Hypertension in transgenic mice with brain-selective overexpression of the alpha(2B)-adrenoceptor

BACKGROUND

Previous studies have shown that the presynaptic alpha(2B)-adrenoceptor subtype in the central nervous system has a sympathoexcitatory function and its activation leads to a hyperadrenergic hypertensive state. The purpose of this project was to develop a novel hyperadrenergic model, a transgenic (TG) mouse model with brain-selective overexpression of the alpha(2B)-adrenergic receptor (alpha(2B)-AR).

METHODS

We used Southern blot analysis to confirm transgene, real-time PCR to assess gene expression, western Blot analysis and immunohistology to assess protein expression and localization in brain areas. Indirect blood pressure (BP) and heart rate were recorded.

RESULTS

In TG mice there was a 1.8-fold increase in alpha(2B)-AR protein expression compared to wild-type (WT) mice. Immunostaining of brain sections revealed that concentration of alpha(2B)-AR was much more pronounced in TG than in WT mice. Systolic BP at 8 weeks of age was significantly elevated in TG 130 +/- 6 mm Hg, compared with WT control nontransgenic littermates of the same age 107 +/- 7 mm Hg, (P < 0.05), indicating that the TG mice had indeed developed hypertension.

CONCLUSIONS

We have therefore documented that overexpression of the alpha(2B)-AR gene leads to increased production of alpha(2B)-AR protein in brain regions known to regulate central sympathetic outflow, thus resulting in sustained BP elevation. This is a unique model of experimental hypertension driven purely by overexpression of the alpha(2B)-AR that would result in an overactive sympathetic system and would be suitable for testing the pharmacologic properties of potential therapeutic agents.

Role of bradykinin B1 and B2 receptors in normal blood pressure regulation

With inhibition or absence of the bradykinin B2 receptor (B2R), B1R is upregulated and assumes some of the hemodynamic properties of B2R, indicating that both participate in the maintenance of normal vasoregulation or to development of hypertension. Herein we further evaluate the role of bradykinin in normal blood pressure (BP) regulation and its relationship with other vasoactive factors by selectively blocking its receptors. Six groups of Wistar rats were treated for 3 wk: one control group with vehicle alone, one with concurrent administration of B1R antagonist R-954 (70 microg x kg(-1) x day(-1)) and B2R antagonist HOE-140 (500 microg x kg(-1) x day(-1)), one with R-954 alone, one with HOE 140 alone, one with concurrent administration of both R-954 and HOE-140 plus the angiotensin antagonist losartan (5 mg x kg(-1) x day(-1)), and one with only losartan. BP was measured continuously by radiotelemetry. Only combined administration of B1R and B2R antagonists produced a significant BP increase from a baseline of 107-119 mmHg at end point, which could be partly prevented by losartan and was not associated with change in catecholamines, suggesting no involvement of the sympathoadrenal system. The impact of blockade of bradykinin on other vasoregulating systems was assessed by evaluating gene expression of different vasoactive factors. There was upregulation of the eNOS, AT1 receptor, PGE2 receptor, and tissue kallikrein genes in cardiac and renal tissues, more pronounced when both bradykinin receptors were blocked; significant downregulation of AT2 receptor gene in renal tissues only; and no consistent changes in B1R and B2R genes in either tissue. The results indicate that both B1R and B2R contribute to the maintenance of normal BP, but one can compensate for inhibition of the other, and the chronic inhibition of both leads to significant upregulation in the genes of related vasoactive systems.

Angiotensin-converting enzyme regulates bradykinin receptor gene expression

The angiotensin-converting enzyme (ACE) is a membrane-bound peptidyl dipeptidase known to act on a variety of peptide substrates in the extracellular space. Its most notable functions are the formation of angiotensin II and the degradation of bradykinin. In the current experiments, we found that exogenous ACE added to vascular smooth muscle cell culture strongly induces and upregulates the genes of bradykinin receptors B1 and B2. This transcriptional regulatory property of ACE was shown to be unrelated to its known enzymatic properties. Indeed, ACE at 3.75 microg/ml added in the culture medium of vascular smooth muscle cells was found to cause marked upregulation of the mRNA expression of the genes for the B1 and B2 receptors of bradykinin by 22- and 11-fold, respectively. This phenomenon was not altered by the addition of specific angiotensin II antagonists for the AT1 or AT2 receptors. Moreover, the ACE inhibitor captopril, which inhibited ACE enzymatic activity, did not block its effect at the bradykinin receptor gene transcription level. Expression of both receptor genes was completely abolished by actinomycin D. Furthermore, transcriptional upregulation was inhibited by curcumin, suggesting involvement of different transcriptional factors in this phenomenon. Electrophoretic mobility shift assay revealed increase in NF-kappaB and activator protein-1 protein binding for consensus sequences, between ACE-treated cells versus untreated cells. The data indicate a novel biological function of the ACE unrelated to its well-known enzymatic function as a peptidyl dipeptidase.

In utero gene therapy: prospect and future

Many genetic disorders are reported to cause irreversible damage to the fetus before birth. In utero gene therapy may be an effective tool for correction of genetic disorders by replacing defective gene with normal one. There are many reasons for moving forward with in utero gene therapy. The most important reason is to provide early intervention as to prevent or slow dysfunction and morbidity. This approach may prove to be advantageous in rapidly replicating fetal cells, and less sensitive to immune response to vector or transgene product due to underdeveloped immune system. In addition, the developing fetus may be a better candidate for gene therapy than the adult because gene engraftment may be more feasible in early fetal life, where stem cells or pleuripotent progenitor cells are more accessible to vectors. Some reports are available on successful in utero gene transfer in animal models but many questions remain to be answered before in utero gene therapy can be considered a viable solution to human. The real moral challenge facing in utero gene therapy is finding ways to insure that the review of protocols is adequate, and that those undertaking trials are competent to do so. Present review article analyzes the overall progress of the field, and the research that still needs to be performed before it can be considered to human clinical trials.

Role of the B(2) receptor of bradykinin in insulin sensitivity

The biological actions of bradykinin (BK) are attributed to its B(2) type receptor (B(2)R), whereas the B(1)R is constitutively absent, inducible by inflammation and toxins. Previous studies in B(2)R gene knockout mice showed that the B(1)R is overexpressed, is further upregulated by hypertensive maneuvers, and assumes some of the hemodynamic functions of the B(2)R. The current experiments were designed to further clarify the metabolic function of the B(2)R and to explore whether the upregulated B(1)R can also assume the metabolic function of the missing B(2)R. One group of B(2)R-/- mice (n=9) and one of B(2)R+/+ controls (n=8) were treated for 3 days with captopril (which produced a similar blood pressure-lowering response in both groups) and studied with the hyperinsulinemic euglycemic clamp. The knockout mice had fasting and steady-state blood glucose levels similar to those of the wild-type mice but a had tendency to higher fasting insulin levels (at 27.8+/-5.2 versus 18+/-2.9 mU/L, respectively). However, they had significantly higher steady-state insulin levels (749+/-127.2 versus 429.1+/-31.5 mU/L, P<0.05) and a significantly lower glucose uptake rate (31+/-2.4 versus 41+/-2.3 mg/kg per minute, P<0.05) and insulin sensitivity index (4.6+/-0.9 versus 10+/-0.7 P<0.001). Analysis of B(1)R and B(2)R gene expression by reverse transcription-polymerase chain reaction in cardiac muscle, skeletal muscle, and adipose tissues revealed significantly higher B(1)R mRNA level in the knockouts versus wild-type (P<0.05) at baseline and a further significant upregulation in mRNA by 1.8- to 3.2-fold (P<0.05) after insulin infusion. We conclude that absence of B(2)R confers a state of insulin resistance because it results in impaired insulin-dependent glucose transport; this is probably a direct B(2)R effect because, unlike the hemodynamic autacoid-mediated effects, it cannot be assumed by the upregulated B(1)R.