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.

Rodent submandibular gland peptide hormones and other biologically active peptides.

The cervical sympathetic trunk-submandibular gland neuroendocrine axis plays an integral role in physiological adaptations and contributes to the maintenance of systemic homeostasis, particularly under the 'stress conditions' seen with tissue damage, inflammation, and aggressive behavior. The variety of polypeptides, whose release from acinar and ductal cells is under sympathetic nervous system control, offers coordinated and progressive levels of endocrine communication. Proteolytic enzymes (e.g. the kallikreins and furin maturases) are involved in the conversion of inactive precursors (e. g. Pro-EGF and SMR1) into biologically active molecules (e.g. EGF, SMR1-pentapeptide), which act on local or distant targets and thereby modulate the homeostatic process.

Crystal structure of the allergen Equ c 1. A dimeric lipocalin with restricted IgE-reactive epitopes.

The three-dimensional structure of the major horse allergen Equ c 1 has been determined at 2.3 A resolution by x-ray crystallography. Equ c 1 displays the typical fold of lipocalins, a beta-barrel flanked by a C-terminal alpha-helix. The space between the two beta-sheets of the barrel defines an internal cavity that could serve, as in other lipocalins, for the binding and transport of small hydrophobic ligands. Equ c 1 crystallizes in a novel dimeric form, which is distinct from that observed in other lipocalin dimers and corresponds to the functional form of the allergen. Binding studies of point mutants of the allergen with specific monoclonal antibodies raised in mouse and IgE serum from horse allergic patients allowed to identify putative B cell antigenic determinants. In addition, total inhibition of IgE serum recognition by a single specific monoclonal antibody revealed the restricted nature of the IgE binding target on the molecular surface of Equ c 1.

Acinar cells are target cells for androgens in mouse submandibular glands.

The variable coding sequence (VCS) multigene family encodes diverse salivary proteins, such as the SMR1 prohormone and the PR-VB1 proline-rich protein in the rat. In situ hybridization was used to study the cell-specific expression of two new mouse VCS genes, Vcs1 and Vcs2. We show that the Vcs1 transcripts, which code for a proline-rich protein, MSG1, are highly abundant in male and female parotid glands, in which they are specifically detected in acinar cells. No expression was seen in the submandibular or sublingual glands. In contrast, Vcs2 transcripts were found only in the acinar cells of the submandibular glands (SMGs) of male mice, in which they are expressed in response to androgens. Expression was found to be heterogeneous within acinar structures. No Vcs2 transcripts were detected in the SMGs of females or castrated males by Northern blot, RNase protection, or in situ hybridization. Androgen administration to females or castrated males induced expression at a level comparable to that of intact males. The Vcs2 gene is the first example of a mouse androgen-regulated gene that is expressed in SMG acinar cells. This result, in addition to our previous observation on SMR1 expression in rats, demonstrates that both acinar cells and granular convoluted tubule (GCT) cells are target cells for androgen action in rodent SMG.

Endotoxin induces expression of type II phospholipase A2 in macrophages during acute lung injury in guinea pigs: involvement of TNF-alpha in lipopolysaccharide-induced type II phospholipase A2 synthesis.

Elevated levels of secretory type II phospholipase A2 (sPLA2-II) have been associated with a poor clinical outcome in the acute respiratory distress syndrome. This study identifies the cell source(s) and the mechanisms of sPLA2-II synthesis in the guinea pig model of acute respiratory distress syndrome induced by intratracheal injection of LPS. Administration of LPS led to an increase in lung membrane-associated calcium-dependent sPLA2 activity, which was abrogated by LY311727, a selective inhibitor of sPLA2-II. No sPLA2 activity was detected in the vascular compartment of the lung. LPS administration induced a parallel accumulation of sPLA2-II mRNA in lung tissues. In situ hybridization showed that sPLA2-II transcripts were synthesized in interstitial and alveolar macrophages (AM). Incubation of AM with LPS enhanced the expression of sPLA2-II mRNA, leading to stimulation of sPLA2-II synthesis and secretion. This increase was prevented by the addition of anti-TNF-alpha and anti-p55 TNF receptor Abs. Furthermore, the addition to AM of cellfree bronchoalveolar fluid collected from LPS-treated guinea pigs increased sPLA2-II expression, which was abrogated by anti-TNF-alpha Ab. These findings demonstrate that 1) macrophages are in vivo the major cell source of sPLA2-II in LPS-induced acute lung injury; 2) in contrast to that in other cell systems, regulation of LPS-induced sPLA2-II synthesis in AM is TNF-alpha dependent; and 3) production of TNF-alpha in the air-lung interface is an important step for sPLA2-II synthesis in macrophages.

cDNA cloning and sequencing reveal the major horse allergen Equ c1 to be a glycoprotein member of the lipocalin superfamily.

The gene encoding the major horse allergen, designated Equus caballus allergen 1 (Equ c1), was cloned from total cDNA of sublingual salivary glands by reverse transcription-polymerase chain reaction using synthetic degenerate oligonucleotides deduced from N-terminal and internal peptide sequences of the glycosylated hair dandruff protein. A recombinant form of the protein, with a polyhistidine tail, was expressed in Escherichia coli and purified by immobilized metal affinity chromatography. The recombinant protein is able to induce a passive cutaneous anaphylaxis reaction in rat, and it behaves similarly to the native Equ c1 in several immunological tests with allergic patients' IgE antibodies, mouse monoclonal antibodies, or rabbit polyclonal IgG antibodies. Amino acid sequence identity of 49-51% with rodent urinary proteins from mice and rats suggests that Equ c1 is a new member of the lipocalin superfamily of hydrophobic ligand-binding proteins that includes several other major allergens. An RNA blot analysis demonstrates the expression of mRNA Equ c1 in liver and in sublingual and submaxillary salivary glands.

Episodic evolution and rapid divergence of members of the rat multigene family encoding the salivary prohormone-like protein SMR1.

In rodents, the variable coding sequence (VCS) multigene family displays extensive evolutionary divergence in the protein-coding region. While certain VCS genes coding for proline-rich proteins (hPR-PB, mMSG1, rPR-VB1) are conserved in primates and rodents, others seem to be specific to certain genera. This appears to be the case for the Rattus genes forming the A-subclass. This subclass is composed of three genes in R. norvegicus and probably five genes in R. rattus. The first described VCSA gene (Rn. VCSA1) was found to encode a prohormone-like protein named SMR1 (-VA1), expressed mainly in the submandibular glands (SMG) of male rats. To further understand the evolution of this variable multigene family, we have cloned the two additional genes (Rn. VCSA2 and Rn. VCSA3) forming the R. norvegicus A-subclass and three VCSA genes (Rr. VCSA1a, b and Rr. VCSA2) of R. rattus. The putative SMR1 proteins encoded by all these genes display the same prohormone-like structure as Rn. SMR1-VA1. However, we observe a polymorphism in some internal cleavage sites which suggests that multiple processing of the SMR1 proteins could result in the liberation of peptides differing in structure and length. The phylogenetic analysis of the sequences reveals that the duplication events giving rise to the VCSA1, -A2, and -A3 progenitors were anterior to the R. norvegicus and R. rattus split, and that a VCSA1 duplication event likely occurred specifically in R. rattus. A striking observation is that the coding sequences of the VCSA genes have rapidly diverged from their ancestors. Along all branches of the phylogeny, the nonsynonymous divergence rate is identical or superior to the synonymous divergence rate. We suggest that frequent changes in functional requirements are mainly responsible for the episodic evolution and the rapid divergence of the VCSA genes.

Various transcripts are generated from the VCSA1 gene by alternative splicing and poly(A) processing in the rat submandibular gland.

The members of the VCS (variable coding sequence) multigene family display extensive evolutionary divergence in the protein-coding region. The first described gene (VCSA1) was found to encode a major 0.7-kb mRNA (VCSA1*1T1) coding for a prohormone-like preproprotein, SMR1-VA1, in the submandibular gland (SMG) of Rattus norvegicus. We report here the cloning of four other VCSA1 cDNAs corresponding to mRNAs (VCSA1*1T2 to *1T5) expressed in the SMG. VCSA1*1T1 to *1T4 mRNAs share the three exons previously described and differ in their 3' untranslated regions (UTR). Their differences originate from the alternative utilization of four polyadenylation sites. Comparison of the tissue levels of VCSA1*1T1 and VCSA1*1T4 during post-natal development of the male rat SMG suggests that the poly(A) addition sites are both used at each stage. The fifth RNA transcript (VCSA1*1T5) contains only the first two exons. The nucleotide sequence of the cDNA reveals that VCSA1 has an additional exon (exon 4) which is spliced to exon 2 in VCSA1*1T5. In addition to VCSA1*1T1, at least VCSA1*1T4 and VCSA1*1T5 are actively translated in vivo, as revealed by their association to the polysomal fractions. The protein, P2-VA1, coded by VCSA1*1T5 is 68 amino acids in length and it is likely to be a glycosylated secretory protein. The putative mature P2-VA1 protein completely differs from the SMR1-VA1 pro-protein and very likely has a different function. VCSA1*1T1 is accumulated in the male rat SMG 200-1000-fold more than the other transcripts. Run-on experiments reveal that almost all transcription proceeds several hundred bp downstream from the poly(A) site corresponding to VCSA1*1T1.(ABSTRACT TRUNCATED AT 250 WORDS)

Selective processing of submandibular rat 1 protein at dibasic cleavage sites. Salivary and bloodstream secretion products.

The amino acid sequence of submandibular rat 1 (SMR1) protein, deduced from its cDNA sequence, led to the prediction that the SMR1 gene encodes a hormone-like precursor [Rosinski-Chupin, I., Tronik, D. & Rougeon, F. (1988) Proc. Natl Acad. Sci. USA 85, 8553-8557]. SMR1 contains an N-terminal putative secretory signal sequence and a tetrapeptide (QHNP), located between dibasic amino acids which constitute the most common signal for prohormone processing. We have isolated and characterized from the male rat submandibular gland and its secretions three structurally related peptides, namely an undecapeptide (VRGPRRQHNPR), a hexapeptide (RQHNPR) and a pentapeptide (QHNPR) generated from SMR1 by selective proteolytic cleavages at pairs of arginine residues. The biosynthesis of these peptides is subjected to distinct regulatory pathways depending on the organ, sex and age of the rat. Furthermore, the peptides are differentially distributed in the submandibular gland and in resting or epinephrine-elicited submandibular salivary secretions, suggesting distinct proteolytic pathways for their maturation. The undecapeptide is generated in the gland of both male and female rats, but under basal conditions it is only released into the saliva in male animals. The hexapeptide is produced in large amounts in the gland of adult male rats and released into the saliva in both resting and stimulated conditions. The pentapeptide appears only in the male saliva and is present mostly under stimulated conditions. In addition, administration of epinephrine induces the release of the hexapeptide from the submandibular gland into the bloodstream. The evidence indicates that the rat submandibular gland can function as a dual exocrine and endocrine organ for the SMR1-derived hexapeptide, as has been reported for nerve growth factor, epidermal growth factor, renin and kallikrein. Although the biological activities of the SMR1-derived peptides are not yet known, their high production and adrenergic-induced release only into the saliva and bloodstream of adult male rats, suggest a physiological involvement in some male-specific processes.

A new proline-rich protein precursor expressed in the salivary glands of the rat is encoded by a gene homologous to the gene coding for the prohormone-like protein SMR1.

A gene encoding a prohormone-like protein (SMR1) has previously been characterized and shown to be expressed in the rat submandibular glands under androgenic control (Rosinski-Chupin, I., Tronik, D., and Rougeon, F. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 8553-8557). This gene, now named VCS-alpha 1, belongs to a multigene family (Rosinski-Chupin, I., and Rougeon, F. (1990) DNA Cell Biol. 9, 553-559). We now describe the structure and the expression of a second member (VCS-beta 1) of this family. The two genes differ principally in the protein-coding region, therefore we have named these related genes VCS (variable coding sequence). Genomic clones containing the VCS-beta 1 gene were obtained by screening a lambda EMBL3 library with a probe corresponding to the VCS-alpha 1 cDNA. The nucleotide sequence of VCS-beta 1 predicted a structure containing three exons. This structure, confirmed by sequencing a VCS-beta 1 cDNA obtained by reverse polymerase chain reaction, is identical to the organization of the VCS-alpha 1 gene. Comparison of the VCS-beta 1 and VCS-alpha 1 genomic sequences indicates regions of homology which are unevenly distributed, suggesting a differential evolution of some areas (particularly the third exon) of the VCS genes. The VCS-beta 1 cDNA codes for a proline-rich protein precursor named PR-V beta 1 (148 amino acids, 39.2% proline, 10.8% glycine) and characterized by a secretory signal-peptide and three repeats of a unit rich in proline residues surrounded by two clusters of potential endoprotease cleavage sites. mrNA coding for PR-V beta 1 was detected in the submandibular-sublingual gland complex of male and female rats. PR-V beta 1 is homologous to the proline-rich peptide B isolated from human saliva (Isemura, S., Saitoh, E., and Sanada, K. (1979) J. Biochem. (Tokyo) 86, 79-86) and to the submandibular proline-rich protein precursor MSG1 of the mouse (D. Tronik-Le Roux, M. Senorale-Pose, and F. Rougeon, manuscript in preparation). Our observations provide evidence that in addition to the known proline-rich protein genes, there is, in rodent and probably human genomes, another class of genes coding for salivary proline-rich proteins. The high conservation of various sites for bacterial collagenases localized in the repeat region of PR-V beta 1, MSG1, and PRP-B suggest a protective function of these proteins in the oral cavity.

Localization of mRNAs of two androgen-dependent proteins, SMR1 and SMR2, by in situ hybridization reveals sexual differences in acinar cells of rat submandibular gland.

Androgen-dependent sexual differences in the granular convoluted tubules of mouse and rat submandibular glands (SMG) have been extensively reported. We studied two major androgen-dependent mRNAs of the rat SMG encoding proteins named SMR1 and SMR2. To determine which cell type in the SMG is responsible for synthesis of these mRNAs, we performed in situ hybridization with digoxigenin-labeled RNA probes coupled with alkaline phosphatase detection. We show that SMR1 and SMR2 mRNAs are synthesized in the acinar cells of the SMG. A clear difference in SMR1 and SMR2 mRNA levels in male and female is demonstrated. During the course of this study we also confirmed the acinar localization of mRNAs encoding the glutamine/glutamic acid-rich proteins (GRP) of rat SMG. Our data are the first clear evidence of androgen-dependent sexual differences in acinar cells of rat submandibular gland.

Gene structure and chromosomal localization of plasma kallikrein.

Plasma kallikrein (Fletcher factor) is a hepatic serine proteinase that participated in the early phase of blood coagulation. From two genomic libraries, we succeeded to isolate four overlapping clones representing the entire rat plasma kallikrein gene. Using selective DNA sequencing, polymerase chain reactions, and restriction mapping, we demonstrated that the gene for rat plasma kallikrein was 22 kb in length. Similar to human factor XI [Asakai et al. (1987) Biochemistry 26, 7221-7228], we also found that the plasma kallikrein gene is composed of 15 exons and 14 introns. A potential transcription initiation step was determined by a novel application of the polymerase chain reaction technique. Computer analysis of the 5'-promoter region of this gene revealed some putative control elements that might regulate the rat plasma kallikrein gene expression. These data and the results of chromosomal localization reported in the present study for mouse (chromosome 8) and human (chromosome 4) plasma kallikrein genes strongly corroborate a genic duplication event from a common ancestor to both plasma kallikren and factor XI.

The gene encoding SMR1, a precursor-like polypeptide of the male rat submaxillary gland, has the same organization as the preprothyrotropin-releasing hormone gene.

SMR1 is a precursor-like polypeptide of the submaxillary glands of rats. Sequence analysis predicts that it could be processed by maturation enzymes to release a small peptide resembling the thyrotropin-releasing hormone. The SMR1 gene was isolated from a rat genomic library and sequenced. The SMR1 gene spans 4.7 kb and consists of three exons. The two introns occur a few nucleotides before the initiation codon in the 5' untranslated region, and a few nucleotides before the first predicted processing site, respectively. Such a structure is reminiscent of that of the preprothyrotropin-releasing hormone gene. The site of transcriptional initiation of the SMR1 gene was determined and 1.4 kb of 5'-flanking sequence was sequenced. The sequence analysis revealed the presence of alternating purine-pyrimidine tracts and of purine-rich sequences. In addition, some sequences which could be involved in the regulation of SMR1 gene expression were identified.

One amino acid change in rat SMR1 polypeptide induces a 1 kDa difference in its apparent molecular mass determined by electrophoretic analysis.

SMR1 is a male-specific, 19 kDa, in vitro translation product of Wistar rat submaxillary glands, which may be the precursor of a small hormone resembling the TRH. In Sprague-Dawley and Fischer rats, instead of SMR1, a male-specific 18 kDa polypeptide may be found. We have cloned the cDNA encoding the 18 kDa polypeptide. We show that the 19 and the 18 kDa polypeptides have the same sequence except for one amino and change.

A new member of the glutamine-rich protein gene family is characterized by the absence of internal repeats and the androgen control of its expression in the submandibular gland of rats.

A cDNA, corresponding to a rat submandibular mRNA which is accumulated at a 20-fold higher level in males than females, has been isolated. The predicted protein, SMR2, has a calculated molecular mass of 15.4 kDa and is rich in glutamine/glutamic acid, proline, and asparagine/aspartic acid, a characteristic of the so-called salivary glutamine-rich proteins (GRPs) of the submandibular gland of rats. Nucleotide sequence comparisons indeed revealed strong similarities between the sequences of the SMR2 mRNA and that of GRPs, except in the region encoding the carboxyl-terminal part of the proteins. In particular, the SMR2 mRNA contains the 5'-untranslated region and the signal peptide region shared by both groups of GRPs and proline-rich proteins (PRPs). A major difference is that, in SMR2, the peptidic motif which is repeated four or five times in GRPs, is only found once. The SMR2 gene is about 3.5 kilobases in length and contains 4 exons. The second intron, which does not exist in characterized GRP genes, splits the "transition" region which separates the repetitive sequences from the signal peptide. This structure is reminiscent of that found in most PRP genes, strengthening the hypothesis that GRP and PRP genes have the same ancestral origin.

High level of accumulation of a mRNA coding for a precursor-like protein in the submaxillary gland of male rats.

NaDodSO4/PAGE analysis of in vitro translation products of rat submaxillary gland (SMG) mRNAs has revealed an important sexual dimorphism. Moreover, most of the rat male-specific major translation products differ in size from those translated from male mouse SMG mRNAs. To characterize proteins accumulated in the rat SMG under androgen control, a cDNA library was constructed. Here we report the nucleotide sequence of a 0.7-kilobase mRNA that is 1000-3000 times more abundant in male rats than in female rats. The predicted corresponding protein, SMR1, has a molecular weight of 16,000 and contains a signal peptide for secretion and potential signals for glycosylation. An interesting feature of SMR1 is the presence, in a hydrophilic region, of the tetrapeptide Gln-His-Asn-Pro surrounded by two pairs of basic residues that represent potential cleavage sites for maturation enzymes. In rats, the tissue distribution of the SMR1 mRNA is restricted to the SMG and the prostate. Only very low amounts of SMR1 mRNA can be detected in the SMG of male or female mice. Southern blot analysis indicates the presence of three genes in rats but only one in mice. Hypotheses on the physiological role of SMR1-derived peptides in male rats are discussed.