Sites of methyl esterification and deamination on the aspartate receptor involved in chemotaxis

The receptors involved in bacterial chemotaxis are post-translationally modified by specific enzymes which catalyze the deamination of glutaminyl residues and the methyl esterification and demethylation of glutamyl residues. In this work we identify the sites of these covalent modifications on the aspartate receptor from Salmonella typhimurium. These were identified using the properties of the Staphylococcus aureus V8 protease which cleaves peptide bonds following glutamyl but not glutaminyl residues. We show here that bonds following methyl-esterified glutamyl residues are also resistant to the protease. A comparison of the fragments obtained after V8 protease cleavage of methyl-esterified (or deaminated) peptides with the fragments from the corresponding unmodified peptides immediately yields the sites of modification. Three of the four methyl-esterified glutamyl residues are located near the middle of the receptor amino acid sequence; one of these is synthesized as a glutaminyl residue and is deaminated by the esterase to form a glutamyl residue. The fourth site of methyl esterification is located near the carboxyl terminus. All four sites occupy analogous positions in a well-conserved arrangement of residues which may form a binding site for the esterase and the methyltransferase.     

Sites of methyl esterification on the aspartate receptor involved in bacterial chemotaxis

The methyl esterification of the aspartate receptor involved in chemotaxis has been studied in order to clarify the role of receptor modification. Receptors were methyl esterified in an in vitro system using S-adenosyl-L-[methyl-3H]methionine as a methyl donor. Methyl esterified receptors were digested with trypsin and radioactive tryptic peptides were purified using high performance liquid chromatography. Comparing the amino acid composition of the modified peptides with the DNA sequence of the receptor gene, two regions of the polypeptide chain which contain methyl esterified residues were identified. The regions are homologous and contain a strongly conserved 13 amino acid sequence. One region, containing up to three modified residues, is near the middle of the protein; the other, containing one modified residue, is near the carboxyl terminus.     

Crystal structure of Saccharomyces cerevisiae cytosolic aspartate aminotransferase.

The crystal structure of Saccharomyces cerevisiae cytoplasmic aspartate aminotransferase (EC 2.6.1.1) has been determined to 2.05 A resolution in the presence of the cofactor pyridoxal-5'-phosphate and the competitive inhibitor maleate. The structure was solved by the method of molecular replacement. The final value of the crystallographic R-factor after refinement was 23.1% with good geometry of the final model. The yeast cytoplasmic enzyme is a homodimer with two identical active sites containing residues from each subunit. It is found in the "closed" conformation with a bound maleate inhibitor in each active site. It shares the same three-dimensional fold and active site residues as the aspartate aminotransferases from Escherichia coli, chicken cytoplasm, and chicken mitochondria, although it shares less than 50% sequence identity with any of them. The availability of four similar enzyme structures from distant regions of the evolutionary tree provides a measure of tolerated changes that can arise during millions of years of evolution.     

The primary structure of the aspartate transcarbamylase region of the URA2 gene product in Saccharomyces cerevisiae. Features involved in activity and nuclear localization

The yeast URA2 locus encodes a multifunctional protein which possesses the carbamylphosphate synthetase and aspartate transcarbamylase activities and which catalyzes the first two reactions of the pyrimidine pathway. We report here the nucleotide sequence of the central and the 3' region of this locus. The latter encodes that part of the multifunctional protein which has the aspartate transcarbamylase activity. The deduced amino acid sequence shows a high degree of homology with the known aspartate transcarbamylases of various organisms from Escherichia coli to mammals. The amino acid residues that have been shown to be involved in the catalytic site of the E. coli enzyme are all conserved suggesting that, in the more complex structure of the yeast protein, the catalytic sites are also located at subunit interfaces. There is also an important conservation of the amino acid pairs that, in E. coli, are implicated in intra- and interchain interactions. As well as the oligomeric structure suggested by these two features, the three-dimensional structure of the yeast enzyme must also be organized to account for the channeling of carbamylphosphate, from the carbamylphosphate synthetase catalytic site to that of aspartate transcarbamylase, and for the concomitant feedback inhibition of the two activities by the end product UTP. The URA2 gene product was shown to be localized in the nucleus. With the aim of identifying the regions that may be involved in this transport, we have determined by electron microscopy the subcellular distribution of aspartate transcarbamylase in three strains expressing different fragments of the URA2 locus. In the first strain the protein lacks 190 residues at the N terminus, but accumulates normally in the nucleus. In the second strain the protein lacks 382 residues in the central part and seems impaired in the nuclear transport process. In the third strain the 476-residue protein encoded by the 3' region of URA2 locus and catalyzing the aspartate transcarbamylase reaction is able by itself to migrate to and accumulate in the nucleus. This suggests that two regions are involved in the nuclear accumulation. On the basis of their conservation in analogous proteins of other eukaryotes and their similarity to sequences already identified as nuclear location signals, a sequence in the central region of the protein and two short sequences in the C-terminal region are good candidates for the nuclear location signal involved in the targeting of the URA2 product.     

Ligand-specific activation of Escherichia coli chemoreceptor transmethylation

Adaptation in the chemosensory pathways of bacteria like Escherichia coli is mediated by the enzyme-catalyzed methylation (and demethylation) of glutamate residues in the signaling domains of methyl-accepting chemotaxis proteins (MCPs). MCPs can be methylated in trans, where the methyltransferase (CheR) molecule catalyzing methyl group transfer is tethered to the C terminus of a neighboring receptor. Here, it was shown that E. coli cells exhibited adaptation to attractant stimuli mediated through either engineered or naturally occurring MCPs that were unable to tether CheR as long as another MCP capable of tethering CheR was also present, e.g., either the full-length aspartate or serine receptor (Tar or Tsr). Methylation of isolated membrane samples in which engineered tethering and substrate receptors were coexpressed demonstrated that the truncated substrate receptors (trTsr) were efficiently methylated in the presence of tethering receptors (Tar with methylation sites blocked) relative to samples in which none of the MCPs had tethering sites. The effects of ligand binding on methylation were investigated, and an increase in rate was produced only with serine (the ligand specific for the substrate receptor trTsr); no significant change in rate was produced by aspartate (the ligand specific for the tethering receptor Tar). Although the overall efficiency of methylation was lower, receptor-specific effects were also observed in trTar- and trTsr-containing samples, where neither Tar nor Tsr possessed the CheR binding site at the C terminus. Altogether, the results are consistent with a ligand-induced conformational change that is limited to the methylated receptor dimer and does not spread to adjacent receptor dimers.     

Role of Escherichia coli IHF protein in lambda site-specific recombination. A mutational analysis of binding sites

The phage lambda attachment site, attP, contains three binding sites for an Escherichia coli protein, IHF, that is needed for efficient integrative recombination. We have used synthetic oligodeoxyribonucleotides to direct multiple base changes at each of these three sites. Alteration by two base-pairs of the consensus sequence for the leftmost binding site specifically interferes with IHF binding to that site and modestly depresses recombination in vitro. For each of the three binding sites, alteration of the consensus sequence by four base-pairs strongly depresses recombination in vitro, indicating that all three sites are important for attP function. The mutated attP sites are also depressed for recombination in vivo but some of the mutants are less affected than they are in vitro. The disparity between effects in vivo and in vitro for some mutants but not others suggests that the three binding sites are not functionally equivalent and that at some sites additional E. coli factors may replace or assist IHF. The non-equivalence of the three IHF sites is also indicated by the behavior of prophage attachment sites carrying mutations in the binding sites.     

Relation of VP7 amino acid sequence to monoclonal antibody neutralization of rotavirus and rotavirus monotype.

The neutralization epitopes of the VP7 of human rotavirus RV-4 were studied by using five neutralizing mouse monoclonal antibodies to select virus variants resistant to neutralization by each of the antibodies. Antibody resistance patterns and sequence analysis of the RV-4 variants revealed that at least four sites on VP7, located at amino acids 94 (region A), 147 to 148 (region B), 213 (region C), and 291, are involved in neutralization of the human G1 rotavirus RV-4. The A-region site elicited antibody cross-reactive between G types and showed species-restricted immunodominance not related to carbohydrate attachment. The monotype 1b rotavirus M37 lacked this site. The B region contained strain-specific and cross-reactive sites, absent in monotype 1c rotaviruses. The C-region site was present in all G1 rotaviruses tested. Monotype 1a rotaviruses contained all these sites of neutralization. Virus monotype and sensitivity to monoclonal antibody neutralization usually related to the presence of a particular amino acid(s) at or next to the positions at which the mutations were selected in the virus variants.     

Aspartate taxis mutants of the Escherichia coli tar chemoreceptor.

The Tar protein of Escherichia coli belongs to a family of methyl-accepting inner membrane proteins that mediate chemotactic responses to a variety of compounds. These transmembrane signalers monitor the chemical environment by means of specific ligand-binding sites arrayed on the periplasmic side of the membrane, and in turn control cytoplasmic signals that modulate the flagellar rotational machinery. The periplasmic receptor domain of Tar senses two quite different chemoeffectors, aspartate and maltose. Aspartate is detected through direct binding to Tar molecules, whereas maltose is detected indirectly when complexed with the periplasmic maltose-binding protein. Saturating levels of either aspartate or maltose do not block behavioral responses to the other compound, indicating that the detection sites for these two attractants are not identical. We initiated structure-function studies of these chemoreceptor sites by isolating tar mutants which eliminate aspartate or maltose taxis, while retaining the ability to respond to the other chemoeffector. Mutants with greatly reduced aspartate taxis are described and characterized in this report. When present in single copy in the chromosome, these tar mutations generally eliminated chemotactic responses to aspartate and structurally related compounds, such as glutamate and methionine. Residual responses to these compounds were shifted to higher concentrations, indicating a reduced affinity of the aspartate-binding site in the mutant receptors. Maltose responses in the mutants ranged from 10 to 80% of normal, but had no detectable threshold shifts, indicating that these receptor alterations may have little effect on maltose detection sensitivity. The mutational changes in 17 mutants were determined by DNA sequence analysis. Each mutant exhibited a single amino acid replacement at residue 64, 69, or 73 in the Tar molecule. The wild-type Tar transducer contains arginines at all three of these positions, implying that electrostatic forces may play an important role in aspartate detection.     

Characterization of products derived from self-splicing of intron aI5 alpha which is located in the mitochondrial COX I gene of Saccharomyces cerevisiae.

We have characterized the in vitro self-splicing of intron aI5 alpha containing precursor RNA from the yeast mitochondrial gene coding for cytochrome oxidase subunit I. This intron follows the rules for group I self-splicing introns and all the characteristic products have been identified. In addition we have detected abnormal RNA products with features that indicate that the self-splicing behaviour of this intron is more complex. Two intron circles are formed by use of a major and minor intron-internal site for circle closure. A cryptic 5'-splice site located in the 3' exon results in guanosine nucleotide mediated opening at a position 30 nt downstream of the normal 3' splice site. The reactions can all be explained on the basis of the "splice guide" model proposed by Davies et al (1982 Nature 300 719-724). Although the sequence motifs at cyclization and splice sites occur more often in this intron, only some of them are allowed to interact with the internal guide sequence, suggesting that both primary structure and spatial folding of the RNA are involved in formation of productive reaction sites.     

Binding of SeqA protein to DNA requires interaction between two or more complexes bound to separate hemimethylated GATC sequences

The SeqA protein binds to the post-replicative forms of the origins of replication of the Escherichia coli chromosome (oriC) and the P1 plasmid (P1oriR) at hemimethylated GATC adenine methylation sites. It appears to regulate replication by preventing premature reinitiation. However, SeqA binding is not exclusive to replication origins: different fragments with hemimethylated GATC sites can bind SeqA in vitro when certain rules apply. Most notably, more than one such site must be present on a bound fragment. The protein appears to recognize individual hemimethylated sites, but must undergo an obligate cooperative interaction with a nearby bound protein for stable binding. SeqA contacts both DNA strands in a discrete patch at each hemimethylated GATC sequence. All four GATC bases are contacted and are essential for binding. Although the recognized sequence is symmetrical, the footprint on the methylated strand is always broader, suggesting that the bound protein is positioned asymmetrically with its orientation dictated by the position of the unique methyl group. Studies of alternative spacings and relative orientations of adjacent sites suggest that each site may be recognized by a symmetrical dimer with an induced asymmetry in one of the subunits similar to that seen with certain type II restriction endonucleases.     

A novel strategy for unambiguous determination of inner esterification sites of ganglioside lactones

A method is described which is suitable for protection of all free hydroxyl groups of a glycosphingolipid under conditions which will not cleave ester linkages, including inner ester linkages characteristic of ganglioside lactones. The protecting methoxyethoxymethyl group is stable in alkaline media, surviving permethylation procedures which introduce a methyl ether at all sites previously acylated. Hydrolysis, reduction, and acetylation then yield alditol acetate derivatives which can be analyzed by conventional GC-MS to locate the methyl ether groups. The method is used to locate the inner esterification site of GM3 lactone.     

Spontaneous formation of L-isoaspartate and gain of function in fibronectin

Isoaspartate formation in extracellular matrix proteins, by aspartate isomerization or asparagine deamidation, is generally viewed as a degradation reaction occurring in vivo during tissue aging. For instance, non-enzymatic isoaspartate formation at RGD-integrin binding sites causes loss of cell adhesion sites, which in turn can be enzymatically "repaired" to RGD by protein-l-isoAsp-O-methyltransferase. We show here that isoaspartate formation is also a mechanism for extracellular matrix activation. In particular, we show that deamidation of Asn263 at the Asn-Gly-Arg (NGR) site in fibronectin N-terminal region generates an alpha(v)beta3-integrin binding site containing the L-isoDGR sequence, which is enzymatically "deactivated" to DGR by protein-L-isoAsp-O-methyltransferase. Furthermore, rapid NGR-to-isoDGR sequence transition in fibronectin fragments generates alpha(v)beta3 antagonists (named "isonectins") that competitively bind RGD binding sites and inhibit endothelial cell adhesion, proliferation, and tumor growth. Time-dependent generation of isoDGR may represent a sort of molecular clock for activating latent integrin binding sites in proteins.     

High-resolution Structures of the Ligand Binding Domain of the Wild-type Bacterial Aspartate Receptor

The high-resolution structures of the wild-type periplasmic domain of the bacterial aspartate receptor have been determined in the absence and presence of bound aspartate to 1.85 and 2.2 Å resolution, respectively. As we reported earlier, in the refined structure of the complexed form of the crosslinked cysteine mutant receptor, the binding of the aspartate at the first site was mediated through four bridging water molecules while the second site showed an occupant electron density that best fit a sulfate group, which was present in the crystallization solution at high concentration. In the wild-type periplasmic domain structure two aspartate residues are bound per dimer, but with different occupancies. There exists a “strong” aspartate-binding site whose binding is again mediated by four water molecules while the second site contains aspartate whoseB-factor is about 10% higher, signifying weaker binding. The interaction between the second, “weaker” aspartate with the three ligand-binding arginine side-chains is slightly different from the first site. The major difference is that there are three water molecules mediating the binding of aspartate at the second site, whereas in the first site there are four bridging water molecules. The fact that aspartate-complexed crystals of the wild-type were grown with a large excess aspartate while the cross-linked crystals were grown with equal molar aspartate may explain the difference in the stoichiometry observed. The conservation of the four bridging water molecules in the strong aspartate site of both the cross-linked and wild-type periplasmic domain may reflect an important binding motif.The periplasmic domain in the apo form is a symmetrical dimer, in which each of the subunits is equivalent, and the two aspartate binding sites are identical. Upon the binding of aspartate, the subunits are no longer symmetrical. The main difference between the aspartate-bound and unbound forms is in a small, rigid-body rotation between the subunits within a dimer. The rotation is similar in both direction and magnitude in the crosslinked and wild-type periplasmic domains. The presence of the second aspartate in the wild-type structure does not make any additional rotation compared to the single-site binding. The conservation of the small angular changein vitrosuggests that the inter-subunit rotation may have relevance to the understanding of the mechanism of transmembrane signal transductionin vivo.     

S-methyl glutathione synthesis is catalyzed by the cheR methyltransferase in Escherichia coli.

The cheR methyltransferase, known to be necessary for the methyl esterification of receptors involved in chemotaxis, is shown to be essential to the synthesis of S-methyl glutathione from glutathione and S-adenosylmethionine in intact Escherichia coli. S-Methyl glutathione is not, however, found to be essential for chemotaxis. It is suggested that the synthesis of S-methyl glutathione may be due to a "parasitic" reaction of glutathione with S-adenosylmethionine bound to the methyltransferase.     

Formation of isoaspartate at two distinct sites during in vitro aging of human growth hormone

In vitro aging at pH 7.4, 37 degrees C causes natural sequence recombinant human growth hormone (rhGH), methionyl rhGH, and human pituitary growth hormone to become substrates for bovine brain protein carboxyl methyltransferase, an enzyme that modifies the "side chain" alpha-carboxyl group present at atypical isoaspartyl linkages. The substrate capacity of rhGH increased at a rate of 1.8 methyl-accepting sites/day/100 molecules of hormone. Reversed-phase high performance liquid chromatography (HPLC) of trypsin digests of aged rhGH revealed two altered peptides not present in digests of control rhGH. These two fragments, which had the amino acid compositions of residues 128-134 (Leu-Glu-Asp-Gly-Ser-Pro-Arg) and 146-158 (Phe-Asp-Thr-Asn-Ser-His-Asn-Asp-Asp-Ala-Leu-Leu-Lys), contained the majority of the induced methylation sites, 22 and 58%, respectively. Isoaspartate can result from deamidation of asparagine or isomerization of aspartate. Isomerization of Asp-130, the only candidate site in 128-134, was corroborated by coelution of the altered fragment with the synthetic isoaspartyl peptide upon reversed-phase HPLC. Evidence is presented that the altered 146-158 fragment is a mixture of two peptides resulting from deamidation of Asn-149 to form 70-80% isoaspartate and 20-30% aspartate at this position. The position of isoaspartate in the altered 146-158 fragment was deduced from mass spectrometry, which indicated a single deamidated asparagine; from methylation stoichiometry, which indicated only one methylation site; and from automated Edman degradation, which showed an absence of asparagine and a low yield of aspartate at position 149. These results show that isoaspartate formation from both aspartate and asparagine is a significant, and possibly the major, source of spontaneous covalent alteration of rhGH and that enzymatic carboxyl methylation provides a powerful tool for assessing this type of modification.     

Characteristic amino acid combinations in olfactory G protein-coupled receptors

The human olfactory subgenome has recently been fully characterized with over 1000 genes. Although as many as two thirds of them are expected to be pseudogenes, it still leaves us with about half of all human G protein-coupled receptors being olfactory. It is therefore of great interest to characterize olfactory receptors with high precision. Usually it is done through sequence motifs that are not fully conserved, making an exact characterization difficult. In this paper, we propose a rule-based characterization of olfactory receptors derived from a multiple sequence alignment of human GPCRs. We show that just seven alignment sites are sufficient to characterize 99% of human olfactory GPCRs with one feature, a tyrosine at site 7.41, being of particular importance. We also show dependencies between sites near the extracellular and intracellular region of a membrane-embedded receptor, indicating that olfactory receptors are characterized by a combination of important residues in these two areas, whereas nonolfactory receptors tend to have residues of lower importance at the same sites.     

Studies on the mechanism of the glutamine-dependent reaction catalyzed by asparagine synthetase from mouse pancreas

Initial velocity and product inhibition studies were conducted with the glutamine-dependent reaction of asparagine synthetase from mouse pancreas. Double reciprocal plots of glutamine versus either aspartate or ATP were parallel, while aspartate versus ATP gave intersecting patterns. These patterns are indicative of a hybrid ping-pong mechanism consisting of a glutaminase partial reaction and a sequential catalysis involving aspartate and ATP. Inhibition patterns of the four products, glutamate, AMP, PPi, and asparagine, versus each of the three substrates are consistent with a hybrid Uni Uni Bi Ter Ping Pong Theorell-Chance mechanism where the glutaminase reaction occurs first and aspartate binds to the enzyme before ATP in the sequential segment. PPi is the first product released in the Theorell-Chance reaction, which is followed by the ordered release of AMP and asparagine. Product inhibition patterns also indicate the formation of E . NH3 . Asn and E . NH3 . Asp . AMP abortive complexes. Although an amide site (for glutamine and asparagine), presumably responsible for the glutaminase reaction, an acid site (for glutamate and aspartate), and a nucleotide site are involved in the overall catalysis, the "two-site" ping-pong mechanism is incompatible with the experimentally observed product inhibition patterns.     

Modeling the three-dimensional structures of bacterial aminotransferases

The refined crystallographic structure of the "closed" conformation of chicken mitochondrial aspartate aminotransferase has been used as a template for the construction of models of the two Escherichia coli aminotransferases encoded by the tyrB and aspC genes. The main results are as follows: (1) Only minor changes are required in the coordinates of the backbone atoms to accommodate the large number of substituted side chains. (2) All deletions and insertions required to allow maximum primary sequence alignment are on the solvent-accessible surface. (3) Charged residues are all located on the surface, in contact with solvent, except for certain conserved active site residues. (4) The close packing within the hydrophobic core is maintained. (5) The interactions between the subunits are maintained. (6) Modeling of tyrosine as an external aldimine into the active sites points to several residues that could be involved in determining the substrate specificities of these aminotransferases.