Identification of two subtypes in the rat type I angiotensin II receptor.

A rat adrenal cDNA library was screened by colony hybridization using a rat cDNA fragment of type I angiotensin II receptor (AT1A) previously isolated from the kidney. Two cDNA clones were identified, designated as AT1B, to have a nucleotide sequence highly homologous to and yet distinct from AT1A. The amino acid sequence of AT1B consists of 359 amino acid residues and has 96% identity with AT1A. No conspicuous difference in the ligand binding characteristics was observed between AT1A and AT1B. The mRNA for AT1B was expressed in many tissues as is the case with AT1A, and most abundantly expressed in the adrenal glands in the Sprague-Dawley rats. The existence of two subtypes in the rat type I angiotensin II receptor might explain the diverse actions of angiotensin II in various tissues.     

Analysis of the evolution of angiotensin II type 1 receptor gene in mammals (mouse, rat, bovine and human).

The nucleotide and amino acid sequences for mouse angiotensin II (AII) type 1A and 1B receptors were deduced from their complementary and genomic DNAs. Evolutionary analyses based on the nucleotide sequences of the coding region of AII type 1 receptor genes indicated that the duplication event of the type 1 gene occurred 24 +/- 2 million years ago before the divergence between the rat and mouse but after the divergence between rodents and the human/artiodactyls couple. This conclusion was consistent with the results of genomic Southern blot analyses, which revealed that the mouse and rat possess 2 similar but separate genes, whereas the bovine and human have only a single class gene.     

Rat angiotensin II receptor: cDNA sequence and regulation of the gene expression

The nucleotide and amino acid sequences for rat type I angiotensin II receptor were deduced through molecular cloning and sequence analysis of its complementary DNAs. The rat angiotensin II receptor consists of 359 amino acid residues and has a sequence similar to G protein-coupled receptors. The expression of this receptor gene was detected in the adrenal, liver and kidney by Northern blotting. Sodium deprivation positively modulated the expression of the receptor gene in the adrenal. No detectable change was observed in the expression levels of this receptor gene between spontaneously hypertensive rats and Wistar-Kyoto rats in the tissues examined including the adrenal, brain, kidney and liver. Interestingly the expression of this receptor gene was developmentally regulated.     

The genomic organization of the rat AT1 angiotensin receptor.

The AT1 receptor subtype modulates all of the hemodynamic effects of the vasoactive peptide, angiotensin II. In this report, we investigate the genomic organization of this important receptor. A rat genomic library was screened with fragments from the 5' region of a previously cloned cDNA, pCa18b, encoding the rat AT1 receptor. Two lambda clones were isolated and the hybridizing restriction fragments were sequenced. Comparison of the genomic and cDNA sequences reveals that the rat AT1 receptor has three exons. Two of the exons encode 5' untranslated sequence while the third exon encompasses the entire coding region, a small portion of the 5' untranslated region and the entire 3' untranslated sequence. Further analysis of the genomic sequence 5' to the start site of pCa18b demonstrates typical sequence motifs found in many eukaryotic promoters including a TATA box, a cap site and a potential Sp1 binding site. Southern analysis of genomic DNA indicates that the AT1 receptor subtype represented by pCa18b is encoded by one gene within the rat genome.     

Heterogeneity of angiotensin II receptors in membranes of developing rat metanephros

Specific and high affinity binding sites for angiotensin II were demonstrated in the membranes of the developing rat metanephros during the second half of pregnancy and in the newborn by binding studies with 125I angiotensin II. Only one type of angiotensin receptor was found during intrauterine life while after birth two classes of angiotensin receptors were present in the membranes of the cortical renal tissue.     

Gene sequencing and tissue expression of unknown isoforms of an angiotensin II type 2 receptor interacting protein, ATIP, in the rat

To investigate the expression of the unknown angiotensin II type 2 receptor interacting protein (ATIP) isoforms in the rat we used the known sequences of human and mouse ATIP to design sequencing primers to enable us to sequence rat ATIP3 and ATIP4. Exon 4, which is present in human but not mouse ATIP, was not identified in the coding region of rat ATIP. The expression levels of these genes in a range of rat tissues were examined, and we concluded that there is little similarity in the relative tissue distribution of the various ATIP isoforms in rat and human.     

Genomic DNA encoding rabbit T cell receptor beta-chains: isotypes and allotypes of C beta

We have discovered sequence differences in DNA encoding the first exon of rabbit T cell receptor beta-chains from unrelated rabbits that probably reflect allelic C beta 1 allotypes. Rabbit I was from a colony bred to maintain the K1-expression mutation Basilea, and rabbit II was from a colony bred to maintain the K1b9 allotype. Genomic DNA from rabbits I and II also exhibit restriction fragment length polymorphism of C beta on Southern blots. In addition, several different restriction enzyme digests of DNA from rabbit I give three bands, whereas DNA from rabbit II gives two when probed with C beta. An approximately 14-kb cloned genomic DNA fragment from rabbit I has two copies of C beta exon 1 and a 6-kb fragment has a third copy, suggesting that rabbit I has three different C beta genes. The DNA sequence of a germ-line genomic DNA fragment encoding the first exon of the beta-chain constant region from rabbit I also has an open reading frame encoding 140 amino acids immediately 5' of the C beta sequence. A corresponding sequence had previously been found in a cDNA clone from the second rabbit (rabbit II).     

Cloning, expression, and characterization of a gene encoding the human angiotensin II type 1A receptor.

The human angiotensin II (AII) type 1a receptor gene and its upstream control sequence has been cloned from a human leukocyte genomic library. The promoter element CAAT and TATA sequences were found at -602 and -538, respectively, upstream from the translational initiation site. The deduced protein sequence is homologous to rat and bovine AT1a receptors (94.7% and 95.3% identity). The expressed gene exhibited high-affinity AII and Dup753 binding and was functionally coupled to inositol phosphate turnover. Northern analysis of human tissues showed AT1 receptor mRNA expression in placenta, lung, heart, liver, and kidney. Using 5' untranslated and coding sequence as probes in a Southern blot analysis, it was established that another AT1 subtype exists in the human genome.     

Organization and evolutionary relatedness of OR37 olfactory receptor genes in mouse and human

We report a comprehensive comparative analysis of human and mouse olfactory receptor (OR) genes encoding OR37 subtypes to determine the repertoire, chromosomal organization, and relatedness of these genes. Two OR37 clusters were found in both mouse (chromosome 4) and human (chromosome 9); with five genes in cluster I and three (mouse) and seven genes (human) in cluster II. The pronounced diversity of noncoding sequence regions in both genomic loci indicates a long-term coexistence of the two clusters and the genes within the clusters. In contrast, the coding regions, particularly of genes in cluster I, showed remarkably high sequence identity, a feature quite unique for OR genes. The conservation of only the coding sequences indicates that OR37 may be under negative selection pressure and suggests that the OR37 receptor family may be tuned to recognize distinct sets of signaling molecules. A comparison of mouse and human OR37 gene clusters revealed that genes in cluster I are highly related within each species whereas genes in cluster II are highly related across species. These data reflect a unique and complex evolutionary history of the OR37 family.     

Cloning and functional characterization of a novel mas-related gene, modulating intracellular angiotensin II actions.

The mas oncogene codes for a GTP binding protein-coupled receptor that determines a physiological response to angiotensin when expressed in Xenopus laevis oocytes or in the neuronal cell line NG115-401L. However, another gene, rat thoracic aorta gene, structurally related to mas, is devoid of any functional similarity with the angiotensin receptor(s). The relationships between the mas-related proteins and the angiotensin receptors were investigated by identifying and characterizing new members of the mas gene family. A new mas-related gene (mrg) was cloned in a human genomic library at low stringency using the mas cDNA as probe. Mrg codes for a seven-hydrophobic-segment receptor that is 35% identical to the mas product and 29% identical to the rat thoracic aorta gene product. Mrg mRNA was not detected in several rat and human adult tissues that normally express the angiotensin II (AII) receptor, and transfections of COS and CHO cells with the mrg gene did not modify the number of AII binding sites. These results indicate that mrg and the human AII receptor genes are not identical. However, injection of mrg mRNA into Xenopus oocytes markedly increased the electrophysiological response to angiotensin peptides, indicating some functional similarities with the mas product. The reduction of the response after defolliculation of the oocyte, together with the full agonist effect of Sar1IIe8AII and the partial agonist effect of Sar1Ala8AII, seem to indicate that mrg interacts with the signaling pathways of the endogenous Xenopus angiotensin receptor to potentiate the response to AII.     

Frequent sequence exchanges between homologs of RPP8 in Arabidopsis are not necessarily associated with genomic proximity

Disease resistance (R) genes are often clustered in plant genomes and may exhibit heterogeneous rates of evolution. Some (type I R genes) have evolved rapidly through frequent sequence exchanges, while others (type II R genes) have evolved independently and tend to be conserved in different genotypes or related species. The RPP8 resistance gene in Arabidopsis thaliana is located at a complex locus that also harbors the sequence-related resistance genes HRT and RCY1 in different ecotypes. We sequenced 98 homologs of RPP8 from A. thaliana, Arabidopsis arenosa and Arabidopsis lyrata. Three lineages of type II and one lineage of type I RPP8 homologs were identified. Two of the three lineages of type II genes are each represented by a single-copy locus on either chromosomes I or V. Chromosome V contains two small clusters of RPP8 paralogs. One cluster contains both type I and type II genes and the other comprises only type I genes. These multi-copy loci have expanded and contracted through unequal crossovers, which have generated chimeric genes as well as variations in copy number. Sequence exchanges, most likely gene conversions, were detected between RPP8 homologs that are spatially separated by 2.2 Mb and 12 cM. The sequence exchanges between type I homologs within a locus have been more frequent than sequence exchanges between homologs from two different loci, indicating the influence of chromosomal position on the evolution of these R genes. However, physical distance was not the only factor determining the frequency of sequence exchange, because some closely linked paralogs exhibited little sequence exchange. At least two distinct lineages of type II RPP8 homologs were identified in different species, with obvious allelic/orthologous relationships within each lineage. Therefore, the differentiation of type I and type II RPP8 homologs seems to have occurred before speciation of A. thaliana, A. arenosa and A. lyrata.     

A recombinant rat vascular AT1 receptor confers growth properties to angiotensin II in Chinese hamster ovary cells.

A rat vascular AT1 receptor cDNA has been stably expressed into Chinese Hamster Ovary cells and the resulting recombinant AT1a receptor has been functionally characterized. This receptor binds 125I Sar1-angiotensin II with an affinity of 0.9 nM and the displacement of this ligand by a series of peptidic and nonpeptidic analogs is shown. Binding of angiotensin II to this receptor causes a rapid increase in inositol phosphate production, whereas this effect is not observed in nontransfected cells. Des-aspartyl1 angiotensin II and at a lesser extent angiotensin I are also able to produce an increase in inositol phosphates. More importantly, the actions of angiotensin II on cell division were clearly demonstrated in this model, since angiotensin II is able to stimulate DNA synthesis by 400% and double the cell population of the transfected cells in 36 hours in the absence of any other growth factor, whereas no effect is observed in nontransfected cells.     

Molecular cloning of a mineralocorticoid (type I) receptor complementary DNA from rat hippocampus

Rat brain expresses two types of corticosteroid-binding proteins. The type I receptor binds corticosterone with high affinity and is structurally related to the kidney mineralocorticoid receptor (MR), while the type II or classical glucocorticoid receptor binds corticosterone with lower affinity and displays an in vivo preference for dexamethasone. Here we describe the isolation and characterization of a cDNA coding for the MR, from a rat hippocampus cDNA library, by low stringency hybridization to radiolabeled human glucocorticoid receptor cDNA. The nucleotide and deduced amino acid sequence for rat hippocampal MR displays extensive homology to a MR cDNA isolated from human kidney, suggesting that they are orthologous genes. Southern analysis suggests that there is only one gene for the MR, and in vitro expression of the receptor generates a high affinity corticosterone-binding protein. These data provide evidence to support the contention that a single gene gives rise to the MR in renal tissues and type I receptors in the brain.     

Cloning, characterization, and expression of two angiotensin receptor (AT-1) isoforms from the mouse genome.

We report the existence of two structurally distinct forms of the angiotensin receptor AT-1 in the mouse. A Balb/c mouse genomic library was screened by homology screening with a polymerase chain reaction (PCR) amplified probe. Restriction mapping and sequencing of the isolated genes revealed the presence of two receptor isoforms, here named the mouse AT-1a and AT-1b receptors, containing 22 different amino acids. Receptor binding studies performed on COS-7 cells transfected with the two receptors revealed that they had similar binding profiles for angiotensin II, angiotensin III and AT-1 or AT-2 specific antagonists. Because many of the structural differences were in the carboxy terminal putative intracellular domain, we speculate that these isoforms may differ in their regulation, signal transduction, or desensitization mechanisms.