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.     

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.     

Tissue-specific expression of the human renin gene in transgenic mice

Transgenic mice carrying human renin gene were produced by microinjection of 15 kilobases (kb) DNA molecules with up to 3 kb of 5'-flanking sequence and 1.2 kb of 3'-flanking sequence. The transgenes have been shown to be stably transmitted to progeny. It was revealed by RNase protection assay that the human renin gene in a transgenic mouse is expressed preferentially in the kidney. The human renin RNA was also detected at a small level in a variety of tissues such as brain, heart, lung, pancreas, spleen, stomach, testis, and thymus. The direct radioimmunoassay using a monoclonal antibody specific for the active site of human renin demonstrated the synthesis of human active renin in the transgenic mouse kidney. These results suggest that the human renin gene in the transgenic mouse is regulated in a tissue-specific manner.     

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.     

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.     

Expression of human angiotensinogen cDNA in Escherichia coli

Human angiotensinogen cDNA clones were isolated from a human liver library. Nucleotide sequence analysis of these cDNA clones revealed that position 1075 in the messenger RNA, which is part of a PstI recognition sequence, is different from the published sequence (Kageyama, R., Ohkubo, H., and Nakanishi, S. (1984) Biochemistry 23, 3603-3609). This change results in an altered amino acid at this position in the corresponding protein sequence and suggests possible restriction fragment length polymorphism. The full length human angiotensinogen cDNA was constructed from partial cDNA clones and ligated into an isopropyl-1-thio-beta-D-galactopyranoside inducible bacterial expression vector pUC9 to develop expression plasmid pUCHAG27. This plasmid permitted the synthesis of human angiotensinogen in Escherichia coli. The recombinant bacteria overproduced a 53-kDa protein which was recognized by anti-human angiotensinogen antibodies. The synthesis of this protein was greatly increased upon induction with isopropyl-1-thio-beta-D-galactopyranoside. The chimeric protein, almost identical to human angiotensinogen, was partially purified by ammonium sulfate fractionation and gel filtration on Sephadex G-100. Human kidney renin was shown to enzymatically cleave this recombinant protein to produce des-(angiotensin I)-angiotensinogen and a small polypeptide. Thus, we provide evidence that recombinant human angiotensinogen synthesized through E. coli is biologically active and serves as a substrate for human renin.     

Molecular cloning of DNA complementary to a mouse α-fetoprotein mRNA sequence

DNA complementary to mouse yolk sac messenger RNA has been inserted at the PstI site of the plasmid pBR322 by annealing of the oligo(dG)-tailed plasmid DNA with the oligo(dC)-tailed mouse DNA. Transformation of Escherichia coli strain RRI with this annealed DNA yielded clones bearing recombinant plasmids. The clones were screened for DNA complementary to mouse a-fetoprotein (AFP) messenger RNA sequences by hybridization with a cDNA probe transcribed from an AFP mRNA of over 90% purity. Out of nine plasmids that were isolated and analyzed by restriction mapping, all had homologous insert DNA of various lengths. The plasmid with the longest insert, pAF6, contained 1.65 kb of added DNA, which is about 70% of the AFP mRNA. This clone was positively identified by a hybridization-translation procedure to contain a cDNA sequence for AFP. A restriction map of this clone and the orientation of the message are presented.     

Structural analysis of 5'-flanking regions of rat, mouse and human renin genes reveals the presence of a transposable-like element in the two mouse genes

The two renin genes of the mouse (Ren1 and Ren2) are expressed at different levels in the submaxillary gland (SMG). In contrast to mice, there is no detectable renin gene expression in the rat SMG. To determine the molecular basis for these different levels of renin expression, we have compared the 5'-flanking regions of the rat and mouse genes. The sequence of mouse, but not rat, genes reveals the presence in Ren1 and Ren2 of a large insertion, probably a new class of transposable elements. A second, apparently unrelated shorter insertion is present only in Ren2. Otherwise, the mouse and rat 5'-flanking sequences are well conserved and resemble the corresponding region of the human Ren gene, indicating that the insertions occurred after the separation of the rat and mouse species but before the duplication of the mouse Ren gene. We suggest that these structural differences may have a role in the differential expression of the Ren genes in mice and other animals.     

Cloning and mapping of 5' exons from the gene encoding chicken beta nerve growth factor.

An NGF cDNA containing the 5' exons of the nerve growth factor (NGF) messenger was obtained from chicken heart mRNA using the anchored polymerase chain reaction technique. Alignment of the chicken with the corresponding murine and human sequences reveals interspecies similarities. A sequence corresponding to an exon found only in the NGF messenger, which is abundant in the submaxillary gland of the male mouse, is present in the chicken NGF cDNA. The first non-coding exons of the NGF gene are much less conserved between chicken and mouse or human than the region of the last exon encoding the mature protein. After the cloning of the chicken NGF gene from a cosmid library, the chicken NGF exons have been located within 20 kb of DNA. The chicken NGF gene is therefore shorter than its murine counterpart which spans more than 43 kb. Furthermore, the organization of the chicken and murine NGF genes markedly differs in their 5' portion.     

Localization of brain nitric oxide synthase (NOS) to human chromosome 12.

Recent research has shown that nitric oxide is a novel neuronal second messenger and transmitter that may be involved in neuronal cell death and damage in neurological illness. To map the chromosomal localization of this important brain enzyme, a rat cDNA probe was prepared by RNA PCR from rat cerebellum RNA. This rat cDNA was used to isolate a human nitric oxide synthase (NOS) cDNA from a human cerebellum cDNA library. The human cDNA clone containing 1.2 kb of brain NOS cDNA was hybridized to Southern blots containing DNAs obtained from human-rodent hybrid cell line panels using EcoRI and HindIII digestion to ascertain the location of the human NOS gene. These data showed that the human brain nitric oxide synthase mapped within 12q14-qter on human chromosome 12.     

Molecular cloning, sequence analysis and mRNA expression of human ADP-ribosylation factor

The ADP-ribosylation factor (ARF) is the small (21 kb) GTP-binding protein required for the efficient cholera toxin-catalyzed ADP-ribosylation of purified Gs, the stimulating regulatory component of adenylate cyclase. Human ARF cDNA clones were obtained from a human cDNA library by cross-species hybridization with bovine ARF1, and the nucleotide and deduced amino acid sequences were determined. Comparison of the sequences of human and bovine ARF1 showed 90% identity at the nucleotide level and 100% identity at the amino acid level, demonstrating the highly conserved nature of the ARF protein. Using human ARF cDNA as the probe, we have detected ARF messenger RNA (approximately 2.2-2.3 kb) in a wide variety of human tissues and tumor cell lines.     

Amino acid sequence homology between the C3 chain of rat prostatic steroid binding protein and human alpha 2-macroglobulin

Using 32P-labeled DNA complementary to mouse submaxillary gland renin mRNA, we probed mRNA gel blots from mouse testis and kidney tissues. Poly(A)-RNA from testis contained a hybridizable RNA species which was blotted onto nitrocellulose paper. The molecular size of testicular renin mRNA (approximately 1600 nucleotides in length) was not significantly different from tht of kidney renin mRNA. Densitometric scan revealed that the content of renin mRNA in mouse testis was approximately 5-fold lower than that in mouse kidney. These results support the proposal that mouse testicular cells synthesize renin.     

Molecular cloning of human plasma glutathione peroxidase gene and its expression in the kidney.

A genomic clone containing the human plasma glutathione peroxidase (GSH-Px) gene has been isolated using a rat plasma GSH-Px cDNA as a probe. The partial nucleotide sequence of the clone completely matched the sequence of the human plasma GSH-Px cDNA. The results of Southern blot hybridization indicate that the human plasma GSH-Px gene consists of at least 4 exons and 3 introns, and spans about 12 kb. RNA blot analysis demonstrated that the human plasma GSH-Px gene is expressed in the kidney.     

Sta!le and transient expression of mouse submaxillary gland renin cDNA in AtT20 cells: proteolytic processing and secretory pathways

Apart from kidney, where renin synthesis takes place in all mammals, the submaxillary gland (SMG) of most mouse strains constitutes an important source of an isoenzyme, renin-2, that is highly homologous to renal renin, but unglycosylated [(1982) Nature 298, 90-92]. This unique phenotype is due to the presence of an extra copy of th renin gene. A puzzling observation is that (pro)renin-2 cannot be detected in the kidney of these animals, although both mRNAs accumulate at similar levels [(1985) Proc. Natl. Acad. Sci. USA 82, 6196-6200]. In order to investigate whether (pro)renin-2 expression is detectable in mouse heterologous cell lines we transfected the renin-2 cDNA into AtT20 (pituitary corticotrope) and BTG9A (hepatoma) cells. Stable clones expressing renin were obtained in both cases. BTG9A cells secreted only prorenin while AtT20 cells secreted prorenin and active renin. In addition, in AtT20 cells the secretion of active renin was stimulated by 8-Br cAMP. Our results show that unglycosylated (pro)renin-2 can be expressed and secreted in two murine cell lines. Moreover, it is correctly processed to active renin and secreted upon stimulation in AtT20 cells.     

Assignment by in situ hybridization of the angiotensinogen gene to chromosome band 1q4, the same region as the human renin gene

Summary A 1.8kb human cDNA probe for angiotensinogen (renin substrate) was used to determine the chromosomal location of the angiotensinogen gene by in situ hybridization. The results show that human chromosome region 1q4 contains the angiotensinogen gene. The human renin gene has also recently been assigned to the same band of chromosome 1. Thus, the angiotensinogen and renin genes are located in the same region of chromosome 1.