Synthesis of 3-O-acyl esters of serine and threonine

The 3-O-acyl derivatives of serine and threonine have been prepared by reacting oleoyl chloride and palmitoyl chloride with N-t-butoxycarbonyl (N-T-BOC) serine and N-t-BOC threonine. The t-BOC group was removed by treatment with 4 N HCl in dioxane. The products were identified by proton magnetic resonance spectroscopy, infrared spectroscopy, elemental analysis and chromatographic properties. The O-acyl serines and O-acyl threonines were converted to their methyl esters by treatment with boron trifluoride in methanol and were converted to their dinitrophyl derivatives by treatment with dinitrofluorobenzen (DNFB). The yield of the dinitrophenyl derivatives was very high but the yield of methyl esters was low due mainly to methanolysis and loss of the fatty acyl group. The O-acyl serines and O-acyld threonines prepared will provide standards for researchers who are interested in identifying fatty acids esterified to serine and threonine hydroxyl groups in membrane proteins.     

An improved procedure for the synthesis of dehydroamino acids and dehydropeptides from the carbonate derivatives of serine and threonine using tetrabutylammonium fluoride

Dehydroamino acids are important precursors for the synthesis of a number of unnatural amino acids and are structural components in many biologically active peptide derivatives. However, efficient synthetic procedures for their production in large amounts and without side reactions are limited. We report here an improved procedure for the synthesis of dehydroalanine and dehydroamino butyric acid from the carbonate derivatives of serine and threonine using TBAF. The antiselective E₂ elimination of the carbonate derivatives of serine and threonine using TBAF is milder and more efficient than other available procedures. The elimination reaction is completed in less than 10 min with various carbonate derivatives studied and the methodology is very efficient for the synthesis of dehydroamino acids and dehydropeptides. The procedure thus provides an easy access to key synthetic precursors and can be used to introduce interesting structural elements to designed peptides. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Effects of Cyclohexanonic Long-Chain Fatty Alcohol, tCFA15 on Amino Acids in Diabetic Rat Brain: A Preliminary Study

The aim of this study was to evaluate the effects of streptozotocin-induced type 1diabetes and a subchronic treatment with cyclohexanonic long-chain fatty alcohol, 3-(15-hydroxypentadecyl)-2,4,4-trimethyl-2-cyclohexen 1-one (tCFA15) on contents of amino acids including aspartate, glutamate, glutamine, GABA, glycine, taurine, alanine, serine, threonine, and arginine in the prefrontal cortex, hippocampus and striatum. Levels of glutamate, threonine, taurine, alanine, arginine, and the ratio of glutamate/glutamine were altered region-differently in the brain of diabetic rats. However, tCFA15 region-specifically antagonized the changes in taurine and arginine levels and the ratio of glutamate/glutamine. The alteration in glutamate/glutamine ratio may indicate that experimental models of type 1 diabetes have abnormalities of neuron-gria interaction in brain.     

Specific sulfonation of tyrosine, tryptophan and hydroxy-amino acids in peptides

1. ClSO3H in trifluoroacetic acid rapidly converts serine and threonine into O-sulfate ester derivatives while tyrosine and tryptophan are converted into arylsulfonic acids. 2. H2SO4 in trifluoroacetic acid reacts more slowly with serine, threonine and tyrosine while is not able to modify tryptophan. 3. All other amino acids are perfectly stable under the above reaction conditions. 4. Peptides containing susceptible amino acid residues are specifically converted into the corresponding sulfonated derivatives in high or quantitative yield.     

The destruction of serine and threonine thiohydantoins during the sequence determination of peptides by 4-N,N-dimethylaminoazobenzene 4'-isothiocyanate.

1. A mechanism for the destruction of serine and threonine thiohydantoins during protein sequence analysis by the Edman-type degradation is proposed. The mechanism begins with the dehydration of serine and threonine side chains (at the cyclization stage) which occurs mainly in anhydrous acid solution. The dehydrated derivatives finally polymerize by way of the reactive methylene group (enamine) to form polymers with various molecular weights. In aqueous acid solution, the dehydrated thiohydantoins of serine and threonine undergo hydration (according to the Markovnikov rule) and ring fission, which leads to the irreversible breakdown of thiohydantoin ring. The serine derivative shows a much greater tendency to undergo these side-reactions than the threonine derivative. 2. In the presence of oxygen, the alkaline hydrolysis of amino acid thiohydantoins goes through an oxidation-deamination reaction at the C-N bond of the thiohydantoin ring and leads to the formation of thiourea derivative and keto acids. This reaction mechanism accounts for the low recoveries of amino acid obtained from the alkaline hydrolysis of amino acid thiohydantoins.     

Adaptational modification of serine and threonine metabolism in the liver to essential amino acid deficiency in rats

It is known that plasma serine and threonine concentrations are elevated in rats chronically fed an essential amino acid deficient diet, but the underlying mechanisms including related gene expressions or serine and threonine concentrations in liver remained to be elucidated. We fed rats lysine or valine deficient diet for 4 weeks and examined the mRNA expressions of serine synthesising (3-phosphoglycerate dehydrogenase, PHGDH) and serine/threonine degrading enzymes (serine dehydratase, SDS) in the liver. Dietary deficiency induced marked elevation of hepatic serine and threonine levels associated with enhancement of PHGDH mRNA expression and repression of SDS mRNA expression. Increases in plasma serine and threonine levels due to essential amino acid deficiency in diet were caused by marked increases in hepatic serine and threonine levels. Proteolytic responses to the amino acid deficiency may be lessened by storing amino radicals as serine and inducing anorexia through elevation of threonine.     

The effect of peptide length on the cleavage kinetics of 2-chlorotrityl resin-bound ethers.

Different characteristics of cleavage kinetics of resin-bound amino alcohols and their peptide derivatives were observed in acid containing protic and aprotic solvent mixtures. The hydrolysis reactions are hindered by steric crowding around the cleaving C--O bond and accelerated by the special solvation effect of CF(3)CH(2)OH on the peptide chain as well as the increase of the strength and concentration of the acid. In trifluoroacetic acid containing mixtures, trifluoroacetylation of the peptide alcohols was detected. The appearance of O-trifluoroacetyl serine and threonine derivatives is detected in cleavage mixtures containing trifluoroacetic acid in anhydrous solvent.     

UV-B Induced Alterations in Composition of Thylakoid Membrane and Amino Acids in Leaves of Rhizophora Apiculata Blume

Seedlings of Rhizophora apiculata were exposed to UV-B radiation at four doses equivalent to 10, 20, 30, and 40 % ozone depletion. The seedlings irradiated with high doses of UV-B had characteristic decline in contents of specific proteins with molecular masses of 33, 23, and 17 kDa. On the contrary, proteins of 55, 33, 25, 23, and 17 kDa were accumulated in the seedlings exposed to low doses of UV-B. The UV-B, in general, enhanced formation of saturated fatty acids and reduced unsaturated fatty acids, to a maximum extent of 88 and 26 %, respectively. The low dose of UV-B increased content of oleic acid by 9 %, and the high dose reduced it by 34 %. The high dose of UV-B enhanced the lipid peroxidation by 48 %, whereas the low dose of UV-B did not show any significant effect. The contents of amino acids such as aspartate, glutamate, asparagine, serine, glutamine, threonine, and histidine were increased in low UV-B doses by 53, 86, 142, 72, 3, 119, and 32 %, respectively; while in high doses they were reduced significantly.     

Approach to systematic analysis of serine/threonine phosphoproteome using Beta elimination and subsequent side effects: intramolecular linkage and/or racemisation

Complete analysis of the phosphorylation of serine and threonine residues directly from biological extracts is still at an early stage and will remain a challenging goal for many years. Analysis of phosphorylated proteins and identification of the phosphorylated sites in a crude biological extract is a major topic in proteomics, since phosphorylation plays a dominant role in post-translational protein modification. Beta elimination of the serine/threonine-bound phosphate by alkali action generates (methyl)dehydroalanine. The reactivity of this group susceptible of nucleophilic attacks might be used as a tool for phosphoproteome analysis. Most of the known serine/threonine kinases recognize motifs in protein targets that are rich in lysine(s) and/or arginine(s). The (methyl)dehydroalanine resulting from beta elimination of the serine/threonine-bound phosphate by alkali action is likely to react with the amino groups of these neighboring amino acids. Furthermore, the addition reaction of dehydroalanine-peptides with a nucleophilic group more likely generates diastereoisomers derivatives. The internal cyclic bonds and/or the stereoisomer peptide derivatives thus generated confer resistance to trypsin cleavage and/or constitute stop signals for exopeptidases such as carboxypeptidase. This might form the basis of a method to facilitate the systematic identification of phosphorylated peptides.     

Entry of glucose carbon into amino acids of rat brain and liver in vivo after injection of uniformly 14C-labelled glucose

1. Glycosidic linkage of carbohydrate to the primary hydroxyl groups of threonine and serine has been established in human blood-group A and Le(a) substances, bovine submaxillary-gland mucin and human pseudomyxomatous mucin. 2. Treatment of these substances in 0.09n-lithium hydroxide at 100 degrees for 1hr. led to beta-elimination at these glycosidic linkages with the resultant formation of alpha-oxobutyric acid and glycine from threonine linkages, and pyruvic acid from serine linkages. Though most of the threonine was destroyed in every case, about one-third to one-half of the serine residues resisted alkaline cleavage. Such results, indicative of the presence of unbound serine residues, allow, in submaxillary mucin, for a close correlation between the remaining serine, threonine, glutamic acid and aspartic acid and the available sialyl-(2-->6)-N-acetylgalactosamine prosthetic groups. 3. The stoichiometry of the beta-eliminations has been demonstrated for pseudomyxomatous mucin. The alpha-oxo acids were separated and determined as their quinoxalinol derivatives by thin-layer chromatography on silica gel. Reaction at the threonine centres favoured alpha-oxobutyric acid formation (70%, via the intermediary dehydropeptide) over the alternative pathway to glycine (30%). 4. 100% of the hexosamine was destroyed in submaxillary-gland mucin, 85% in pseudomyxomatous mucin and about 60% in the blood-group substances. In the latter cases, the glucosamine/galactosamine ratio was increased from about 4:1 to 8-10:1, suggesting a preferential destruction of galactosamine. Evidence was obtained, however, for a further destruction of hexosamine, in addition to that which could be theoretically attached to peptide at possible known binding sites. 5. The major part of the alkali-resistant hexosamine in the blood-group substances was non-diffusible and was accompanied by the constituent carbohydrates in similar molar proportions to the native materials.     

Identification of major ERK-related phosphorylation sites in Gab1

Gab1 (Grb2-associated binder1) belongs to a family of multifunctional docking proteins that play a central role in the integration of receptor tyrosine kinase (RTK) signaling, i.e., mediating cellular growth response, transformation, and apoptosis. In addition to RTK-specific tyrosine phosphorylation, these docking proteins also can be phosphorylated on serine/threonine residues affecting signal transduction. Since serine and threonine phosphorylation are capable of modulating the initial signal one major task to elucidate signal transduction via Gab1 is to determine the exact localization of distinct phosphorylation sites. To address this question in this report we examined extracellular signal-regulated kinases 1/2 (ERK) specific serine/threonine phosphorylation of the entire Gab1 engaged in insulin signaling in more detail in vitro. To elucidate the ERK1/2-specific phosphorylation pattern of Gab1, we used phosphopeptide mapping by two-dimensional HPLC analysis. Subsequently, phosphorylated serine/threonine residues were identified by sequencing the separated phosphopeptides using matrix assisted laser desorption ionization mass spectrometry (MALDI-MS) and Edman degradation. Our results demonstrate that ERK1/2 phosphorylate Gab1 at six serine/threonine residues (T312, S381, S454, T476, S581, S597) in consensus motifs for MAP kinase phosphorylation. Serine residues S454, S581, S597, and threonine residue T476 represent nearly 80% of overall incorporated phosphate. These sites are located adjacent to src homology region-2 (SH2) binding motifs (YVPM-motif: Y447, Y472, Y619) specific for the phosphatidylinositol 3kinase (PI3K). The biological role of identified phosphorylation sites was proven by PI3K and Akt activity in intact cells. These data demonstrate that ERK1/2 modulate insulin action via Gab1 by targeting serine and threonine residues beside YXXM motifs. Accordingly, insulin signaling is blocked at the level of PI3K.     

Mutagenesis of the cyclic AMP receptor protein of Escherichia coli: targeting positions 83, 127 and 128 of the cyclic nucleotide binding pocket.

The cyclic 3', 5' adenosine monophosphate (cAMP) binding pocket of the cAMP receptor protein (CRP) of Escherichia coli was mutagenized to substitute cysteine or glycine for serine 83; cysteine, glycine, isoleucine, or serine for threonine 127; and threonine or alanine for serine 128. Cells that expressed the binding pocket residue-substituted forms of CRP were characterized by measurements of beta-galactosidase activity. Purified wild-type and mutant CRP preparations were characterized by measurement of cAMP binding activity and by their capacity to support lacP activation in vitro. CRP structure was assessed by measurement of sensitivity to protease and DTNB-mediated subunit crosslinking. The results of this study show that cAMP interactions with serine 83, threonine 127 and serine 128 contribute to CRP activation and have little effect on cAMP binding. Amino acid substitutions that introduce hydrophobic amino acid side chain constituents at either position 127 or 128 decrease CRP discrimination of cAMP and cGMP. Finally, cAMP-induced CRP structural change(s) that occur in or near the CRP hinge region result from cAMP interaction with threonine 127; substitution of threonine 127 by cysteine, glycine, isoleucine, or serine produced forms of CRP that contained, independently of cAMP binding, structural changes similar to those of the wild-type CRP:cAMP complex.     

Water and nonelectrolyte permeability of plant cell membranes after short term application of amino acids and phosphorylated amino acids

The effects of amino acids (aa) and N-(diisopropyloxyphosphoryl)-amino acids (DIPP-aa) on cell membranes were investigated by evaluating water and methyl urea permeability. Permeability coefficients P_f and P_s were determined by standard osmotic methods for cells ofPisum sativum stem base epidermis after 20 min exposure to a 5 mM solution of each aa and DIPP-aa. The P_f value ofP. sativum epidermal cells (untreated controls) was 1.3 ± 0.4 × 10^-3 μm s^-1. Treat ments with the diisopropyl-oxyphosphoryl derivatives of three one charged and three polar amino acids (serine, threonine, asparagine, and aspartic acid) and unsubstituted (free) serine and threonine increased water permeability up to about two fold of the control value. Serine and threonine and their DIPP-derivatives increased methyl urea permeability (controls 1.03 ± 0.09 × 10^-3 μm s^-1) 30 to 80 percent Other amino acids and their DIPP-derivatives caused small or insignificant changes of water permeability. Only certain polar amino acids and their DIPP-derivatives increased the osmotic water and methyl urea permeation through the plasma membrane. The specificity of these molecules on plasma membranes suggests that the active amino acids (serine and threonine) and their DIPP-derivatives interact with charged membrane molecules. The relatively small changes in water and methyl urea permeability may indicate that the effective aa’s and their DIPP-derivatives interact with phospholipids rather than aquaporin. A concurring alteration of water channel proteins, however, cannot excluded.     

The structure of a glycopeptide (GP-II) isolated from Rhizopus saccharogenic amylase.

Mild alkaline treatment of glycopeptide (GP-II) resulted in the loss of 1 mole of serine and 5 moles of threonine per mole of GP-II, suggesting the presence of O-glycosyl bonds between 1 serine and 5 threonine residues and carbohydrate chains. Treatment of GP-II with alkaline borohydride released only disaccharide. Methylation studies of the carbohydrate moiety gave 2,3,4,6-tetra-O-methyl and 2,4,6-tri-O-methyl derivatives of mannose in a ratio of approximately 1:1. In addition, one step of Smith degradation resulted in the loss of about 6 residues of mannose per mole of GP-II. Moreover, alpha-mannosidase [EC 3.2.1.24] liberated about 6 residles of mannose per mole of GP-II. On the basis of these data, the structure of the carbohydrate moiety of GP-II was confirmed to be 3-O-alpha-mannosylmannose. The amino- and carboxyl-terminal amino acids of GP-II were determined to be threonine and serine, respectively. On reductive cleavage of N-proline bonds with metallic sodium in liquid ammonia, 2 moles of alanine per mole of GP-II were lost. From the compositions of three fragments isolated from the reductive cleavage products, the amino acid sequence of the peptide portion of GP-II was determined. Based on these data, a probable structure was proposed for GP-II.     

Synthesis of glycosylated serine and threonine derivatives employing glycosidases

The galactosyl derivatives Galβ-Ser(N-Boc) and Galβ-Thr(N-Boc) of N-Boc-protected serine and threonine were prepared with galactose or lactose as the glycosyl donor employing β-galactosidase as the catalyst. Similarly, the mannosyl derivatives Manα-Ser(N-Boc) and Manα-Thr(N-Boc) were prepared with mannose as the glycosyl donor (equilibrium reaction) employing α-mannosidase as the catalyst.     

Hydroxy amino acid metabolism in Pseudomonas cepacia: role of L-serine deaminase in dissimilation of serine, glycine, and threonine.

Growth of Pseudomonas cepacia (P. multivorans) on serine depended upon induction of a previously undescribed L-serine deaminase distinct from threonine deaminase. Formation of the enzyme was induced during growth on serine, glycine, or threonine. The induction pattern reflected a role of the enzyme in catabolism of these three amino acids. Both threonine and glycine supported growth of serine auxotrophs and were presumably converted to serine and pyruvate in the course of their degradation. Mutant strains deficient in serine deaminase, or unable to use pyruvate as a carbon source, failed to utilize serine or glycine and grew poorly with threonine, whereas strains deficient in threonine dehydrogenase or alpha-amino beta-ketobutyrate:coenzyme A ligase (which together convert threonine to glycine and acetyl coenzyme A) failed to utilize threonine or derepress serine deaminase in the presence of this amino acid. The results confirm for the first time the role of alpha-amin beta-ketobutyrate:coenzyme A ligase in threonine degradation and indicate that threonine does not mimic serine as an inducer of serine deaminase.     

Regulation of acetyl-CoA carboxylase in rat mammary gland. Effects of incubation with Ca2+, Mg2+ and ATP on enzyme activity in tissue extracts.

The catalytical role of the hydroxy amino acid in the "marker sequence" Asn-Xaa-Thr(Ser) for the N-glycosylation step of glycoprotein formation was investigated by using a series of hexapeptides derived from Tyr-Asn-Gly-Xaa-Ser-Val by substituting threonine, serine, cysteine, valine and O-methylthreonine respectively for Xaa. The results, which were obtained with calf liver microsomal fractions as enzyme source and dolichyl diphosphate di-N-acetyl [14C] chitobiose as glycosyl donor showed that the threonine-, serine- and cysteine-containing derivatives could be glycosylated, although at very different rates, whereas the valine and O-methylthreonine analogues did not work as glycosyl acceptors. Replacement of threonine by serine resulted in a 4-fold decrease in Vmax, and about a 10-fold increase in Km for glycosyl transfer. Replacement of serine by cysteine again decreased acceptor activity 2-3-fold. The various results, taken together, indicate an absolute requirement for a hydrogen-bond-donor function in the side chain of the hydroxy amino acid of the "marker sequence" and furthermore, point to a considerable influence of the structure of this amino acid on binding as well as on the glycosyl transfer itself. In order to explain the observed differences in the glycosyl-transfer rates, a model is proposed with a hydrogen-bond interaction between the amide of asparagine as the hydrogen-bond donor and the oxygen of the hydroxy group of the hydroxy amino acid as the hydrogen-bond acceptor. The participation of the hydroxy group in the catalytic mechanism of glycosyl transfer in the kind of proton-relay system is discussed.     

Zinc ion acts as a cofactor for serine/threonine kinase MST3 and has a distinct role in autophosphorylation of MST3

We examined the metal ion cofactor preference for MST3 (mammalian Ste20-like kinase 3) of the Ste20 serine/threonine kinase family. Four metal ions (Mg(+2), Mn(+2), Zn(2+), and Co(2+)) activate endogenous, exogenous, and baculovirus-expressed recombinant MST3 within the physiological concentration range. In contrast, Fe(+2) and Ca(+2) do not function as MST3 cofactors. Mn(2+), Co(2+), and Mg(2+)-dependent autophosphorylation of MST3 is mainly on threonine residue while Zn(2+)-stimulated MST3 autophosphorylation is on both serine and threonine residues. The distinct autophosphorylation pattern on MST3 suggests that MST3 may exert various types of kinase reactions depending on the type of metal ion cofactor used. To our knowledge, this is the first report showing Zn(2+) as the metal ion cofactor of a recombinant serine/threonine kinase.     

Phosphorylation alters backbone conformational preferences of serine and threonine peptides

Despite the notion that a control of protein function by phosphorylation works mainly by inducing its conformational changes, the phosphorylation effects on even small peptide conformation have not been fully understood yet. To study its possible effects on serine and threonine peptide conformations, we recently carried out pH- and temperature-dependent circular dichroism (CD) as well as (1)H NMR studies of the phosphorylated serine and threonine peptides and compared them with their unphosphorylated analogs. In the present article, by performing the self-consistent singular value decomposition analysis of the temperature-dependent CD spectra and by analyzing the (3)J(H(N),H(α)) coupling constants extracted from the NMR spectra, the populations of the polyproline II (PPII) and β-strand conformers of the phosphorylated Ser and Thr peptides are determined. As temperature is increased, the β-strand populations of both phosphorylated serine and threonine peptides increase. However, the dependences of PPII/β-strand population ratio on pH are different for these two cases. The phosphorylation of the serine peptide enhances the PPII propensity, whereas that of the threonine peptide has the opposite effect. This suggests that the serine and threonine phosphorylations can alter the backbone conformational propensity via direct but selective intramolecular hydrogen-bonding interactions with the peptide N--H groups. This clearly indicates that the phosphoryl group actively participates in modulating the peptide backbone conformations.