a conserved amino acid in glycosyltransferases located at position 2 and is important for enzyme activity, does not serve as the nucleophile in the catalytic centre as proposed. When it is replaced by Ala, the resulting mutant enzyme E368A exhibits comparable activity as found for E368D in respect to vanillin. Enzyme activities of wild-type and E368A towards several substrates were not affected at the same level. His360 at position 1 of NRD1beta glycosyltransferases occupies a more crucial role as expected. When it is exchanged against other basic amino acids such as Lys or Arg the enzyme activity decreases approximately 1000-fold. Replacement of His360 by Glu leads to a mutant enzyme (H360E) with an approximately 4000-fold lower activity compared with the wild-type. This mutein still produces a beta-glucoside, not an alpha-glucoside and therefore indicates that generation of the typical E-E motif of NRD1alpha glycosyltransferases does not convert a NRD1beta enzyme into a NRD1alpha enzyme. The presented data do not support several suggestions made in the literature about catalytic amino acids involved in the glycosyltransfer reaction.     

The role of histidine residues conserved in the putative ATP-binding region of macrolide 2'-phosphotransferase II

Macrolide 2'-phosphotransferase (MPH(2')) catalyzes the transfer of the gamma-phosphate of ATP to the 2'-hydroxyl group of macrolide antibiotics. In this study, H198 and H205, conserved in the ATP-binding region motif 1 in the putative amino acid sequence of MPH(2')II, were replaced by Ala to investigate their role. H205 was also subsequently replaced by Asn. H198A and H205N mutant enzymes retained more than 50% of the specific activity of the original enzyme to substrate oleandomycin. On the other hand, the specific activity of the H205A mutant enzyme was reduced to less than 1% of that of the wild enzyme. The results suggested that H205 is crucial for maintaining the catalytic activity of MPH(2')II, and Asn can substitute for His at this position.     

Histidine-aromatic interactions in barnase. Elevation of histidine pKa and contribution to protein stability.

Aromatic side-chains are found in the vicinity of histidine residues in many proteins and protein complexes. We have studied the interaction between a histidine residue (His18) and aromatic residues at position 94 in barnase. Three different techniques have been applied to show that Trp94 interacts more strongly with the protonated form of His18. The aromatic-histidine interaction stabilizes the protonated form of histidine by 0.8 to 1 kcal mol-1 relative to the unprotonated and, thereby, increases its pKa value. This was shown indirectly from the pH dependence of the stability of the wild-type protein and the mutant Trp94----Leu; and directly from the difference in pKa of His18 between wild-type barnase and the same mutant protein, and from double-mutant cycles that measure the total interaction energy of Trp94 with His18 at both low and high pH. When Trp94 is replaced by other aromatic amino acids, the strength of the interaction decreases in the series His-Trp greater than His-Tyr greater than His-Phe. The interaction is not masked by high salt concentrations. The raising of the pKa value of His18 by interaction with Trp94 is shown to be consistent with solution studies with model compounds. The histidine-aromatic interaction could have implications in binding and catalysis for modulation of the histidine pKa value.     

Chemical rescue of a site-specific mutant of bacterial copper amine oxidase for generation of the topa quinone cofactor

The topa quinone (TPQ) cofactor of copper amine oxidase is produced by posttranslational modification of a specific tyrosine residue through the copper-dependent, self-catalytic process. We have site-specifically mutated three histidine residues (His431, His433, and His592) involved in binding of the copper ion in the recombinant phenylethylamine oxidase from Arthrobacter globiformis. The mutant enzymes, in which each histidine was replaced by alanine, were purified in the Cu/TPQ-free precursor form and analyzed for their Cu-binding and TPQ-generating activities by UV-visible absorption, resonance Raman, and electron paramagnetic resonance spectroscopies. Among the three histidine-to-alanine mutants, only H592A was found to show a weak activity to form TPQ upon aerobic incubation with Cu(2+) ions. Also for H592A, exogenous imidazole rescued binding of copper and markedly promoted the TPQ formation. Accommodation of a free imidazole molecule within the cavity created in the active site of H592A was suggested by X-ray crystallography. Although the TPQ cofactor in H592A mutant was readily reduced with substrate, its catalytic activity was very low even in the presence of imidazole. Combined with the crystal structures of the mutant enzymes, these results demonstrate the importance of the three copper-binding histidine residues for both TPQ biogenesis and catalytic activity, fine-tuning the position of the essential metal.     

Structure-function studies of the non-heme iron active site of isopenicillin N synthase: some implications for catalysis

Isopenicillin N synthase (IPNS) is a non-heme ferrous iron-dependent oxygenase that catalyzes the ring closure of delta-(L-alpha-aminoadipoyl)-L-cysteinyl-D-valine (ACV) to form isopenicillin N. Spectroscopic studies and the crystal structure of IPNS show that the iron atom in the active species is coordinated to two histidine and one aspartic acid residues, and to ACV, dioxygen and H2O. We previously showed by site-directed mutagenesis that residues His212, Asp214 and His268 in the IPNS of Streptomyces jumonjinensis are essential for activity and correspond to the iron ligands identified by crystallography. To evaluate the importance of the nature of the protein ligands for activity, His214 and His268 were exchanged with asparagine, aspartic acid and glutamine, and Asp214 replaced with glutamic acid, histidine and cysteine, each of which has the potential to bind iron. Only the Asp214Glu mutant retained activity, approximately 1% that of the wild type. To determine the importance of the spatial arrangement of the protein ligands for activity, His212 and His268 were separately exchanged with Asp214; both mutant enzymes were completely defective. These findings establish that IPNS activity depends critically on the presence of two histidine and one carboxylate ligands in a unique spatial arrangement within the active site. Molecular modeling studies of the active site employing the S. jumonjinensis IPNS crystal structure support this view. Measurements of iron binding by the wild type and the Asp214Glu, Asp214His and Asp214Cys-modified proteins suggest that Asp214 may have a role in catalysis as well as in iron coordination.     

Site-directed mutagenesis of the hole-forming toxin aerolysin: studies on the roles of histidines in receptor binding and oligomerization of the monomer

The six histidines of the channel-forming protein aerolysin have been replaced one at a time with asparagine by site-directed mutagenesis, and each of the modified proteins has been purified. Three proteins had the same hemolytic activity as native toxin, but the others, those changed at His107, His132, or His332, were less able to disrupt both human and rat erythrocytes. The largest reduction in activity, more than 100-fold, was observed with the His132 mutant protein. Studies with radioiodinated samples showed that it had approximately the same affinity as native aerolysin for the rat erythrocyte receptor. However, once bound to either rat or human erythrocytes, it was much less able to carry out the next essential step in hole formation, aggregation to form a stable oligomer. Aggregation was also reduced by replacing His107, but the contrast with native aerolysin and the effect on hemolytic activity were less pronounced. The protein modified at His332 behaved in a different way from those substituted at positions 107 and 132. Its affinity for the rat erythrocyte receptor was considerably lower than the affinity of the wild-type protein, but when bound it appeared to aggregate normally. The results suggest that His132 and perhaps His107 are involved in the aggregation of aerolysin whereas His332 may be at or near the receptor binding site.