Effect of N-linked glycosylation on the aspartic proteinase porcine pepsin expressed from Pichia pastoris

A study was undertaken to examine the effects of N-linked glycosylation on the structure-function of porcine pepsin. The N-linked motif was incorporated into four sites (two on the N-terminal domain and two on the C-terminal domain), and the recombinant protein expressed using Pichia pastoris. All four N-linked recombinants exhibited similar secondary and tertiary structure to nonglycosylated pepsin, that is, wild type. Similar K(m) values were observed, but catalytic efficiencies were approximately one-third for all mutants compared with the wild type; however, substrate specificity was not altered. Activation of pepsinogen to pepsin occurred between pH 1.0 to 4.0 for wild-type pepsin, whereas the glycosylated recombinants activated over a wider range, pH 1.0 to 6.0. Glycosylation on the C-terminal domain exhibited similar pH activity profiles to nonglycosylated pepsin, and glycosylation on the N-domain resulted in a change in activity profile. Overall, glycosylation on the C-domain led to a more global stabilization of the structure, which translated into enzymatic stability, whereas on the N-domain, an increase in structural stability had little effect on enzymatic stability. Finally, glycosylation on the flexible loop region also appeared to increase the overall structural stability of the protein compared with wild type. It is postulated that the presence of the carbohydrate residues added rigidity to the protein structure by reducing conformational mobility of the protein, thereby increasing the structural stability of the protein.     

The three typical aspartic proteinase genes of Arabidopsis thaliana are differentially expressed.

Genomic sequencing has identified three different typical plant aspartic proteinases in the genome of Arabidopsis thaliana, named Pasp-A1, A2 and A3. A1 is identical to a cDNA we had previously isolated and the two others produce proteins 81 and 63% identical to that predicted protein. Sequencing of the aspartic proteinase protein purified from Arabidopsis seeds showed that the peptides are derived from two of these genes, A1 and A2. Using gene specific probes, we have analyzed RNA from different tissues and found these three genes are differentially expressed. A1 mRNA is detected in all tissues analyzed and more abundant in leaves during the light phase of growth. The other two genes are expressed either primarily in flowers (A3) or in seeds (A2). Insitu hybridization demonstrated that all three genes are expressed in many cells of the seeds and developing seed pods. The A1 and A3 genes are expressed in the sepals and petals of flowers as well as the outer layer of the style, but are not expressed in the transmitting tract or on the stigmatal surface. The A2 gene is weakly expressed only in the transmitting tissue of the style. All three genes are also expressed in the guard cells of sepals. These data suggest multiple roles for aspartic proteinases besides those proposed in seeds.     

IL-22 is expressed by the invasive trophoblast of the equine (Equus caballus) chorionic girdle

The invasive trophoblast cells of the equine placenta migrate into the endometrium to form endometrial cups, dense accumulations of trophoblast cells that produce equine chorionic gonadotropin between days 40 and 120 of normal pregnancy. The mechanisms by which the trophoblast cells invade the endometrium while evading maternal immune destruction are poorly defined. A gene expression microarray analysis performed on placental tissues obtained at day 34 of gestation revealed a >900-fold upregulation of mRNA encoding the cytokine IL-22 in chorionic girdle relative to noninvasive chorion. Quantitative RT-PCR assays were used to verify high expression of IL-22 in chorionic girdle. Additional quantitative RT-PCR analysis showed a striking increase in IL-22 mRNA expression in chorionic girdle from days 32 to 35 and an absence of IL-22 expression in other conceptus tissues. Bioinformatic analysis and cDNA sequencing confirmed the predicted length of horse IL-22, which carries a 3' extension absent in IL-22 genes of humans and mice, but present in the cow and pig. Our discovery of IL-22 in the chorionic girdle is a novel finding, as this cytokine has been previously reported in immune cells only. IL-22 has immunoregulatory functions, with primary action on epithelial cells. mRNA of IL-22R1 was detected in pregnant endometrium at levels similar to other equine epithelia. Based upon these findings, we hypothesize that IL-22 cytokine produced by the chorionic girdle binds IL-22R1 on endometrium, serving as a mechanism of fetal-maternal communication by modulating endometrial responses to trophoblast invasion.     

Identification of twelve O-glycosylation sites in equine chorionic gonadotropin beta and equine luteinizing hormone ss by solid-phase Edman degradation

The O-glycosylation sites for equine LHss (eLHss) and eCGss were identified by solid-phase Edman degradation of four glycopeptides derived from the C-terminal region. Both subunits were O-glycosylated at the same 12 positions, rather than the 4-6 sites anticipated. These sites were partially glycosylated, with carbohydrate attachment ranging from 20% to 100% for eCGss and from 10% to 100% for eLHss. When the C-terminal peptide containing all but one of the O-linked oligosaccharides was removed by mild acid hydrolysis of either eLHss or eCGss, hybrid hormones could be obtained by reassociating eLHalpha,eFSHalpha, or eCGalpha with the truncated ss subunit derivatives. These hybrid hormones were identical in LH receptor-binding activity when des(121-149)eLHss or des(121-149)eCGss were combined with the same alpha subunit preparation. Thus, O-glycosylation appears to be responsible for the ss subunit contribution to the substantial difference in LH receptor-binding activity between eLH and eCG. Comparison of the equid LH/CGss sequences with those available for the primate CGss subunits indicated a greater conservation of glycosylation patterns in the former.     

Inhibition of the aspartic proteinase from HIV-2

Kinetic constants were determined for the interaction of the HIV-2 aspartic proteinase with a synthetic substrate and a number of inhibitors at several pH values. Acetyl-pepstatin was more effective towards HIV-2 proteinase than the renin inhibitor, H-261; this effect is exactly the opposite from that observed previously for the proteinase from the HIV-1 AIDS virus.     

Stereochemical analysis of peptide bond hydrolysis catalyzed by the aspartic proteinase penicillopepsin

The X-ray crystal structures of native penicillopepsin and of its complex with a synthetic analogue of the inhibitor pepstatin have been refined recently at 1.8-A resolution. These highly refined structures permit a detailed examination of peptide hydrolysis in the aspartic proteinases. Complexes of penicillopepsin with substrate and catalytic intermediates were modeled, by using computer graphics, with minimal perturbation of the observed inhibitor complex. A thallium ion binding experiment shows that the position of solvent molecule O39, between Asp-33(32) and Asp-213(215) in the native structure, is favorable for cations, a fact that places constraints on possible mechanisms. A mechanism for hydrolysis is proposed in which Asp-213(215) acts as an electrophile by protonating the carbonyl oxygen of the substrate, thereby polarizing the carbon-oxygen bond, a water molecule bound to Asp-33(32) (O284 in the native structure) attacks the carbonyl carbon as the nucleophile in a general-base mechanism, the newly pyramidal peptide nitrogen is protonated, either from the solvent after nitrogen inversion or by an internal proton transfer via Asp-213(215) from a hydroxyl of the tetrahedral carbon, and the tetrahedral intermediate breaks down in a manner consistent with the stereoelectronic hypothesis. The models permit the rationalization of observed subsite preferences for substrates and may be useful in predicting subsite preferences of other aspartic proteinases.     

Phytepsin, a barley vacuolar aspartic proteinase, is highly expressed during autolysis of developing tracheary elements and sieve cells

Vacuolarisation, formation of autophagocytotic vacuoles and tonoplast disruption have been reported in plant cells undergoing developmentally regulated programmed cell death (PCD), but little is known about the vacuolar proteins involved. In HeLa cells, cathepsin D, a lysosomal aspartic proteinase has been shown to mediate PCD. Based on immunohistochemical staining of barley roots, we show here that the previously well characterised barley vacuolar aspartic proteinase (phytepsin), a plant homologue to cathepsin D, is highly expressed both during formation of tracheary elements and during partial autolysis of sieve cells. In serial transverse sections of the vascular cylinder, starting from the root tip, phytepsin is expressed in root cap cells, in the tracheary elements of early and late metaxylem, and in the sieve cells of the protophloem and metaphloem. Aleurain, a barley vacuolar cysteine proteinase, is expressed similarly in root cap cells but differently in the tracheary elements of protoxylem and early metaxylem. This is the first evidence that a vacuolar aspartic proteinase, in analogy to cathepsin D in animals, may play a role in the active autolysis of plant cells.     

Activity and inhibition of plasmepsin IV, a new aspartic proteinase from the malaria parasite, Plasmodium falciparum

A new aspartic proteinase from the human malaria parasite Plasmodium falciparum is able to hydrolyse human haemoglobin at a site known to be the essential primary cleavage site in the haemoglobin degradation pathway. Thus, plasmepsin IV may play a crucial role in this critical process which yields nutrients for parasite growth. Furthermore, synthetic inhibitors known to inhibit parasite growth in red cells in culture are able to inhibit the activity of this enzyme in vitro. As a result, plasmepsin IV appears to be a potential target for the development of new antiparasitic drugs.     

cDNA cloning of an aspartic proteinase secreted by Candida albicans.

cDNA of an aspartic proteinase secreted by Candida albicans No. 114 was isolated using the polymerase chain reaction (PCR). The primary structure of the enzyme was deduced from the nucleotide sequence of the cDNA and compared with the structures of Saccharomyces cerevisiae proteinase A and vacuolar aspartyl proteinase of C. albicans. The mature aspartic proteinase consisted of 341 amino acid residues, and was 17.6 and 15.3% identical with the proteinase A and the aspartyl proteinase, respectively. Two active aspartic acid sites and the amino acids near those sites were conserved in the aspartic proteinase. We also showed that there is another gene of aspartic proteinase than that of strain ATCC10231 reported by Hube et al (J. Med. Vet. Mycol. 29 (1991)) in the same C. albicans genome, both in that strain and in No. 114.     

Demonstration of a COOH-terminal extension on equine lutropin by means of a common acid-labile bond in equine lutropin and equine chorionic gonadotropin

The beta subunits of equine lutropin and equine chorionic gonadotropin were incubated in 0.013 N HCl for 30 min at 110 degrees C and separated into two fragments by reverse-phase high performance liquid chromatography. The amino acid and carbohydrate compositions of both fragments from each subunit were analyzed. The results demonstrated that equine lutropin-beta has a glycosylated COOH-terminal extension that differs only in carbohydrate composition from the COOH-terminal portion of equine chorionic gonadotropin-beta. This is the first demonstration of a glycosylated COOH-terminal extension in a pituitary glycoprotein hormone.     

Identification by mass spectrometry of a new alpha-tubulin isotype expressed in human breast and lung carcinoma cell lines

The extensive C-terminal molecular heterogeneity of alpha- and beta-tubulin is a consequence of multiple isotypes, the products of distinct genes, that undergo several posttranslational modifications. These include polyglutamylation and polyglycylation of both subunits, reversible tyrosination and removal of the penultimate glutamate from alpha-tubulin, and phosphorylation of the beta III isotype. A mass spectrometry-based method has been developed for the analysis of the C-terminal diversity of tubulin from human cell lines. Total cell extracts are resolved by SDS--PAGE and transferred to nitrocellulose, and the region of the blot corresponding to tubulin (approximately 50 kDa) was excised and digested with CNBr to release the highly divergent C-terminal tubulin fragments. The masses of the human alpha- and beta-tubulin CNBr-derived C-terminal peptides are all in the 1500--4000 Da mass range and can be analyzed directly by MALDI-TOF mass spectrometry in the negative ion mode without significant interference from other released peptides. In this study, the tubulin isotype diversity in MDA-MB-231, a human breast carcinoma cell line, and A549, a human non-small lung cancer cell line, is reported. The major tubulin isotypes present in both cell lines are k-alpha 1 and beta 1. Importantly, we report a previously unknown alpha isotype present at significant levels in both cell lines. Moreover, the degree of posttranslational modifications to all isotypes was limited. Glu-tubulin, in which the C-terminal tyrosine of alpha-tubulin is removed, was not detected. In contrast to mammalian neuronal tubulin which exhibits extensive polyglutamylation, only low-level monoglutamylation of the k-alpha 1 and beta 1 isotypes was observed in these two human cell lines.     

Cleavage of human big endothelin-1 by Candida albicans aspartic proteinase

Abstract A Candida albicans aspartic proteinase (CAP), one of the secretory proteinases of Candida albicans , is thought to be a possible virulence factor in Candida albicans infection. Whereas endothelin-1 is found as an endothelium-derived strong vasoconstrictive peptide, it is known to have a role in the maintenance of vascular homeostasis and tissue survival. Endothelin-1 is generated from a precursor form of endothelin-1, the so-called big endothelin-1. It has recently been reported that cathepsin D, E and pepsin, which are aspartic proteinases, convert big endothelin-1 to endothelin-1. In this study, the relationship between CAP and big endothelin-1 was studied. High performance liquid chromatography analysis revealed that big endothelin-1 was cleaved into several amino acid sites by CAP, but endothelin-1 was not converted from big endothelin-1. CAP cleaved big endothelin-1 at different sites when compared with that of other known aspartic proteinases, and it suppressed endothelin-1 production through the degradation of big endothelin-1. CAP may break homeostatic mechanism of endothelin-1 in Candida albicans infectious lesion.     

Chlapsin, a chloroplastidial aspartic proteinase from the green algae Chlamydomonas reinhardtii

Aspartic proteinases have been extensively characterized in land plants but up to now no evidences for their presence in green algae group have yet been reported in literature. Here we report on the identification of the first (and only) typical aspartic proteinase from Chlamydomonas reinhardtii. This enzyme, named chlapsin, was shown to maintain the primary structure organization of typical plant aspartic proteinases but comprising distinct features, such as similar catalytic motifs DTG/DTG resembling those from animal and microbial counterparts, and an unprecedentedly longer plant specific insert domain with an extra segment of 80 amino acids, rich in alanine residues. Our results also demonstrated that chlapsin accumulates in Chlamydomonas chloroplast bringing this new enzyme to a level of uniqueness among typical plant aspartic proteinases. Chlapsin was successfully expressed in Escherichia coli and it displayed the characteristic enzymatic properties of typical aspartic proteinases, like optimum activity at acidic pH and complete inhibition by pepstatin A. Another difference to plant aspartic proteinases emerged as chlapsin was produced in an active form without its putative prosegment domain. Moreover, recombinant chlapsin showed a restricted enzymatic specificity and a proteolytic activity influenced by the presence of redox agents and nucleotides, further differentiating it from typical plant aspartic proteinases and anticipating a more specialized/regulated function for this Chlamydomonas enzyme. Taken together, our results revealed a pattern of complexity for typical plant aspartic proteinases in what concerns sequence features, localization and biochemical properties, raising new questions on the evolution and function of this vast group of plant enzymes.     

Atypical Kunitz-type serine proteinase inhibitors produced by the ruminant placenta

Recently, an unusual family of genes was identified with expression confined to the trophoblast of ruminant ungulate species. The members of this family (the trophoblast Kunitz domain proteins, or TKDPs) are characterized by the presence of one or more similar, approximately 80-residue repeat sequences placed ahead of a Kunitz serine proteinase-inhibitor domain. To examine the specificity of the Kunitz moiety, the Kunitz domains of selected TKDPs and a control Kunitz protein, bovine pancreatic trypsin inhibitor (BPTI), were produced as glutathione S-transferase fusions, and their abilities to inhibit six serine proteinases were examined. Circular dichroism spectroscopy confirmed that the Kunitz fold was intact. Three of the TKDPs had unusual residues at their P1 "warhead" (ovine TKDP-1, Asn; bovine TKDP-3, Thr; and bovine TKDP-5, Ile) and exhibited no measurable inhibitory activity toward any of the proteinases. Three (ovine TKDP-3, bovine TKDP-3, and bovine TKDP-4) lacked the conserved cysteines at residues 14 and 38 that form one of the highly conserved disulfide bonds that are structurally important in all known mammalian Kunitz proteins. Ovine TKDP-3 and bovine TKDP-4 had P1 lysines and inhibited trypsin and plasmin with K(i) values only approximately 10-fold higher than that of BPTI. Bovine TKDP-2 had a P1 lysine and the three conserved disulfides, but it possessed an unusual residue (Asp) at P2. It exhibited no inhibitory activity. These data suggest that the function of the TKDP, like certain Kunitz proteins found in snake venoms, may not be in proteinase inhibition.     

Some new findings about Hofbauer cells in the chorionic villi of the human placenta

The cytological structure of the Hofbauer cells was investigated in human placentas of the first and second trimesters of gestation. These cells are found in the stromal channel system of the chorionic villi core. Their walls, which are supported by collagen fiber bundles, are produced by reticulum cells and fibroblasts. The cytoplasmic processes of the Hofbauer cells are in contact with the walls of the channels without being associated with them by desmosomal complexes. Some of these cells have features in common with macrophages, such as cytoplasmic processes, larger vacuoles, many pinocytotic vesicles and intracytoplasmic granules. This system of vacuoles and vesicles enables micropinocytotic activity and phagocytosis. This type of Hofbauer cell resembles the typical macrophages. These cells may play a role in the regulation of stromal water content, transportation of ions and the flow of interstitial fluid. The most original finding of this study are long tubes observed in some Hofbauer cells and extending between the nucleus and the extracellular ground substance through the cytoplasm. One of these tubular formations resembles a cilium in structure with three limiting membranes and is filled with a slightly electron-dense substance. This type of Hofbauer cell may transport information between the nucleus and the extracellular ground substance by means of these tubular structures.