Structure of rabbit skeletal myosin: Analysis of the amino acid sequences of two fragments from the rod region

The amino acid sequences of fragments from light meromyosin and heavy meromyosin subfragment-2 have been analysed and structural features noted. As with other α-fibrous protein sequences, there is a regular disposition of apolar residues in positions a and d of the heptapeptide-type repeat characteristic of the coiled-coil conformation. The common occurrence of acidic and basic residues in the e and g positions, respectively, give rise to a maximum number of interchain ionic interactions when the two parallel chains of myosin are in axial register. Although the quasi-repeating heptapeptides in the sequences both have two points of discontinuity (unlike that in most other α-fibrous proteins), secondary structure prediction methods indicate that the fragments will be 90 to 100% α-helical. Fast Fourier transform techniques have revealed a significant periodicity of about 27.4 ± 0.3 residues (~41 Å) in the linear disposition of the acidic residues and the basic residues in both of the fragments. This period is compatible with similarly directed myosin molecules in the thick filament being axially staggered with respect to one another by an odd multiple of 143 Å. Preliminary evidence is also presented to show that the sequence of the rod region of myosin may have a 28 residue gene duplication repeat.     

A new neuraminic acid derivative and three types of glycopeptides isolated from the Cuvierian tubules of the sea cucumber Holothuria forskali

The Cuvierian tubules of Holothuria forskali Della Chiaje, a sea cucumber found in the Adriatic Sea, were investigated with regard to their carbohydrate moieties. From a Pronase digest of these tubules three types of carbohydrate units were isolated and characterized. 1. A high-molecular-weight glycopeptide fraction was shown to contain sulphated polyfucose, galactosamine, a uronic acid and a previously unknown neuraminic acid derivative. The sulphate was shown by i.r. analysis to be present as an O-ester. The carbohydrate unit was linked O-glycosidically to threonine and serine residues in the polypeptide chain. The hitherto unknown neuraminic acid derivative (Hf-neuraminic acid) was resistant to enzymic cleavage by neuraminidase, even after mild alkaline hydrolysis for the removal of O-acyl residues. However, the glycosidic linkage of this compound to the other part of the carbohydrate moiety was readily cleaved by mild acid hydrolysis. Its chromatographic properties distinguished Hf-neuraminic acid from other known neuraminic acid derivatives (N-acetyl-, NO-diacetyl-, NOO-triacetyl- and N-glycollyl-neuraminic acid). Further, this acidic sugar was shown to possess neuraminic acid as its basic structure. Thus, an as yet unknown substituent lends the distinct properties to Hf-neuraminic acid. 2. The carbohydrate composition of a second glycopeptide fraction consisting of a derivative of neuraminic acid, galactose, mannose and glucosamine was similar to that of the well-known carbohydrate groups of the globular glycoproteins. 3. The third fraction contained two glycopeptides containing the disaccharide, glucosylgalactose, which was shown to be linked to the hydroxyl group of hydroxylysine residues of a collagen-like protein. Approximately half of these residues were glycosylated. In addition to these glycopeptides, a small amount of a third glycopeptide that carried only a galactosyl residue was detected. The amino acid sequence of the two major compounds were found to be Gly-Ala-Hyl*-Gly-Ser and Gly-Pro-Hyl*-Gly-Asp, where Hyl* represents a glycosylated amino acid residue.     

Localization of cysteine residues in the alpha-chain of histidine decarboxylase from Micrococcus sp. n

It was shown that the alpha-chain of histidine decarboxylase of Micrococcus sp. n. is split off by 2-nitro-5-thiocyanobenzoic acid at only one of the two cysteine residues. Determination of the C-terminal sequences, amino acid composition, molecular weight of the fragments obtained demonstrated that these fragments constitute a complete alpha-chain whose cleavage occurs at the cysteine residue which is readily modified by SH-reagents. the Ile-Cys peptide bond appeared to be resistant to cleavage under these conditions. This cleavage permitted to identify the amino acid environment of the cysteine residue active center and its localization in the alpha-chain of histidine decarboxylase.     

Active-site amino acid residues in γ-glutamyltransferase and the nature of the γ-glutamyl-enzyme bond

Active-site residues in rat kidney γ-glutamyltransferase (EC 2.3.2.2) were investigated by means of chemical modification. 1. In the presence of maleate, the activity was inhibited by phenylmethanesulphonyl fluoride, and the inhibition was not reversed by β-mercaptoethanol, suggesting that a serine residue is close to the active site, but is shielded except in the presence of maleate. 2. Treatment of the enzyme with N-acetylimidazole modified an amino group, exposed a previously inaccessible cysteine residue and inhibited hydrolysis of the γ-glutamyl-enzyme intermediate, but not its formation. 3. After reaction of the enzyme successively with N-acetylimidazole and with non-radioactive iodoacetamide/serine/borate, two active-site residues reacted with iodo[¹⁴C]acetamide. One of these possessed a carboxy group, which formed a [¹⁴C]glycollamide ester, and the other was cysteine, shown by isolation of S-[¹⁴C]carboxymethylcysteine after acid hydrolysis. When N-acetylimidazole treatment was omitted, only the carboxy group reacted with iodo[¹⁴C]acetamide. 4. Isolation of the γ-[¹⁴C]glutamyl-enzyme intermediate was made easier by prior treatment of the enzyme with N-acetylimidazole. The γ-glutamyl-enzyme bond was stable to performic acid, and to hydroxylamine/urea at pH10, but was hydrolysed slowly at pH12, indicating attachment of the γ-[¹⁴C]glutamyl group in amide linkage to an amino group on the enzyme. Proteolysis of the γ-[¹⁴C]glutamyl-enzyme after performic acid oxidation gave rise to a small acidic radioactive peptide that was resistant to further proteolysis and was not identical with γ-glutamyl-ε-lysine. 5. A scheme for the catalytic mechanism is proposed.     

Studying the S-nitrosylation of model peptides and eNOS protein by mass spectrometry.

Oxidative addition of a nitric oxide (NO) molecule to the thiol group of cysteine residues is a physiologically important post-translational modification that has been implicated in several metabolic and pathophysiological events. Our previous studies have indicated that S-nitrosylation can result in the disruption of the endothelial NO synthase (eNOS) dimer. It has been suggested that for S-nitrosylation to occur, the cysteine residue must be flanked by hydrophilic residues either in the primary structure or in the spatial proximity through appropriate conformation. However, this hypothesis has not been confirmed. Thus, the objective of this study was to determine if the nature of the amino acid residues that flank the cysteine in the primary structure has a significant effect on the rate and/or specificity of S-nitrosylation. To accomplish this, we utilized several model peptides based on the eNOS protein sequence. Some of these peptides contained point mutations to allow for different combinations of amino acid properties (acidic, basic, and hydrophobic) around the cysteine residue. To ensure that the results obtained were not dependent on the nitrosylation procedure, several common S-nitrosylation techniques were used and S-nitrosylation followed by mass spectrometric detection. Our data indicated that all peptides independent of the amino acids surrounding the cysteine residue underwent rapid S-nitrosylation. Thus, there does not appear to be a profound effect of the primary sequence of adjacent amino acid residues on the rate of cysteine S-nitrosylation at least at the peptide levels. Finally, our studies using recombinant human eNOS confirm that Cys98 undergoes S-nitrosylation. Thus, our data validate the importance of Cys98 in regulating eNOS dimerization and activity, and the utility of mass spectroscopy to identify cysteine residues susceptible to S-nitrosoylation.     

Properties of ACE inhibitory peptide prepared from protein in green tea residue and evaluation of its anti-hypertensive activity

Green tea contains active ingredients which are beneficial for health. While numerous studies have been conducted on the components extracted from green tea, few studies have investigated the active ingredients in tea residue. In this study, proteins were extracted from green tea residue via an optimised alkaline extraction combined with enzymatic hydrolysis, of which, an acidic protease was selected to prepare an enzymatic hydrolysate because of its high angiotensin converting enzyme (ACE) inhibitory activity. The composition characteristics of extracted green tea proteolysis products were elucidated, including amino acid composition, molecular weight distribution and possible amino acid sequences. In addition, the protein hydrolysate had anti-digestive properties, maintained its activity of inhibiting ACE enzyme at different temperatures, pH and metal ions, and exhibited antihypertensive activity in animals. In conclusion, the optimised alkaline extraction and enzymatic hydrolysis conditions of a ACE inhibitory peptide from green tea residue is an optimal extraction method to maintain its antihypertensive activity, providing the basis for the clinical application of green tea for blood pressure reduction.     

Amino acid sequence of ferredoxin from Arctium lappa

Ferredoxin from Arctium lappa consists of a single polypeptide chain of 97 residues, four of which are cysteine. These residues, which are in the active centre, are in identical positions to those of other ferredoxins. Overlap between residue positions 50/51 was not obtained, but amino acid composition of the two cyanogen bromide fragments which were overlapped corresponded with the amino acid composition of the total protein.     

Cytochrome c from Schizosaccharomyces pombe. 2. Amino-acid sequence.

The amino acid sequence of Schizosaccharomyces pombe cytochrome c has been established by automatic degradation of the protein and by manual degradation of fragments obtained by cyanogen bromide cleavage and chymotryptic digestion. The chymotryptic peptides were aligned by homology with other known cytochrome c sequences. The protein is 108 residues long, with a four-residue amino-terminal tail. It has only one methionine residue and differs from other fungal cytochromes c in lacking the one-residue deletion at the C-terminal end. After a cyanogen bromide step, an unexpected cleavage of the peptide chain before a cysteine residue was observed. This is ascribed to formation of a dehydroalanyl residue during an incomplete S-carboxymethylation of the apoprotein, and subsequent cleavage under acidic conditions. Experimental evidence is presented in favour of the proposed mechanisms.     

Identification of a single and non-essential cysteine residue in dextransucrase of Leuconostoc mesenteroides NRRL B-512F

Amino acid analysis of purified dextransucrase (sucrose: 1,6-α-D-glucan 6-α-D-glucosyltransferase EC 2.4.1.5) from Leuconostoc mesenteroides NRRL B-512F was carried out. The enzyme is virtually devoid of cysteine residue there being only one cysteine residue in the whole enzyme molecule comprising over 1500 amino acid residues. The enzyme is rich in acidic amino acid residues. The number of amino acid residues was calculated based on the molecular weight of 188,000 (Goyal and Katiyar 1994). Amino sugars were not found, implying that the enzyme is not a glycoprotein. It has been shown earlier that the cysteine residue in dextransucrase is not essential for enzyme activity (Goyal and Katiyar 1998). The presence of only one cysteine residue per enzyme molecule illustrates that its tertiary structure is solely dependent on other types of non-covalent interactions such as hydrogen bonding, ionic and nonpolar hydrophobic interactions.     

Identification of a single and non-essential cysteine residue in dextransucrase of Leuconostoc mesenteroides NRRL B-512F

Amino acid analysis of purified dextransucrase (sucrose: 1,6-alpha-D-glucan 6-alpha-D-glucosyltransferase EC 2.4.1.5) from Leuconostoc mesenteroides NRRL B-512F was carried out. The enzyme is virtually devoid of cysteine residue there being only one cysteine residue in the whole enzyme molecule comprising over 1500 amino acid residues. The enzyme is rich in acidic amino acid residues. The number of amino acid residues was calculated based on the molecular weight of 188,000 (Goyal and Katiyar 1994). Amino sugars were not found, implying that the enzyme is not a glycoprotein. It has been shown earlier that the cysteine residue in dextransucrase is not essential for enzyme activity (Goyal and Katiyar 1998). The presence of only one cysteine residue per enzyme molecule illustrates that its tertiary structure is solely dependent on other types of non-covalent interactions such as hydrogen bonding, ionic and nonpolar hydrophobic interactions.     

Modification of the cysteine residues of cytochrome P-450cam with 2-bromoacetamido-4-nitrophenol

The Pseudomonas putida cytochrome P-450 was alkylated with the SH-reagent, 2-bromoacetamido-4-nitrophenol. One out of eight cysteine residues present in the enzyme reacted rapidly while another 3 ～ 4 cysteine residues were gradually alkylated at longer reaction times. The derivative in which the most reactive cysteine residue was labeled with this reagent was hydrolyzed with trypsin and a tryptic peptide isolated. From the amino acid composition and end group analysis of the peptide, the rapidly reacting cysteine residue was shown to be Cys 355. This cysteine residue is probably exposed on the surface and is involved in the dimerization of the enzyme. The amino acid sequence about cysteine 355 shows sequence homology with residues 429–445 of the rat liver cytochrome P-450-LM-2.     

Amino acid sequence studies on sheep liver fructose-bisphosphatase. II. The complete sequence

The cyanogen bromide fragments of S-carboxymethylated fructose-bisphosphatase were purified. The amino acid sequences of the small fragments were determined by the dansyl-Edman method. The large fragments were subjected to proteolytic digestion to give smaller peptides more amenable for purification and sequencing by similar methods. Enzyme digests of the S-carboxymethylated enzyme gave overlap peptides containing the methionine residues. In conjunction with the amino acid sequence of the 60-residue N-terminal fragment previously determined on the S-peptide released by limited proteolysis with subtilisin the complete sequence of 336 residues was deduced. The sequence has been compared with the 335 residue sequence of pig kidney fructose-bisphosphatase and some areas of sequence for rabbit liver enzyme. The strong homology previously noted for the S-peptide sequence is maintained for the complete enzyme with only 34 changes in 336 residues when comparing the pig and sheep enzymes.     

Intracellular turnover of stable and labile soluble liver proteins

The cytosol proteins of mouse or rat liver were separated on the basis of charge and characterized with respect to molecular size, turnover in vivo, and several chemical properties. The basic proteins, which were synthesized and degraded slower than acidic proteins, were generally smaller, as multimers and subunits, than the acidic proteins. Charge and size, therefore, did not appear to be independent characteristics for soluble liver proteins. The amino acid composition of the smaller, basic, stable proteins was very similar to that of the larger, acidic, labile proteins. The charge differences between these two protein fractions could be attributed to the ratio of acidic to basic amino acid residues rather than to carbohydrate, nucleic acid, or phosphate content. The percentage of hydrophobic amino acid residues in the two protein fractions was the same. The acidic labile proteins were more vulnerable to proteolysis and associated with the lysosomal-mitochondrial fractions somewhat more extensively in vitro than the basic, stable proteins. These studies indicate that the information determining the half-lives of soluble enzymes is in the protein moiety of those enzymes and that the factors that correlate with turnover may not be independent variables for soluble mammalian proteins.     

Electrostatic engineering of the interface between heavy and light chains promotes antibody Fab fragment production

Monoclonal antibodies and antibody fragments are used for diverse diagnostic and therapeutic applications. We have investigated the secretory production of Fab fragments from insect cells cotransfected with plasmid vectors carrying heavy- and light-chain genes. In the present study, to promote the formation of the disulfide bond between the heavy and light chains, some positively charged amino acid residues were introduced near the cysteine residue for the disulfide bond at the C-terminus of C_L, while some negatively charged amino acid residues were added near the cysteine residue for the disulfide bond at the C-terminus of C_H1. This electrostatic steering led to an increase in Fab secretions from insect cells.     

Quantitative gas chromatographic analysis of amino acids on a short glass capillary column

A study of the quantitative gas chromatographic analysis of protein amino acids as their N-heptafluorobutyric amino acid n-propyl esters on a glass capillary column has been made. The analysis is completed within 35 min with good separation of the common protein amino acids in a single-column run.Hydrolyzed peptides have been analyzed. The analyses were performed with a precision varying between 1 and 6% (mean relative standard deviation) depending on the number of amino acid residues in the peptide. The amount taken for analysis was 20–300 μg. The results agree with the known sequences of the peptides and with the analyses by ion-exchange chromatography except for cysteine. This amino acid can be analyzed after modification as S-methylated cysteine.     

Some chemical properties of carboxymethyl derivatives of amino acids

Tritium-labeled carboxymethyl derivatives of various functional groups in proteins show ready exchange of the tritium label when exposed to standard protein hydrolysis conditions (6 n HCl, 21 h, 110 °C). While N_?-[³H]carboxymethyl lysine does not show any tritium exchange, the two N-[³H]carboxymethyl histidine derivatives lose their tritium with a half time of about 15 h, and S-[³H]carboxymethyl cysteine loses its tritium with a half time of about 1.5 h. The tritium exchange of S-[³H]carboxymethyl methionine was so fast that the derivative could not be prepared with any of the tritium label intact. The rate of exchange for this compound was consequently determined by following the disappearance of the methylene NMR signal when S-carboxymethyl methionine was dissolved in D₂O. The half time for the exchange was about 12 min. Mechanisms involving either a sulfonium ion or enolization of the protonated conjugate carboxylic acid appear to give a satisfactory explanation of the relative stability of the different derivatives. The practical use of the differential rate of hydrogen exchange as a means of establishing rapidly and with small quantities of material the site of carboxymethylation in unknown proteins is suggested.     

Localization of a DNA-binding determinant in the bacteriophage P22 Erf protein

Four amber fragments of the recombination-promoting P22 Erf protein were characterized. The intact Erf monomer contains 204 amino acids. The amber mutations produce fragments of 190, 149, 130 and 95 amino acid residues, all of which are inactive in vivo. The 190 residue fragment is more susceptible to proteolysis in cell extracts than is intact Erf. It breaks down to a stable remnant that is slightly larger than the 149 residue fragment. The 149 and 130 residue fragments are stable; electron microscopy of the purified fragments reveals that they have similar morphologies, retaining the ring-like oligomeric structure, but lacking the tooth-like protruding portions of intact Erf. Intact Erf and the 149 residue fragment have similar affinities for single-stranded DNA; the affinity of the 130 residue fragment is 40-fold lower in low salt at pH 6.0. The 95 residue fragment is unstable in vivo. These observations, combined with previous observations, are interpreted as suggesting that the boundary of the amino-terminal domain of the protein lies between residues 96 and 130, that certain residues between 131 and 149 form part of an interdomain DNA-binding segment of the protein, that the boundary of the carboxy-terminal domain lies to the C-terminal side of residue 149, and that the carboxy-terminal domain is not necessary for assembly of the ring oligomer, although it is essential for Erf activity in vivo.     

Analysis of beta-tubulin sequences reveals highly conserved, coordinated amino acid substitutions. Evidence that these 'hot spots' are directly involved in the conformational change required for dynamic instability

Vertebrate beta-tubulins have been classified into six classes on the basis of their C-terminal sequences [(1987) J. Cell Biol. 105, 1707-1720]. In particular, the sequences starting at residue 430 differ between isotypes of the same animal but are conserved between species. We extend this analysis and show that there are three 'hot spots', at residues 35, 55-57 and 124 which exhibit intra-species heterogeneity but inter-species conservation. There is a remarkable correlation between the identity of these residues and the C-terminal sequences, and suggests that the vertebrate beta-tubulins fall into three broad types. This correlation extends to those non-vertebrate organisms which have the Type 1 C-terminal sequence. We propose that these three 'hot spots' and the C-terminal peptide interact in the tertiary structure. We have also noted that the C-terminal peptide almost always contains a single phenylalanine or tyrosine residue, and that there is a strong correlation between this residue and the amino acids at positions 217/218, in both the vertebrate and non-vertebrate sequences. We propose that the C-terminal aromatic amino acid interacts with residues 217/218 in the tertiary structure. Analysis of conditions which stabilise microtubules and/or lower the steady state critical concentration strongly suggests that these two sets of coordinated amino acid substitutions are directly involved in effecting the conformational change associated with GTP hydrolysis which results in dynamic instability. We propose that there is an interaction between the highly acidic sequence between residue 430 and the aromatic amino acid (termed peptide A) and conserved basic amino acids located close to the 'hot spots'. We suggest that this interaction is altered in response to the assembly-dependent GTP hydrolysis, with the consequential increase in the subunit dissociation rate constant.     

A structural model of human erythrocyte protein 4.1

Limited proteolysis and specific chemical cleavage methods have enabled a detailed structural characterization of human erythrocyte protein 4.1. This protein is composed of two chemically very similar polypeptide chains (a and b) with apparent molecular masses of 80,000 and 78,000 daltons. Cleavage of protein 4.1 at cysteine residues by 2-nitro-5-thiocyanobenzoic acid produces a series of doublets which differ by approximately 2,000 daltons and have identical peptide maps. Alignment of these peptides by mapping analysis has localized 4 cysteine residues within a 17,000-dalton segment on both a and b polypeptides. Mild chymotryptic treatment at 0 degrees C cleaves protein 4.1 primarily in three central locations and generates two families of unrelated peptides. Analysis of these fragments in two-dimensional gels and by peptide mapping reveals an unusual polarity in protein 4.1 structure in that each polypeptide chain contains two segments, one relatively acidic the other basic, that are segregated at opposite ends of the molecule. The basic region is digested into a cysteine-rich 30,000-dalton domain which resists further breakdown while the acidic region is readily degraded into smaller fragments. The peptides derived from the acidic region all appear as doublets suggesting that protein 4.1 a and b polypeptides differ close to the terminus of the acidic end. Similar phosphorylation sites occur on both polypeptides within a segment some 24,000-34,000 daltons from the acidic terminus.