Molecular characterization of glutamic acid/glutamine-rich secretory proteins from rat submandibular glands

Marked Differences in the Submandibular Salivary Proteome between Sardinian Alcohol-Preferring and Sardinian Alcohol-Non Preferring Rats Revealed by an Integrated Top-Down-Bottom-Up Proteomic Platform

Sardinian alcohol-preferring (sP) and Sardinian alcohol-non preferring (sNP) rats have been selectively bred for opposite alcohol preference and consumption. Aiming to verify possible differences at the proteomics level between sP and sNP rats, we investigated the salivary proteome by a a liquid chromatography-mass spectrometry top-down-bottom-up integrated approach. For this purpose, submandibular saliva was collected from alcohol-naive sP and sNP rats under isoprenaline stimulation. A total of 200 peptides and proteins were detected and quantified in the two rat lines, 149 of which were characterized in their naturally occurring structure. The data are available via ProteomeXchange with identifier PXD006997. Surprisingly, sP rats exhibited marked quantitative and qualitative differences with respect to sNP rats, namely higher levels of proteoforms originating from submandibular gland protein C, and from submandibular rat protein 2, as well as those of several unidentified peptides and proteins. sP rats expressed some proteins not detectable in sNP rats such as the glutamine and glutamic acid-rich protein (GRP)-CB. The isoform GRP-B, detectable in both rat lines, was more abundant in sNP rats. The submandibular saliva of sNP rats was also characterized by very high levels of GRP-B proteolytic peptides and rat salivary protein 1. Whether these differences could contribute to the opposite alcohol preference and consumption of sP and sNP rats is currently unknown and requires further investigation.

Top-down HPLC-ESI-MS characterization of rat gliadoralin A, a new member of the family of rat submandibular gland glutamine-rich proteins and potential substrate of transglutaminase

During HPLC-ESI-MS/MS analysis of rat submandibular saliva secreted under isoprenaline stimulation, a protein with an experimental [M+H](1+) = 10,544.24 m/z was detected (17.5 ± 0.7 min). The MS/MS fragmentation pattern, manually investigated, allowed establishing an internal sequence in agreement with a DNA-derived sequence of an unknown rat protein coded D3Z9M3 (Swiss-Prot). To match the experimental MS/MS fragmentation pattern and protein mass with theoretical data, the removal from the N terminus of the signal peptide and from the C terminus of three amino acid (a.a.) residues (Arg-Ala-Val) and the cyclization of the N-terminal glutamine in pyroglutamic had to be supposed, resulting in a mature protein of 90 a.a. HPLC-ESI-MS/MS of the trypsin digest ensured 100% sequence coverage. For the high glutamine content (34/90 = 37.8%) we propose to name this protein rat gliadoralin A 1-90. Low amounts of five different isoforms were sporadically detected, which did not significantly change their relative amounts after stimulation. Gliadoralin A is substrate for transglutaminase-2, having Lys 60 and different Gln residues as major determinants for enzyme recognition. In silico investigation of superior structures evidenced that a small part of the protein adopts an α-helical fold, whereas large segments are unfolded, suggesting an unordered conformation.

A novel mouse protein differentially regulated by androgens in the submandibular and lacrimal glands

We characterized a cDNA clone derived from the female mouse submandibular gland (SMG). The transcript of this cDNA was approximately 1.2kb in size and predicted to code a 165-amino acid protein with a putative signal peptide for a secretory pathway. This protein, named submandibular androgen-repressed protein (SMARP), had homology in the N-terminal region with members of the glutamine/glutamic acid-rich protein (GRP) family from rats. Northern blot analysis revealed that SMARP mRNA is expressed, out of the major mouse organs, only in the SMG and exorbital lacrimal gland (LG), with much more abundance in the former. For the SMG, the level of SMARP mRNA was 36 times higher in females than males, whereas for the LG it was 28 times higher in males than females. Furthermore, the level of SMARP mRNA was increased in the SMG but reduced in the LG with castration in males, whereas it was reduced in SMG but increased in LG after administration of testosterone in females or castrated males. In situ hybridization detected the signal for SMARP mRNA in the female SMG, and immunohistochemistry detected the signal for SMARP protein in the female SMG and male LG. In the female SMG, SMARP mRNA, and protein were localized intensively in a subpopulation of acinar cells, whereas in the male LG, SMARP protein was distributed diffusely in all acinar cells. These results suggested that SMARP is a secretory protein whose expression is regulated by androgens negatively in the SMG and positively in the LG.

Identification of a human ortholog of the mouseDcppgene locus, encoding a novel member of the CSP-1/Dcpp salivary protein family

Salivary fluid, the collective product of numerous major and minor salivary glands, contains a range of secretory proteins that play key defensive, digestive, and gustatory roles in the oral cavity. To understand the distinct protein “signature” contributed by individual salivary glands to salivary secretions, we studied a family of proteins shown by in vitro mRNA translation to be abundantly expressed in mouse sublingual glands. Molecular cloning, Southern blotting, and restriction fragment length polymorphism analyses showed these to represent one known and two novel members of the common salivary protein (CSP-1)/Demilune cell and parotid protein (Dcpp) salivary protein family, the genes for which are closely linked in the T-complex region of mouse chromosome 17. Bioinformatic analysis identified a putative human CSP-1/Dcpp ortholog, HRPE773, expressed predominantly in human salivary tissue, that shows 31% amino acid identity and 45% amino acid similarity to the mouse Dcpp query sequence. The corresponding human gene displays a similar structure to the mouse Dcpp genes and is located on human chromosome 16 in a region known to be syntenic with the T-complex region of mouse chromosome 17. The predicted mouse and human proteins both display classical NH2-terminal signal sequences, putative jacalin-related lectin domains, and potential N-linked glycosylation sites, suggesting secretion via sublingual saliva into the oral cavity where they may display antimicrobial activity or provide a defensive coating to enamel. Identification of a human CSP-1/Dcpp ortholog therefore provides a key tool for investigation of salivary protein function in human oral health and disease.

Molecular cloning and characterization of the neonatal rat and mouse submandibular gland protein SMGC

We report the molecular cloning and characterization of SMGC, a major secretory product and a marker of the type I (terminal tubule) cells of the neonatal rat and mouse submandibular gland. SMGC is expressed in the submandibular gland at high levels through postnatal day 20, but in the adult is present only in some intercalated duct cells. Rat and mouse SMGC have deduced molecular weights of 67.8 and 74.4 kDa, respectively, are 37% Ser+Gly+Thr, and contain tandem repeats of between 8 and 60 amino acids. Secreted SMGC visualized by SDS-PAGE and silver staining is 89 kDa in rat and 105 kDa in mouse, although Western blot analyses with anti-SMGC antisera demonstrate multiple additional lower molecular weight forms. Contributions to the heterogeneity of SMGC include alternate splicing, proteolysis and N-glycosylation. Smgc is localized on rat chromosome 7q34-35 and on mouse chromosome 15E3, both immediately upstream of the high molecular weight salivary mucin, Muc19. Amino acid sequence identity between the signal peptides of SMGC, human MUC19 and pig submaxillary mucin suggest that rat and mouse Smgc and Muc19 arose from a single ancestral mucin gene.

Androgen regulation of SMR2 gene expression in rat submandibular gland: evidence for a graded but not a binary response

Expression of SMR2, a member of the gene family encoding salivary glutamine/glutamic acid-rich proteins, is regulated by androgens in rat submandibular gland acinar cells. To further characterize SMR2 regulation, we analyzed SMR2 expression during submandibular gland postnatal development and rat puberty at both a global and a single-cell level. Using in situ detection of mature and primary SMR2 transcripts, we show that SMR2 expression is heterogeneous among acinar cells. However, only one cell population with various amounts of mRNAs can be defined. The number of high-expressing cells increases in males during puberty and in females up to 6 weeks of age, suggesting that some factor in addition to acinar differentiation might be important for SMR2 expression in female rats. Involvement of the beta-adrenergic system in regulating SMR2 expression was tested in rats exposed daily to isoproterenol for 4 days. Under these conditions we found an increase in SMR2 expression in female rats, associated with an increase in SMR2 mRNA levels in most acinar cells. This suggests that a signaling cascade, elicited by beta-adrenergic stimuli, might act in concert with androgens to regulate SMR2 expression.

Evaluation of salivary gland acinar and ductal cell-specific promoters in vivo with recombinant adenoviral vectors

Adenoviral vectors efficiently deliver exogenous genes to salivary glands. There are two general epithelial cell types, with very different functions, in salivary glands--acinar and ductal. To determine if gene expression can be restricted in vivo to either general cell type using a relatively cell/tissue-specific promoter in conjunction with adenovirus-mediated gene transfer, we tested the human amylase and kallikrein promoters. For initial studies the sensitive reporter gene luciferase was used in two adenoviral constructs. The adenovirus AdAMY-luc contains the human salivary gland amylase promoter (-1003 to +2)(AMY1C) and AdKALL-luc contains the human tissue kallikein promoter (-315 to -1)(KLK1). The adenovirus AdKALL-hAQP1 was also used to test a therapeutic gene, human aquaporin-1 (hAQP1), potentially of importance in treating surviving ductal cells in irradiation-damaged glands. Luciferase expression after AdAMY-luc delivery in vivo directly to the parotid, submandibular, and sublingual glands, as well as to the lungs, and intravenously via the femoral vein, was restricted to the three salivary glands and the pancreas. AdKALL-luc delivery via the same routes resulted in a more general distribution of luciferase expression, although greatest luciferase activity was seen in salivary glands and lung. Luciferase activity after AdAMY-luc delivery was proportionally greater (approximately 14-fold) in acinar cells, whereas luciferase activity after AdKALL-luc delivery was proportionally greater (approximately 9-fold) in ductal cells. The expression of hAQP1 after AdKALL-hAQP1 gene transfer was mainly observed in ductal cells in vivo. AdKALL-hAQP1 was as useful as AdCMV-hAQP1 in increasing salivary flow rates of irradiated rats. This study demonstrates that adenoviral vectors containing the relatively cell/tissue-specific AMY1C or KLK1 promoters may be useful for targeting therapeutic gene expression in salivary glands.

The transcriptional response to androgens of the rat VCSA1 gene is amplified by both binary and graded mechanisms

In higher eukaryotes, gene expression can be highly modified in response to small variations of circulating hormonal inducers. To determine the mechanisms responsible for the 100- to 200-fold enhancement of expression of an androgen-regulated gene, VCSA1, in the acinar cells of rat submandibular glands during puberty, we performed a detailed analysis of VCSA1 expression at the single cell level. Using in situ detection of mature and primary VCSA1 transcripts, we show that VCSA1 expression is activated in only a small proportion of differentiated acinar cells in the presence of low levels of circulating androgens in prepubescent and in castrated males, as well as in females. During the time course of sexual maturation in males, we demonstrate an increase in the proportion of acinar cells expressing VCSA1 and an increase in VCSA1 heterogeneous nuclear RNA and mRNA content in the positive cell population. Finally, we show that changes in the methylation pattern of VCSA1 are correlated with VCSA1 transcriptional activation. These results demonstrate that androgens can, in physiological conditions, elicit both a binary and a graded response. They also provide evidence that the range of gene regulation may be expanded by a transcriptional repression in a majority of cells under basal conditions.

Low levels of GRP-Ca expression in transgenic mice

The GRP-Ca gene of the rat encodes a member of the glutamine/glutamic-acid-rich protein (GRP) family. This gene is expressed in a highly tissue-specific fashion, with transcription being found only in the acinar cells of the submandibular gland (SMG). To begin to define the cis-acting elements governing GRP-Ca expression, we constructed transgenic mice containing the rat GRP-Ca gene plus 9.5 kb of 5' genomic sequence and 1 kb of 3 genomic sequence. Expression of GRP-Ca was detectable in progeny from only 1 of 3 independent founders. Expression levels of the transgenic GRP-Ca were much lower than the native GRP-Ca found in the rat SMG. Furthermore, GRP-Ca in transgenic mice was not tissue-specifically expressed, being found in both the SMG/SLG complex and the liver. These results indicate that the genomic region of GRP-Ca included in these transgenic mice is not sufficient to confer the high levels of tissue-specific expression seen in the rat.

Expression of gross cystic disease fluid protein-15/Prolactin-inducible protein in rat salivary glands

Gross cystic disease fluid protein-15 (GCDFP-15)/prolactin-inducible protein (PIP) is present at moderate levels in human submandibular and sublingual glands and is barely detectable in human parotid gland. The rodent homologue, PIP, has previously been identified in adult submandibular and lacrimal glands. Here we present the molecular characterization of rat PIP and show that this protein is a product of neonatal and adult rat submandibular, sublingual, and parotid glands. cDNA clones encoding rat PIP were isolated and sequenced. The deduced amino acid sequence of rat PIP shows 56% overall identity and 80% similarity with mouse PIP. By SDS-PAGE, secreted rat PIP has an apparent Mr of 17,000, with a minor proportion present as Mr 20-22,000 N-glycosylated forms. PIP was localized in rat salivary glands by immunogold silver staining. PIP was identified in acinar cells of developing and mature submandibular and parotid glands and at very low levels in sublingual gland serous demilunes. Typically, rat submandibular gland secretory proteins are produced by either acinar cell progenitors (Type III cells) or mature acinar cells. The expression pattern observed for PIP is similar to that previously reported for salivary peroxidase, an important component of nonimmune mucosal defense.

Transcriptional regulation of salivary proline-rich protein gene expression

Mechanisms governing gene expression and regulation in eukaryotes are remarkably complex. The results from in vivo transgenic and in vitro transfection studies designed to identify cis-element(s) and trans-factor(s) associated with the salivary proline-rich proteins (PRPs) gene expression are utilized as a paradigm to discuss the regulation of salivary-specific gene expression. Particular attention is given to the molecular mechanism(s) underlying the salivary PRP R15 gene regulation. In rodents, the PRPs are selectively expressed in the acinar cells of salivary glands, and are inducible by the beta-agonist isoproterenol as well as by dietary tannins. The results from a series of experiments using chimeric reporter constructs containing different lengths of the R15 distal enhancer region, their mutations, and various expressing constructs are analyzed and discussed. These data suggest that the inducible nuclear orphan receptor NGFI-B may participate in the regulation of salivary acinar cell-specific and inducible expression of the rat R15 gene via three distinct distal NGFI-B sites. Taken together, a model for the induction of R15 gene expression by isoproterenol is proposed. However, the exact molecular basis of this NGFI-B-mediated transactivation of cAMP-regulated R15 expression remains to be established.

Comparative study of kallikrein-like serine proteinases from rat submandibular glands

The present investigation describes the comparative properties, particularly the substrate specificity of three kallikrein-like serine proteinases (I, II and III) purified from rat submandibular gland extract (Bedi, G.S., Prep. Biochem. 22,67-81, 1992). The physico-chemical and immunological properties of three proteinases were compared by Western blot analysis, immunodiffusion, immuno-electrophoresis, amino terminal sequence analysis, molecular weight determination and isoelectric focusing. Detailed substrate specificity of these proteinases was determined using chromogenic substrates, synthetic peptides and native proteins. The chromogenic substrate tosyl-gly-pro-arg-pNA was hydrolyzed preferentially by Proteinase I. The replacement of pro at the P2 position with bulky hydrophobic residues phe and leu completely abolished the hydrolysis by Proteinase I. The hydrolysis of the chromogenic substrates by Proteinase II was also affected by the amino acid residue present at the P2 position in the order of pro > gly > val > leu > phe. Neither Proteinase I nor Proteinase II hydrolyzed substrates in which arg was replaced with lys at the P1 position. Proteinase III was reactive against all the chromogenic substrates with arg or lys at the P1 position. Synthetic polypeptides T-kinin-leu and insulin B chain were resistant to cleavage by both Proteinase I and II and were cleaved specifically at arg-X peptide bond by Proteinase III. Tonin-like activity of Proteinase II was confirmed by cleavage of the angiotensin 1-14 at phe-his linkage to generate two fragments DRVYIHPF and HLLVYS respectively. All three proteinases cleaved human high molecular weight kininogen but only Proteinase III could cleave T-kininogen. Proteinase III was also reactive towards human and bovine fibronectin, fibrinogen and gelatin. Several other salivary and serum proteins were resistant to cleavage by these proteinases. Although the three enzymes are immunologically related, they differ with respect to size, isoelectric point, amino terminal sequence and inhibition profile.

Three novel SMR1-related cDNAs characterized in the submaxillary gland of mice show extensive evolutionary divergence in the protein coding region

We have previously characterized an abundant male-specific mRNA from the submaxillary gland (SMG) of rats, encoding the SMR1 (androgen-regulated) protein, which has the structure of a prohormone and is processed by maturation enzymes to release a small peptide in the blood and saliva. We have now characterized three SMR1-related cDNAs in the SMG of Balb/c mice. These cDNAs encode three novel proteins, designated MSG1, MSG2 and MSG3. They are 639, 662 and 471 nucleotides (nt) long, respectively, and the corresponding mRNAs appear to be expressed only in the SMG. The putative polypeptides they encode carry an N-terminal secretory peptide sequence and are, therefore, presumably secreted into saliva. Although closely related, the three mRNAs show striking differences: a particularly different expression pattern and an extremely high degree of variability observed in the central part of the molecules. The MSG1 and MSG3 cDNAs are identical, except for a 173-bp insert found only in MSG1. This insert contains three Pro-rich repeats (GPGIGRPPPPPP), reminiscent of the most abundant multigenic family of the SMG, the Pro-rich proteins (PRP). Although MSG1 shares several common features with PRP, it is structurally related to SMR1. The unusually high ratio of replacement/silent nt changes provides a basis to address complex aspects concerning the molecular events leading to the emergence of new proteins in the SMG.

Salivary proline-rich proteins: biochemistry, molecular biology, and regulation of expression

The proline-rich proteins (PRPs) in mammalian salivary glands are encoded by tissue-specific multigene families whose members have diverged with respect to structure and regulation of expression. PRPs are expressed constitutively in humans, and comprise about [70%] of the total salivary proteins. Families of similar proteins are dramatically increased or induced in parotid and submandibular glands of rats, mice and hamsters by treatment with the [beta-] agonist isoproterenol. Feeding tannins to rats and mice mimics the effects of isoproterenol on the parotid glands. Salivary PRPs may constitute a defense mechanism against tannins and other polyhydroxylated phenols ingested. Putative transcriptional regulatory sequences have been identified in mouse PRP genes.

Molecular cloning of developmentally regulated neonatal rat submandibular gland proteins

At birth, the rat submandibular gland (SMG) contains two transient secretory cell types that produce several characteristic salivary proteins. Proteins SMG-A, B1, and B2 (23.5, 26 and 27.5 kDa) are products of the neonatal type III cells, but not the adult acinar cells. Protein C (89 kDa), a major product of the neonatal type I cells, is either absent or present at greatly diminished levels in the secretory cells of the adult gland. The decrease in biosynthesis of these neonatal salivary proteins occurs concomitantly with the increase in levels of characteristic adult SMG products. In order to understand these developmentally regulated changes in SMG salivary protein gene expression, we have initiated the molecular cloning and characterization of neonatal submandibular gland proteins from a 5-d-old rat submandibular gland cDNA library. Clones encoding SMG-A were isolated by homology to the mouse parotid secretory protein (PSP). SMG-A was shown to be derived from a salivary protein multigene family that also includes PSP. Cloning and characterization of additional neonatal rat submandibular gland proteins was initiated by screening the 5-d-old rat submandibular gland cDNA library with first strand cDNA prepared from 1-d-old rat submandibular glands. Clones corresponding to a highly abundant 3 kb transcript present in the neonatal rat SMG, but not in adult submandibular, sublingual, or parotid gland have been identified. The size, abundance, and organ specificity of this transcript suggest that it may encode protein C.(ABSTRACT TRUNCATED AT 250 WORDS)

Macaque salivary proline-rich protein: structure, evolution, and expression

Proline-rich proteins are a family of proteins that exhibit unique features including an unusual high proline content and salivary-specificity. As a major constituent in the salivary secretion of higher primates, proline-rich proteins may have biological roles in oral lubrication and protection. In this article, the genomic structure and regulation by cAMP of one of the macaque salivary proline-rich protein genes, MnP4, is reviewed. The evolution of this multigene family of proteins is also discussed.

A 55 kDa antigen of Pneumocystis carinii: analysis of the cellular immune response and characterization of the gene

Rat-derived Pneumocystis carinii contains a major antigen complex of 45-55 kDa. The fusion protein of a cDNA encoding the 3' portion of the 55kDa antigen, which had previously been shown to be recognized by serum antibodies of exposed subjects, was investigated for its ability to stimulate a cellular immune response. Rats exposed to P. carinii via the environment exhibited a vigorous proliferative response to the antigen whereas unexposed rats did not. The full-length cDNA for a 55kDa antigen was cloned and found to contain a 1245bp open reading frame capable of encoding a 414-amino-acid peptide. The gene encoding this protein contained a single 39bp intron and transcribed a 1.45kb RNA message. The cloning and characterization of the 55kDa antigen gene will allow production of the specific immunological reagents necessary to characterize this molecule and study its role in the biology and pathogenesis of P. carinii.

Effects of clonidine on the calcium content and morphology of rat salivary glands

These effects were examined with and without pretreatment of animals with reserpine and the adrenergic antagonists prazosin (alpha 1), yohimbine (alpha 2) and propranolol (beta). The effects of clonidine on glandular concentrations of norepinephrine and dopamine also were examined. These effects were compared with those of xylazine, a presynaptic alpha 2-adrenergic agonist. A single, high dose of clonidine followed by an overnight fast caused marked increases in calcium content and acinar secretory granules in the submandibular and sublingual glands, similar to those caused by reserpine. However, the calcium content of the parotid gland was not altered by clonidine, although there seemed to be a modest increase in acinar secretory granules. The clonidine-induced increase in submandibular calcium content could not be attributed to any adrenergic receptor activity since it was not blocked by either alpha- or beta-adrenergic antagonists. Unlike reserpine, clonidine did not affect catecholamine concentrations in the parotid and submandibular glands. Pretreatment with reserpine did not significantly alter the clonidine-induced increase in submandibular calcium content. It is likely that the greater accumulation of acinar secretory granules is related to the increased calcium stores of the glands in clonidine- and/or reserpine-treated rats. The large differences in calcium content among the three glands might be attributable, in part, to differences in the calcium-binding capacity of their secretory granules. Possible mechanisms for the clonidine effects on salivary-gland calcium include disturbances in membrane-associated pools or gating mechanisms for calcium, which need further study.

Characterization of the gene encoding the salivary Gln/Glu-rich C-terminal variant A protein

The rat submandibular gland-specific GRP-Ca gene (encoding C-terminal variant A of the glutamine/glutamic acid-rich protein) has been cloned from a male Wistar/Furth genomic library. The complete sequence, including 2.0 kb of 5' flanking and 0.5 kb of 3' flanking DNA has been determined. Electron microscopic heteroduplex analysis and sequence analysis established that transcripts coding for GRP-Ca and GRP-Cb are encoded by separate genes. The GRP-Ca gene is approx. 4.5 kb in size and is comprised of four exons and three introns. Comparison of this gene with several rodent and human salivary proline-rich protein-encoding genes (PRP) indicates that GRP-Ca shares this exon-intron structure with the rat SMR-2 gene, the hamster H29 gene, and the human PRP genes. In addition, a 28-bp element found in the proximal promoter region of GRP-Ca was found to be highly conserved among the superfamily of PRP genes.

Sequence and expression of the MnP4 gene encoding basic proline-rich protein in macaque salivary glands

We report here the macaque MnP4 cDNA and genomic sequences which encode a basic proline-rich protein (PRP), which is synthesized in macaque parotid gland and submandibular gland. The locations of intron positions and the prototype of the tandem 20-amino-acid repeat motif with the sequence, PPPPGKPQGPPQQGGNKPQG, in MnP4, were compared to those in related genes encoding PRP and glutamic/glutamine-rich proteins (GRP) in humans and rodents. Exceedingly high homology of the first exon and 40-bp region immediately upstream of exon I is observed with other PRP genes of all species studied. In order to identify the regulatory elements involved in control of MnP4 gene expression, a rat submandibular gland-derived cell line (RSMT-A5) was transfected with MnP4-cat constructs that contained the promoter and 5'-flanking regions of the macaque MnP4 gene fused to the bacterial cat gene. Deletion analysis revealed that putative positive and negative regulatory elements reside between nucleotides (nt) -107 and +5, and nt -586 and -108, respectively. As part of this study, the promoter of the macaque MnP4 gene appears to be salivary gland specific. This salivary gland-specific gene expression attests to the complexity of transcriptional regulation in eukaryotes.

Accumulation and localization of two adult acinar cell secretory proteins during development of the rat submandibular gland

The seromucous acinar cells of the adult rat submandibular gland secrete a characteristic mucin glycoprotein and a family of unusual glutamine/glutamic acid-rich proteins (GRP). Monoclonal antibodies to the mucin and GRP localized in a very few Type III cells in glands of newborn and 1 day-old rats, using light and electron microscopic immunocytochemistry. Both mucin and GRP reactivities were present in the polymorphic Type IIIP granules during the 1st postnatal week. By 9 days after birth, the granules contained both mucin and GRP and were mucous-like in appearance. At earlier stages, however, cells containing only GRP or mucin could be found, indicating that the initiation of GRP and mucin biosynthesis may not be coordinately regulated. No reactivity was seen in the neonatal Type I cells or in duct cells at any age. Northern and Western blot analysis showed GRP mRNA and protein levels to be barely detectable at birth, with marked increases during the first 2 postnatal weeks. In contrast, Western blots of B1-immunoreactive proteins (B1-IP) showed levels highest in the 1st week and markedly decreased in the adult. Immunocytochemical colocalization, using gold particles of different sizes, showed that the B1-IP, mucin, and GRP colocalized in the granules. These results strengthen the hypothesis that the adult acinar cells develop from the neonatal Type III cells. No evidence was obtained for the involvement of Type I cells in the pathway of acinar cell development.

The effects of autonomic drugs on the concentration of kallikrein-like proteases and cysteine-proteinase inhibitor (cystatin) in rat whole saliva

The influence of isoproterenol, phenylephrine, propranolol, and reserpine on the salivary concentration of kallikrein-like proteases and cysteine-proteinase inhibitor (cystatin) was investigated. The protease activities in saliva from treated rats were studied by means of five different chromogenic substrates. In the isoproterenol- and phenylephrine-treated groups, a significant decrease in protease activity was found, compared with the control group. The protease activity of saliva was found to be elevated by about 25-50% after chronic administration of reserpine (0.5 mg/kg). Specific polyclonal antibodies to rat glandular kallikrein and cystatin were utilized to determine the salivary concentrations of these proteins. Results from the use of anti-kallikrein antibodies in Western blot analysis and crossed immuno-electrophoresis indicated that differences observed in the kallikrein-like protease levels of saliva from treated animals were due to altered immunoreactive protein levels. The salivary concentrations of kallikrein and cystatin were measured by direct radio-immunoassays with specific antibodies. The concentration of cystatin in the saliva of normal animals or animals treated with reserpine or propranolol was very low, but was increased about 100-fold in phenylephrine-treated animals and more than 5000-fold in isoproterenol-treated animals. Western blot analysis with antibodies to submandibular gland mucin, glutamine/glutamic-acid-rich protein (GRP), and proline-rich proteins (PRP) were also utilized to compare the effects of autonomic drugs on these salivary proteins. The salivary mucin showed an increase in reactivity and increased mobility in saliva from both isoproterenol- and phenylephrine-treated animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular characterization of rat multigene family encoding proline-rich proteins

Three members of the rat proline-rich protein multigene family have been characterized. Each of these genes, RP4, RP13, and RP15, contains three exons and they are approximately 4.8, 5.7, and 5.4 kb, respectively. The DAN sequences of RP4 and RP13 are greater than 93% homologous in the 3.1-kb segment extending from the 5'-upstream region (approximately nucleotide -930) to 238 nucleotides after the second exon/intron junction; however, regions further downstream, intron II and exon III, share less than 43% identity. In contrast, exon III from RP15, RP13, and the previously sequenced mouse PRP gene MP2 are more than 73% conserved. These analyses suggest that the duplication of the ancestral genes to RP13 and RP4 occurred prior to the divergence of the rat PRP genes. The results also indicate that in the past 21.5 million years, multiple recombination events have resulted in a very high degree of divergence among intron II and exon III of RP4 and RP13. This divergence is due in part to the insertion of members of the rat long interspersed repeat DNA family at -930 bp upstream from the transcription initiation site and within intron II of RP13. Comparisons of the nucleotide sequences and organization of exon I with the genomic organization of PRP and glutamic acid/glutamine-rich protein genes in this and previous studies reveal striking resemblance among these genes. These observations are consistent with the notion that this super multigene family arose from duplication of progenitor genes via unequal crossing over events. In addition, the results suggest that concerted evolution has occurred within the tandemly repeated motif of exon II.

Genetic regulation of salivary proteins in rodents

The presence of a protein in the cell is the result of a complex pathway that is known by the term gene expression. In this article we review the existing literature on the structure and expression of representative salivary gland genes and their regulated expression during development and upon extracellular stimulation. The expression of one of the "nuclear" protooncogenes, c-fos, in rat parotid glands is also discussed. Finally, we present some suggestions for future studies that will help to understand the mechanisms leading to gene regulation in rat salivary glands.

Biosynthesis and secretion of rat salivary proteins by Xenopus laevis oocytes

Xenopus laevis oocytes injected with poly (A+) RNA isolated from rat parotid and submandibular glands synthesize and secrete salivary proteins. Amylase was identified in the media of cultured oocytes injected with rat parotid mRNA by size and immunoprecipitation with anti-human amylase serum. Secretion of the salivary proteins was detectable in the medium eight h following the parotid mRNA injection and continued in a time-dependent fashion for up to 96 h. In contrast to rat parotid slices in culture, which demonstrate a regulated pathway of secretion highly responsive to the secretagogue isoproterenol, secretion of salivary proteins by oocytes did not respond to the stimulation by isoproterenol. Though parotid mRNA is presumed to contain the templates encoding the regulated pathway of secretion, reconstitution of this pathway of secretion in oocytes was not observed in our experiments. Since Xenopus laevis oocytes secrete constitutively significant amounts of proteins when injected with salivary gland mRNA, they are a useful biological system for the analysis of secretion, processing, and function of salivary proteins.

Localization of neonatal secretory proteins in different cell types of the rat submandibular gland from embryogenesis to adulthood

In the neonatal rat submandibular gland, Type III cells contain a group of related proteins that we call the B1-immunoreactive proteins (B1-IP; 23.5, 26, and 27.5 kDa). Type I cells lack these, but synthesize a different protein, Protein C (89 kDa). With maturation of the gland, these neonatal cell types are no longer seen in the seromucous acini, which are no longer reactive for the B1-IP. Here, we report the ultrastructural immunocytochemical localization of the B1-IP and Protein C over the course of development. From their first appearance in the embryo, the B1-IP and Protein C are present in different cells which become morphologically typical Type I and III cells prior to birth. At all stages, Type I cells have strong Protein C labeling and no B1 labeling. By 3 days postpartum, ultrastructurally atypical Type III cells are seen (Type IIIP); these label for the B1-IP, but also show labeling with antibody to Protein C. In the next week, as mucous cells appear in the acini, these show both B1-IP and C labeling; the B1 marker is lost by 30 days postpartum, but adult mucous acinar cells continue to show Protein C reactivity. In view of the appearance of Protein C reactivity in neonatal Type IIIP and then in mucous cells, and the presence of B1 reactivity in early but not mature mucous cells, we suggest that Type III cells differentiate into mucous cells and that Type IIIP cells are intermediates in this transformation. We see no evidence for the differentiation of either Type III or mucous cells from Type I cells, although our data cannot rule out this possibility. In adult glands, cells with B1 labeling are seen in intercalated ducts. Cells that appear to be Type I cells are also present in these ducts and label for Protein C. Double labeling for B1-IP and Protein C demonstrated that the two markers were exclusively present in different cells within intercalated ducts. This is of considerable interest, as intercalated ducts have been reported to be the stem cell population for normal and trauma-induced cellular replacement.

Expression of glutamine/glutamic acid-rich proteins in rat submandibular glands

The expression of GRP transcripts was found to be highly specific to the rat submandibular gland. GRP cross-reactive species were detected in the saliva of both inbred and outbred rat strains. There was no evidence of GRP transcripts in RNA prepared from bovine, ovine, porcine or murine submandibular glands. Thus the GRPs differ from the family of PRPs that are expressed in several species. The restriction of GRP expression to the rat suggests a relatively recent origin for a functional GRP gene, presumably after rat-mouse divergence. The ontogeny of the relative steady-state levels of GRP transcripts was assessed by dot blot analysis. Maximal levels of RNA-encoding GRP were detected at 6 months; there was a significant age-related decline at both 12 and 18 months. There was, however, no significant age-related alteration in the size of transcripts which encode this protein family.

Purification and characterization of an inducible cysteine proteinase inhibitor from submandibular glands of isoproterenol-treated rats

A low-molecular-weight protein, induced in rats following prolonged isoproterenol treatment, has been purified from rat submandibular glands by chromatography on columns of Sepharose CL-6B, DEAE-Sepharose CL-6B, and Sephadex G-75. The purified protein is homogeneous based on gel electrophoresis and Ouchterlony double diffusion. The molecular weight of the purified protein was 14,000 and 15,500 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration on a Superose 12 column, respectively. This protein contains 31% glutamic acid/glutamine and aspartic acid/asparagine, 3.6% cysteine, and 2.5% proline. This protein is shown to be an inhibitor of several cysteine proteinases, papain and ficin being inhibited very strongly in approximately 1:1 molar ratio of enzyme to inhibitor. The protein is not detected in normal rat tissues but is induced in submandibular and sublingual glands even after 1 day of isoproterenol treatment of rats as early as 7 days after birth. Based on cysteine proteinase inhibitor activity, molecular size, and chemical composition this protein appears to belong to the cystatin superfamily.

Effect of protein malnutrition on the composition of submandibular glands of aged rats

Fifty 22-month-old male Sprague-Dawley rats were fed for 8 weeks ad libitum with either a 20% protein diet (control) or a 5% protein diet (protein malnourished group). Submandibular glands were removed, weighed and homogenate prepared. After the low protein diet, there was a slight but significant decrease in body weight, glandular content of total protein (mg/g tissue), kallikrein activity/mg protein and glutamine-rich peptide. In contrast, the gland weight, DNA and mucin content were not changed by feeding a low protein diet. Thus in aged rats submandibular glands are only modestly affected by protein malnutrition and the effects on gland-specific proteins vary.

Dissociation between c-fos gene expression and DNA synthesis in rat parotid glands

Two experimental approaches were used to examine the relationship between c-fos gene expression and tissue proliferative responses. Beta-Adrenergic and muscarinic receptor stimulation yielded equivalent levels of c-fos expression, although only beta-adrenergic receptor agonists are reported as capable of eliciting DNA synthesis in parotid cells. Similarly, beta-adrenergic stimuli evoked comparable levels of c-fos expression in parotid cells from 2- and 12-month-old rats, whereas DNA synthesis has been shown to be much greater in younger animals. The results indicate that enhanced c-fos expression by itself is incapable of eliciting proliferative responses in rat parotid glands.

Proline-rich proteins and glycoproteins: expression of salivary gland multigene families

Our recent research interests have focused on a group of unusual proteins and glycoproteins high in proline content, or the so-called proline-rich proteins (PRPs). The PRPs are tissue-specific expressions of salivary gland multigene families. Normally PRPs are not detected or are present in very low amounts in rat, mouse and hamster salivary glands, but these unusual proteins are dramatically induced by treatment with the catecholamine isoproterenol. The structures and organizations of several PRP mRNAs and PRP genes have been determined. The amino acid sequences of all PRPs show 4 distinct regions, namely, a signal peptide, a transition region, a repeat region and a carboxyl-terminal region. Glycoproteins induced by isoproterenol treatment may be N-glycosylated or O-glycosylated. The N-glycosylated glycoprotein GP-158 from rat submandibular glands has a 12 amino acid glycopeptide which repeats possibly 49 times. Proline-rich proteins of the parotid glands of rats and mice are also greatly induced by dietary tannins. The apparent unique occurrence of PRPs in saliva suggests that one biological role is to neutralize the detrimental effects of dietary tannins and other polyphenols. The upstream regions of the mouse and hamster PRP genes contain cyclic AMP-regulated sequences as demonstrated by deletions and transient transfections. The PRP multigene family members of mouse are all located on chromosome 8.

Cloning and sequencing of cDNA for a highly anionic peroxidase from potato and the induction of its mRNA in suberizing potato tubers and tomato fruits

A highly anionic peroxidase was strongly suggested to be involved in the deposition of the aromatic domain of suberin. cDNA containing the coding region of the suberization-associated anionic peroxidase from potato has been cloned and sequenced. The deduced amino acid sequence of the peroxidase shows that it is an anionic protein with considerable homology to other peroxidases. The amino acid sequence of two tryptic peptides obtained from the anionic peroxidase purified from suberizing potato tuber slices matched exactly with two segments of the amino acid sequence deduced from the nucleotide sequence of the cloned cDNA. The identity of the cloned cDNA is further supported by hybrid-selected translation and immunological recovery of the product with antibodies prepared against the purified anionic peroxidase. This anionic peroxidase was barely detectable at 2 days after wounding, and reached a maximal level at 8 days after wounding. Using the cDNA for the anionic peroxidase as a probe, we showed that the mRNA for the enzyme was induced in suberizing potato. The mRNA levels increased from an undetectable level in control tuber tissue to a maximal level in suberizing tuber tissue aged for four days. In suberizing tomato fruit the peroxidase mRNA showed induction and the level reached a maximum in three days. Ine data suggest that the induction of the peroxidase by wounding is preceded by transcriptional activation of the peroxidase gene or by increased stabilization of the mRNA. The time course of increase in mRNA for the anionic peroxidase was consistent with its postulated role in suberization.