The molecular interaction of human salivary histatins with polyphenolic compounds

Dietary tannins are polyphenols that are effectively precipitated by salivary histatins (Hsts), a novel family of tannin binding proteins. Epigallocatechin gallate (EGCG), a flavan-3-ol ester related to condensed tannins (polymerized products of flavan-3-ols), and pentagalloyl glucose (PGG), a hydrolyzable tannin, were used to evaluate the molecular nature of Hst-polyphenol interaction. NMR demonstrated that Hst5, a representative Hst, bound to EGCG in a hydrophobic manner via basic and aromatic residues. In contrast, proline plays a dominant role in polyphenol binding to other tannin precipitating proteins. The role of basic and aromatic amino acids in EGCG binding was investigated using a series of modified Hsts in each of which one type of amino acid was substituted by Ala. EGCG bound to all modified Hsts, but the binding was diminished. Optimal EGCG binding also depended on the primary structure, as a polypeptide with randomised Hst5 sequence showed significantly diminished interaction with EGCG. Soluble EGCG/Hst5 complexes containing up to seven molecules of EGCG per mol of Hst5 had a 1-mM dissociation constant. In contrast to EGCG, PGG formed small soluble complexes with Hst5 consisting of only one molecule each of PGG and Hst5, as demonstrated by analytical ultracentrifugation. These complexes became insoluble upon binding of additional molecules of PGG. Diminished PGG binding was seen to a peptide with a Hst5 randomized sequence showing the importance of the primary structure. Hsts may serve to form insoluble complexes with tannins thereby preventing their absorption from the intestines and potentially harmful biological effects. In contrast the much weaker interaction with EGCG may allow its uptake into the organism and exploitation of its antioxidant effect.

Proteolytic processing of a human salivary proline-rich protein precursor by proprotein convertases

Salivary proline-rich proteins (PRPs) are synthesized as precursors that are cleaved before secretion giving rise to glycosylated PRPs which have lubricating function and basic PRPs which are potent precipitators of dietary tannins. The putative cleavage sites in the precursors for basic and glycosylated PRPs all conform to the sequence RSXR downward arrowS (X can be A, S or P) in agreement with the recognition sequence (RXXR downward arrow) for various proprotein convertases. PRB4S, a proprotein giving rise to a basic PRP (IB-5) as well as a glycosylated PRP (II-1) was synthesized by in vitro transcription-translation. It was cleaved by furin at RSAR downward arrowS(173-178) giving rise to two proteins II-1 and IB-5. Similarly another precursor with the sequence RSAR downward arrowS(173-178) was also cleaved by furin. This together with previous results show that in vitro furin can cleave all RSXR downward arrowS sequences in the proproteins that give rise to glycosylated and basic PRPs. To demonstrate cellular cleavage, a human submandibular cell line (HSG) was transfected with a vector encoding PRB4S. This resulted in secretion of II-1 and IB-5. The degree of cleavage was enhanced by coexpressing furin and PRB4S. No cleavage occurred if the cells expressed a mutant PRB4S, R177Q, where the furin cleavage site had been destroyed. Cleavage was also inhibited if a furin inhibitor was coexpressed with PRB4S. Incubating the cells at 20 degrees C which blocks exit of proteins from the trans-Golgi network demonstrated that cleavage occurs before exit of the proteins from this network. These results show that furin may be responsible for in vivo cleavage of PRP precursors. Transfecting furin-deficient RPE.40 cells with a vector encoding PRB4S also led to secretion of II-1 and IB-5 showing that convertases other than furin can also cleave PRB4S in tissue culture.

Cellular phosphorylation of an acidic proline-rich protein, PRP1, a secreted salivary phosphoprotein

Phosphorylation of many secreted salivary proteins is necessary for their biological functions. Identification of the kinase, which is responsible for in vivo phosphorylation, is complicated, because several of the protein phosphorylation sites conform both to the recognition sequence of casein kinase 2 (CK2) and Golgi kinase (G-CK), which both are found in the secretory pathway. This study was undertaken to determine the kinase recognition sequence in a secreted proline-rich salivary protein, PRP1, and thereby identify the responsible kinase. This was done by transfecting a human submandibular cell line, HSG, and a kidney cell line, HEK293, with expression vectors encoding wild-type or mutated PRP1. It was shown that phosphorylation occurred only at the same sites, Ser8 and 22, as in PRP1 purified from saliva. Phosphorylation at either site did not depend on the other site being phosphorylated. The sequence surrounding Ser8 has characteristics of both CK2 and G-CK recognition sequences, but destruction of the CK2 recognition site had no effect on phosphorylation, whereas no phosphorylation occurred if the G-CK recognition sequence was altered. The sequence surrounding Ser22 did not conform to any known kinase recognition sites. If Ser22 was mutated to Thr, no phosphorylation was seen, and a cluster of negatively charged residues at positions 27-29 was identified as part of the enzyme recognition site. Ser22 may be phosphorylated by a G-CK that recognizes an atypical substrate sequence or by a novel kinase. No difference in phosphorylation was seen between undifferentiated and differentiated HSG cells.

Interaction of tannin with human salivary histatins

The ability of all major human salivary histatins to precipitate condensed tannin was demonstrated, and it was found that histatins 3 and 5 share the same condensed tannin-binding region but less tannin bound to histatin 1. The condensed tannin-binding region of histatin 5 includes both the N- and the C-terminal parts, although more tannin binding occurs in the C-terminal region. Epigallocatechin gallate (EGCG) showed similar binding characteristics as condensed tannin, but much less EGCG was precipitated. Pentagalloyl glucose (PGG) was precipitated equally well by histatins 1, 3, and 5 and bound equally well to the N- and C-terminal regions of histatin 5. In contrast to condensed tannin, cleaving histatin 5 into N- and C-terminal fragments increased their ability to precipitate PGG. Together, these results show a number of differences in the nature of interaction of histatins with condensed tannin, EGCG, and PGG. Most of the condensed tannin-protein complexes remained insoluble under conditions similar to those in the stomach and the small intestine, suggesting that histatins may act as a defense against dietary tannin in humans.

Encoding of human basic and glycosylated proline-rich proteins by the PRB gene complex and proteolytic processing of their precursor proteins

Proline-rich proteins (PRPs) constitute a family of about 20 members in human saliva that are encoded by six genes. Assignment of genomic DNA coding regions is complicated because of the occurrence of many alleles and the great similarity of amino acid sequences of PRPs. To overcome these problems, the nucleotide sequences of the genes encoding basic and glycosylated PRPs from one person were determined and then aligned with her previously determined protein sequences. This, together with additional protein data, has also resolved various discrepancies between corresponding protein and DNA sequences. For the first time in one person it is now possible to account for all the regions in the PRB genes encoding basic and glycosylated PRPs, and the primary structures of all secreted basic and glycosylated PRPs have been determined. Each gene encodes a precursor protein that subsequently undergoes proteolytic cleavage, thereby giving rise to the secreted proteins. The results have allowed identification of all the proteolytic cleavage sites in the precursor proteins, which all conform to a consensus cleavage site for furin. To evaluate if furin is responsible for the precursor protein cleavages, a recombinant precursor protein was synthesized by in vitro transcription translation of a PRB1 allele. The protein was shown to be correctly cleaved by furin, giving rise to the expected secreted proteins.

Interaction of tannin with human salivary proline-rich proteins

Tannins are polyphenolic compounds, widely distributed in plant-based foods, which have harmful effects on animals including humans. Salivary proline-rich proteins (PRPs) may act as a defence against tannins by forming complexes with them and thereby preventing their interaction with other biological compounds and absorption from the intestinal canal. The aim here was to compare the ability of members of the family of human PRPs to form insoluble complexes with tannin and to assess the stability of such complexes under conditions similar to those in the alimentary tract. Basic PRPs (BPRPs), which have no other known biological functions, were very effective in forming insoluble complexes with both condensed tannin and tannic acid. Practically no tannin bound to acidic PRPs (APRPs) and glycosylated PRPs (GPRPs), suggesting that tannin in the diet would not affect their biological activities. There were only small differences in the tannin-precipitating ability of various BPRPs of different sizes or sequences, indicating that, although there is considerable phenotypic variation of PRPs, it is not likely to cause marked individual variation in tannin-binding ability. Tryptic digestion of an APRP led to a marked increase in tannin binding to the resulting proline-rich peptides, supporting observations in other studies that there may be an interaction between the proline-poor N-terminal and the proline-rich C-terminal regions in native APRPs, which inhibits the biological activities of the proteins. Deglycosylation of a GPRP also led to a dramatic increase in tannin-binding ability, showing that the carbohydrate side-chains prevent binding of tannin. Most of the condensed tannin-PRP complexes remained insoluble under conditions similar to those in the stomach and small intestine, supporting the proposal that PRPs act as a defence against tannin.

Characterization of human sublingual-gland protein kinase by phosphorylation of a peptide related to secreted proteins

Phosphoproteins in human saliva include proline-rich proteins, statherins, histatin 1 and cystatin SA-III. The presence of phosphate in these proteins is necessary for various functions in the mouth including calcium binding, inhibition of precipitation of calcium phosphate, inhibition of growth of hydroxyapatite crystals and adherence to hydroxyapatite. To elucidate the process of phosphorylation of these proteins, the phosphorylation of a peptide (APRP8) with an amino acid sequence identical to one of the phosphorylated sites in acidic proline-rich proteins by a kinase from the human sublingual gland was investigated. The kinase, which was highly labile, was purified 58-fold by fractionation of sublingual gland homogenate and gel filtration, but the enzyme was inactivated when further purification by chromatographic techniques commonly used for protein kinases was attempted. To compare the enzyme with other kinases, and to obtain information that could be used in its further purification, a characterization was undertaken. The enzyme required 10 mM Mg2+ for optimum activity, it had a KM of 0.09 mM for ATP and the KM for the peptide substrate APRP8 was 0.42 mM. It was not activated by cAMP or calmodulin, characteristics that are shared with casein kinases and mammary gland kinase. The sublingual kinase as well as casein kinase 2 were inhibited by heparin, but in other respects the two kinases had different properties. While casein kinase 2 is activated by polylysine and has optimal activity in 150 mM KCl, sublingual kinase was inhibited by polylysine and the addition of KCl. Moreover, casein kinase 2 can utilize both ATP and GTP as phosphoryl donors, but GTP was not a substrate for sublingual kinase. The sublingual kinase shared a substrate recognition sequence with mammary gland kinase, but, unlike that kinase, it could not utilize Ca2+ instead of Mg2+. While the sublingual kinase thus shared some properties with both casein kinase 2 and mammary gland kinase, distinct differences were also seen and the relationship to these enzymes remains to be determined. The characterization of the sublingual kinase will be useful in its further purification.

D-dimer specific monoclonal antibodies react with fibrinogen aggregates

Human fibrinogen exposed to 46.5 degrees C was subjected to gel permeation chromatography. The protein eluted in two distinct peaks. The first peak appeared in the void volume containing soluble fibrinogen aggregates, while the other peak represented monomeric fibrinogen. In contrast to the monomeric peak material, the aggregate fraction reacted with a panel of monoclonal antibodies specific for fragment D-dimer using an ELISA system. Edman degradation showed that both the aggregate and the monomeric fractions were devoid of soluble fibrin, and immunoblots of SDS-PAG electrophoretic profiles disclosed no sign of stabilized high molecular weight derivatives. We have previously shown that the aggregate fraction of similarly treated fibrinogen, in contrast to the monomeric fraction, stimulates the t-PA catalyzed conversion of plasminogen to plasmin and concomitantly exposes the sequences Aalpha-(148-160) and gamma-(312-324) involved in t-PA stimulation. Our present and previous findings suggest that soluble fibrinogen aggregates possess a fibrin-like structure, and that fibrin or fibrinogen polymer formation is a prerequisite for the enhancing effect on t-PA-mediated plasminogen to plasmin conversion which is seen even with the polymers in the soluble state.

Aggregated, conformationally changed fibrinogen exposes the stimulating sites for t-PA-catalysed plasminogen activation

The present paper shows that conformationally changed fibrinogen can expose the sites A alpha-(148-160) and gamma-(312-324) involved in stimulation of the tissue-type plasminogen activator (t-PA)-catalysed plasminogen activation. The exposure of the stimulating sites was determined by ELISA using mABs directed to these sites, and was shown to coincide with stimulation of t-PA-catalysed plasminogen activation as assessed in an assay using a chromogenic substrate for plasmin. Gel permeation chromatography of fibrinogen conformationally changed by heat (46.5 degrees C for 25 min) demonstrated the presence of both aggregated and monomeric fibrinogen. The aggregated fibrinogen, but not the monomeric fibrinogen, has exposed the epitopes A alpha-(148-160) and gamma-(312-324) involved in t-PA-stimulation. Fibrinogen subjected to heat in the presence of 3 mM of the tetrapeptide GPRP neither aggregates nor exposes the rate-enhancing sites. Thus, aggregation and exposure of t-PA-stimulating sites in fibrinogen seem to be related phenomena, and it is tempting to believe that the exposure of stimulating sites is a consequence of the conformational changes that occur during aggregation, or self-association. Fibrin monomers kept in a monomeric state by a final GPRP concentration of 3 mM do not expose the epitopes A alpha-(148-160) and gamma-(312-324) involved in t-PA-stimulation, whereas dilution of GPRP to a concentration that is not longer anti-polymerizing, results in exposure of these sites. Consequently, the exposure of t-PA-stimulating sites in fibrin as well is due to the conformational changes that occur during self-association.

Identification of histatins as tannin-binding proteins in human saliva

Tannins have a number of detrimental biological effects and these include interference with normal growth and metabolism if they are present in the feed of various animals. Proline-rich proteins (PRPs) in saliva have been shown to provide protection against tannin, but little is known about the mechanism of protection and interaction of other salivary proteins with tannin. To identify tannin-binding human salivary proteins, parotid and submandibular/sublingual saliva samples were adsorbed with tannin. PRPs, and in particular a group of low-M(r) proteins, were readily precipitated by tannin. The low-M(r) proteins were purified from parotid saliva and demonstrated to be histatins, a family of well-characterized histidine-rich salivary proteins. The ability of synthetic histatin 5, as well as an acidic PRP (PRP-1) and gelatin to precipitate quebracho condensed tannin and tannic acid was determined. At pH 7.4 histatin 5 was the most effective precipitant of both condensed tannin and tannic acid and it also precipitated the largest amount of condensed tannin at pH 3.0, but the smallest amount of tannic acid at that pH. In contrast PRP-1 showed a greater ability to precipitate both condensed tannin and tannic acid at pH 3.0 than at pH 7.4. Under most circumstances histatin 5 was therefore more effective in precipitating tannins than proteins with high proline content which generally have been recognized as strong precipitants of tannin. Pre-incubation of tannic acid with alpha-amylase inhibited the enzyme, but addition of histatin 5 or the acidic PRP PIF-s protected amylase from inhibition by tannin. Similarly salivary proteins may protect other biological activities in the digestive tract from inhibition by dietary tannin.

Stimulating effect on tissue-type plasminogen activator--a new and sensitive indicator of denatured fibrinogen

A high clottability and a short thrombin clotting time have routinely been considered as evidence of genuineness of the fibrinogen molecule. Since denatured fibrinogen stimulates the t-PA-catalysed conversion of plasminogen to plasmin, it was of interest to study the sensitivity of t-PA-stimulation as evidence of fibrinogen denaturation. Therefore, fibrinogen was intentionally exposed to various denaturating conditions (freeze-drying, heating, EDTA, alkali), and the clottability, the thrombin clotting time and the t-PA-stimulating effect were recorded. We found that the clottability was a poor indicator of fibrinogen denaturation, whereas the t-PA-stimulating effect could detect even mild fibrinogen denaturation. The thrombin clotting time was shortened after freeze-drying or heating at 47 degrees C, in spite of what might have been expected. Thus, denaturation is not necessarily accompanied by a prolonged clotting time. In some instances therefore, the t-PA-stimulation is an even more sensitive and reliable indicator of fibrinogen denaturation than is the thrombin clotting time. Consequently, this parameter should be combined with the thrombin clotting time to characterise preparations of fibrinogen.

Fibrinogen present in EDTA--anticoagulated plasma stimulates the tissue-type plasminogen activator-catalysed conversion of plasminogen to plasmin

The presence of soluble fibrin in plasma is an early and sensitive indicator of activation of the coagulation system. Quantitative spectrophotometric assays for soluble fibrin can be based on the principle that soluble fibrin stimulates the tissue-type plasminogen activator-catalysed conversion of plasminogen to plasmin. It was previously shown that treatment of purified fibrinogen by EDTA, which removes the three tightly bound Ca2+ ions, results in exposure of tissue-type plasminogen activator-catalytic sites similar to those unveiled by thrombin. Since EDTA is a common anticoagulant, it was of interest to study the effect of EDTA on a test based on plasminogen activation. It is concluded that the determination of soluble fibrin in EDTA-anticoagulated plasma from healthy individuals gives a false positive indication of the presence of soluble fibrin. This was true irrespective of whether the test was performed at pH 7.4, 7.8 or 8.5. The most probable explanation is that tissue-type plasminogen activator-stimulating sites are exposed in fibrinogen by EDTA. Therefore, EDTA-plasma is unsuitable for assaying soluble fibrin with tests based on the tissue-type plasminogen activator-mediated conversion of plasminogen to plasmin.

Freeze-dried fibrinogen or fibrinogen in EDTA stimulate the tissue-type plasminogen activator-catalysed conversion of plasminogen to plasmin

Both soluble and insoluble fibrin stimulate the tissue-type plasminogen activator-catalysed conversion of plasminogen to plasmin. Whether fibrinogen can exert a similar effect has been a controversial issue. The present investigation shows that while fibrinogen purified by beta-alanine precipitation does not stimulate the tissue-type plasminogen activator-catalysed plasminogen activation, fibrinogen which has been either lyophilized or stripped of bound Ca2+ ions by EDTA chelation, stimulates this reaction. The data indicate that such procedures alter the molecular conformation of fibrinogen, and expose stimulatory sites which are hidden in the native fibrinogen molecule. These results may explain previous findings concerning the capacity of fibrinogen as a stimulator of the tissue-type plasminogen activator-catalysed plasminogen activation. Since even slight alteration of the molecular structure of fibrinogen leads to an increase in the tissue-type plasminogen activator stimulation, the authors suggest that this can be used to test if the fibrinogen is in a native state.

A rapid method for selecting specific hybridoma clones using paramagnetic Dynabeads

This paper describes how specific hybridoma clones can be rapidly selected using paramagnetic beads coated with the antigen used for immunization. Spleen cells from a mouse immunized with fragment D dimer (DD) from plasminolysed fibrin were first fused with X-63 mouse myeloma cells. Paramagnetic monodisperse beads (precoated with sheep anti-mouse antibodies) were then coated with S4, a monoclonal antibody to DD, and subsequently with DD. Mixing such beads with the fused cells allowed selective harvesting of cells with membrane-expressed anti-DD gammaglobulins using a magnetic particle concentrator. Within 24 h, the cells spontaneously detached from the beads and were plated out on 96-well plates. Supernatants from the clones obtained were tested by the ELISA technique. Antibodies specific for DD were produced by 40-79% of the tested clones. It is concluded that it is possible to use antigen-coated paramagnetic beads to select, prior to cloning, hybridomas that produce specific antibodies. Implementation of this technique has significantly reduced costs and time in our efforts to obtain hybridoma clones of interest.

Characterization of fibrinogen/fibrin derivatives isolated from normal and fibrinaemic plasma and serum using paramagnetic particles coated with a monoclonal antibody (mAb) to D-dimer

Paramagnetic particles coated with a monoclonal antibody to D-dimer (mAb S4) were used to isolate and concentrate D-dimer and D-dimer-containing complexes in plasma and serum. Antibody-captured material was eluted with SDS-urea buffer and examined by either SDS-polyacrylamide or submerged SDS-agarose gel electrophoresis followed by Western blotting. The protein pattern was visualized by either polyclonal antibodies to human fibrinogen or monoclonal antibodies specific for fibrinogen derivatives containing fibrinopeptide A (FpA; mAb Y18), the N-terminus of the beta-chain in fibrin (mAb 59D8) or the gamma-chains (mAb J88B). The results obtained show that paramagnetic particles coated with mAb S4 catch intact D-dimer as well as a variety of cross-linked fibrin molecules of high-molecular-weight (HMW) in plasma. The existence of HMW derivatives in fibrinaemic serum indicates that some of the HMW fibrin related material in such plasma is not clottable. Fibrinogen/fibrin monomers and some of the fibrinogen/fibrin related derivatives found in the eluates were probably non-covalently bound to the complexes caught by mAb S4 coated particles. The present technique combines the selective concentrating power of immunoparticles and the sensitivity of immunovisualization and allows rapid and direct identification of minute amounts of circulating immunoreactive fibrinogen/fibrin derivatives.

Localization of salivary proteins in granules of human parotid and submandibular acinar cells

Electron microscopic immunocytochemistry was used to investigate the distribution of four secretory proteins within the granules of human parotid and submandibular gland acinar cells. The results demonstrate that the distribution of the individual proteins differs significantly. Amylase is concentrated within the electron-dense regions of the granules, whereas agglutinin is present mainly in the regions of lower density. In contrast, the proline-rich proteins and histatins are distributed throughout the content of the granules and do not appear to be concentrated in either the high- or low-density regions. The results also suggest that different mechanisms, such as self-aggregation or ionic complexes with metal ions and charged macromolecules, may be involved in the packaging of individual proteins within the same granule. Further, they also show that among the salivary glands of various species, the intragranular distribution of similar proteins (e.g., amylase and proline-rich proteins) may differ.

Alignment of amino acid and DNA sequences of human proline-rich proteins

Human proline-rich proteins (PRPs) constitute a complex family of salivary proteins that are encoded by a small number of genes. The primary gene product is cleaved by proteases, thereby giving rise to about 20 secreted proteins. To determine the genes for the secreted PRPs, therefore, it is necessary to obtain sequences of both the secreted proteins and the DNA encoding these proteins. We have sequenced most PRPs from one donor (D.K.) and aligned the protein sequences with available DNA sequences from unrelated individuals. Partial sequence data have now been obtained for an additional PRP from D.K. named II-1. This protein was purified from parotid saliva by gel filtration and ion-exchange chromatography. Peptides were obtained by cleavage with trypsin, clostripain, and N-bromosuccinimide, followed by column chromatography. The peptides were sequenced on a gas-phase protein sequenator. Overlapping peptide sequences were obtained for most of II-1 and aligned with translated DNA sequences. The best fit was obtained with clones containing sequences for the allele PRB4M (Lyons et al., 1988). However, there was not complete identity of the protein amino acid sequence and the DNA-derived sequences, indicating that II-1 is not encoded by PRB4M. Other PRPs isolated from D.K. also fail to conform to any DNA structure so far reported. This shows the need to obtain amino acid sequences and corresponding DNA sequences from the same person to assign genes for the PRPs and to determine the location of the postribosomal cleavage points in the primary translation product.

Early cross-linked fibrin in human plasma contains alpha-polymers with intact fibrinopeptide A

alpha-polymer formation, as opposed to gamma-chain dimerization has been considered a relatively late event in factor XIII-induced fibrin stabilization. Recently it has been shown, however, that plasma from healthy individuals and from patients with fibrinaemia contains small amounts of soluble fibrin/fibrinogen oligomers interlinked through dimerized gamma-chains as well as cross-linked alpha-chains. The present work was carried out to see if these early alpha-chain polymers also arise during coagulation of plasma in vitro. Plasma samples from healthy individuals, prepared by immediate centrifugation of blood collected without anticoagulant, were allowed to clot spontaneously for varying periods. The plasma clots were solubilized in SDS-urea-mercaptoethanol and samples were subjected to SDS-PAGE and Western blotting using polyclonal antibodies to human fibrinogen, or monoclonal antibodies specific either for A alpha/alpha-chains, for fibrinopeptide A-containing chains, for the N-terminus of the fibrin beta-chain or for the gamma-chains. Fibrin/fibrinogen oligomers were seen to form long before visible gelation of plasma. These oligomers were cross-linked through gamma-chain dimerization, but also through A alpha- or alpha-chain polymerization. The number and amount of alpha-polymers containing A alpha-chains increased immediately after clot formation, but these disappeared about 20 min later, due to complete removal of fibrinopeptide A (FPA) by thrombin. It is concluded that alpha-polymer formation is a very early event during plasma coagulation in vitro, and that both A alpha- and alpha-chains are involved.

Differential expression of proline-rich proteins in rabbit salivary glands

Salivary glands synthesize and secrete an unusual family of proline-rich proteins (PRPs) that can be broadly divided into acidic and basic PRPs. We studied the tissue-specific expression of these proteins in rabbits, using antibodies to rabbit acidic and basic PRPs as well as antibodies and cDNA probes to human PRPs. By immunoblotting, in vitro translation, and Northern blotting, basic PRPs could be readily detected in the parotid gland but were absent in other salivary glands. In contrast, synthesis in vitro of acidic PRPs was detected in parotid, sublingual, and submandibular glands. Ultrastructural localization with immunogold showed heavy labeling with antibodies to acidic PRPs of secretory granules of parotid acinar cells and sublingual serous demilune cells. Less intense labeling occurred in the seromucous acinar cells of the submandibular gland. With antibodies to basic PRPs, the labeling of the parotid gland was similar to that observed with antibodies to acidic PRPs, but there was only weak labeling of granules of a few sublingual demilune cells, and no labeling of the submandibular gland. These results demonstrate a variable pattern of distribution of acidic and basic PRPs in rabbit salivary glands. These animals are therefore well suited for study of differential tissue expression of PRPs.

Soluble, cross-linked fibrin(ogen) hybrid oligomers do not stimulate t-PA conversion of plasminogen

Cross-linked hybrid oligomers of fibrinogen and fibrin are found in plasma from fibrinaemic patients and normal individuals as well as in preparations of purified human fibrinogen. The present study was undertaken to see if such hybrid oligomers have the same stimulatory effect on tissue plasminogen activator (t-PA) conversion of plasminogen as do polymeric and monomeric fibrin. Hybrid oligomeric fibrin(ogen) material was provided by subjecting purified human fibrinogen to gel filtration in urea-containing buffer at pH 5.6. Well separated fractions of hybrid oligomeric material and monomeric fibrinogen were thus obtained. Some of this material was converted to soluble polymeric or monomeric fibrin using insolubilized thrombin. Hybrid polymeric fibrin, polymeric fibrin or monomeric fibrin were then added to citrated, normal plasma to 2.5 or 5 per cent of the plasma fibrinogen concentration. The added material was kept in solution by plasma fibrinogen. The "COA-SET Fibrin Monomer Test" (Kabi,Stocholm,Sweden), based on the ability of fibrin monomers to enhance t-PA mediated plasminogen-plasmin conversion, was used to compare the potential stimulatory effect of the preparations above. The results led to the following conclusions: 1) Cross-linked, soluble fibrin(ogen) hybrid polymers in a concentration of 5 per cent of plasma fibrinogen concentration (w/w) do not stimulate t-PA. 2) Thrombin conversion of the fibrin-fibrinogen hybrid material resulted in an increase in the rate of t-PA mediated plasminogen conversion, corresponding to the one observed with equivalent (w/w) amounts of fibrin monomers. Compared on a mole to mole basis, fibrin oligomers are more powerful than fibrin monomers as stimulators of t-PA activity.

cDNA for the carboxyl-terminal region of a rat intestinal mucin-like peptide

When subjected to thiol reduction, purified intestinal mucins have been shown to undergo a decrease in molecular mass and to liberate a 118-kDa glycopeptide (Roberton, A. M., Mantle, M., Fahim, R. E. F., Specian, R., Bennick, A., Kawagishi, S., Sherman, P., and Forstner, J. F. (1989) Biochem. J. 261, 637-647). The latter has been called a putative "link" component because it is assumed to be important for disulfide bond-mediated mucin polymerization. Controversy exists as to whether the putative link is an integral mucin component or a separate mucin-associated glycopeptide. In the present study both NH2-terminal and internal amino acid sequences of the 118-kDa glycopeptide of rat intestinal mucin were used to generate opposing oligonucleotide primers for polymerase chain reaction. A specific 1.2-kilobase (kb) product was obtained, from which a 0.5-kb HindIII fragment was used as a probe to screen a lambda ZAP II cDNA library of rat intestine. A 2.6-kb cDNA (designated MLP 2677) was sequenced and revealed an open reading frame of 2.5 kb encoding 837 amino acids. The deduced amino acid sequence showed that the putative link peptide is equivalent to the carboxyl-terminal 689 amino acids of a larger peptide. Northern blots revealed a mRNA size of approximately 9 kb. Computer searches revealed no sequence homology with other proteins, but similarities were seen in the alignment of cysteine residues in the link and in several domains of human von Willebrand factor, as well as cysteine-rich areas of bovine and porcine submaxillary mucins and a frog skin mucin designated FIM-B.1. In keeping with earlier demonstrations of the presence of mannose in the 118-kDa glycopeptide, there were several (13) consensus sequences for attachment of N-linked oligosaccharides within the link domain. Further sequencing of MLP 2677 in a direction 5' to the codon specifying the NH2-terminal proline of the link has revealed a coding region for 148 amino acids, including a unique 75-amino acid domain rich in cysteine and proline, and a region containing 4.5-variable tandem repeats (each 11-12 amino acids) rich in serine, threonine, and proline. The presence of mucin-like tandem repeats suggests that the entire cysteine-rich link peptide represents the carboxyl-terminal region (75.5 kDa) of a mucin-like peptide (MLP). The latter is estimated to have a molecular mass of approximately 300 kDa.

Hybridomas can successfully be prepared from frozen/thawn spleen cells

Spleens from mice immunized with either human von Willebrand factor, albumin or fragment DD from plasminolyzed fibrin were divided into two equal parts. Subsequently, one half of the spleen cells were fused directly with X-63 mouse myeloma cells and the other half fused after freezing and thawing. The results show that hybridomas may successfully be prepared from frozen/thawn spleen cells, but that a higher cell density than with fresh cells is required. The possibility of making use of frozen spleen cell material implies that valuable time and cell material can be saved, and that fusions can be postponed and performed at the time of choice.

Basic proline-rich proteins from human parotid saliva: relationships of the covalent structures of ten proteins from a single individual

Eleven basic proline-rich proteins were purified from the parotid saliva of a single individual. The complete amino acid sequences of six of these were determined by conventional protein sequence methodology, bringing to nine the number of known primary structures of nonglycosylated basic proline-rich proteins from the same individual. The partial sequence of one additional protein is also reported. All of the basic proline-rich proteins studied contain segments with identical or very similar sequences, but with two possible exceptions, none of the proteins is derived from another secreted proline-rich protein. The amino acid sequences of nine nonglycosylated basic proline-rich proteins were compared with primary structures deduced from published nucleotide sequences of DNA coding for human parotid proline-rich proteins. The sequences align well, in general, but differences also exist pointing to the complexity of the genetics of these proteins. Seven secretory basic proline-rich proteins appear to be formed from three larger precursors by selective posttranslational proteolyses of arginyl bonds. One of the basic proline-rich proteins appears to derive from human acidic proline-rich proteins. The remaining two proteins studied do not conform to any DNA structure as yet reported. Two of the basic proline-rich proteins studied are phosphoproteins and exhibit abilities to inhibit hydroxyapatite formation in vitro.

Purification and characterization of a rabbit salivary protein, a potent inhibitor of crystal growth of calcium phosphate salts

Human saliva is supersaturated with respect to basic calcium phosphate salts but is stabilized by specific macromolecules that inhibit calcium phosphate precipitation. One of the families of inhibitory proteins in human and monkey saliva is the acidic proline-rich proteins. The purpose of this study was to isolate and characterize inhibitors of calcium phosphate precipitation from rabbit parotid saliva. Saliva was fractionated by immunoaffinity chromatography and anion exchange chromatography. Individual fractions were assayed for their ability to inhibit calcium phosphate crystal growth and the fraction associated with the inhibition was purified by repeated anion exchange chromatography, preparative gel electrophoresis and electroelution. A major (APRP) and two minor proteins (AM1, AM2) that were inhibitory were purified. APRP is an acidic proline-rich phospho-glycoprotein and a very potent inhibitor of secondary crystal growth of calcium phosphate as it was active at a concentration of 2 x 10(-8) M in a standard assay. The N-terminal sequence of one APRP was EYENLDGSLAATQNDDD?Q and a clostripain fragment of APRP had the following N-terminal sequence PQHRPPRPGGH-????SPPP?GN???PPP. Although the N-terminal segment of APRP does not resemble that of proline-rich proteins, alignment of the clostripain fragment with the repeat region of such proteins from rat, mouse, monkey and man revealed a high degree of similarity, indicating a structural relationship with the proline-rich protein family.

Phosphopeptides derived from human salivary acidic proline-rich proteins. Biological activities and concentration in saliva

Human saliva contains a large number of phosphopeptides derived by cleavage of acidic proline-rich proteins (APRPs). These peptides were purified by column chromatography and they constituted 0.5% of APRPs in parotid saliva, but 11% of APRPs in saliva expectorated from the mouth (whole saliva), indicating that there is considerable cleavage of APRPs after secretion from the gland. Similarly to APRP, the phosphopeptides bind Ca2+, but they accounted for only 4% of protein-bound Ca2+ in whole saliva. APRPs as well as the phosphopeptides inhibited formation of hydroxyapatite, but, whereas 19-20 micrograms of APRP was needed for 50% inhibition, only 0.7-3.3 micrograms of purified peptides was needed for the same degree of activity, and the phosphopeptides accounted for 18% of total inhibitory activity in whole saliva. All phosphopeptides adsorbed on hydroxyapatite in vitro, and adsorption of phosphopeptides on tooth surfaces in vivo could also be demonstrated, indicating that they would be able to inhibit unwanted mineral formation on the tooth surface in vivo. Degradation of APRPs after secretion therefore does not lead to a loss of their biological activities.

Normal and fibrinaemic patient plasma contain high-molecular weight crosslinked fibrin(ogen) derivatives with intact fibrinopeptide A

Freshly drawn plasma samples from healthy subjects and from fibrinaemic patients were subjected to electrophoresis on SDS-agarose (unreduced material) or on SDS-PAG (1D and 2D, reduced material) and Westernblotted. The blots were immunovisualized using either polyclonal anti-fibrinogen or a monoclonal antibody (Y18) to fibrinopeptide A-containing molecules. The following results were obtained: 1. Normal plasma as well as plasma from patients with fibrinaemia contained FXIII-crosslinked HMW oligomers, stabilized through gamma gamma-dimerization as well as alpha-polymer formation and these oligomers contained molecules with intact A alpha-chain N-termini. 2. Cross-linked material amounted to less than 0.1% of the fibrinogen pool regardless of the sample studied, and apparently less in fibrinaemic patient plasma than in normal plasma. Thus, since the ratio of crosslinked fibrin(ogen) derivatives to that of fibrinogen was lower for fibrinaemic plasma than for normal plasma, it is suggested that the type of soluble fibrin which gives rise to a positive EGT in fibrinaemia patients is not crosslinked.

Purification and characterization of subunits of a high molecular weight human salivary mucin

A high molecular-weight mucin was purified from human submandibular-sublingual saliva. The purity of the mucin preparation was demonstrated by the absence of other salivary proteins, by antibody reactivity and by gel electrophoresis. After reduction with mercaptoethanol a putative link component with approximate Mr 150,000 and a glycoprotein component of higher Mr could be detected by gel electrophoresis. These subunits were subsequently purified and they showed distinct differences in their amino acid compositions, demonstrating that the mucin consisted of two different subunits. The link had a number of similarities with the link component of intestinal mucin and a parotid agglutinin and has previously been shown to cross-react with antiserum to link component from intestinal mucin. Salivary and intestinal mucins may therefore have similar subunit structure.

Primary structure and possible origin of the non-glycosylated basic proline-rich protein of human submandibular/sublingual saliva

Human submandibular/sublingual saliva contains one non-glycosylated basic proline-rich protein whereas parotid saliva contains multiple such components. The submandibular protein has a primary structure identical with the C-terminal segment [TZ] of the human parotid acidic proline-rich proteins that contain 150 amino acid residues (Mr 16,000). Northern-blot analyses of human parotid and submandibular glands revealed that mRNAs containing the HaeIII repeat sequence typical for acidic proline-rich proteins are expressed in both of these salivary glands whereas mRNAs for non-glycosylated basic proline-rich proteins containing a typical BstN1 repeat sequence are expressed in the parotid but not in the submandibular gland. Products of translation in vitro of mRNAs from human parotid and submandibular glands were also examined. Two immunoprecipitable bands with Mr 29,000 and 28,000 were obtained by translation of both parotid and submandibular mRNA. In the presence of microsomal membranes these proteins gave rise to proteins electrophoretically identical with the secreted acidic proline-rich proteins of Mr 16,000. These proteins were cleaved by kallikrein, giving rise to proteins with electrophoretic mobilities identical with those of a smaller acidic proline-rich protein with Mr 11,000 and peptide TZ. Additional immunoprecipitable bands with Mr ranging from 35,000 to 46,000 were seen when parotid mRNA was used for translation in vitro, and are believed to be precursors of the basic proline-rich proteins encoded by the BstN1 repeat type mRNA. Neither these bands nor a separate precursor for the basic non-glycosylated proline-rich protein was detected when submandibular mRNA was used for translation in vitro. It is suggested that the non-glycosylated basic proline-rich protein present in human submandibular saliva arises by cleavage of acidic proline-rich proteins.

The putative 'link' glycopeptide associated with mucus glycoproteins. Composition and properties of preparations from the gastrointestinal tracts of several mammals

The existence of a discrete 'link' peptide in epithelial mucins has been debated for many years. There is evidence that at least some mucins contain a specific 'link' peptide (or glycopeptide) that enhances mucin polymerization by forming disulphide bridges to large mucin glycoprotein subunits. A major difficulty has been to know whether the reported differences in putative 'link' components represent artifacts generated by inter-laboratory differences in technical procedures used in mucin purification. The present paper outlines the results of a collaborative study involving five laboratories and 53 samples of purified gastrointestinal mucins (including salivary, gastric, small-intestinal and colonic mucins) prepared by five techniques from four different animal species. An early step in mucin purification in all cases was the addition of proteinase inhibitors. Representative mucins were analysed for their composition, electrophoretic mobility in SDS/polyacrylamide-gel electrophoresis before and after disulphide-bond reduction, and for their reactivity with monospecific antibodies developed against the 118 kDa putative 'link' glycopeptide isolated from either rat or human small-intestinal mucins. Our results indicate that, despite differences in laboratory techniques, preparative procedures, organs and species, each of the purified mucins contained a 'link' component that was released by disulphide-bond reduction and produced a band on SDS/polyacrylamide-gel electrophoresis at a position of approx. 118 kDa. After electroelution and analyses, the 118 kDa bands from the different mucins were found to have similar amino acid profiles and to contain carbohydrate. It would appear therefore that a 'link' glycopeptide of molecular mass approx. 118 kDa is common to all of the gastrointestinal mucins studied.

Isolation and characterization of six proteins from rabbit parotid saliva belonging to a unique family of proline-rich proteins

Proline-rich proteins are major components of salivary secretion from humans non-human primates, rats, hamsters and rabbits. They are also synthesized in mice in response to chronic stimulation by beta agonists. This study to provide an understanding of the structural and genetic relationships within these families of proteins to determine the possible function of the proline-rich proteins. Rabbit parotid saliva was collected and proline-rich proteins were affinity purified using goat antibodies to human proline-rich proteins. Purification was achieved by repeated cation exchange chromatography on a Mono S column a Fast Protein Liquid Chromatography system. Six basic proline-rich proteins were purified. The apparent molecular weights were between 75,000 and 125,000, based on their mobilities in sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Glycine, glutamine (and glutamate) and proline accounted for 79-87% of total amino acids in all proteins, but proline was present in smaller amounts (17-21%) than in proline-rich proteins from other species. All proteins were glycosylated but not phosphorylated. Circular dichroism of two proline-rich proteins, MS7A and MS5B, indicated the absence of secondary structure. The N-terminal sequences of three proteins electro-eluted after preparative gel electrophoresis were determined. A high degree of similarity was found in various regions of mouse, rat, monkey and human proline-rich proteins. Rabbits thus synthesize constitutively a family of proteins that are immununologically and structurally related to proline-rich proteins other species.

Immunovisualization of fibrinogen A alpha-chain heterogeneity in normal plasma and plasma from patients with DIC or on streptokinase therapy

Purified fibrinogen as well as normal plasma, or plasma from patients with DIC or undergoing streptokinase(SK)-therapy was subjected to 1D- and 2D SDS-electrophoresis under reducing conditions. The pattern was revealed either by Coomassie-staining or immunostaining after Western-blotting and then compared. The use of polyclonal antibodies to fibrinogen as well as two monoclonal anti-bodies reacting with FPA and C-terminal part of the A alpha-chain confirmed immunologically the previously reported molecular weight heterogeneity of the A alpha-chain of the fibrinogen molecule as being a constituent of normal plasma, and lead to the following conclusions: 1. The MW-heterogeneity is observed in the fibrinogen pool of normal plasma as well as in DIC-plasma, SK-plasma and in purified fibrinogen, being the least noticeable in normal plasma and most advanced in SK-plasma. Patterns obtained using immunostaining with monoclonal anti-FPA confirm that the MW-heterogeneity of fibrinogen is mainly due to C-terminal degradation of the A alpha-chain. 2. Numerous A alpha-chain remnants (at least 9), with intact N-terminal ends, are found to be present in normal plasma, with a MW range from 66,200 to 36,000 Da, demonstrating that each of the "classical" HMW, LMW, LMW' subgroups consist of fibrinogen molecules which are very heterogeneous. 3. Two populations of A alpha-chains in purified fibrinogen and in fibrinogen in plasma react with the C-terminal specific Mab G-8. This is in contrast to the findings in plasma from streptokinase-treated patients, where several bands of lower molecular weights than the gamma-chain can be seen, suggesting the presence of free, circulating A-alpha chains split in the N-terminal half of the chain beyond the last inter-chain disulphide bond. 4. 2D electrophoresis disclosed substantial deviations in the patterns obtained with DIC-plasma, SK-plasma and with fibrinogen purified by beta-alanine-precipitation from that observed with normal plasma. The present technique allows selective characterization of fibrinogen independently of the other proteins present in plasma and offers extreme sensitivity.

The primary structures of six human salivary acidic proline-rich proteins (PRP-1, PRP-2, PRP-3, PRP-4, PIF-s and PIF-f)

Human glandular salivary secretions contain several acidic proline-rich phosphoproteins (PRPs). These proteins have important biological functions related to providing a protective environment for the teeth, and appear to possess other activities associated with modulation of adhesion of bacteria to oral surfaces. These functions and activities depend on the primary structures of the PRPs. Previously determined amino acid sequences of two 150-residue molecules, PRP-1 and PRP-2, and two related 106-residue proteins, PRP-3 and PRP-4, indicated that residue 4 was Asn in PRP-1 and PRP-3, and Asp in PRP-2 and PRP-4, and position 50 was Asn in all four proteins. Recent data from cDNA sequence studies and further structural studies, however, showed that the previously proposed sequences cannot be completely correct. The present work has shown that the protein previously designated as PRP-1 actually consisted of two positional isomers, PIF-s, which has Asn and Asp at positions 4 and 50 respectively, and authentic PRP-1, which has the reverse arrangement. The same isomerism is present in the smaller proteins, PIF-f and PRP-3. Since the isomeric pairs have identical compositions and charges, their presence was not previously detected. Also, by using a more highly purified preparation, it has been found that position 50 in PRP-2 and PRP-4 is Asp, rather than Asn previously reported. These new findings for the six PRPs define their complete primary structures, which are now consistent with those proposed for PRP-1 and PIF-s from cDNA data, and are also consistent with the chromatographic and electrophoretic behaviours of the six PRPs and their derived peptides. These corrected structures are important for understanding the biological functions and activities of these unusual proteins.

The presence and origin of phosphopeptides in human saliva

The presence of phosphopeptides in whole saliva (saliva expectorated from the mouth) was demonstrated and their origin was evaluated. Whole saliva contained much larger numbers of small phosphopeptides than are found in the glandular secretions. Most of these originated from the acidic proline-rich proteins (PRPs) in the major salivary glands and were formed, after secretion into the oral cavity, as a result of rapid degradation by proteolytic enzymes from extraglandular sources contained in sediment from whole saliva. Some peptides may have been formed by cleavage of basic PRPs, but other phosphoproteins apparently contributed little to the observed phosphopeptides. Most of the enzymes that produced phosphopeptides are serine proteinases. The gel-electrophoretic band patterns of the phosphopeptides obtained from 26 individuals of various acidic-PRP phenotypes were remarkably similar, demonstrating that the enzymes responsible were generally present in the population surveyed and that similar cleavages occur regardless of the nature of the acidic PRPs. Many of these peptides were N-terminal proteolytic cleavage products of acidic PRPs. The N-terminal phosphorylated region of acidic PRPs contains various biological activities, such as inhibition of hydroxyapatite formation, calcium binding and binding to hydroxyapatite, the major mineral of teeth. The demonstration of these phosphopeptides in the saliva that is in contact with the oral surface may therefore be of biological importance.

Structural and genetic aspects of proline-rich proteins

Considerable advances have been made in the genetics of salivary proline-rich proteins (PRP). The genes for acidic, basic, and glycosylated PRP have been cloned. They code for precursor proteins that all have an acidic N-terminal followed by proline-rich repeat sequences. Structural studies on secreted proteins have demonstrated that not only acidic but also some basic PRPs have this general structure. It is possible that mRNA for different PRP may have originated from a single gene by differential mRNA splicing, but post-translational cleavages of the primary translation product apparently also occur. In vitro translation of salivary gland mRNA results in a single precursor protein for acidic PRP. Such in vitro translated protein can be cleaved by salivary kallikrein, giving rise to two commonly secreted acidic PRPs, and kallikrein or kallikrein-like enzymes may be responsible for other post-translational cleavages of PRPs. Acidic as well as some basic PRPs are phosphorylated. A protein kinase has been demonstrated in salivary glands which phosphorylates the PRPs and other secreted salivary proteins in a cAMP and Ca2+-calmodulin-independent manner. Knowledge of the conformation of PRPs is limited. There is no conclusive evidence of polyproline-like structure in the proline-rich part of PRPs. Ca2+ binding studies on acidic PRPs indicate that there is interaction between the Ca2+ binding N-terminal end and the proline-rich C-terminal part. This interaction is relieved by modification of arginine side-chains. 1H, 32P, and 43Ca NMR studies have further elucidated the conformation of acidic PRPs in solution.(ABSTRACT TRUNCATED AT 250 WORDS)

Basic proline-rich proteins from human parotid saliva: complete covalent structures of proteins IB-1 and IB-6

The complete amino acid sequences of two basic proline-rich proteins, IB-1 and IB-6, from human parotid saliva have been determined. Fragments for sequence analysis were obtained by enzymatic digestions. The proteins have molecular weights of 9571 (IB-1) and 11,530 (IB-6) and contain 34 and 39 mol % proline, respectively. IB-1 and IB-6 contain an identical sequence of 54 residues except for an alanine in position 52 of IB-6, where IB-1 has proline. An unusually high number of repeated sequences occurs in both molecules. IB-1 has a blocked amino-terminal residue, pyroglutamic acid, and also contains one phosphoserine residue in position 8. The relationship of these proteins to the basic proline-rich protein IB-9 [Kauffman, D., Wong, R., Bennick, A., & Keller, P. (1982) Biochemistry 21, 6558-6562] and to other salivary proline-rich proteins is discussed.

Phosphorylation of salivary proteins by salivary gland protein kinase

Human saliva contains a number of phosphorylated acidic proline-rich proteins (APRP). Monkey parotid saliva contains a similar protein with the same phosphorylated sequences as the human proteins. A crude protein kinase was prepared from Macaca fascicularis parotid glands which phosphorylated human APRP. The enzyme was activated by Mg2+, it had a pH optimum between pH 7.0 and 7.5, the Km for ATP was 78 mumol/L, and for APRP it was 85 mumol/L. Phosphorylation of APRP was independent of cAMP and calmodulin. Phosphate was incorporated as phosphoserine, and the kinase phosphorylated the same residues in dephosphorylated APRP which are phosphorylated in the secreted protein. In addition, the enzyme preparation also phosphorylated dephosphorylated and native APRP in a region which is not phosphorylated in the secreted protein. There was no difference in the rate of phosphorylation of APRPs and their tryptic peptides. The kinase also phosphorylated other dephosphorylated salivary phosphoproteins. An enzyme was demonstrated in the human salivary gland which gave the same pattern of phosphorylation of APRP as did the simian kinase. More than one kinase may be necessary for the observed phosphorylation.

A calcium-43 NMR study of calcium binding to an acidic proline-rich phosphoprotein from human saliva

The 43Ca NMR line width measured for Ca2+ bound to protein A, an acidic proline-rich salivary protein, is 1 order of magnitude narrower than has previously been observed for other proteins of similar molecular weight. The correlation times, quadrupole coupling constants, and chemical shifts estimated for Ca2+ ions bound to the intact protein (Mr approximately 10 000) and its 30 amino acid residue long acidic N-terminal TX peptide were indistinguishable within experimental error. These results--as well as the outcome of 1H NMR relaxation rate measurements--are indicative of extensive motions for the protein residues, which in turn give rise to a high degree of flexibility for the protein-bound Ca2+. Ca2+ titration and pH-dependent measurements on protein A, the TX peptide, and the dephosphorylated TX peptide established the importance of the two phosphoserine residues in the binding of Ca2+. Moreover, a comparison of the 43Ca NMR parameters with those obtained for other Ca2+-binding proteins suggests the presence of Ca2+-binding sites of similar symmetry in all these proteins. No evidence was found for a proposed interaction between the highly acidic N-terminal and the weakly basic C-terminal regions of protein A. In contrast, the high pH inflection that was observed in the pH titration curve for the intact protein was also found for the phospho and dephospho TX peptides, thus suggesting that basic moieties in the N-terminal region rather than those in the C-terminal region may be responsible for this observation.

Quantitation of human salivary acidic proline-rich proteins in oral diseases

Acidic proline-rich proteins (APRP) were quantitated immunochemically in salivary secretions from groups of: caries-resistant (CR) and caries-susceptible (CS) subjects; heavy- and light-calculus-formers; and patients with Sjögren's Syndrome, drug-induced xerostomia, and recurrent parotitis. In all groups except the parotitis patients, there were comparable levels of APRP, about 40-50 mg%, with similar values in parotid and submandibular saliva. In chronic recurrent parotitis, the values were somewhat higher (about 60 mg%). There were no differences in the proportion of APRP-A to C in a subset of CR and CS. Taken as a whole, the data support the view that the secretion of APRP is stable and that caries status and propensity to calculus formation are not associated with abnormal levels of these phosphoproteins.

The role of glandular kallikrein in the formation of a salivary proline-rich protein A by cleavage of a single bond in salivary protein C

An enzyme was purified from human parotid saliva that can cleave a single arginine-glycine peptide bond between residues 106 and 107 in human salivary proline-rich protein C, hereby giving rise to another proline-rich protein A, which is also found in saliva. The enzyme was purified 2400-fold. It cleaved salivary protein C at the rate of 59 micrograms of protein/h per microgram of enzyme and had amino acid composition, molecular weight and inhibition characteristics similar to those reported for human salivary kallikrein. Confirmation that the enzyme was kallikrein was demonstrated by its kinin-generating ability. Histochemical evidence indicates that a post-synthetic cleavage of protein C by kallikrein would have to take place during passage of saliva through the secretory ducts. In secreted saliva, cleavage of salivary protein C can only be observed after 72 h incubation. In addition, there is no effect of salivary flow rate on the relative amounts of proteins A and C in saliva. On the basis of the experimental observations, it is proposed that in vivo it is unlikely that kallikrein secreted from ductal cells plays a significant role in converting protein C into protein A.

Interaction of calcium ions and salivary acidic proline-rich proteins with hydroxyapatite. A possible aspect of inhibition of hydroxyapatite formation

The relationship between Ca2+- and hydroxyapatite-binding sites in salivary acidic proline-rich phosphoproteins A and C was investigated. Coating of hydroxyapatite with protein before adsorption had no effect on Ca2+ binding to the mineral, but simultaneous adsorption of Ca+ and protein to hydroxyapatite caused additional Ca2+ binding to the solid. The additional amount of Ca2+ adsorbed, measured in mol of Ca2+/mol of protein adsorbed to hydroxyapatite, was approx. 2 for protein C, 4 for protein A, 9 for the N-terminal tryptic peptide and 2 for dephosphorylated protein A. It is suggested that the ability of the proteins to inhibit hydroxyapatite formation is related to the binding of the proteins to crystal growth sites on the mineral, which prevents access of Ca2+ from the surrounding liquid.

The role of human salivary acidic proline-rich proteins in the formation of acquired dental pellicle in vivo and their fate after adsorption to the human enamel surface

The pellicles formed on fragments of human dental enamel worn on a palatal appliance for 1 min to 24 h were removed by acid extraction and the total amounts of protein and of acidic proline-rich proteins were determined. The percentage of total extracted protein constituted by the proline-rich proteins increased during the first hour of formation to about 37 per cent. Little difference was seen in total proline-rich protein between pellicles formed in a 1 and a 24-h period, but there was a gradual degradation of the proteins. There was no preferential retention of the N- or C-terminal parts of the proteins. Extracts of old acquired dental pellicle contained less than 0.1 per cent proline-rich proteins and pellicles more than 24 h old showed degradation of the adsorbed proline-rich proteins; there is no indication that the N-terminal part which contains the known biological activities was retained to a greater extent than the C-terminal part.

Demonstration of proline-rich proteins in rabbit parotid saliva and partial characterization of some of the proteins

Rabbit parotid saliva was collected by cannulation of the secretory duct in anaesthetized animals. Proteins which cross-react with antibodies to human acidic proline-rich proteins were demonstrated in the secretion and fractionated by chromatography on an immunosorbent and CM32-cellulose. At least 5 proline-rich proteins were identified with molecular weights ranging from 19,000 to 61,000 as determined by sodium dodecylsulphate acrylamide gel electrophoresis. The major immunoreactive components were basic proteins with similar size and charge properties. In two of the proteins, proline, glycine and glutamic acid or glutamine accounted for 84 or 99 per cent of all residues. In contrast to proline-rich proteins from other species, proline constituted only 13 or 17 per cent of total amino acids.

Immuno-radiometric assays for human salivary acidic proline-rich proteins and their N- and C-terminal fragments

An immuno-radiometric assay was developed for acidic proline-rich proteins from human saliva, and assays designed which specifically detect the N- or C-terminal parts of the proteins. The immuno-radiometric assay depends on the binding of antigen to paper discs coated with specific antibodies. Subsequently, the discs are incubated with radioactive specific antibodies. The amount of radioactive antibodies bound to the discs depends on the amount of antigen already adhering to the discs.

Studies on the glycolipids of human saliva and gastric juice

It has been reported that both human saliva and gastric juice (cf. Slomiany, B. L., and Slomiany, A. (1980) in Cell Surface Glycolipids (Sweeley, C. C., ed) American Chemical Society Symposium, No. 128, pp. 149-176, American Chemical Society, Washington, D.C.) contain substantial amounts of certain members of a series of novel glucoglycerolipids with a 1-O-alkyl glyceryl ether backbone. We have analyzed the glycolipids present in samples of saliva obtained from 10 individuals and in samples of gastric juice obtained from 5 individuals. In both fluids, compounds corresponding in the properties studied to standards of glucosyl- and lactosylceramides were found to be the major glycolipids. Other more complex glycosphingolipids were also present in smaller amounts. Human saliva was found to contain two glucoglycerolipids that were not detected in gastric juice. Analyses of these compounds indicated that they were mono- and diglucosyl diglycerides and were probably of bacterial origin. Methanolysis of the glycolipid fractions of saliva and gastric juice failed to reveal the presence of any more than traces of 1-O-alkyl glyceryl ethers. Our results do not exclude the possibility that glyceryl ether-containing glucoglycerolipids occur in human saliva and gastric juice. However, at most they would appear to be rather minor components of either fluid.

Basic proline-rich proteins from human parotid saliva: complete covalent structure of protein IB-9 and partial structure of protein IB-6, members of a polymorphic pair

The complete amino acid sequence of a basic proline-rich protein, IB-9, from human parotid saliva was determined by automated Edman degradation of peptides obtained by enzymatic cleavage of the intact protein with clostripain. The protein was digested with papain and elastase to obtain overlapping peptides. Automated Edman degradation of the intact protein was also performed. The protein consists of 61 amino acids, of which 26 are proline residues. The partial sequence of another human parotid basic proline-rich protein, IB-6, was also obtained. With one exception the first 54 residues of the two proteins are identical. An exceptional degree of internal reiteration occurs in both molecules, including several repeated sequences of 12-14 amino acids. The proteins show a high degree of homology with the C-terminal portion of the salivary acidic proline-rich protein C.

Salivary proline-rich proteins

Proline-rich proteins are major components of parotid and submandibular saliva in humans as well as other animals. They can be divided into acidic, basic and glycosylated proteins. The primary structure of the acidic proline-rich proteins is unique and shows that the proteins do not belong to any known family of proteins. The proline-rich proteins are apparently synthesized the acinar cells of the salivary glands and their phenotypic expression is under complex genetic control. The acidic proline-rich proteins will bind calcium with a strength which indicates that they may be important in maintaining the concentration of ionic calcium in saliva. Moreover they can inhibit formation of hydroxyapatite, whereby growth of hydroxyapatite crystals on the tooth surface in vivo may be avoided. Both of these activities as well as the binding site for hydroxyapatite are located in the N-terminal proline-poor part of the protein. Little is known about the functions of the glycosylated and basic proline-rich proteins.

The location and nature of calcium-binding sites in salivary acidic proline-rich phosphoproteins

The location of the calcium-binding sites in the human acidic proline-rich proteins, salivary proteins A and C, were determined by equilibrium dialysis of the tryptic peptides with buffers containing 45Ca. All the calcium-binding sites are located in the NH2-terminal tryptic peptide (TX peptide). The nature of the calcium binding sites in the TX peptide and native salivary proteins A and C, as well as dephosphorylated proteins were compared. Two types of sites can be distinguished in peptide TX. Type I sites have an apparent dissociation constant (K) of 38 microM and are responsible for the binding of 2.6 mol of Ca/mol of peptide. The corresponding figures for Type II sites are 780 microM and 5.3 mol of Ca/mol of peptide. In the native proteins, the amount of calcium bound at the type II sites decreases to 3.9 mol of Ca/mol of proteins A and C and K increases to 1100 microM. The amount of calcium bound at type I sites decreases to 1.5 mol/mol of protein A and 0.6 mol/mol of protein C, but there is no change in K. Dephosphorylation affects the calcium binding at both types of sites. The experiments indicate that the COOH-terminal parts of the native proteins affect the number and the nature of the protein calcium-binding sites. Proton and phosphorous NMR data demonstrate that beta-COOH in aspartic acid, as well as phosphoserine, are part of the calcium-binding sites. The difference in calcium binding to salivary proteins A and C may be due at least partially to differences in the environment of one or more aspartic acids.