The two homologous domains of human angiotensin I-converting enzyme are both catalytically active.

Molecular cloning of human endothelial angiotensin I-converting enzyme (kininase II; EC 3.4.15.1) (ACE) has recently shown that the enzyme contains two large homologous domains (called here the N and C domains), each bearing a putative active site, identified by sequence comparisons with the active sites of other zinc metallopeptidases. However, the previous experiments with zinc or competitive ACE inhibitors suggested a single active site in ACE. To establish whether both domains of ACE are enzymatically active, a series of ACE mutants, each containing only one intact domain, were constructed by deletion or point mutations of putative critical residues of the other domain, and expressed in heterologous Chinese hamster ovary cells. Both domains are enzymatically active and cleave the C-terminal dipeptide of hippuryl-His-Leu or angiotensin I. Moreover, both domains have an absolute zinc requirement for activity, are activated by chloride and are sensitive to competitive ACE inhibitors, and appear to function independently. However, the two domains display different catalytic constants and different patterns of chloride activation. At high chloride concentrations, the C domain hydrolyzes the two substrates tested faster than does the N domain. His-361,365 and His-959,963 are established as essential residues in the N and C domains, respectively, most likely involved in zinc binding, and Glu-362 in the N domain and Glu-960 in the C domain are essential catalytic residues. These observations provide strong evidence that ACE possesses two independent catalytic domains and suggest that they may have different functions.     

The isolation of angiotensin-converting enzyme cDNA

Angiotensin-converting enzyme (ACE) is an Zn(II)-containing dipeptidyl carboxypeptidase that converts angiotensin I to the potent vasoconstrictor, angiotensin II. Using oligonucleotide probes based on the amino acid sequence of mouse kidney ACE, cDNA encoding this protein has been isolated. One cDNA, ACE.31, encodes the N-terminal 332 amino acids of mouse ACE, a portion of the protein containing a putative 34-amino acid leader sequence and the N terminus of the mature protein. Northern analyses with cloned ACE cDNA revealed that both mouse kidney and lung express two ACE mRNAs, one of 4900 and another of 4150 bases. Southern analysis suggests that cDNA ACE.31 is the product of a single gene, and thus these data add evidence to the hypothesis that the converting enzymes produced by epithelial and endothelial cells are identical.     

Mouse angiotensin-converting enzyme is a protein composed of two homologous domains

Angiotensin-converting enzyme (ACE) is a dipeptidyl carboxypeptidase that converts angiotensin I into the potent vasoconstrictor angiotensin II. We have used cDNA and genomic sequences to assemble a composite cDNA, ACE.315, encoding the entire amino acid sequence of mouse converting enzyme. ACE.315 contains 4838 base pairs and encodes a protein of 1278 amino acids (147.4 kDa) after removal of a 34-amino acid signal peptide. Within the protein, there are two large areas of homologous sequence, each containing a potential Zn-binding region and catalytic site. These homologous regions are approximately half the size of the whole ACE protein and suggest that the modern ACE gene is the duplicated product of a precursor gene. Mouse ACE is 83% homologous to human ACE in both nucleic acid and amino acid sequence, and like human ACE, contains a hydrophobic region in the carboxyl terminus that probably anchors the enzyme to the cell membrane (Soubrier, F., Alhenc-Gelas, F., Hubert, C., Allegrini, J., John, M., Tregear, G., and Corvol, P. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 9386-9390). Northern analysis of mouse kidney, lung, and testis RNA demonstrates that the testicular isozyme of ACE is encoded by a single, smaller RNA (2500 bases) than the two message sizes found in kidney or lung (4900 and 4150 bases), and that this testicular RNA hybridizes to the 3' portion of ACE.315.     

The structure of the rabbit macrophage defensin genes and their organ-specific expression

Defensins are a family of microbicidal and cytotoxic peptides abundant in the lysosomal granules of mammalian phagocytes. We present the cDNA and genomic sequences of two rabbit defensins, macrophage cationic peptides MCP-1 and MCP-2. Their cDNA and genomic sequences are highly homologous, reflecting the homology between the two defensins (32 of 33 amino acids). The MCP genes are closely linked (within 13 kb) suggesting that they evolved by a recent tandem gene duplication. Their cDNA sequences indicate that the peptides are synthesized as 95 amino acid prepro-MCPs, consistent with their lysosomal location. The MCP genes are separated into three exons encoding distinct domains: the 5' untranslated region, the prepropeptide domain, and the mature defensin sequence. Fully developed polymorphonuclear leukocytes, short-lived phagocytes with limited capacity for protein and nucleic acid synthesis, contained MCPs but lacked MCP mRNA. MCP mRNA was found in bone marrow and spleen, organs which contained immature polymorphonuclear leukocytes. MCP and MCP mRNA were detected in lung macrophages, but not in macrophages from other organs, nor in monocytes, the putative macrophage precursors. In macrophages, the expression of MCPs appears to be a marker of lung-specific differentiation.     

Organ-specific distribution of ACE2 mRNA and correlating peptidase activity in rodents

Biochemical analysis revealed that angiotensin-converting enzyme related carboxy-peptidase (ACE2) cleaves angiotensin (Ang) II to Ang-(1-7), a heptapeptide identified as an endogenous ligand for the G protein-coupled receptor Mas. No data are currently available that systematically describe ACE2 distribution and activity in rodents. Therefore, we analyzed the ACE2 expression in different tissues of mice and rats on mRNA (RNase protection assay) and protein levels (immunohistochemistry, ACE2 activity, western blot). Although ACE2 mRNA in both investigated species showed the highest expression in the ileum, the mouse organ exceeded rat ACE2, as also demonstrated in the kidney and colon. Corresponding to mRNA, ACE2 activity was highest in the ileum and mouse kidney but weak in the rat kidney, which was also confirmed by immunohistochemistry. Contrary to mRNA, we found weak activity in the lung of both species. Our data demonstrate a tissue- and species-specific pattern for ACE2 under physiological conditions.     

Angiotensin-converting enzyme: zinc- and inhibitor-binding stoichiometries of the somatic and testis isozymes.

The blood pressure regulating somatic isozyme of angiotensin-converting enzyme (ACE) consists of two homologous, tandem domains each containing a putative metal-binding motif (HEXXH), while the testis isozyme consists of just a single domain that is identical with the C-terminal half of somatic ACE. Previous metal analyses of somatic ACE have indicated a zinc stoichiometry of 1 mol of Zn2+/mol of ACE and inhibitor-binding studies have found 1 mol of inhibitor bound/mol of enzyme. These and other data have indicated that only one of the two domains of somatic ACE is catalytically active. We have repeated the metal and inhibitor-binding analyses of ACE from various sources and have determined protein concentration by quantitative amino acid analysis on the basis of accurate polypeptide molecular weights that are now available. We find that the somatic isozyme in fact contains 2 mol of Zn2+ and binds 2 mol of lisinopril (an ACE inhibitor) per mol of enzyme, whereas the testis isozyme contains 1 mol of Zn2+ and binds 1 mol of lisinopril. In the case of somatic ACE, the second equivalent of inhibitor binds to a second zinc-containing site as evidenced by the ability of a moderate excess of inhibitor to protect both zinc ions against dissociation. However, active site titration with lisinopril assayed by hydrolysis of furanacryloyl-Phe-Gly-Gly revealed that 1 mol of inhibitor/mol of enzyme abolished the activity of either isozyme, indicating that the principal angiotensin-converting site likely resides in the C-terminal (testicular) domain of somatic ACE and that binding of inhibitor to this site is stronger than to the second site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure and physiological importance of angiotensin converting enzyme domains

Somatic angiotensin converting enzyme (ACE) consists of two homologous catalytic domains (N- and C-domain), exhibiting different biochemical properties. The catalytically active ACE isoforms consisted of just one domain have been also detected in mammals. Substantial progress in ACE domain research was achieved during the last years, when their crystal structures were determined. The crystal structures of domains in complex with diverse potent ACE inhibitors provided new insights into structure-based differences of the domain active sites. Physiological functions of ACE are not limited by regulation of the cardiovascular system. Recent evidence suggests that the ACE domains may be also involved into control of different physiological functions. The C-terminal catalytic domain plays an important role in the regulation of blood pressure: it catalyzes angiotensin I cleavage in vivo. The N-domain contributes to the processing of other bioactive peptides for which it exhibits high affinity. The role of the N-domain is not ultimately associated with functioning of the rennin-angiotensin system and it contributes processing of other bioactive peptides for which it exhibits high affinity (goralatide, luliberin, enkephalin heptapeptide, beta-amyloid peptide). Domain-selective inhibitors selectively blocking either the N- or C-domain of ACE have been developed.     

Comparison of ACE activity in amphibian tissues: Rana esculenta and Xenopus laevis

Angiotensin converting enzyme (ACE) is the dipeptidyl-carboxypeptidase of the renin-angiotensin system involved in the control of blood pressure and hydromineral metabolism. It converts angiotensin I to angiotensin II, the biologically active octapeptide. Angiotensin converting enzyme-like activity has been demonstrated in a wide range of vertebrates. The presence of ACE was investigated in tissues of two amphibian species, the frog Rana esculenta and the toad Xenopus laevis. ACE activities were determined by specific substrate hydrolysis in gut, gonads, lung, kidney, heart, liver, skin, erythrocytes, and muscle homogenates and plasma by means of high performance liquid chromatography. Significant ACE activity was found in gut, gonads, lung and kidney, while that in heart, liver, skin, erythrocytes, muscle, and plasma was very low. Testis of toad contained the highest ACE activity, while that in erythrocytes of male and female frogs was notable.     

Molecular cloning and expression of the cDNA for the alpha 1A-adrenergic receptor. The gene for which is located on human chromosome 5.

Pharmacological and molecular cloning studies have demonstrated heterogeneity of alpha 1-adrenergic receptors. We have now cloned two alpha 1-adrenergic receptors from a rat cerebral cortex cDNA library, using the hamster alpha 1B-adrenergic receptor as a probe. The deduced amino acid sequence of clone RA42 encodes a protein of 560 amino acids whose putative topology is similar to that of the family of G-protein-coupled receptors. The primary structure though most closely resembles that of an alpha 1-adrenergic receptor, having approximately 73% amino acid identity in the putative transmembrane domains with the previously isolated hamster alpha 1B receptor. Analysis of the ligand binding properties of RA42 expressed in COS-7 cells with a variety of adrenergic ligands demonstrates a unique alpha 1-adrenergic receptor pharmacology. High affinity for the antagonist WB4101 and agonists phenylephrine and methoxamine suggests that cDNA RA42 encodes the alpha 1A receptor subtype. Northern blot analysis of various rat tissues also shows the distribution expected of the alpha 1A receptor subtype with abundant expression in vas deferens followed by hippocampus, cerebral cortex, aorta, brainstem, heart and spleen. The second alpha 1-adrenergic receptor cloned represents the rat homolog of the hamster alpha 1B subtype. Expression of mRNA for this receptor is strongly detected in liver followed by heart, cerebral cortex, brain stem, kidney, lung, and spleen. This study provides definitive evidence for the existence of three alpha 1-adrenergic receptor subtypes.     

Role of the N-terminal catalytic domain of angiotensin-converting enzyme investigated by targeted inactivation in mice

Angiotensin-converting enzyme (ACE) produces the vasoconstrictor angiotensin II. The ACE protein is composed of two homologous domains, each binding zinc and each independently catalytic. To assess the physiologic significance of the two ACE catalytic domains, we used gene targeting in mice to introduce two point mutations (H395K and H399K) that selectively inactivated the ACE N-terminal catalytic site. This modification does not affect C-terminal enzymatic activity or ACE protein expression. In addition, the testis ACE isozyme is not affected by the mutations. Analysis of homozygous mutant mice (termed ACE 7/7) showed normal plasma levels of angiotensin II but an elevation of plasma and urine N-acetyl-Ser-Asp-Lys-Pro, a peptide suggested to inhibit bone marrow maturation. Despite this, ACE 7/7 mice had blood pressure, renal function, and hematocrit that were indistinguishable from wild-type mice. We also studied compound heterozygous mice in which one ACE allele was null (no ACE expression) and the second allele encoded the mutations selectively inactivating the N-terminal catalytic domain. These mice produced approximately half the normal levels of ACE, with the ACE protein lacking N-terminal catalytic activity. Despite this, the mice have a phenotype indistinguishable from wild-type animals. This study shows that, in vivo, the presence of the C-terminal ACE catalytic domain is sufficient to maintain a functional renin-angiotensin system. It also strongly suggests that the anemia present in ACE null mice is not due to the accumulation of the peptide N-acetyl-Ser-Asp-Lys-Pro.     

急性压力超负荷后心肌cAMP与肾素血管紧张素系统活化的关系

为阐明急性压力超负荷后心肌细胞内ｃＡＭＰ浓度升高和心肌肾素血管紧张素系统活化之间是否存在内在因果联系,用腹主动脉缩窄的方法建立急性压力超负荷大鼠模型。发现在术后１ｈ心肌组织中血管紧张素转换酶（ＡＣＥ）ｍＲＮＡ及蛋白表达均显著增加,ＡＣＥ活性及血管紧张素Ⅱ（ＡｎｇⅡ）含量也明显升高,并在高水平。同时,心肌组织ｃＡＭＰ含量于术后０．５ｈ明显增加,术后５ｄ时达峰值,术后３０ｄ降至正常。在心肌细胞培养的基     

Both P1 and P2 protamine genes are expressed in mouse, hamster, and rat

To date, in mammals except for the mouse and human, only one protamine variant has been isolated from sperm. These mammalian protamines share amino acid sequence homology with mouse protamine 1 (mP1), the tyrosine-containing variant. Southern blot analysis of restriction enzyme digests of hamster and rat liver DNA reveals the presence of sequences homologous to mP1, and also to mouse protamine 2 (mP2) cDNAs. Northern blots of hamster and rat total testis RNA probed with mP2 cDNA confirm that the protamine 2 gene in these species is transcribed into two size classes of mRNA of approximately 830 and 700 nucleotides. However, the relative abundance of the rat and hamster protamine 2 mRNAs (rP2 and hP2) in total testis is approximately 50-fold lower and 2- to 5-fold lower, respectively, than the mouse protamine 2 mRNA. Northern blot analysis of hamster and rat testis polysome gradients demonstrates that although the amount of rP2 mRNA and hP2 mRNA is reduced, both are present on polysomes. The decreased expression of rat and hamster protamine 2 mRNA relative to their protamine 1 counterparts contrasts protamine expression in the mouse testis, where approximately equal amounts of mP1 and mP2 protamine mRNAs are present. These results suggest differential expression of the P1 and P2 protamine genes in three closely related mammals.     

Sequence of a cDNA Encoding Turtle High Mobility Group 1 Protein

In order to understand sequence information about turtle HMG1 gene, a cDNA encoding HMG1 protein of the Chinese soft-shell turtle (Pelodiscus sinensis) was amplified by RT-PCR from kidney total RNA, and was cloned, sequenced and analyzed. The results revealed that the open reading frame (ORF) of turtle HMG1 cDNA is 606 bp long. The ORF codifies 202 amino acid residues, from which two DNA-binding domains and one polyacidic region are derived. The DNA-binding domains share higher amino acid identity with homologous sequences of chicken (96.5%) and mammals (74%) than homologous sequence of rainbow trout (67%). The polyacidic region shows 84.6% amino acid homology with the equivalent region of chicken HMG1 cDNA. Turtle HMG1 protein contains 3 Cys residues located at completely conserved positions. Conservation in sequence and structure suggests that the functions of turtle HMG1 cDNA may be highly conserved during evolution. To our knowledge, this is the first report of HMG1 cDNA sequence in any reptilian.From Genetika, Vol. 41, No. 7, 2005, pp. 925–930.Original English Text Copyright © 2005 by Jifang Zheng, Bi Hu, Duansheng Wu.The text was submitted by the authors in English.