Characterization of a Kunitz trypsin inhibitor with one disulfide bridge purified from Swartzia pickellii

Swartzia pickellii is a Leguminosae that belongs to the Caesalpinioideae sub-family the Swartzia pickellii Trypsin Inhibitor (SWTI), a serine proteinase inhibitor was isolated from its seeds. SWTI is a single polypeptide chain protein and it's structure has 174 amino acid residues, it homologous to other Kunitz plant inhibitors, however shows some major differences: it contains only one disulfide bridge, instead two which are usually found in plant Kunitz inhibitors, and the SWTI reactive site does not contain the usual Arg or Lys residues at the putative reactive site (position 65). A glycosylation site was detected at Asn38 with 1188 kDa carbohydrate portion. The primary structure micro heterogeneity was found combining the sequence determination and mass spectrometry. Three forms of SWTI were actually defined: two glycosylated forms a 20,204 kDa (Arg 165) and 20,185 kDa (His 165) and one deglycosylated form 19,016 kDa (Arg 165), all of them contain a Met residue at position 130.     

Structure requirement and identification of a cryptic cleavage site in the mitochondrial processing of a plant F1-ATPase beta-subunit presequence

We sought to determine the structural features involved in the processing of the mitochondrial F1-ATPase beta-subunit (F1beta) presequence (54 residues) from Nicotiana plumbaginifolia. The cleavage efficiency of F1beta presequence mutants linked to the green fluorescent protein (GFP) was evaluated in vivo in tobacco by in situ microscopy and Western blotting. The residue at position -1 (Tyr) was required to be an aromatic residue and the residue at position +2 (Thr) was found to be important for F1beta processing, while, unexpectedly, changing the distal (Arg-15) and proximal (Arg-5) arginine residues did not strongly reduce processing. In addition, results also supported the requirement of a helical structure around the cleavage position. Sequencing of the mature form of a precursor containing the first 30 residues of the F1beta presequence linked to GFP revealed the presence of a cryptic cleavage site between residues 26 and 27, which showed the features of a classical mitochondrial processing site, suggesting dual processing of the F1beta presequence. In vitro processing confirmed these data and showed that processing was sensitive to o-phenanthroline, thus catalyzed by mitochondrial processing peptidase.     

Structural and functional analysis of human germ cell alkaline phosphatase by site-specific mutagenesis.

Human germ cell alkaline phosphatase (GCAP), which shares 98% amino acid sequence identity with the placental AP (PLAP), is expressed by malignant trophoblasts. Protein sequence analysis suggests that the Ser residue at position 92 is the putative active site of GCAP which contains two recognition sequences (Asn122-Thr-Thr124 and Asn249-Arg-Thr251) for asparagine-linked glycosylation. To examine the roles of the Ser residue and glycan moieties on GCAP activity and processing, we altered the GCAP cDNA by site-directed mutagenesis and expressed the GCAP mutants in COS-1 cells. Substitution of Ser-92 with either a Thr (S92T) or an Ala (S92A) residue yielded a GCAP devoid of catalytic activity, suggesting that the Ser codon 92 is the active site of GCAP. Six GCAP mutants that lack one or both glycosylation sites were constructed by substituting either Asn-122 or Asn-249 with an Asp residue or either Thr-124 or Thr-251 with an Ala residue. The mature GCAP migrated as a 65-kDa product, but GCAP mutants lacking one or both glycosylation sites migrated as 62- or 58-kDa polypeptides, respectively, indicating that both sites were glycosylated. All six glycosylated mutants were active enzymatically and, in addition, were equally sensitive to heat, L-leucine, and EDTA inhibition as the parental enzyme. GCAP as well as its two active-site and six glycosylation mutants could be released from the plasma membrane of transfected COS-1 cells by the proteinase bromelain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Correlation of glycosylation forms with position in amino acid sequence

We surveyed published reports on about 50 glycoproteins whose amino acid sequence, glycosylation sites, and type of glycosylation at a particular site have been established. We note that high-mannose substances were rarely found at the N-terminal side of a previously glycosylated complex site. There was a very definite distribution of complex sites about the N-terminal region. Furthermore, secreted glycoproteins usually contained only complex oligosaccharides whereas membrane proteins contained both types. We suggest that the position of the glycosylation site with respect to the N-terminus affects the extent of oligosaccharide processing and subsequent presentation of complex or high-mannose structures in the mature glycoprotein. This review relates glycosylation type to its position in the known sequence of given proteins and discusses these observations in light of known glycosylation processing reactions.     

N-linked glycans of the human insulin receptor and their distribution over the crystal structure

The human insulin receptor (IR) homodimer is heavily glycosylated and contains a total of 19 predicted N-linked glycosylation sites in each monomer. The recent crystal structure of the IR ectodomain shows electron density consistent with N-linked glycosylation at the majority of sites present in the construct. Here, we describe a refined structure of the IR ectodomain that incorporates all of the N-linked glycans and reveals the extent to which the attached glycans mask the surface of the IR dimer from interaction with antibodies or other potential therapeutic binding proteins. The usefulness of Fab complexation in the crystallization of heavily glycosylated proteins is also discussed. The compositions of the glycans on IR expressed in CHO-K1 cells and the glycosylation deficient Lec8 cell line were determined by protease digestion, glycopeptide purification, amino acid sequence analysis, and mass spectrometry. Collectively the data reveal: multiple species of complex glycan at residues 25, 255, 295, 418, 606, 624, 742, 755, and 893 (IR-B numbering); multiple species of high-mannose glycan at residues 111 and 514; a single species of complex glycan at residue 671; and a single species of high-mannose glycan at residue 215. Residue 16 exhibited a mixture of complex, hybrid, and high-mannose glycan species. Of the remaining five predicted N-linked sites, those at residues 397 and 906 were confirmed by amino acid sequencing to be glycosylated, while that at residue 78 and the atypical (NKC) site at residue 282 were not glycosylated. The peptide containing the final site at residue 337 was not recovered but is seen to be glycosylated in the electron density maps of the IR ectodomain. The model of the fully glycosylated IR reveals that the sites carrying high-mannose glycans lie at positions of relatively low steric accessibility.     

Rabbit secretory components of different allotypes vary in their carbohydrate content and their sites of N-linked glycosylation

The asparagine-linked glycosylation sites in rabbit high and low Mr secretory components (SC) have been determined for the three known allotypes, t61, t62, and t63. Purified SC polypeptides were subjected to mild periodate oxidation of terminal nonreducing sugars followed by selective reduction with [3H]sodium borohydride, SC polypeptides were further proteolytically cleaved, and the 3H-labeled peptides were isolated and characterized. Both high and low Mr SCs of the three allotypes possess a common glycosylation site at the asparagine residue position 400, whereas the second site, in the amino-terminal domain of SC, was found to be variable: the t61 and t63 allotypes contained a glycosylation site at positions 70 and 90, respectively. Moreover, although the t62 allotype was found to contain a triplet acceptor site (N-X-S) at positions 90-92, analyses showed that less than 30% of the t62 allotype peptides encompassing this region were glycosylated at residue 90. Furthermore, the amino acid sequence of the t61 SC in the region of residues 69-90 varies by 8 and 10 amino acid substitutions when compared with the t62 and t63 allotype sequences, respectively. However, neither the variation in amino acid sequence nor the variation in degree or site of glycosylation measurably affected the non-covalent binding of domain 1 to dimeric IgA.     

Experimental determination of proline hydroxylation and hydroxyproline arabinogalactosylation motifs in secretory proteins

Many secretory and several vacuolar proteins in higher plants contain hydroxylated proline residues. In many cases, hydroxyprolines in proteins are glycosylated with either arabinogalactan or oligoarabinose. We have previously shown that a sporamin precursor is O-glycosylated at the hydroxylated proline 36 residue with an arabinogalactan-type glycan when this protein is expressed in tobacco BY-2 cells (Matsuoka et al., 1995). Taking advantage of the fact that this is the only site of proline hydroxylation and glycosylation in sporamin, we analyzed the amino acid requirement for proline hydroxylation and arabinogalactosylation. We expressed several deletion constructs and many amino acid substitution mutants in tobacco cells and analyzed glycosylation and proline hydroxylation of the expressed sporamins. Hydroxylation of a proline residue requires the five amino acid sequence [AVSTG]-Pro-[AVSTGA]-[GAVPSTC]-[APS or acidic] (where Pro is the modification site) and glycosylation of hydroxyproline (Hyp) requires the seven amino acid sequence [not basic]-[not T]-[neither P, T, nor amide]-Hyp-[neither amide nor P]-[not amide]-[APST], although charged amino acids at the -2 position and basic amide residues at the +1 position relative to the modification site seem to inhibit the elongation of the arabinogalactan side chain. Based on the combination of these two requirements, we concluded that the sequence motif for efficient arabinogalactosylation, including the elongation of the glycan side chain, is [not basic]-[not T]-[AVSG]-Pro-[AVST]-[GAVPSTC]-[APS].     

Antibody variable region glycosylation: position effects on antigen binding and carbohydrate structure.

The presence of N-linked carbohydrate at Asn58 in the VH of the antigen binding site of an antibody specific for alpha(1----6)dextran (TKC3.2.2) increases its affinity for dextran 10- to 50-fold. Site-directed mutagenesis has now been used to create novel carbohydrate addition sequences in the CDR2 of a non-glycosylated anti-dextran at Asn54 (TST2) and Asn60 (TSU7). These antibodies are glycosylated and the carbohydrates are accessible for lectin binding. The amino acid change in TSU7 (Lys62----Thr62) decreases the affinity for antigen; however, glycosylation of TSU7 increased its affinity for antigen 3-fold, less than the greater than 10-fold increase in affinity seen for glycosylated TKC3.2.2. The difference in impact of glycosylation could result either from the position of the carbohydrate or from its structure; unlike the other antibodies, TSU7 attaches a high mannose, rather than complex, carbohydrate in CDR2. In contrast, glycosylation of TST2 at amino acid 54 inhibits dextran binding. Thus slight changes in the position of the N-linked carbohydrate in the CDR2 of this antibody result in substantially different effects on antigen binding. Unlike what was observed for the anti-dextrans, a carbohydrate addition site placed in a similar position in an anti-dansyl is not utilized.     

Structural and genetic characterization of glycosylation of type a flagellin in Pseudomonas aeruginosa

Type a flagellins from two strains of Pseudomonas aeruginosa, strains PAK and JJ692, were found to be glycosylated with unique glycan structures. In both cases, two sites of O-linked glycosylation were identified on each monomer, and these sites were localized to the central, surface-exposed domain of the monomer in the assembled filament. The PAK flagellin was modified with a heterogeneous glycan comprising up to 11 monosaccharide units that were O linked through a rhamnose residue to the protein backbone. The flagellin of JJ692 was less complex and had a single rhamnose substitution at each site. The role of the glycosylation island gene cluster in the production of each of these glycosyl moieties was investigated. These studies revealed that the orfA and orfN genes were required for attachment of the heterologous glycan and the proximal rhamnose residue, respectively.     

Peptide binding by protein disulfide isomerase, a resident protein of the endoplasmic reticulum lumen

Previously we had demonstrated by photoaffinity labeling that a 57-kDa protein of the endoplasmic reticulum can bind and become covalently linked to glycosylatable photoreactive peptides containing the sequence-Asn-Xaa-Ser/Thr-. Subsequently, it was found that this protein, called glycosylation site-binding protein, was a multifunctional protein, i.e. it was identical to protein disulfide isomerase (PDI), the beta-subunit of prolyl hydroxylase and thyroid hormone-binding protein. In this study, the peptide specificity for binding to this 57-kDa protein, hereafter called PDI, has been investigated in more detail using photoaffinity probes. The results reveal that although N-glycosylation by oligosaccharyl transferase in the endoplasmic reticulum has an absolute requirement for an hydroxyamino acid in the third amino acid residue of the glycosylation site sequence, no such specificity is observed in the binding of such peptides to PDI. In addition to the lack of specificity for an hydroxyamino acid in the third residue position, no specificity was observed for the asparagine residue in the first position. Thus, binding is not restricted to peptides containing N-glycosylation sites. We have investigated the discrepancy between this apparent lack of sequence specificity and earlier results indicating that binding of peptides to PDI was specific for N-glycosylation site sequences. We now demonstrate that PDI in the lumen of microsomes is more efficiently labeled by peptides containing photoreactive-Asn-Xaa-Ser/Thr- sequences than by nonacceptor site sequences because the former become glycosylated. This increased labeling does not occur because the glycosylated form of the probes are preferentially recognized by PDI. Rather, it appears that increased polarity of the affinity probe after attachment of the oligosaccharide chain prevents its exit from the sealed microsomes, in effect concentrating it within the lumen of the microsome. These results, coupled with other studies on the multifunctional nature of PDI, suggest that the observed peptide binding may be a manifestation of the ability of PDI to recognize the backbone of polypeptides in the lumen of the endoplasmic reticulum.     

Role for the P4 amino acid residue in substrate utilization by the poliovirus 3CD proteinase.

Amino acid insertions or substitutions were introduced into the poliovirus P1 capsid precursor at locations proximal to the two known Q-G cleavage sites to examine the role of the P4 residue in substrate processing by proteinase 3CD. Analysis of the processing profile of P1 precursors containing four-amino-acid insertions into the carboxy terminus of VP3 or a single-amino-acid substitution at the P4 position of the VP3-VP1 cleavage site demonstrates that substitution of the alanine residue in the P4 position of the VP3-VP1 cleavage site significantly affects cleavage at that site by proteinase 3CD. A single-amino-acid substitution at the P4 position of the VP0-VP3 cleavage site, on the other hand, has only a slight effect on 3CD-mediated processing at this cleavage site. Finally, analysis of six amino acid insertion mutations containing Q-G amino acid pairs demonstrates that the in vitro and in vivo selection of a cleavage site from two adjacent Q-G amino acid pairs depends on the presence of an alanine in the P4 position of the cleaved site. Our data provide genetic and biochemical evidence that the alanine residue in the P4 position of the VP3-VP1 cleavage site is a required substrate determinant for the recognition and cleavage of that site by proteinase 3CD and suggest that the P4 alanine residue may be specifically recognized by proteinase 3CD.     

Conformation analysis of the N-glycosylation site Asn-X-Thr/Ser in glycoproteins

Theoretical conformational analysis of oligopeptides CH3CO-Asn-X-Thr-NHCH3 (X = Gly, Ala, Pro), modelling N-glycosylation site, and their glycosylated derivatives CH3CO-(GlcNAc beta 1-4GlcNAc beta 1) Asn-X-Thr-NHCH3 has been carried out. Active conformations of the site are found, corresponding to structural prerequisities of N-glycosylation: Asn residue's position in beta-turn and hydrogen bond formation between side chains of Asn and Thr/Ser residues. In this case the L conformation of the central residue X is most probable. Since Pro residue does not possess this conformation, sequences with X = Pro are not glycosylated. It is shown that glycosylation of the above-mentioned sites is accompanied by reorientation of the Asn residue's side chains.     

Heterogeneous glycosylation of murine transferrin receptor subunits

The N-linked glycosylation of the murine receptor for transferrin has been investigated. Previously we have found that purified receptors appear as two bands after sodium dodecyl sulfate/polyacrylamide gel electrophoresis and Coomassie blue staining [van Driel, I.R., Stearne, P.A., Grego, B., Simpson, R.J. and Goding, J.W. (1984) J. Immunol. 133, 3220-3224]. In the current report we show that the two bands are due to different glycosylation of individual receptor molecules. The receptors have three asparagines to which N-linked glycans can be added, but only two sites are glycosylated in all receptors. The level of glycosylation of the third site varies depending on cell line or tissue. Limited endoglycosidase digestion of mature receptors indicates that differential glycosylation probably occurs at only one particular asparagine residue. Possible mechanisms that could result in such a glycosylation pattern are discussed.     

Analysis of recognition elements for mitochondrial processing peptidase using artificial amino acids: roles of the intervening portion and proximal arginine.

We recently demonstrated, using synthetic peptides modeled on the extension peptide of malate dehydrogenase, that amino acid residues present at the proximal and distal positions relative to the cleavage site are critical determinants for the recognition of substrates by mitochondrial processing peptidase [Niidome et al. (1994) J. Biol. Chem. 269, 24719-24722). While the proximal arginine is unexceptionally located at the -2 position, the position of the distal residue varies among mitochondrial precursor proteins. Between the proximal and distal residues, proline and/or glycine are present in most mitochondrial precursor proteins, and they are considered to play a role in the specific recognition of a substrate by the peptidase. To elucidate the role of the intervening portion, we introduced a non-natural amino acid [2-(2-aminoethoxy)acetic acid] between the distal and proximal residues. We also analyzed the functional elements in the proximal arginine by replacing the residue with various arginine or lysine analogs. The results of kinetic studies indicated that the intervening portion should be flexible for efficient processing, and that the guanidino group of the proximal arginine is recognized by the peptidase through hydrogen and ionic bonds.     

Characterization of a single glycosylated asparagine site on a glycopeptide using solid-phase Edman degradation

The characterization of site-specific glycosylation is traditionally dependent on the availability of suitable proteolytic cleavage sites between each glycosylated residue, so that peptides containing individual glycosylation sites are recovered. In the case of heavily glycosylated domains such as theO-glycosylated mucins, which have no available protease sites, this approach is not possible. Here we introduce a new method to gain site-specific compositional data on the oligosaccharides attached to a single amino acid. Using a model glycopeptide from a mutant human albumin Casebrook, glycosylated PTH-Asn was recovered after sequential solid-phase Edman degradation, subjected to acid hydrolysis and the sugars were identified by high performance anion exchange chromatography with pulsed amperometric detection. The PTH-Asn(Sac) derivative was further characterized by ionspray mass spectrometry. Comparison between an endoproteinase Glu-C glycopeptide and a tryptic glycopeptide showed that the oligosaccharide attached to Asn494 was stable after at least 10 cycles of Edman degradation.     

Structural requirements of N-glycosylation of proteins. Studies with proline peptides as conformational probes

Conformational aspects of N-glycosylation have been investigated with a series of proline-containing peptides as molecular probes. The results demonstrate that, depending on the position of the imino acid in the peptide chain, dramatic alterations of glycosylation rates are produced, pointing to a critical contribution of the amino acids framing the 'marker sequence' triplet Asn-Xaa-Thr(Ser) on the formation of a potential sugar-attachment site. No glycosyl transfer at all was detectable to those peptides containing a proline residue either in position Xaa or in the next position beyond the threonine of the Asn-sequon on the C-terminal side, whereas the hexapeptide Pro-Asn-Gly-Thr-Ala-Val was glycosylated at a high rate. (Emboldened residues denote the 'marker sequence' that is identical in all the peptides; italicized residues distinguish the positions of proline in the various peptides.) Studies with space-filling models reveal that the lack of glycosyl-acceptor capabilities of Ala(Pro)-Asn-Gly-Thr-Pro-Val might be directly related to their inability to adopt and/or stabilize a turn or loop conformation which permits the catalytically essential interaction between the hydroxy amino acid and the asparagine residue within the 'marker sequence' [Bause & Legler (1981) Biochem. J. 195, 639-644]. This conclusion is supported by circular-dichroism spectroscopic data, which suggest structure-forming potentials in this type of non-acceptor peptides dominating over those that favour the induction of an appropriate sugar-attachment site in the acceptor peptides. The lack of acceptor properties of Tyr-Asn-Pro-Thr-Ser-Val indicates that even small modifications in the 'recognition' pattern are not tolerated by the N-glycosyltransferases.     

Characterization of recombinant murine interleukin 5 expressed in Chinese hamster ovary cells.

We have purified recombinant murine interleukin 5 (rmIL-5) from the supernatant of Chinese hamster ovary cells. Each peptide fragment of the purified rmIL-5 generated by Achromobacter protease I digestion was characterized and glycosylation sites were determined. Although rmIL-5 contains three potential sites of N-linked glycosylation (Asn-26, Asn-55 and Asn-69), Asn-69 is not glycosylated. The oligosaccharides released from the protein by hydrazinolysis were fractionated by paper electrophoresis, lectin column chromatography and gel permeation chromatography, and their structures were analysed by sequential exoglycosidase digestion in combination with methylation analysis. The results indicated that they are a mixture of bi-, tri- and tetraantennary complex-type sugar chains with and without a fucose at the C-6 position of the proximal N-acetylglucosamine residue and high-mannose-type sugar chains. Although > 80% of the sugar chains are neutral oligosaccharides similar to recombinant human IL-5 (rhIL-5; Kodama, S., Endo, T., Tsuroka, N., Tsujimoto, M. and Kobata, A. (1991) J. Biochem., 110, 693-701), rmIL-5 has more tetraantennary oligosaccharides than rhIL-5. A site differential study revealed that Asn-55 has more tetraantennary oligosaccharides than Asn-26.     

A potyvirus vector efficiently targets recombinant proteins to chloroplasts,mitochondria and nuclei in plant cells when expressed at the amino terminus of the polyprotein

Plant virus‐based expression systems allow quick and efficient production of recombinant proteins in plant biofactories. Among them, a system derived from tobacco etch virus (TEV; genus potyvirus) permits coexpression of equimolar amounts of several recombinant proteins. This work analyzed how to target recombinant proteins to different subcellular localizations in the plant cell using this system. We constructed TEV clones in which green fluorescent protein (GFP), with a chloroplast transit peptide (cTP), a nuclear localization signal (NLS) or a mitochondrial targeting peptide (mTP) was expressed either as the most amino‐terminal product or embedded in the viral polyprotein. Results showed that cTP and mTP mediated efficient translocation of GFP to the corresponding organelle only when present at the amino terminus of the viral polyprotein. In contrast, the NLS worked efficiently at both positions. Viruses expressing GFP in the amino terminus of the viral polyprotein produced milder symptoms. Untagged GFPs and cTP and NLS tagged amino‐terminal GFPs accumulated to higher amounts in infected tissues. Finally, viral progeny from clones with internal GFPs maintained the extra gene better. These observations will help in the design of potyvirus‐based vectors able to coexpress several proteins while targeting different subcellular localizations, as required in plant metabolic engineering.     

A new strategy for identification of N-glycosylated proteins and unambiguous assignment of their glycosylation sites using HILIC enrichment and partial deglycosylation

Characterization of glycoproteins using mass spectrometry ranges from determination of carbohydrate-protein linkages to the full characterization of all glycan structures attached to each glycosylation site. In a novel approach to identify N-glycosylation sites in complex biological samples, we performed an enrichment of glycosylated peptides through hydrophilic interaction liquid chromatography (HILIC) followed by partial deglycosylation using a combination of endo-beta-N-acetylglucosaminidases (EC 3.2.1.96). After hydrolysis with these enzymes, a single N-acetylglucosamine (GlcNAc) residue remains linked to the asparagine residue. The removal of the major part of the glycan simplifies the MS/MS fragment ion spectra of glycopeptides, while the remaining GlcNAc residue enables unambiguous assignment of the glycosylation site together with the amino acid sequence. We first tested our approach on a mixture of known glycoproteins, and subsequently the method was applied to samples of human plasma obtained by lectin chromatography followed by 1D gel-electrophoresis for determination of 62 glycosylation sites in 37 glycoproteins.     

文昌鱼GFP基因的鉴定及表达分析

近年在隶属头索动物亚门的文昌鱼体内发现有内源性绿色荧光蛋白存在,并发现文昌鱼荧光蛋白的发光现象在不同发育时期以及个体间有较大的差异。为了进一步揭示GFP基因在文昌鱼中的进化模式,探索其可能执行的功能,该文首先对白氏文昌鱼(Branchiostoma belcheri)GFP基因作了全面鉴定,并对其不同发育阶段胚胎及成体不同区域中的荧光信号进行了实时观察记录,进而对GFP基因在绿色荧光表达强烈的两个特定时期做了绝对定量检测。研究结果表明,文昌鱼基因组中至少有12个内源性GFP基因,在个体发育的不同时期,内源性荧光出现的位置有所变化,而且在变态后的个体之间出现荧光的情况差异较大,荧光蛋白基因的表达由多个GFP同源基因共同参与,这些基因在不同的发育时期表达量有较大的差异,提示不同的GFP基因在特定发育阶段可能行使各自的功能。