Regulation of glutamine synthesis by glycine and serine in Neurospora crassa.

The biosynthetic activities of the polypeptide subunits alpha and beta of glutamine synthetase (GS) were inhibited in vitro by glycine and serine. These amino acids inhibited the growth of a mutant strain with partial GS activity when grown on glutamate as the nitrogen source and also blocked the synthesis of the glutamine in vivo, thus demonstrating the inhibitory effect on GS activity in vivo. Glycine and serine lowered the intracellular glutamine pool and regulated GS beta synthesis. A preferential induction of synthesis of the GS beta polypeptide was observed when either of these amino acids was present in the medium. On this basis, we obtained a glycine-sensitive mutant which showed a structural alteration of the GS beta polypeptide. The double regulatory effect of either glycine or serine on glutamine synthesis may be considered an example of the regulation of glutamine synthesis by alpha-amino nitrogen. It may be a mechanism that regulates the assimilation of ammonium into glutamate versus glutamine.     

Stereospecific assignments of glycine in proteins by stereospecific deuteration and 15N labeling

Summary A method is described for stereospecifically assigning the -protons of glycine residues in proteins. The approach involves the stereospecific deuteration and ¹⁵N labeling of glycine and subsequent selective incorporation of this residue into the protein. The stereospecific assignments of the glycine -protons are obtained from a comparison of a 3D ¹⁵N-resolved TOCSY spectrum of the uniformly ¹⁵N-labeled protein with a 2D/3D ¹⁵N-edited TOCSY spectrum of the protein, containing the stereospecifically deuterated and ¹⁵N-labeled glycine. The approach is demonstrated by stereospecifically assigning the glycine -protons of the FK506 binding protein when bound to the immunosuppressant ascomycin.     

A glycine to serine substitution identifies the CYP 3 locus as the structural gene of iso 2 cytochrome c in Saccharomyces cerevisiae.

The CYP 3 locus which was until lately considered as a regulatory gene for the synthesis of iso-2 cytochrome c in Saccharomyces cerevisiae has now been identified as the structural gene of iso-2 cytochrome c by the analysis of a mutant protein in which it was found that the invariant glycine at position 6 (horse cytochrome c nomenclature) is replaced by a serine residue. This replacement can be explained by a G-C to A-T transition, induced by the mutagenic agent ethyl methyl sulfonate used to obtain the mutant strain. Moreover a revertant was obtained in which the original mutation was conserved and the activity of the protein was apparently restored by an unidentified modification of residue 52, an invariant asparagine. In view of these results, the regulatory mutations previously obtained (1) are interpreted as “up promoter” mutations.     

Substitution of conserved glycine residue by alanine in natural and synthetic neuropeptide ligands causes partial agonism at the stomoxytachykinin receptor

A few naturally occurring insect tachykinin-related peptides, such as stomoxytachykinin (Stc-TK), contain an Ala-residue instead of the highly conserved Gly-residue that is present in most other members of this peptide family. Stc-TK is a potent, partial agonist of the stable fly (Stomoxys calcitrans) tachykinin receptor, STKR. By means of synthetic analogues, the Gly/Ala exchange, representing the addition of a single methyl group in the active core region of these peptides, was shown to be fully responsible for the generation of this partial agonism, which was also accompanied by an increase in agonistic potency. Surprisingly, this Ala-dependent reduction in maximal response levels was only observed for the agonist-induced cellular calcium rise. Stomoxytachykinin, Stc-TK, did not display partial agonism for the STKR-mediated cyclic AMP response. A possible explanation for this differential partial agonism is that the Gly-containing and Ala-replaced peptides recognize and stabilize active receptor conformations that differ in their functional coupling efficacies towards these response pathways. Drosotachykinins, Drm-TK, tachykinin-like peptides encoded in the fruit fly genome, were shown to be STKR-agonists. Interestingly, one of these peptides, which contains an Ala-residue instead of the conserved Gly-residue, also proved to be a potent, partial agonist for STKR.     

Characteristics of alanine: glyoxylate aminotransferase from Saccharomyces cerevisiae, a regulatory enzyme in the glyoxylate pathway of glycine and serine biosynthesis from tricarboxylic acid-cycle intermediates.

Alanine: glyoxylate aminotransferase (EC 2.6.1.44), which is involved in the glyoxylate pathway of glycine and serine biosynthesis from tricarboxylic acid-cycle intermediates in Saccharomyces cerevisiae, was highly purified and characterized. The enzyme had Mr about 80 000, with two identical subunits. It was highly specific for L-alanine and glyoxylate and contained pyridoxal 5'-phosphate as cofactor. The apparent Km values were 2.1 mM and 0.7 mM for L-alanine and glyoxylate respectively. The activity was low (10 nmol/min per mg of protein) with glucose as sole carbon source, but was remarkably high with ethanol or acetate as carbon source (930 and 430 nmol/min per mg respectively). The transamination of glyoxylate is mainly catalysed by this enzyme in ethanol-grown cells. When glucose-grown cells were incubated in medium containing ethanol as sole carbon source, the activity markedly increased, and the increase was completely blocked by cycloheximide, suggesting that the enzyme is synthesized de novo during the incubation period. Similarity in the amino acid composition was observed, but immunological cross-reactivity was not observed among alanine: glyoxylate aminotransferases from yeast and vertebrate liver.     

Mechanism of the stimulation of serine and alanine transport into isolated rat liver cells by bicarbonate ions.

1. Bicarbonate ions stimulate the transport of serine and alanine into isolated hepatocytes. 2. The effect of bicarbonate is to increase the Vmax. of the transport process without changing the apparent Km. 3. The intracellular pH was estimated from the distribution of the weak base methylamine and the weak acid 5,5'-dimethyloxazolidine-2,4-dione (DMO) across the plasma membrane. 4. The addition of bicarbonate to a cell suspension caused the internal pH to become more acid. 5. The initial rate of serine, alanine and glycine transport was a linear function of the initial difference in pH across the membrane. 6. It is concluded that bicarbonate activates the transport of these amino acids primarily by increasing the pH difference across the plasma membrane. 7. It is suggested that the uptake of serine together with Na+ ions occurs in exchange for H+ ions, which are translocated outwards on the same carrier system. Some preliminary evidence consistent with this model is presented.     

Structure and stability effects of the mutation of glycine 34 to serine in Rhodobacter capsulatus cytochrome c(2)

Gly 34 and the adjacent Pro 35 of Rhodobacter capsulatus cytochrome c(2) (or Gly 29 and Pro 30 in vertebrate cytochrome c) are highly conserved side chains among the class I c-type cytochromes. The mutation of Gly 34 to Ser in Rb. capsulatus cytochrome c(2) has been characterized in terms of physicochemical properties and NMR in both redox states. A comparison of the wild-type cytochrome c(2), the G34S mutation, and the P35A mutation is presented in the context of differences in chemical shifts, the differences in NOE patterns, and structural changes resulting from oxidation of the reduced cytochrome. G34S is substantially destabilized relative to wild-type (2.2 kcal/mol in the oxidized state) but similarly destabilized relative to P35A. Nevertheless, differences in terms of the impact of the mutations on specific structural regions are found when comparing G34S and P35A. Although available data indicates that the overall secondary structure of G34S and wild-type cytochrome c(2) are similar, a number of both perturbations of hydrogen bond networks and interactions with internal waters are found. Thus, the impact of the mutation at position 35 is propagated throughout the cytochrome but with alterations at defined sites within the molecule. Interestingly, we find that the substitution of serine at position 34 results in a perturbation of the heme beta meso and the methyl-5 protons. This suggests that the hydroxyl and beta carbon are positioned away from the solvent and toward the heme. This has the consequence of preferentially stabilizing the oxidized state in G34S, thus, altering hydrogen bond networks which involve the heme propionate, internal waters, and key amino acid side chains. The results presented provide important new insights into the stability and solution structure of the cytochrome c(2).     

Substitutions for glycine alpha 1-637 and glycine alpha 2-694 of type I procollagen in lethal osteogenesis imperfecta. The conformational strain on the triple helix introduced by a glycine substitution can be transmitted along the helix

Two substitutions for glycine in the triple-helical domain were found in type I procollagen synthesized by skin fibroblasts from two probands with lethal osteogenesis imperfecta. One was a substitution of valine for glycine alpha 1-637, and the other was a substitution of arginine for glycine alpha 2-694. The effects of the mutations on the zipper-like folding of the collagen triple helix were similar, since there was post-translational overmodification of the collagenase A fragments (amino acids 1-775) but not of more COOH-terminal fragments of the protein. The mutations differed markedly, however, on their effects on thermal unfolding of the triple helix. The collagenase A fragment from the collagen containing the arginine alpha 2-694 substitution was cleaved at about amino acid 700 when incubated with trypsin at 30-35 degrees C. Therefore, there was micro-unfolding of the triple helix at a site close to the glycine substitution. Surprisingly, however, the collagenase A fragment with the valine alpha 1-637 substitution was also cleaved at about amino acid 700 under the same conditions. The results, therefore, demonstrated that although most glycine substitutions delay folding of the triple helix in regions that are NH2-terminal to the site of the substitution, the effects on unfolding can be transmitted to regions that are COOH-terminal to the site of the glycine substitution.     

Base dynamics in a UUCG tetraloop RNA hairpin characterized by 15N spin relaxation: correlations with structure and stability.

Intramolecular dynamics of guanine and uracil bases in a 14-nt RNA hairpin including the extraordinarily stable UUCG tetraloop were studied by 15N spin relaxation experiments that are sensitive to structural fluctuations occurring on a time scale of picoseconds to nanoseconds. The relaxation data were interpreted in the framework of the anisotropic model-free formalism, using assumed values for the chemical shift anisotropies of the 15N spins. The rotational diffusion tensor was determined to be symmetric with an axial ratio of 1.34 +/- 0.12, in agreement with estimates based on the ratio of the principal moments of the inertia tensor. The model-free results indicate that the bases of the G x U pair in the tetraloop are at least as rigid as the interior base pairs in the stem, whereas the 5'-terminal guanine is more flexible. The observed range of order parameters corresponds to base fluctuations of 19-22 degrees about the chi torsion angle. The results reveal dynamical consequences of the unusual structural features in the UUCG tetraloop and offer insights into the configurational entropy of hairpin formation.     

Origin of the mutual activation of the alpha and beta 2 subunits in the alpha 2 beta 2 complex of tryptophan synthase. Effect of alanine or glycine substitutions at proline residues in the alpha subunit.

To understand how the alpha and beta 2 subunits of tryptophan synthase from Escherichia coli interact to form an alpha 2 beta 2 complex and undergo mutual activation, we have investigated alpha subunits with single amino acid replacements at conserved proline residues. Although the activities of alpha 2 beta 2 complexes that contain wild type alpha subunit or alpha subunits substituted at positions 28, 62, 96, and 207 are similar, the activities of alpha 2 beta 2 complexes that contain alpha subunits substituted at positions 57 and 132 are remarkably altered. Whereas the latter enzymes have greatly reduced activities in the individual half-reactions, they have considerably higher activities in the overall reaction. These remarkable activity results are explained by a decrease in the affinity of these mutant alpha subunits for the beta 2 subunit and by an increase in the affinity in the combined presence of ligands of both the alpha subunit and the beta 2 subunit. Isothermal calorimetric titrations of wild type beta 2 subunit with wild type alpha subunit and a mutant alpha subunit containing a substitution of glycine for proline at position 132 show that both the affinity and the exothermic association enthalpy are greatly reduced in the mutant alpha subunit although the stoichiometry of association is unchanged. The affinity of the mutant alpha subunit for the beta 2 subunits is greatly increased in the presence of an alpha subunit ligand, alpha-glycerol phosphate. We conclude that proline 132 plays a critical role in subunit interaction and in mutual subunit activation.     

Coiled coils at the edge of configurational heterogeneity. Structural analyses of parallel and antiparallel homotetrameric coiled coils reveal configurational sensitivity to a single solvent-exposed amino acid substitution

A detailed understanding of the mechanisms by which particular amino acid sequences can give rise to more than one folded structure, such as for proteins that undergo large conformational changes or misfolding, is a long-standing objective of protein chemistry. Here, we describe the crystal structures of a single coiled-coil peptide in distinct parallel and antiparallel tetrameric configurations and further describe the parallel or antiparallel crystal structures of several related peptide sequences; the antiparallel tetrameric assemblies represent the first crystal structures of GCN4-derived peptides exhibiting such a configuration. Intriguingly, substitution of a single solvent-exposed residue enabled the parallel coiled-coil tetramer GCN4-pLI to populate the antiparallel configuration, suggesting that the two configurations are close enough in energy for subtle sequence changes to have important structural consequences. We present a structural analysis of the small changes to the helix register and side-chain conformations that accommodate the two configurations and have supplemented these results using solution studies and a molecular dynamics energetic analysis using a replica exchange methodology. Considering the previous examples of structural nonspecificity in coiled-coil peptides, the findings reported here not only emphasize the predisposition of the coiled-coil motif to adopt multiple configurations but also call attention to the associated risk that observed crytstal structures may not represent the only (or even the major) species present in solution.     

Probing stability and dynamics of proteins by protease digestion. I: Comparison of protease susceptibility and thermal stability of cytochromes c

Protease susceptibility of homologous proteins in their native conformations was studied. This work aims to establish a broad and quantitative basis for the utilization of protease digestion to analyze the local stability of native proteins. Using high-performance liquid chromatography (HPLC) the time course of the proteolytic degradation of intact proteins was quantitatively traced. Rapid separation of peptide fragments with HPLC made possible the elucidation of sequential digestion originating from the cleavage at a very few sites which are locally unstable in the protein structure. Using four serine proteases, chymotrypsin, trypsin, elastase and subtilisin BPN', we found some common trends in proteolysis for a group of proteins of the cytochrome c family. By comparing of the proteolysis and thermal denaturation with ten homologous cytochromes c extracted from horse, beef, Candida krusei, Saccharomyces cerevisiae, chicken, tuna, pigeon, rabbit, dog and rat, protease susceptibility was related to locally unfolding states intrinsic to the native conformation.     

Prothrombin Salakta: substitution of glutamic acid-466 by alanine reduces the fibrinogen clotting activity and the esterase activity.

Structural studies on a hereditary abnormal prothrombin, prothrombin Salakta, have been performed to identify the difference responsible for its reduced fibrinogen clotting activity and its reduced esterase activity. Amino acid composition and sequence analyses of a peptide isolated from a lysylendopeptidase digest of the abnormal thrombin indicated that Glu-466 had been replaced by Ala. This amino acid substitution can result from a single nucleotide change in the codon for Glu-466 (GAG----GCG). The model building and the molecular dynamics simulation of thrombin Salakta suggest that the Glu-466----Ala substitution would change the proper conformation around the substrate binding site containing Trp-468, which is a unique surface loop on the thrombin molecule. This is the experimental and theoretical evidence supporting the role of the surface loop containing Trp-468 for the proper conformation of the substrate binding site.     

Fish meal replacement by plant protein substitution and guar gum addition in trout feed. Part II: Effects on faeces stability and rheology

In the explosively growing aquaculture industry, the challenge of sustainability includes a requirement to produce more fish than are consumed by stock. A promising avenue of research is the substitution of the fish meal in feeds with plant protein. However, there are inherent risks in the development of such feeds, and serious consideration should be given not only to nutritional content, but also to the mechanical quality of resulting faecal wastes. The present study uses a plate on plate rheometer running in different flow modes (creep, oscillation) to assess the rheological properties of wastes resulting from different diets.All faeces were shown to be thixotropic in nature, independent of diet composition. Details of dietary composition influence the consistency and the characteristic stresses at which faecal structure changes from a viscoelastic solid into a viscoelastic liquid. Furthermore, in linking active food components with mechanical properties of chyme faeces, rheological studies may be used to understand and counteract some problematic properties. Substituting 100% of fish meal with plant proteins leads to faeces that rapidly disintegrate into very fine solids which threaten the viability of aquacultural operations. Adding just 0.3% of the rapidly hydrating non-starch polysaccharide, guar gum (GG), significantly increased the viscosity and elastic modulus of the faeces. These mechanical improvements increase the size of the resulting particles and the effectiveness with which they can be removed, thereby leading to optimized water quality. GG addition was sufficiently effective to counter the stability and particle size effects of a 50% substitution of fish meal, but could not mitigate those of a 100% substitution, wherein dissolution effects of an unknown emulsifier are suspected.     

The effect of valine substitution for glycine in the dimer interface of citrate synthase from Thermoplasma acidophilum on stability and activity

To determine the role of hydrophobic interactions in the dimer interface of citrate synthase (CS) from Thermoplasma (Tp) acidophilum in thermostabilization, we have used site-directed mutagenesis to replace Gly 196 by Val on the helix L of the subunit interface. Recombinant wild-type and Gly 196 mutant TpCS enzymes were largely identical in terms of substrate specificities (K(m) for oxaloacetate and acetyl CoA). However, the mutation not only reduced catalytic activity (about 10-fold) (i.e., V(max), k(cat) and specific activity) of the TpCS, but also decreased its thermal and chemical stability. Archaeal citrate synthase is active as a dimer, since residues from both monomers participate in the active site. Our results suggest that Gly196 --> Val mutation interferes with dimerization, so that improper dimerization or dissociation of the dimer would have a profound affect on the activity as well as the conformational stability of TpCS.