Gene therapy attenuates the elevated blood pressure and glucose intolerance in an insulin-resistant model of hypertension.

OBJECTIVE: Fructose feeding in male Sprague-Dawley (SD) rats results in a mild hypertension and glucose intolerance. Although the mechanism of this glucose intolerance and hypertension is not completely understood, a role for the renin-angiotensin system (RAS) has been proposed. In the current study our aim was to test the hypothesis that intervention of the RAS with a gene therapy approach would be effective in preventing the development of hypertension and glucose intolerance in this animal model. DESIGN AND METHODS: Five-day-old SD rats were administered either an empty retroviral vector (LNSV) or retroviral vector containing AT1 receptor antisense DNA (AT1R-AS). The virus (25 microl, 8 x 10(9) CFU/ml) was injected into the heart and the animals were returned to their mothers. After weaning, half the animals from each group were placed on breeder's chow or a 60% fructose diet. Indirect blood pressures (BP) were determined and an oral glucose tolerance test (OGTT) was performed when the animals had been on the respective diets for 2 months. RESULTS: Fructose-fed animals developed mild hypertension (145 +/- 3 versus 132 +/- 4 mmHg) by 6 weeks of dietary intervention. This increase in BP was prevented by AT1R-AS treatment (125 +/- 3 mmHg). At 2 months of age, fasting blood glucose was comparable among the four groups; however, the glucose excursion during the OGTT was significantly greater and more prolonged in the LNSV-treated, fructose-fed group than the other three groups. AT1R-AS treatment significantly prevented glucose intolerance in the fructose rat to levels observed in the controls. CONCLUSIONS: Early fructose dietary treatment results in moderate hypertension and glucose intolerance, which is prevented by a single neonatal treatment with AT1R-AS. These results suggest that the RAS is involved in the glucose intolerance associated with fructose feeding and that genetic intervention is effective in this rat model.

Attenuation of hypertension by systemic delivery of retroviral vector containing type I angiotensin II receptor antisense cDNA.

Despite recent strides in the traditional pharmacological therapies in the control and management of hypertension, a successful prevention and cure for this disease by conventional drug strategy remain at a standstill. We have begun to investigate the conceptual possibility of the use of gene therapy in the control of hypertension. In this article we describe an experimental protocol that provides proof of the principle that antisense (AS) inhibition of Type I angiotensin II receptor (AT(1)-R) could prevent development of hypertension on a long-term basis. A retrovirus-based vector has been used to deliver AT(1)R-AS with high efficiency that attenuates development of high blood pressure and hypertension-associated cardiac and vascular pathophysiology in the spontaneously hypertensive rat.

Targeting of the renin-angiotensin system by antisense gene therapy: a possible strategy for the long-term control of hypertension.

Traditional pharmacological agents have been successfully used for the treatment of hypertension for a number of decades. However, this therapeutic regimen has reached a conceptual plateau and a cure for the disease is far from appearing on the horizon. With this in mind, and recent advances in state of the art gene delivery system coupled with the anticipated completion of the human genome project, it is timely to think about the possibility of treating and/or curing hypertension using genetic means. In this review, we discuss the role of renin-angiotensin system (RAS) in hypertension; the current gene delivery/gene transfer systems and the RAS as a target for gene therapy to treat hypertension; the successful use of retroviral vectors to deliver antisense to the AT1 receptor (AT1-AS) to prevent the development of hypertension and cardiovascular pathophysiology; the potential use of the viral vectors for the reversal of hypertension; and the future of antisense gene therapy and potential advantages and limitations of this regimen in the treatment and/or control of hypertension.

Angiotensin I-converting enzyme antisense gene therapy causes permanent antihypertensive effects in the SHR.

The renin-angiotensin system plays a critical role in the control of blood pressure (BP), and its hyperactivity is associated with the development and maintenance of hypertension. Although traditional pharmacological therapies targeted toward the inhibition of the renin-angiotensin system are effective in the control of this disease, they pose significant limitations. We used an antisense gene delivery strategy to circumvent these limitations and established that a single intracardiac administration of angiotensin type 1 receptor antisense (AT(1)R-AS) causes permanent prevention of hypertension in the spontaneously hypertensive rat (SHR), an animal model of primary human hypertension. Our objectives in this study were 2-fold: to determine (1) whether the targeting of angiotensin I-converting enzyme (ACE) mRNA by a similar antisense strategy would prevent the SHR from developing hypertension and (2) whether the antihypertensive phenotype is transmitted to the offspring from the antisense-treated parents. Administration of a retroviral vector containing ACE antisense (LNSV-ACE-AS) caused a modest yet significant attenuation of high BP ( approximately 15+/-2 mm Hg) exclusively in the SHR. This was associated with a complete prevention of cardiac and renovascular pathophysiological alterations that are characteristic of hypertension. Like their parents, the F(1) generation offspring of the LNSV-ACE-AS-treated SHR expressed lower BP, decreased cardiac hypertrophy, and normalization of renal arterial excitation-coupling compared with offspring derived from the LNSV-ACE-tS (truncated sense)-treated SHR. In addition, the endothelial dysfunction commonly observed in the SHR renal arterioles was significantly prevented in both parents and offspring of the LNSV-ACE-AS-treated SHR. Polymerase chain reaction followed by Southern analysis revealed that the ACE-AS was integrated into the SHR genome and transmitted to the offspring. These observations suggest that transmission of ACE-AS by retroviral vector may be responsible for the transference of normotensive phenotypes in the SHR offspring.

Angiotensin I-converting enzyme antisense prevents altered renal vascular reactivity, but not high blood pressure, in spontaneously hypertensive rats.

The renin-angiotensin system plays a critical role in the control of blood pressure, and its hyperactivity is associated with the development of human primary hypertension. Because low-dose angiotensin I-converting enzyme (ACE) inhibitors cause small reductions in blood pressure that are associated with the complete reversal of altered vascular pathophysiology, our objective in this study was to determine whether ACE antisense (ACE-AS) gene delivery prevents alterations in renal vascular physiology in the parents and F(1) offspring of AS-treated spontaneously hypertensive rats (SHR). A single bolus intracardiac injection of ACE-AS (2x10(8) colony-forming units) in SHR neonates caused a modest (18+/-3 mm Hg, n=7 to 9) lowering of blood pressure, which was maintained in the F(1) generation offspring (n=7 to 9). Alterations in renal vascular reactivity, electrophysiology, and [Ca(2+)](i) homeostasis are underlying mechanisms associated with the development and establishment of hypertension. Renal resistance arterioles from truncated ACE sense-treated SHR showed a significantly enhanced contractile response to KCl and phenylephrine (n=24 rings from 6 animals, P<0.01) and significantly attenuated acetylcholine-induced relaxations (n=24 rings from 6 animals, P<0.01) compared with arterioles from ACE-AS-treated SHR. In addition, compared with cells dissociated from arterioles of ACE-AS-treated SHR, cells from truncated ACE sense-treated animal vessels had a resting membrane potential that was 22+/-4 mV more depolarized (n=38, P<0.01), an enhanced L-type Ca(2+) current density (2.2+/-0.3 versus 1.2+/-0.2 pA/pF, n=23, P<0.01), a decreased Kv current density (16.2+/-1.3 versus 5.4+/-2.2 pA/pF, n=34, P<0.01), and increased Ang II-dependent changes in [Ca(2+)](i) (n=142, P<0.01). Similar effects of ACE-AS treatment were observed in the F(1) offspring. These results demonstrate that ACE-AS permanently prevents alterations in renal vascular pathophysiology in spite of the modest effect that ACE-AS had on high blood pressure in SHR.

Retrovirally mediated delivery of angiotensin II type 1 receptor antisense in vitro and in vivo.

In spite of excellent drugs that are available for the control of hypertension, the pharmacological approach has major disadvantages including compliance, side effects, and inability to cure the disease. In the present chapter we provide evidence that a gene therapy concept based on the inhibition of the RAS at a genetic level, with the use of an antisense to the AT1R, is an exciting and viable approach for long-term control of hypertension without the disadvantages inherent in pharmaceutical therapy. A retrovirus-based vector has been used to deliver AT1R-AS in Ang II target tissues both in vitro and in vivo. The transduction efficiency is high and leads to the attenuation of Ang II action in vitro and prevention of hypertension in the SH rat, a model for primary human hypertension. These studies have unveiled a new avenue in which a similar approach could be attempted in the reversal of hypertension in adult animals.

Permanent cardiovascular protection from hypertension by the AT(1) receptor antisense gene therapy in hypertensive rat offspring.

Our previous studies have demonstrated that the introduction of angiotensin II type I receptor antisense (AT(1)R-AS) cDNA by a retrovirally mediated delivery system prevents the development of hypertension in the spontaneously hypertensive rat (SHR), an animal model for primary hypertension in humans. These results have led us to propose the hypothesis that an interruption of the renin-angiotensin system (RAS) activity at a genetic level would prevent hypertension on a permanent basis. F(1) and F(2) generations of offspring from a retroviral vector, LNSV- and LNSV-AT(1)R-AS-treated SHR, were generated, and various physiological parameters indicative of hypertension were studied and compared with those of their parents to investigate this hypothesis. Both F(1) and F(2) generations of LNSV-AT(1)R-AS-treated SHR expressed a persistently lower blood pressure, decreased cardiac hypertrophy and fibrosis, decreased medial thickness, and normalization of renal artery excitation-contraction coupling, Ca(2+) current, and [Ca(2+)](i) when compared with offspring derived from the LNSV-treated SHR. In fact, the magnitude of the prevention of these pathophysiological alterations was similar to that observed in the LNSV-AT(1)R-AS-treated SHR parent. The prevention of cardiovascular pathophysiology and expression of normotensive phenotypes are, at least in part, a result of integration and subsequent transmission of AT(1)R-AS from the SHR parents to offspring. These data demonstrate that a single intracardiac injection of LNSV-AT(1)R-AS causes a permanent cardiovascular protection against hypertension as a result of a genomic integration and germ line transmission of the AT(1)R-AS in the SHR offspring.

Sustained inhibition of angiotensin I-converting enzyme (ACE) expression and long-term antihypertensive action by virally mediated delivery of ACE antisense cDNA.

Angiotensin I-converting enzyme (ACE) inhibitors have been proven to be highly effective and are for the most part the drugs of choice in the treatment and control of hypertension, congestive heart failure, and left ventricular dysfunction. Despite this, questions regarding side effects and compliance with this traditional pharmacological strategy remain. In view of these observations, coupled with recent advances in gene-transfer technology, our objective in this study was to determine whether the expression of ACE could be controlled on a permanent basis at a genetic level. We argued that the introduction of ACE antisense to inhibit the enzyme would be a prerequisite in considering the antisense gene therapy for the control of hypertension and other related pathological states. Retroviral vectors (LNSV) containing ACE sense (LNSV-ACE-S) and ACE antisense (LNSV-ACE-AS) sequences were constructed and were used in rat pulmonary artery endothelial cells (RPAECs) to determine the feasibility of this approach. Infection of rat RPAECs with LNSV-ACE-S and LNSV-ACE-AS resulted in a robust expression of transcripts corresponding to ACE-S and ACE-AS, respectively, for the duration of these experiments, ie, 8 consecutive passages. The expression of ACE-AS but not of ACE-S was associated with a permanent decrease of approximately 70% to 75% in ACE expression and a 50% increase in the B(max) for the AT(1)s. Although angiotensin II caused a concentration-dependent stimulation of intracellular Ca(2+) levels in both ACE-S- and ACE-AS-expressing cells, the stimulation was significantly higher in ACE-AS-expressing RPAECs. In vivo experiments demonstrated a prolonged expression of ACE-AS transcripts in cardiovascularly relevant tissues of rats. This was associated with a long-term reduction in blood pressure by approximately 15 mm Hg, exclusively in the spontaneously hypertensive rat. These observations demonstrate that delivery of ACE-AS by retroviral vector results in a permanent inhibition of ACE and a long-term reduction in high blood pressure in the spontaneously hypertensive rat.

Angiotensin II type 1 receptor antisense gene therapy prevents altered renal vascular calcium homeostasis in hypertension.

Intracellular Ca2+ ([Ca2+]i) homeostasis regulates vascular smooth muscle tone, and alteration in [Ca2+]i handling is associated with the development and establishment of hypertension. We have previously established in the spontaneously hypertensive rat (SHR) that virally mediated delivery of angiotensin II type 1 receptor antisense (AT1R-AS) prevents the development of high blood pressure and some pathophysiology associated with hypertension for 120 days. In light of this, our objectives in this study were to determine whether AT1R-AS gene therapy (1) could have a longer duration in the prevention of hypertension and (2) would attenuate the alterations in renal vascular Ca2+ homeostasis and therefore vasoconstriction, characteristics of hypertension. Intracardiac delivery of AT1R-AS in neonates prevented the development of hypertension in SHR for at least 210 days. At this time, untreated SHR renal resistance arterioles showed a significantly enhanced contractile response to KCl and angiotensin II (Ang II) when compared with normotensive Wistar-Kyoto rats. In addition, L-type Ca2+ current density and Ang II-dependent increases in [Ca2+]i were significantly increased in cells dissociated from renal resistance arterioles of the untreated SHR. AT1R-AS treatment prevented all of the above vascular alterations associated with the hypertensive state in SHR. Finally, Western blot analysis of L-type Ca2+ channel (alpha1C) protein levels in renal resistance arterioles of untreated SHR showed no significant difference when compared with control. These results are novel and demonstrate that viral-mediated delivery of AT1R-AS not only attenuates the development of hypertension on a long-term basis but prevents changes in renal vascular Ca2+ homeostasis associated with the disease.

Prevention of renovascular and cardiac pathophysiological changes in hypertension by angiotensin II type 1 receptor antisense gene therapy.

Hypertension produces pathophysiological changes that are often responsible for the mortality associated with the disease. However, it is unclear whether normalizing blood pressure (BP) with conventional therapy is effective in reversing the pathophysiological damage. The duration and initiation of treatment, site of administration, and agent used all appear to influence the reversal of the pathophysiological alterations associated with hypertension. We have previously established that retrovirally mediated delivery of angiotensin II type 1 receptor antisense (AT1R-AS) attenuates the development of high BP in the spontaneously hypertensive (SH) rat model of human essential hypertension. Our objective was to determine whether this attenuation of high BP is associated with prevention of other pathophysiological changes induced by the hypertensive state. Intracardiac delivery of AT1R-AS in neonates prevented the development of hypertension in SH rats for at least 120 days. Contractile experiments demonstrated an impaired endothelium-dependent vascular relaxation (acetylcholine) and an enhanced contractile response to vasoactive agents (phenylephrine and KCl) in the SH rat renal vasculature. In addition, the voltage-dependent K+ current density, which is believed to contribute to smooth muscle resting membrane potential and basal tone, was decreased in renal resistance artery cells of the SH rat. AT1R-AS treatment prevented each of these renal vascular alterations. Finally, AT1R-AS delivery prevented the pathological alterations observed in the SH rat myocardium, including left ventricular hypertrophy, multifocal fibrosis, and perivascular fibrosis. These observations demonstrate that viral-mediated delivery of AT1R-AS attenuates the development of hypertension on a long term basis, and this is associated with prevention of pathophysiological changes in SH rats.

Structural remodeling of cardiac myocytes in patients with ischemic cardiomyopathy.

BACKGROUND: Chronic ischemic heart disease may lead to ventricular dilation and congestive heart failure (ischemic cardiomyopathy [ICM]). The changes in cardiac myocyte shape associated with this dilation, however, are not known. METHODS AND RESULTS: Left ventricular myocyte dimensions were assessed in cells isolated from explanted human hearts obtained from patients with ICM (n = 6) who were undergoing heart transplantation. Cells were also examined from three nonfailing donor hearts with normal coronary arteries (NCA). Compared with cells from patients with NCA, myocyte length was 40% longer in hearts from patients with ICM (197 +/- 8 versus 141 +/- 9 microns, p less than 0.01), cell width was not significantly different, and cell length/width ratio was 49% greater (11.2 +/- 0.9 versus 7.5 +/- 0.6, p less than 0.01). Sarcomere length was the same in myocytes from both groups. The extent of myocyte lengthening is comparable to the increase in end-diastolic diameter commonly reported in patients with ICM. CONCLUSIONS: These data suggest that increased myocyte length (an intracellular event), instead of myocyte slippage (an extracellular event), is largely responsible for the chamber dilation in ICM. Furthermore, maladaptive remodeling of myocyte shape (e.g., increased myocyte length/width ratio) may contribute to the elevated wall stress (e.g., increased chamber radius/wall thickness) in ICM.