Ahsan Husain

Proposed Update of Angiotensin Receptor Nomenclature

Angiotensin II exerts a wide range of actions on the heart, blood vessels, adrenals, kidneys, and nervous system and plays a major role in blood pressure maintenance and volume homeostasis. Its effects are mediated mainly by plasma membrane receptors. Efforts to elucidate the nature and distribution of these receptors have involved intensive research on the part of pharmacologists, molecular biologists, and clinicians, and to avoid confusion it is therefore important that a uniform nomenclature be adopted by all disciplines concerned. The International Union of Pharmacology (IUPHAR) Nomenclature Subcommittee for Angiotensin Receptors met in Oxnard, Calif, in February 1994. At this meeting, scientists working in the field were invited to exchange views on new issues relating to angiotensin receptor subtypes, their functions, and appropriate amendments to the nomenclature proposed in 1991.1 The committee has not yet been able to put forward a definitive recommendation in this fast-moving area, but the simple and workable guidelines suggested in this article reflect the opinion of many specialists. Comments from the scientific community are welcome to help in formulating a proposal that could be endorsed by the IUPHAR. To avoid any ambiguity, it is recommended that Ang should be used as the standard abbreviation for the hormone angiotensin, in conformity with a previous report2 from the Joint Nomenclature and Standardization Committee of the International Society of Hypertension, American Heart Association, and the …

A Proliferative Burst During Preadolescence Establishes the Final Cardiomyocyte Number

It is widely believed that perinatal cardiomyocyte terminal differentiation blocks cytokinesis, thereby causing binucleation and limiting regenerative repair after injury. This suggests that heart growth should occur entirely by cardiomyocyte hypertrophy during preadolescence when, in mice, cardiac mass increases many-fold over a few weeks. Here, we show that a thyroid hormone surge activates the IGF-1/IGF-1-R/Akt pathway on postnatal day 15 and initiates a brief but intense proliferative burst of predominantly binuclear cardiomyocytes. This proliferation increases cardiomyocyte numbers by ~40%, causing a major disparity between heart and cardiomyocyte growth. Also, the response to cardiac injury at postnatal day 15 is intermediate between that observed at postnatal days 2 and 21, further suggesting persistence of cardiomyocyte proliferative capacity beyond the perinatal period. If replicated in humans, this may allow novel regenerative therapies for heart diseases.

Rapid Reversal of Left Ventricular Hypertrophy and Intracardiac Volume Overload in Patients With Resistant Hypertension and Hyperaldosteronism A Prospective Clinical Study

We have shown previously that patients with resistant hypertension and hyperaldosteronism have increased brain natriuretic peptide suggestive of increased intravascular volume. In the present study, we tested the hypothesis that hyperaldosteronism contributes to cardiac volume overload. Thirty-seven resistant hypertensive patients with hyperaldosteronism (urinary aldosterone ≥12 &mgr;g/24 hours and plasma renin activity ≤1.0 ng/mL per hour) and 71 patients with normal aldosterone status were studied. Both groups had similar blood pressure and left ventricular mass, whereas left and right ventricular end-diastolic volumes measured by cardiac MRI were greater in high versus normal aldosterone subjects (P<0.05). Spironolactone treatment (19 patients in the high aldosterone group and 15 patients from the normal aldosterone group participated in the follow-up) resulted in a significant decrease in clinic systolic blood pressure, right and left ventricular end diastolic volumes, left atrial volume, left ventricular mass, and brain natriuretic peptide at 3 and 6 months of follow-up in patients with high aldosterone, whereas in those with normal aldosterone status, spironolactone decreased blood pressure and left ventricular mass without changes in ventricular or atrial volumes or plasma brain natriuretic peptide. Hyperaldosteronism causes intracardiac volume overload in patients with resistant hypertension in spite of conventional thiazide diuretic use. Mineralocorticoid receptor blockade induces rapid regression of left ventricular hypertrophy irrespective of aldosterone status. In subjects with high aldosterone, mineralocorticoid receptor blockade induces a prominent diuretic effect compared with a greater vasodilatory effect in subjects with normal aldosterone status.

Mechanism of allosteric regulation of transglutaminase 2 by GTP

Allosteric regulation is a fundamental mechanism of biological control. Here, we investigated the allosteric mechanism by which GTP inhibits cross-linking activity of transglutaminase 2 (TG2), a multifunctional protein, with postulated roles in receptor signaling, extracellular matrix assembly, and apoptosis. Our findings indicate that at least two components are involved in functionally coupling the allosteric site and active center of TG2, namely (i) GTP binding to mask a conformationally destabilizing switch residue, Arg-579, and to facilitate interdomain interactions that promote adoption of a compact, catalytically inactive conformation and (ii) stabilization of the inactive conformation by an uncommon H bond between a cysteine (Cys-277, an active center residue) and a tyrosine (Tyr-516, a residue located on a loop of the β-barrel 1 domain that harbors the GTP-binding site). Although not essential for GTP-mediated inhibition of cross-linking, this H bond enhances the rate of formation of the inactive conformer.

Mast cell chymase limits the cardiac efficacy of Ang I–converting enzyme inhibitor therapy in rodents

Ang I-converting enzyme (ACE) inhibitors are widely believed to suppress the deleterious cardiac effects of Ang II by inhibiting locally generated Ang II. However, the recent demonstration that chymase, an Ang II-forming enzyme stored in mast cell granules, is present in the heart has added uncertainty to this view. As discussed here, using microdialysis probes tethered to the heart of conscious mice, we have shown that chronic ACE inhibitor treatment did not suppress Ang II levels in the LV interstitial fluid (ISF) despite marked inhibition of ACE. However, chronic ACE inhibition caused a marked bradykinin/B2 receptor-mediated increase in LV ISF chymase activity that was not observed in mast cell-deficient KitW/KitW-v mice. In chronic ACE inhibitor-treated mast cell-sufficient littermates, chymase inhibition decreased LV ISF Ang II levels substantially, indicating the importance of mast cell chymase in regulating cardiac Ang II levels. Chymase-dependent processing of other regulatory peptides also promotes inflammation and tissue remodeling. We found that combined chymase and ACE inhibition, relative to ACE inhibition alone, improved LV function, decreased adverse cardiac remodeling, and improved survival after myocardial infarction in hamsters. These results suggest that chymase inhibitors could be a useful addition to ACE inhibitor therapy in the treatment of heart failure.

Involvement of chymase-mediated angiotensin II generation in blood pressure regulation

Angiotensin I-converting enzyme (ACE) inhibitors are thought to lower blood pressure in hypertensive patients, mainly by decreasing angiotensin II (Ang II) formation. Chymase, a human mast cell protease, has recently been proposed to play a role in blood pressure regulation because of its Ang II-forming activity. Here we show that the predominant chymase mRNA species in the mouse aorta are those for types 4 and 5 isoforms, and that both are efficient Ang II-forming enzymes. Evaluation of ACE-dependent and ACE-independent Ang II-forming pathways in mast cell-deficient (Kit(w)/Kit(w-v)) mice and their mast cell-sufficient littermate (MC(+/+)) controls revealed that, in contrast to the latter, Kit(w)/Kit(w-v) mice fail to express chymase mRNAs in the vasculature and have almost no ACE-independent Ang II-forming activity in either isolated blood vessels or homogenates. Moreover, in MC(+/+) but not in Kit(w)/Kit(w-v) mice, a contribution of ACE-independent Ang II generation to blood pressure regulation was evident by a 1.6-fold greater maximal reduction in mean arterial pressure with acute ACE inhibition plus AT(1) receptor blockade than with ACE inhibition alone. Thus, mast cells are the source of the vascular ACE-independent pathway, and the antihypertensive benefit of combining ACE inhibitor therapy with AT(1) receptor antagonist therapy is most likely due to negation of chymase-catalyzed Ang II generation.

c-kit Is Required for Cardiomyocyte Terminal Differentiation

c-kit, the transmembrane tyrosine kinase receptor for stem cell factor, is required for melanocyte and mast cell development, hematopoiesis, and differentiation of spermatogonial stem cells. We show here that in the heart, c-kit is expressed not only by cardiac stem cells but also by cardiomyocytes, commencing immediately after birth and terminating a few days later, coincident with the onset of cardiomyocyte terminal differentiation. To examine the function of c-kit in cardiomyocyte terminal differentiation, we used compound heterozygous mice carrying the W (null) and Wv (dominant negative) mutations of c-kit. In vivo, adult W/Wv cardiomyocytes are phenotypically indistinguishable from their wild-type counterparts. After acute pressure overload adult W/Wv cardiomyocytes reenter the cell cycle and proliferate, leading to left ventricular growth; furthermore in transgenic mice with cardiomyocyte-restricted overexpression of the dominant negative Wv mutant, pressure overload causes cardiomyocytes to reenter the cell cycle. In contrast, in wild-type mice left ventricular growth after pressure overload results mainly from cardiomyocyte hypertrophy. Importantly, W/Wv mice with pressure overload–induced cardiomyocyte hyperplasia had improved left ventricular function and survival. In W/Wv mice, c-kit dysfunction also resulted in an ≈14-fold decrease (P<0.01) in the number of c-kit+/GATA4+ cardiac progenitors. These findings identify novel functions for c-kit: promotion of cardiac stem cell differentiation and regulation of cardiomyocyte terminal differentiation.

Microarray identifies extensive downregulation of noncollagen extracellular matrix and profibrotic growth factor genes in chronic isolated mitral regurgitation in the dog.

Background— The volume overload of isolated mitral regurgitation (MR) in the dog results in left ventricular (LV) dilatation and interstitial collagen loss. To better understand the mechanism of collagen loss, we performed a gene array and overlaid regulated genes into ingenuity pathway analysis. Methods and Results— Gene arrays from LV tissue were compared in 4 dogs before and 4 months after MR. Cine-magnetic resonance–derived LV end-diastolic volume increased 2-fold (P=0.005), and LV ejection fraction increased from 41% to 53% (P<0.007). LV interstitial collagen decreased 40% (P<0.05) compared with controls, and replacement collagen was in short strands and in disarray. Ingenuity pathway analysis identified Marfan syndrome, aneurysm formation, LV dilatation, and myocardial infarction, all of which have extracellular matrix protein defects and/or degradation. Matrix metalloproteinase-1 and -9 mRNA increased 5- (P=0.01) and 10-fold (P=0.003), whereas collagen I did not change and collagen III mRNA increased 1.5-fold (P=0.02). However, noncollagen genes important in extracellular matrix structure were significantly downregulated, including decorin, fibulin 1, and fibrillin 1. In addition, connective tissue growth factor and plasminogen activator inhibitor were downregulated, along with multiple genes in the transforming growth factor-β signaling pathway, resulting in decreased LV transforming growth factor-β1 activity (P=0.03). Conclusions— LV collagen loss in isolated, compensated MR is chiefly due to posttranslational processing and degradation. The downregulation of multiple noncollagen genes important in global extracellular matrix structure, coupled with decreased expression of multiple profibrotic factors, explains the failure to replace interstitial collagen in the MR heart.

Dissecting the role of chymase in angiotensin II formation and heart and blood vessel diseases.

Inhibition of angiotensin II action or its formation by angiotensin-converting enzyme has been highly successful in the treatment of cardiovascular diseases. Since the identification of chymase as a major angiotensin II-forming enzyme in the human heart and its vessels more than a decade ago, numerous studies have sought to understand the importance of this enzyme in tissue angiotensin II formation and in the pathogenesis of hypertension, congestive heart failure, and vascular disease. Recent studies show that chymase and angiotensin-converting enzyme regulate angiotensin II production in distinct tissue compartments and that, in the pathogenesis of cardiovascular diseases, chymase-dependent effects extend beyond its ability to regulate tissue angiotensin II levels.

Dynamic molecular and histopathological changes in the extracellular matrix and inflammation in the transition to heart failure in isolated volume overload

Left ventricular (LV) volume overload (VO) causes eccentric remodeling with inflammatory cell infiltration and extracellular matrix (ECM) degradation, for which there is currently no proven therapy. To uncover new pathways that connect inflammation and ECM homeostasis with cellular dysfunction, we determined the cardiac transciptome in subacute, compensated, and decompensated stages based on in vivo hemodynamics and echocardiography in the rat with aortocaval fistula (ACF). LV dilatation at 5 wk was associated with a normal LV end-diastolic dimension-to-posterior wall thickness ratio (LVEDD/PWT; compensated), whereas the early 2-wk (subacute) and late 15-wk (decompensated) ACF groups had significant increases in LVEDD/PWT. Subacute and decompensated stages had a significant upregulation of genes related to inflammation, the ECM, the cell cycle, and apoptosis. These changes were accompanied by neutrophil and macrophage infiltration, nonmyocyte apoptosis, and interstitial collagen loss. At 15 wk, there was a 40-fold increase in the matricellular protein periostin, which inhibits connections between collagen and cells, thereby potentially mediating a side-to-side slippage of cardiomyocytes and LV dilatation. The majority of downregulated genes was composed of mitochondrial enzymes whose suppression progressed from 5 to 15 wk concomitant with LV dilatation and systolic heart failure. The profound decrease in gene expression related to fatty acid, amino acid, and glucose metabolism was associated with the downregulation of peroxisome proliferator associated receptor (PPAR)-α-related and bioenergetic-related genes at 15 wk. In VO, an early phase of inflammation subsides at 5 wk but reappears at 15 wk with marked periostin production along with the suppression of genes related to PPAR-α and energy metabolism.