Angiotensin II, dopamine and nitric oxide. An asymmetrical neurovisceral interaction between brain and plasma to regulate blood pressure.

Vital functions, such as blood pressure, are regulated within a framework of neurovisceral integration in which various factors are involved under normal conditions maintaining a delicate balance. Imbalance of any of these factors can lead to various pathologies. Blood pressure control is the result of the balanced action of central and peripheral factors that increase or decrease. Special attention for blood pressure control was put on the neurovisceral interaction between Angiotensin II and the enzymes that regulate its activity as well as on nitric oxide and dopamine. Several studies have shown that such interaction is asymmetrically organized. These studies suggest that the neuronal activity related to the production of nitric oxide in plasma is also lateralized and, consequently, changes in plasma nitric oxide influence neuronal function. This observation provides a new aspect revealing the complexity of the blood pressure regulation and, undoubtedly, makes such study more motivating as it may affect the approach for treatment.

[Brain asymmetry and dopamine: beyond motor implications in Parkinson's disease and experimental hemiparkinsonism]. / Asimetria cerebral y dopamina: mas alla de las implicaciones motoras en la enfermedad de Parkinson y hemiparkinsonismo experimental.

INTRODUCTION: Brain asymmetry could be defined as the existence of functional, anatomic or neurochemical differences between both hemispheres. It is a dynamic phenomenon, regulated by endogenous and exogenous factors. Its functional significance is poorly clarified and is only partially understood in very specific cases such as the relationship between the lateralized brain content of dopamine and its motor effects which is specially patent in Parkinson's disease. DEVELOPMENT: The asymmetric brain content of dopamine not only displays lateralized motor effects but also behavioral and autonomic asymmetric consequences. In fact, Parkinson's disease is characterized not only by unilateral motor symptoms that arise at the early stages, but has other non-motor symptoms such as autonomic or cognitive alterations that are also revealed asymmetrically. CONCLUSIONS: Brain asymmetry has been underestimated when analyzing the pathogeny of brain diseases and it has been partially studied only in some specific cases, such as Parkinson's disease. However, in order to appropriately understand some brain diseases such as Parkinson's disease, the need to consider this phenomenon has been highlighted.

TITLE: Asimetria cerebral y dopamina: mas alla de las implicaciones motoras en la enfermedad de Parkinson y hemiparkinsonismo experimental.Introduccion. La asimetria cerebral se puede definir como la existencia de diferencias funcionales, anatomicas o neuroquimicas entre los dos hemisferios cerebrales. Se trata de un fenomeno dinamico modulable por factores endogenos y exogenos. Su significado funcional esta apenas aclarado y solo lo esta en algunos casos muy concretos como, por ejemplo, la relacion existente entre el contenido cerebral lateralizado de dopamina y sus efectos motores, que se manifiesta especialmente en la enfermedad de Parkinson. Desarrollo. El contenido asimetrico cerebral de dopamina no solo da lugar a efectos motores lateralizados, sino que se extiende a consecuencias autonomicas y de conducta igualmente lateralizadas. De hecho, la enfermedad de Parkinson se caracteriza por sintomas motores unilaterales, que surgen en las fases iniciales de la enfermedad, y por otros sintomas no motores, como alteraciones autonomicas o cognitivas, que tambien se manifiestan de forma lateralizada. Conclusiones. La asimetria cerebral ha sido un aspecto infravalorado a la hora de analizar la patogenia de las enfermedades cerebrales, y solo en determinados casos, como en la enfermedad de Parkinson, se ha profundizado parcialmente en su estudio. Sin embargo, se ha puesto en evidencia que es necesario considerar este fenomeno para la adecuada comprension de algunas patologias cerebrales, como es el caso de la enfermedad de Parkinson.

Handedness and gender influence blood pressure in young healthy men and women: A pilot study.

OBJECTIVE: The type and level of sex steroids influence blood pressure (BP). It has been suggested that functional brain asymmetries may be influenced by sex hormones. In addition, there are inter-arm differences in BP not yet related with handedness. In this study, we hypothesize a possible association between sex hormones, handedness, and inter-arm differences in blood pressure. METHODS: To analyze this hypothesis, we measured BP in the left and right arm of the left and right handed adult young men and women in menstrual and ovulatory phase and calculated their mean arterial pressure (MAP). RESULTS: Significant differences depending on sex, arm, handedness or phase of the cycle were observed. MAP was mostly higher in men than in women. Remarkably, in women, the highest levels were observed in the left handed in menstrual phase. Interestingly, the level of handedness correlated negatively with MAP measured in the left arm of right-handed women in the ovulatory phase but positively with the MAP measured in the right arm of right-handed women in the menstrual phase. CONCLUSIONS: These results may reflect an asymmetrical modulatory influence of sex hormones in BP control.

Influence of thyroid disorders on the kidney expression and plasma activity of aminopeptidase A.

OBJECTIVE: Thyroid disorders may affect blood pressure and renal function modifying factors of the plasmatic and kidney renin-angiotensin system such as aminopeptidase A (AP A) that metabolizes angiotensin II to angiotensin III. We investigated the expression of AP A in the kidney, as well as its enzymatic activity in the plasma of euthyroid, hyperthyroid, and hypothyroid adult male rats. METHODS: Hyperthyroidism was induced by daily subcutaneous injections of tetraiodothyronine. Hypothyroid rats were obtained by administration of methimazole in drinking water. Expression of AP A was determined by Western blot analysis. Plasma AP A activity was measured fluorometrically using glutamyl-ß-naphthylamide as substrate. RESULTS: While hyperthyroid rats exhibited lower levels of plasma AP A activity than controls, the kidney of hyperthyroid animals expressed significantly higher AP A than controls and hypothyroid animals. CONCLUSIONS: A discrepancy between the high expression of AP A in kidney of hyperthyroid rats and the low activity of AP A measured in plasma and kidney of hyperthyroid animals was found. The posttranslational influence of environmental biochemical factors may be in part responsible for that divergence.

Relationship of angiotensinase and vasopressinase activities between hypothalamus, heart, and plasma in L-NAME-treated WKY and SHR.

The renin-angiotensin system (RAS), vasopressin, and nitric oxide (NO) interact to regulate blood pressure at central and peripheral level. To improve our understanding of their interaction and their relationship with the hypothalamus and the cardiovascular system, we analyzed angiotensin- and vasopressin-metabolizing activities in hypothalamus (HT), left ventricle (LV), and plasma, collected from Wistar-Kyoto (WKY) and spontaneously hypertensive rats (SHR) treated or not with L-NAME [N(G)-nitro-L-arginine methyl ester], which inhibits the formation of NO and over-activates the sympathetic nervous system. Previous observations in WKY suggested higher formation of Ang III and Ang IV in the HT and higher availability of Ang II in plasma after L-NAME treatment. Our current results show higher formation of Ang IV and higher metabolism of vasopressin after treatment with L-NAME in the LV of WKY rats. In SHR treated with L-NAME, there is higher availability of Ang III in the HT leading to higher release of vasopressin together with lower formation of Ang 2-10. In their LV, however, there is an increase of vasopressinase. Interestingly, while the enzymatic activities in the HT and LV of WKY rats and control SHR are poorly correlated, they are well but inversely correlated in the L-NAME treated SHR. On the other hand, no significant correlations between enzymatic activities in HT or LV and plasma were noticed. Our results suggest that eNOS inhibition in SHR induces or enhances an inverse reciprocal interaction between HT and LV involving the RAS and vasopressin, which may be mediated by the autonomic nervous system.

The renin-angiotensin system: new insight into old therapies.

Although the renin-angiotensin system (RAS) is already an old acquaintance, there are often exciting discoveries that improve our knowledge of it and open new therapeutic possibilities. Moreover, well-established drugs, such as angiotensin-converting enzyme inhibitors (ACEI), angiotensin receptor blockers (ARB), or beta-blockers, show that their mechanism of action may be the result of parallel pathways other than the ones initially established. A detailed analysis of the RAS can be carried out in part through the study of the enzymes, named angiotensinases, involved in its cascade, whose activity is a reflection of the functionality of their peptide substrates. The study of these enzymes offers the possibility of controlling the effects of angiotensins through various pharmacological manipulations. For example, angiotensinase inhibitors or activators are being used or have been proposed as antihypertensive agents. They have also been suggested as analgesic and antidepressant drugs or targets for drug development against different pathologies such as Alzheimer's disease, epilepsy or ischemia. On the other hand, the analysis of brain asymmetry has revealed surprising results about the laterality of central and peripheral components of the RAS. Such studies indicate that the neurovisceral integration, already proposed by Claude Bernard (1867) should also be analyzed from a bilateral perspective. In this review, the RAS and the role of various angiotensinases implicated in the cascade are revisited. Therapeutic strategies involving some components of the RAS with an unusual vision resulting from a bilateral perspective added to their study are discussed.

Effects of antihypertensive drugs on angiotensinase activities in the testis of spontaneously hypertensive rats.

Sexual dysfunction is a frequent adverse effect during antihypertensive therapy. However, the mechanisms responsible for these effects are not well understood. The renin-angiotensin system has been identified in testis where it may play a role in testicular function and be involved in the detrimental effects of antihypertensive drugs. Therefore, our objective was to compare the influence of captopril and propranolol on plasma testosterone levels and on hydrolyzing angiotensin's enzymes (angiotensinases) in the testis of spontaneously hypertensive rats (SHRs) and in control animals. Twenty-four adult male SHRs were used in this study; eight were treated with captopril in drinking water, 8 with propranolol, and 8 were controls. At the end of the 4 weeks treatment period, systolic blood pressure (SBP) was recorded, blood samples were collected, and the right testis was dissected after perfusion of the rat with saline. The soluble (Sol) and membrane-bound (MB) fractions were obtained after solubilization and ultracentrifugation. Fluorometric measurement of Sol and MB angiotensinase activities were performed using arylamide derivatives as substrates. Testosterone was measured by enzyme immunoassay. SBP decreased after captopril but did not change with propranolol treatment. Whereas captopril did not affect angiotensinase activities, highly significant reductions in Sol and MB angiotensinase activities, particularly glutamyl- and aspartyl-aminopeptidases, were observed after treatment with propranolol. Plasma testosterone decreased in captopril treated rats but propranolol had a greater effect. The present results support a general functional depression of the RAS cascade in the testis of propranolol-treated SHR, which may influence the sexual function of these animals.

Angiotensinase and vasopressinase activities in hypothalamus, plasma, and kidney after inhibition of angiotensin-converting enzyme: basis for a new working hypothesis.

Reducing angiotensin II (Ang II) production via angiotensin-converting enzyme (ACE) inhibitors is a key approach for the treatment of hypertension. However, these inhibitors may also affect other enzymes, such as angiotensinases and vasopressinase, responsible for the metabolism of other peptides also involved in blood pressure control, such as Ang 2-10, Ang III, Ang IV, and vasopressin. We analyzed the activity of these enzymes in the hypothalamus, plasma, and kidney of normotensive adult male rats after inhibition of ACE with captopril. Aspartyl- (AspAP), glutamyl- (GluAP), alanyl- (AlaAP) and cystinyl-aminopeptidase (CysAP) activities were measured fluorimetrically using arylamides as substrates. Systolic blood pressure (SBP), water intake, and urine flow were also measured. Captopril reduced SBP and increased urine flow. In the hypothalamus, GluAP and AspAP increased, without significant changes in either AlaAP or CysAP. In contrast with effects in plasma, GluAP was unaffected, AspAP decreased, while AlaAP and CysAP increased. In the kidney, enzymatic activities did not change in the cortex, but decreased in the medulla. These data suggest that after ACE inhibition, the metabolism of Ang I in hypothalamus may lead mainly to Ang 2-10 formation. In plasma, the results suggest an increased formation of Ang IV together with increased vasopressinase activity. In the kidney, there is a reduction of vasopressinase activity in the medulla, suggesting a functional reduction of vasopressin in this location. The present data suggest the existence of alternative pathways in addition to ACE inhibition that might be involved in reducing BP after captopril treatment.

Blood pressure increased dramatically in hypertensive rats after left hemisphere lesions with 6-hydroxydopamine.

Plasma angiotensinase activity, nitric oxide and systolic blood pressure (SBP) were differently affected after unilateral intrastriatal injection of 6-hydroxydopamine (6-OHDA), depending on the brain hemisphere injured. Moreover, normotensive and hypertensive rats responded differently suggesting an asymmetry in the organization of the autonomic nervous system of the vessels. The aim of this study was to investigate the evolution of SBP and heart rate (HR) over time after nigrostriatal lesions in normotensive and hypertensive rat strains. Unilateral depletions of brain dopamine were performed by injecting 6-OHDA into the left or right striatum of normotensive and hypertensive rats. Vehicle without 6-OHDA was unilaterally injected in control (sham) groups. SBP and heart rate (HR) were measured in un-anesthetised animals 10 and 3 days before administration of 6-OHDA or vehicle and 3 and 25 days after treatment. In normotensive rats, at the end of study, SBP increased significantly from pre-lesioned values in left-lesioned animals but no differences were observed in right-lesioned or sham groups. Before sacrifice, there was a significant reduction from pre-lesion values in HR. In hypertensive animals, there was a highly significant increase of SBP in left-lesioned and sham left rats and a slight increase in right-lesioned but no differences were observed in sham right group. No differences in HR were observed throughout the study in the groups studied. The present results represent direct experimental evidence of an asymmetrical cardiovascular response to unilateral brain lesions, suggesting that left injury may have a worst prognosis.

The profile of fatty acids in frontal cortex of rats depends on the type of fat used in the diet and correlates with neuropeptidase activities.

The kind of fat in the diet modifies the profile of fatty acids in brain and also affects aminopeptidase activities in tissues. Although modifications in brain fatty acids, neurotransmitters, or enzymes due to dietary fat composition have been reported, no direct relationship has yet been described between specific brain fatty acid changes and neuropeptide metabolism following the fat composition of the diet. We investigated the lipid profile and some neuropeptidase activities in the frontal cortex of adult male rats after a period in which diets were supplemented with fatty acids differing in their degrees of saturation such as fish oil (rich in polyunsaturated fatty acids, PUFAs), olive oil (rich in monounsaturated fatty acids, MUFAs), and coconut oil (rich in saturated fatty acids, SAFAs). It is observed that the diet composition affects fatty acid distribution in the brain. Although there is no change of global aminopeptidase/neuropeptidase, their activities in the brain correlate positively or negatively with the dietary fat composition. It is hypothesized that fatty acid in the diet modifies membrane fluidity, peptidases tertiary structure, and therefore, the availability and function of neuropeptides. The present results support the notion that cognitive functions may be modulated depending on the type of fat used in the diet.

Hypothalamic and plasmatic angiotensin metabolism in L-NAME treated rats.

In order to study the interaction between the renin-angiotensin system (RAS) and nitric oxide (NO), we analyzed the activity of aspartyl- (AspAP), glutamyl- (GluAP), alanyl- (AlaAP), and cystinylaminopeptidase (CysAP) enzymes involved in the RAS cascade, in the hypothalamus, and plasma of normotensive adult male rats after the inhibition of NO production with the NO synthase inhibitor L-NAME (L-N (G)-nitroarginine methyl ester). L-NAME treatment produced a significant increase of systolic blood pressure (SBP). In plasma, while GluAP activity decreased significantly, suggesting a lower Ang III formation, the other aminopeptidases did not change after L-NAME treatment. In hypothalamus, the activities of AspAP and CysAP were not affected after L-NAME treatment. In contrast, GluAP and AlaAP increased significantly. These results suggested mainly a higher formation of Ang III, but also higher levels of Ang IV in the hypothalamus of L-NAME treated rats. Both peptides have hypertensive properties at central level. On the contrary, Ang III may counteract the hypertensive action of Ang II at the periphery. Therefore, the increased SBP in L-NAME treated rats may be due in part to the increased activity of GluAP and AlaAP in hypothalamus and to a decreased activity of GluAP in plasma.

Plasma aminopeptidase activities in Parkinson's disease.

Parkinson's disease (PD) is an age-related neurodegenerative disease characterized by a progressive motor disorder, but frequently is accompanied by autonomic symptoms such as hypotension. Together with the decrease of dopamine, significant decreases in aminopeptidase activities have been reported in PD brains. However, up to date there are no studies about changes of aminopeptidase activities in plasma of PD patients. We studied plasma activities of alanyl-, aspartyl-(AspAP), cystinyl-(CysAP) and glutamyl-aminopeptidase (GluAP) in two groups of subjects: control (n=41) and PD (n=48). Plasma activities of AspAP, CysAP, and GluAP showed significant decreases of 24.9% (p<0.05), 39.4% (p<0.01) and 33.3% (p<0.01), respectively, in PD group. These aminopeptidases are involved in the metabolism of circulating peptides such as the ones of the renin-angiotensin system. The importance of aminopeptidases in striatal dopamine content and in neuroendocrine system in PD is discussed.

Influence of thyroid disorders on kidney angiotensinase activity.

Thyroid disorders affect renal function, which involves changes in local renin angiotensin system (RAS). Angiotensin peptide levels in the tissue are regulated by the activity of several aminopeptidases (AP) known as angiotensinases. The nature and consequences of the thyroid-induced RAS changes are not completely understood. We investigated the relationship between thyroid status (hyper- and hypothyroidism) and several kidney AP actions involved in RAS control. We have determined fluorometrically soluble (SOL) and membrane-bound (M-B) alanylaminopeptidase (AlaAP), glutamylaminopeptidase (GluAP) and aspartylaminopeptidase (AspAP) activity using naphthylamide derivatives as substrates. Sprague-Dawley rats were divided into three groups--control, hyperthyroid, and hypothyroid. Hyperthyroidism was induced by daily subcutaneous injection of L-thyroxin (300 microg/kg/day). Hypothyroidism was induced by continuous administration of methimazole (0.03%) in drinking water. Hypothyroid animals demonstrated a significant increase in SOL and M-B GluAP activity in renal cortex and a decrease in M-B AlaAP compared to euthyroid rats. This result may suggest higher Ang III availability. In hyperthyroid animals, M-B AlaAP and M-B AspAP activity increased significantly, which may suggest increased Ang III to Ang IV metabolism and greater formation of Ang 2-10, respectively. In contrast, no differences were observed between euthyroid and hypothyroid animals for SOL and M-B AP activity in renal medulla. However, hyperthyroid animals demonstrated a significant decrease in SOL and M-B GluAP activity compared to euthyroid rats, which may suggest a greater availability of Ang II in renal medulla. Alterations in angiotensin metabolism may, in part, account for some changes in renal function during thyroid disorders.

Angiotensinase activity is asymmetrically distributed in the amygdala, hippocampus and prefrontal cortex of the rat.

There are important asymmetries in brain functions such as emotional processing and stress response in humans and animals. Knowledge of the bilateral distribution of brain neurotransmitters is important to appropriately understand its functions. Some peptides such as those included in the renin-angiotensin system (RAS) and cholecystokinin (CCK) are related to modulation of behavior and stress. However, although angiotensin AT1 and CCK type 2 receptors were found in adult rat brain, there are no studies of their bilateral distribution in stress-related areas. The function of angiotensin peptides is depending on the action of several aminopeptidases (AP) called angiotensinases, some of them being also involved in the metabolism of CCK. We have studied the bilateral distribution of soluble (SOL) and membrane-bound (MEM) alanyl- (AlaAP), cystinyl- (CysAP), glutamyl- (GluAP) and aspartyl- (AspAP) AP activities in stress-related areas such as amygdala, hippocampus and medial prefrontal cortex of adult male rats in resting conditions. These enzymes are involved in the metabolism of angiotensins (AlaAP, CysAP, GluAP, AspAP) and CCK (GluAP, AspAP). In the amygdala, all the activities studied showed a right predominance with a significant difference ranging from 30% for SOL CysAP to 125% for SOL GluAP. In the hippocampus, there was a left predominance for SOL AlaAP, SOL and MEM CysAP and MEM AspAP activities (100, 80, 300 and 100% higher, respectively). In contrast, GluAP predominated remarkably in the right hippocampus (eight-fold for SOL and three-fold for MEM). In the prefrontal cortex, SOL and MEM CysAP and SOL AspAP predominated in the left hemisphere (40, 100 and 40% higher, respectively). These results demonstrated a heterogeneous bilateral pattern of angiotensinase activities in motivation and stress-related areas. This may reflect an uneven asymmetrical distribution of their endogenous substrates depending on the brain location and consequently, it would be also a reflect of the asymmetries in the functions they are involved in.