Kidney and submaxillary gland renins are encoded by two non-allelic genes in Swiss mice.

Two distinct phenotypic groups of inbred strains of mice, with different amounts of submaxillary gland (SMG) renin have been described. We have previously shown that strains with high levels of SMG renin, such as Swiss or AKR mice, have two renin genes, Rn1 and Rn2, per haploid genome, while strains with low levels of SMG, such as BALB/c or C57Bl/6, have only one renin gene. We now report the molecular cloning of cDNA copies of Swiss mouse kidney renin mRNA and present nucleotide sequence data of the recombinant clones. Comparison of these sequences with the sequence of Swiss mouse SMG renin mRNA we have previously reported, demonstrates that Swiss mice express the two non-allelic genes, Rn1 and Rn2.     

Molecular cloning of two distinct renin genes from the DBA/2 mouse.

We report the molecular cloning of cDNA copies of DBA/2 mouse submaxillary gland (SMG) renin mRNA, which were used to probe Southern transfers of mouse genomic DNA. The results suggested either that there is a single renin gene containing a large intron in that part of the gene corresponding to the probe, or that there are two distinct renin genes. We have shown that the latter is the case by cloning and isolating two similar but distinct renin genes from DBA/2 mouse DNA. Restriction maps of the regions containing the two renin genes are presented, together with nucleotide sequence data locating a complete exon coding for amino acids 268-315 of mouse SMG renin.     

Pregnancy-induced changes in renin gene expression in mice.

A puzzling feature of the renin-angiotensin system during pregnancy is the appearance in the maternal circulation of a large increase in the concentration of prorenin and renin. The physiologic role of these changes is not understood. We determined that high levels of renin protein occur in the circulation of pregnant mice, thereby establishing the mouse as a valuable model for understanding gestation-induced changes in the renin-angiotensin system. We used the murine model to show that high levels of renin gene expression occur at the mother-fetus interface, first in maternal decidua and subsequently in placentas. These results were obtained using ICR mice that have 2 related renin genes, Ren1 and Ren2. We also examined renin gene expression in C57Bl/6 mice that have only the Ren1 gene. In these mice, very little renin gene expression was observed in placentas but instead was upregulated in kidneys during pregnancy. In both ICR and C57Bl/6 mice, there is an increase in renin protein in the maternal circulation during pregnancy. However, these mice differ with regard to gestation-induced sites of increased renin gene expression. These studies suggest that mice are a convenient and valuable model for studying renin gene expression during pregnancy.     

The mouse Rn locus: S allele of the renin regulator gene results from a single structural gene duplication.

Inbred strains of mice have been divided into two distinct phenotypic groups having different levels of renin activity regulated by androgen in the submaxillary gland (SMG). Strains carrying the Rnrs allele of the renin gene regulator, located on chromosome 1, have a high level of renin activity; strains carrying the Rnrb allele have a low level of renin activity. The level of SMG renin activity correlates with the level of renin mRNA. We have analyzed, by Southern blot hybridization, the organization of renin genes in both strains. Strains carrying the Rnrb allele, such as BALB/c or C57 Bl/6, or CH3 mice, have one renin structural gene per haploid genome, while those having the Rnrs allele, such as AKR or Swiss mice, have two renin genes. We have also identified renin genes in mice belonging to different biochemical groups: Mus spretus has one renin gene while M. vrania and M. musculus brevirostris have two renin genes.     

Ablation of renin-expressing juxtaglomerular cells results in a distinct kidney phenotype

Renin-expressing cells are peculiar in that they act as differentiated cells, producing the hormone renin, while they also seem to act as progenitors for other renal cell types. As such, they may have functions independent of their ability to generate renin/angiotensin. To test this hypothesis, we ablated renin-expressing cells during development by placing diphtheria toxin A chain (DTA) under control of the Ren1d mouse renin promoter by homologous recombination in a two-renin gene strain (Ren2 and Ren1d). Renin-expressing cells are essentially absent from kidneys in homozygotes (DTA/DTA) which, unlike wild-type mice, are unable to recruit renin-expressing cells when homeostasis is threatened. In contrast, renin staining in the submandibular gland (SMG), which expresses mainly Ren2, is normal. Homozygous mice survive normally, but the kidneys are small and have morphological abnormalities: 25% of the glomeruli are hyperplastic or atrophic, tubules are dilated and atrophic, and areas of undifferentiated cells exist near the atrophic glomeruli and tubules. However, in contrast to the very abnormal renal vessels found when renin-angiotensin system genes are deleted, the kidney vessels in homozygotes have normal wall thickness and no decrease in lumen size. Homozygotes have severely reduced kidney and plasma renin concentrations and females have reduced blood pressure. Homozygotes have elevated blood urea nitrogen and potassium levels, which are suggestive of altered renal function. We conclude that renin cells per se are necessary for the morphological integrity of the kidney and may have a role in maintenance of normal kidney function.     

DNA insertions distinguish the duplicated renin genes of DBA/2 and M. hortulanus mice.

In a survey of inbred and wild mouse DNAs for genetic variation at the duplicate renin loci, Ren-1 and Ren-2, a variant Not I hybridization pattern was observed in the wild mouse M. hortulanus. To determine the basis for this variation, the structure of the M. hortulanus renin loci has been examined in detail and compared to that of the inbred strain DBA/2. Overall, the gross features of structure in this chromosomal region are conserved in both Mus species. In particular, the sequence at the recombination site between the linked Ren-1 and Ren-2 loci was found to be identical in both DBA/2 and M. hortulanus, indicating that the renin gene duplication occurred prior to the divergence of ancestors of these mice. Renin flanking sequences in M. hortulanus, however, were found to lack four DNA insertions totaling approximately 10.5 kb which reside near the DBA/2 loci. The postduplication evolution of the mouse renin genes is thus characterized by a number of insertion and/or deletion events within nearby flanking sequences. Analysis of renin expression showed little or no difference between these mice in steady state renin RNA levels in most tissues examined, suggesting that these insertions do not influence expression at those sites. A notable exception is the adrenal gland, in which DBA/2 and M. hortulanus mice exhibit different patterns of developmentally regulated renin expression.     

Molecular mechanism of tissue-specific regulation of mouse renin gene expression by cAMP. Identification of an inhibitory protein that binds nuclear transcriptional factor.

Renin gene expression in the mouse kidney and submandibular gland (SMG) are differentially regulated by cAMP. In this study, we examined the potential molecular mechanism responsible for this tissue-specific regulation. 32P end-labeled synthetic oligonucleotide containing mouse renin cAMP-responsive element (CRE) was incubated with kidney nuclear extracts from either control or cAMP-treated mice and analyzed by gel mobility shift assay. Our results demonstrated that cAMP induced a nuclear protein which complexed with the CRE oligonucleotide in a specific manner. This nuclear protein-DNA binding was competed effectively by the oligonucleotide containing human chorionic gonadotropin alpha-subunit CRE but not by the mouse renin DNA fragment from which the CRE was deleted by site-directed mutagenesis. In contrast, no DNA-protein complex formation could be detected when this [32P]CRE oligonucleotide was incubated with the SMG nuclear extract from control or cAMP-treated mice. However, CRE-binding protein complex formation was demonstrated in the SMG nuclear extract when the incubation was performed in the presence of 0.8% sodium deoxycholate and 1.2% Nonidet P-40, detergents that dissociate protein-protein complexes. Furthermore, in the absence of deoxycholate, we observed that SMG nuclear extract attenuated the binding of the kidney CRE-binding protein to mouse renin CRE in a dose-dependent manner and this inhibitory effect of SMG nuclear extract disappeared in the presence of sodium deoxycholate. This inhibitory nuclear protein in SMG is specific for CRE-binding protein since it does not affect nuclear protein binding to synthetic DNA oligonucleotides of human collagenase AP-1 and human metallothionein AP-2. Our data further suggest that inhibitory nuclear protein is present in lower quantities in other extrarenal tissues, i.e. testes, liver, brain, heart, but is not detectable in the kidney. Taken together, these results suggest that the SMG and certain extrarenal tissues contain nuclear trans-acting factor(s) that interact with CRE-binding protein, thereby interfering with its binding to mouse renin CRE. The presence of this inhibitory protein in the mouse SMG nucleus may contribute to the tissue-specific regulation of the renin gene expression by cAMP.     

Evaluation of the 5'-flanking regions of murine glutathione peroxidase five and cysteine-rich secretory protein-1 genes for directing transgene expression in mouse epididymis

Based on strong epididymal expression of the mouse glutathione peroxidase 5 (GPX5) and cysteine-rich secretory protein-1 (CRISP-1) genes, we evaluated whether the 5.0-kilobase (kb)-long GPX5 and 3.8-kb-long CRISP-1 gene 5'-flanking regions could be used to target expression of genes of interest into the epididymis in transgenic mice. Of the two candidate promoters investigated, the CRISP-1 promoter-driven enhanced green fluorescent protein (EGFP) reporter gene was highly expressed in the tubular compartment of the testis in all stages of the seminiferous epithelial cycle between pachytene spermatocytes at stage VII to elongated spermatids at step 16. In contrast to CRISP-1, the 5.0-kb 5' region of the mouse GPX5 gene directed EGFP expression to the epididymis. In the various GPX5-EGFP mouse lines, strongest expression of EGFP mRNA was found in the epididymis, but low levels of reporter gene mRNA were detected in several other tissues. Strong EGFP fluorescence was found in the principal cells of the distal caput region of epididymis, and few fluorescent cells were also detected in the cauda region. No EGFP fluorescence was detected in the corpus region or in the other tissues analyzed. Hence, it is evident that the 5.0-kb 5'-flanking region of GPX5 promoter is suitable for directing the expression of structural genes of interest into the caput epididymidis in transgenic mice.     

Regulated expression of chimaeric genes containing the 5''-flanking regions of human growth hormone-related genes in transiently transfected rat anterior pituitary tumor cells.

The expression and hormonal regulation of chimaeric genes containing the 5'-flanking regions of the normal human growth hormone (hGH-1), the variant hGH (hGH-2) and chorionic somatomammotropin (hCS-1) genes fused to the chloramphenicol acetyl transferase (CAT) gene has been examined after transient transfection into cultured rat pituitary (GC), and non-pituitary (HeLa and Rat 2) tumor cells. As assessed by levels of CAT activity, the hGH-1 and hCS-1 gene hybrids were expressed at 5- to 25-fold higher levels in GC cells than in HeLa or Rat 2 cells. The hGH-2 gene hybrid was expressed at very low levels in all 3 cell types. Triiodothyronine treatment of transiently transfected GC cells had little effect on CAT activity from the hGH-1 gene hybrid but increased CAT activity from the hCS-1 gene hybrid. A slight but significant increase in CAT expression was detected with both genes after dexamethasone treatment. The data indicate that elements present on the hGH-1 and hCS-1 genes' 5'-flanking DNA are required for the efficient expression of these genes in GC cells.     

Evolution of aspartyl proteases by gene duplication: the mouse renin gene is organized in two homologous clusters of four exons.

Overlapping recombinant clones that appear to encompass the entire renin gene, named Ren 1, have been isolated from a library of BALB/c mouse genomic DNA fragments. Based on restriction endonuclease mapping and DNA sequence analysis, Ren 1 spans 9.6 kb and contains nine exons interrupted by eight intervening sequences of highly variable size. The first exon, encoding the signal peptide of preprorenin, is separated from the eight following exons by a 3-kb intron. These eight exons are organized into two clusters of four separated by a 2-kb intron. DNA stretches encoding the aspartyl residues, which are part of the active site of renin, are located at homologous positions in both clusters. Our results show that aspartyl protease genes have arisen by duplication and fusion of an ancestral gene containing five exons. The estimated date of the duplication event of the mouse renin genes Ren 1 and Ren 2 is discussed.     

DNA insertions distinguish the duplicated renin genes of DBA/2 andM. hortulanus mice

In a survey of inbred and wild mouse DNAs for genetic variation at the duplicate renin loci,Ren-1 andRen-2, a variantNot I hybridization pattern was observed in the wild mouseM. hortulanus. To determine the basis for this variation, the structure of theM. hortulanus renin loci has been examined in detail and compared to that of the inbred strain DBA/2. Overall, the gross features of structure in this chromosomal region are conserved in bothMus species. In particular, the sequence at the recombination site between the linkedRen-1 andRen-2 loci was found to be identical in both DBA/2 andM. hortulanus, indicating that the renin gene duplication occurred prior to the divergence of ancestors of these mice. Renin flanking sequences inM. hortulanus, however, were found to lack four DNA insertions totaling approximately 10.5 kb which reside near the DBA/2 loci. The postduplication evolution of the mouse renin genes in thus characterized by a number of insertion and/or deletion events within nearby flanking sequences. Analysis of renin expression showed little or no difference between these mice in steady state renin RNA levels in most tissues examined, suggesting that these insertions do not influence expression at those sites. A notable exception is the adrenal gland, in which DBA/2 andM. hortulanus mice exhibit different patterns of developmentally regulated renin expression.     

A DNA polymorphism,consistent with gene duplication,correlates with high renin levels in the mouse submaxillary gland

The renin regulatory locus (Rnr) is a genetic element governing mouse submaxillary gland (SMG) renin levels. A 45,000 dalton polypeptide detectable after in vitro translation of mouse SMG mRNA has been identified by genetic and physical criteria as SMG renin. A cDNA recombinant clone specific for SMG renin has been isolated and used to demonstrate that the previously described genetic regulation of SMG renin levels is manifest at the level of renin mRNA concentration. The renin cDNA clone has also been used in Southern blot analyses to study the organization of homologous DNA sequences in strains carrying different alleles at the Rnr locus. Restriction digest patterns of high renin strains (Rnr^s) are characteristically distinct from patterns observed for low renin strains (Rnr^b) and are suggestive of a structural gene duplication at the chromosome 1 locus in high renin strains. However, gene dosage cannot account for the increased levels in high renin strains, since SMG renin levels in Rnr^s and those in Rnr^b may differ up to 100-fold.     

Tubular morphogenesis and mesenchymal interactions affect renin expression and secretion in SIMS mouse submandibular cells

We have previously immortalized a mouse submandibular gland (SMG) ductal epithelial cell line, SIMS, from pubertal male mice transgenic for the SV40 large T antigen under the control of the adenovirus 5 E1A promoter. Here we demonstrate the role of the extracellular environment in directing not only the morphogenetic behavior of the cells, but also their functional differentiation in terms of renin expression and secretion. First, we measured renin activity of polarized SIMS cells. Low levels of renin are secreted from both the apical and the basolateral domains; the mechanism appears to be direct as no renin was found to be transcytosed across the cell. Second, we studied homotypic and heterotypic mesenchymal cell interactions with SIMS cells. We found that epithelial-mesenchymal coculture in collagen I gels results in branching tubular morphogenesis of SIMS cells and that significant amounts of renin are secreted, probably into the lumen, as the precursor form, prorenin. Third, we investigated the effects of the basement membrane on SIMS cell morphology and function and found that this structure alone is sufficient to allow expression and secretion of both prorenin and active renin. Finally, we established that SIMS cells can express androgen-regulated genes in a transient transfection assay. In addition, in Matrigel cultures androgen receptor expression appears to be induced, suggesting that the SIMS cell line will be useful for further studies on the molecular basis of the observed high-level expression of SMG-specific genes in male mice.