Hong D. Xiao

Mice with Cardiac-Restricted Angiotensin-Converting Enzyme (ACE) Have Atrial Enlargement, Cardiac Arrhythmia, and Sudden Death

To investigate the local effects of angiotensin II on the heart, we created a mouse model with 100-fold normal cardiac angiotensin-converting enzyme (ACE), but no ACE expression in kidney or vascular endothelium. This was achieved by placing the endogenous ACE gene under the control of the alpha-myosin heavy chain promoter using targeted homologous recombination. These mice, called ACE 8/8, have cardiac angiotensin II levels that are 4.3-fold those of wild-type mice. Despite near normal blood pressure and a normal renal function, ACE 8/8 mice have a high incidence of sudden death. Both histological analysis and in vivo catheterization of the heart showed normal ventricular size and function. In contrast, both the left and right atria were three times normal size. ECG analysis showed atrial fibrillation and cardiac block. In conclusion, increased local production of angiotensin II in the heart is not sufficient to induce ventricular hypertrophy or fibrosis. Instead, it leads to atrial morphological changes, cardiac arrhythmia, and sudden death.

ACE and ACE2 Activity in Diabetic Mice

ACE-related carboxypeptidase (ACE2) may counterbalance the angiotensin (ANG) II–promoting effects of ACE in tissues where both enzymes are found. Alterations in renal ACE and ACE2 expression have been described in experimental models of diabetes, but ACE2 activity was not assessed in previous studies. We developed a microplate-based fluorometric method for the concurrent determination of ACE and ACE2 activity in tissue samples. Enzymatic activity (relative fluorescence unit [RFU] · μg protein−1 · h−1) was examined in ACE and ACE2 knockout mice and in two rodent models of diabetes, the db/db and streptozotocin (STZ)-induced diabetic mice. In kidney cortex, preparations consisting mainly of proximal tubules and cortical collecting tubules, ACE2 activity had a strong positive correlation with ACE2 protein expression (90-kDa band) in both knockout models and their respective wild-type littermates (r = 0.94, P < 0.01). ACE activity, likewise, had a strong positive correlation with renal cortex ACE protein expression (170-kDa band) (r = 0.838, P < 0.005). In renal cortex, ACE2 activity was increased in both models of diabetes (46.7 ± 4.4 vs. 22.0 ± 4.7 in db/db and db/m, respectively, P < 0.01, and 22.1 ± 2.8 vs. 13.1 ± 1.5 in STZ-induced diabetic versus untreated mice, respectively, P < 0.05). ACE2 mRNA levels in renal cortex from db/db and STZ-induced diabetic mice, by contrast, were not significantly different from their respective controls. In cardiac tissue, ACE2 activity was lower than in renal cortex, and there were no significant differences between diabetic and control mice (db/db 2.03 ± 0.23 vs. db/m 1.85 ± 0.10; STZ-induced diabetic 0.42 ± 0.04 vs. untreated 0.52 ± 0.07 mice). ACE2 activity in renal cortex correlated positively with ACE2 protein in db/db and db/m mice (r = 0.666, P < 0.005) as well as in STZ-induced diabetic and control mice (r = 0.621, P < 0.05) but not with ACE2 mRNA (r = −0.468 and r = −0.522, respectively). We conclude that in renal cortex from diabetic mice, ACE2 expression is increased at the posttranscriptional level. The availability of an assay for concurrent measurement of ACE and ACE2 activity should be helpful in the evaluation of kidney-specific alterations in the balance of these two carboxypeptidases, which are involved in the control of local ANG II formation and degradation.

Effect of Reduced Angiotensin-Converting Enzyme Gene Expression and Angiotensin-Converting Enzyme Inhibition on Angiotensin and Bradykinin Peptide Levels in Mice

Abstract—There is uncertainty about the contribution of angiotensin-converting enzyme (ACE) to angiotensin II formation, with recent studies suggesting that non-ACE enzymes may be the predominant pathway of angiotensin II formation in kidney, heart, and lung. To investigate the role of ACE in angiotensin II formation, we measured angiotensin I and II levels in blood, kidney, and heart of 2 mouse genetic models (ACE.1 and ACE.4) of reduced somatic ACE gene expression and in blood, kidney, heart, lung, adrenal, and brain of mice administered the ACE inhibitor lisinopril. We also measured the levels of bradykinin (1-9) and its ACE metabolite bradykinin (1-7). Reduced ACE gene expression and ACE inhibition had similar effects on angiotensin and bradykinin peptide levels. Angiotensin II levels were reduced by 70% to 97% in blood, 92% to 99% in kidney, 93% to 99% in heart, 97% in lung, and 85% in adrenal and brain. The marked reductions in angiotensin II/angiotensin I ratio indicated that ACE was responsible for at least 90% of angiotensin I conversion to angiotensin II in blood, kidney, heart, lung, and brain, and at least 77% in adrenal. Blood bradykinin (1-9) levels were increased 6.4-fold to 8.4-fold. Heart bradykinin (1-9) levels were increased in ACE.4 mice and the bradykinin (1-7)/bradykinin (1-9) ratio was reduced in kidney and heart of ACE.4 mice and heart of lisinopril-treated mice. These studies demonstrate that ACE is the predominant pathway of angiotensin II formation in blood and tissues of mice and plays a major role in bradykinin (1-9) metabolism in blood and, to a lesser extent, in kidney and heart.

Angiotensin-Converting Enzyme C-Terminal Catalytic Domain Is the Main Site of Angiotensin I Cleavage In Vivo

Angiotensin-converting enzyme (ACE) plays a central role in the production of the vasoconstrictor angiotensin II. ACE is a single polypeptide, but it contains 2 homologous and independent catalytic domains, each of which binds zinc. To understand the in vivo role of these 2 domains, we used gene targeting to create mice with point mutations in the ACE C-domain zinc-binding motif. Such mice, termed ACE13/13, produce a full-length ACE protein with tissue expression identical to wild-type mice. Analysis of ACE13/13 mice showed that they produce ACE having only N-domain catalytic activity, as determined by the hydrolysis of domain specific substrates and by chloride sensitivity. ACE13/13 mice have blood pressure and blood angiotensin II levels similar to wild-type mice. However, plasma renin concentration is increased 2.6-fold and blood angiotensin I levels are increased 7.5-fold. Bradykinin peptide levels are not different from wild-type levels. ACE13/13 mice have a reduced increase of blood pressure after intravenous infusion of angiotensin I. ACE13/13 mice have a normal renal structure, but they are not able to concentrate urine after dehydration as effectively as wild-type mice. This study shows that the C-domain of ACE is the predominant site of angiotensin I cleavage in vivo. Although mice lacking C-domain activity have normal physiology under laboratory conditions, they respond less well to the stress of dehydration.

Male fertility is dependent on dipeptidase activity of testis ACE.

c Figure 2 ACE overexpression in CHO and HEK cells does not affect the shedding of multiple GPI-anchored proteins. (a) CHO cells were stably transfected with vector alone (mock), full-length wild-type (FL-ACE) or GPI-ACE10. Endogenous alkaline phosphatase activity shed into the media was determined using p-nitrophenylphosphate as substrate. Results are means ± s.d. (n = 3) and are expressed as a percentage of activity shed into media of mock-transfected cells. (b) HEK cells stably transfected with either doppel or prion protein were transiently transfected with vector alone (mock), FL-ACE or GPI-ACE. Endogenous alkaline phosphatase activity shed into the media was determined using p-nitrophenylphosphate as substrate. Doppel and prion protein shed into media were determined by immunoblotting followed by densitometric analysis. Results are means ± s.d. (n = 3 or 6 (alkaline phosphatase)) and are expressed as a percentage of protein shed into the media of mock-transfected cells. (c) ACE activity determined using BzGly-His-Leu as substrate in lysates from the HEK cells transiently transfected with vector alone (mock), FL-ACE or GPI-ACE as in b. Results are means ± s.d. (n = 3).

Six Truisms Concerning ACE and the Renin-Angiotensin System Educed From the Genetic Analysis of Mice

This Review is part of a thematic series on Angiotensin Converting Enzyme , which includes the following articles: Six Truisms Concerning ACE and the Renin-Angiotensin System Educed From the Genetic Analysis of Mice ACE and Vascular Remodeling ACE II in the Heart and the Kidney ACE Signaling ACE Polymorphisms Rudi Bussi Editors The history of the renin-angiotensin system (RAS) is one of marvelous discoveries extending from Robert Tigerstedt’s naming renin in 1898 to the present time; biochemists, physiologists, pharmacologists, and practicing clinicians have all combined to describe the physiologic implications of converting angiotensinogen into angiotensin II. Indeed, one may argue that the clinical development of ACE inhibitors and angiotensin II receptor antagonists has benefited humankind to a level seen only with the development of antibiotics and steroids. As we begin the twenty-first century, it is worthwhile to summarize the state of our knowledge concerning ACE and angiotensin II. In doing, we benefit from a whole class of experiments not available to those writing reviews even 10 years ago: the revolution in our ability to genetically manipulate the mouse as an experimental model. This is due to the widespread application of gene targeting by homologous recombination in embryonic stem cells. As is widely appreciated, this technology can produce a knockout mouse lacking any particular gene. Less appreciated are the full capabilities of this methodology which can be summarized as: if it can be dreamed, it can be done. Gene targeting can be used to create point mutations, duplicate a gene, and modify the expression pattern of a protein almost as easily as creating knockout mice null for a particular protein. We, and others, have used gene targeting in mice to create modifications in the renin-angiotensin system of a sort not seen in humans. While any single experiment may be assailed as …

Angiotensin-Converting Enzyme N-Terminal Inactivation Alleviates Bleomycin-Induced Lung Injury

Bleomycin has potent anti-oncogenic properties for several neoplasms, but drug administration is limited by bleomycin-induced lung fibrosis. Inhibition of the renin-angiotensin system has been suggested to decrease bleomycin toxicity, but the efficacy of such strategies remains uncertain and somewhat contradictory. Our hypothesis is that, besides angiotensin II, other substrates of angiotensin-converting enzyme (ACE), such as the tetrapeptide N-acetyl-seryl-aspartyl-lysyl-proline (AcSDKP), play a significant role in controlling fibrosis. We studied bleomycin-induced lung injury in normotensive mice, termed N-KO and C-KO, which have point mutations inactivating either the N- or C-terminal catalytic sites of ACE, respectively. N-KO, but not C-KO mice, have a marked resistance to bleomycin lung injury as assessed by lung histology and hydroxyproline content. To determine the importance of the ACE N-terminal peptide substrate AcSDKP in the resistance to bleomycin injury, N-KO mice were treated with S-17092, a prolyl-oligopeptidase inhibitor that inhibits the formation of AcSDKP. In response to bleomycin injection, S-17092-treated N-KO mice developed lung fibrosis similar to wild-type mice. In contrast, the administration of AcSDKP to wild-type mice reduced lung fibrosis due to bleomycin administration. This study shows that the inactivation of the N-terminal catalytic site of ACE significantly reduced bleomycin-induced lung fibrosis and implicates AcSDKP in the mechanism of protection. These data suggest a possible means to increase tolerance to bleomycin and to treat fibrosing lung diseases.

New insights into the role of angiotensin-converting enzyme obtained from the analysis of genetically modified mice

Angiotensin-converting enzyme (ACE) has been well-recognized for its role in blood pressure regulation. ACE is made by many tissues, though it is most abundantly expressed on the luminal surface of vascular endothelium. ACE knockout mice show a profound phenotype with low blood pressure, but also with hemopoietic and developmental defects, which complicates understanding the biological functions of ACE in individual tissue types. Using a promoter-swapping strategy, several mouse lines with unique ACE tissue expression patterns were studied. These include mice with ACE expression in the liver (ACE 3/3), the heart (ACE 8/8), and macrophages (ACE 10/10). We also investigated mice with a selective inactivation of either the N- or C-terminal ACE catalytic domain. Our studies indicate that ACE plays a role in many other physiologic processes beyond simple blood pressure control.

Establishing the Role of Angiotensin-Converting Enzyme in Renal Function and Blood Pressure Control through the Analysis of Genetically Modified Mice

Angiotensin II is a vasoconstrictor and a hypertensive peptide that binds to the AT1 receptor and, through both direct and indirect mechanisms, induces salt reabsorption. Also, angiotensin II is thought to be a profibrotic and proproliferative peptide; abundant evidence now suggests that angiotensin

Tissue specific expression of angiotensin converting enzyme: a new way to study an old friend.

Angiotensin-converting enzyme (ACE) plays a central role in blood pressure regulation by producing the vasoconstrictor angiotensin II. When ACE knockout mice were studied, they presented with a complicated phenotype, including cardiovascular, reproductive, hematologic and developmental defects. The complexity of an ACE knockout mouse emphasizes the advantages and disadvantages of the classic knockout strategy. An animal lacking all ACE is very different from a wild type animal, and can be modeled as representing an extreme phenotype. To understand the role of ACE in a tissue and organ specific fashion, our group used targeted homologous recombination to create mouse models in which a promoter swapping strategy results in very restricted tissue patterns of ACE expression. Mice with ACE expression only in the heart, termed ACE 8/8 mice, present with atria enlargement and electrical conduction defects, but normal ventricular function. Mice with ACE expression only in monocytes and macrophages, termed ACE 10/10 mice, have a marked resistance to the growth of melanoma due to an enhanced immune response characterized by increased tumor specific CD8+ T cells and increased proinflammatory cytokines. These mice may define a new means of augmenting the immune response, potentially useful in human clinical situations. The promoter swapping strategy permits scientific investigation of questions unapproachable by other experimental approaches.