John W. Wright

Regulatory role of brain angiotensins in the control of physiological and behavioral responses

Considerable evidence now indicates that a separate and distinct renin-angiotensin system (RAS) is present within the brain. The necessary precursors and enzymes required for the formation and degradation of the biologically active forms of angiotensins have been identified in brain tissues as have angiotensin binding sites. Although this brain RAS appears to be regulated independently from the peripheral RAS, circulating angiotensins do exert a portion of their actions via stimulation of brain angiotensin receptors located in circumventricular organs. These circumventricular organs are located in the proximity of brain ventricles, are richly vascularized and possess a reduced blood-brain barrier thus permitting accessibility by peptides. In this way the brain RAS interacts with other neurotransmitter and neuromodulator systems and contributes to the regulation of blood pressure, body fluid homeostasis, cyclicity of reproductive hormones and sexual behavior, and perhaps plays a role in other functions such as memory acquisition and recall, sensory acuity including pain perception and exploratory behavior. An overactive brain RAS has been identified as one of the factors contributing to the pathogenesis and maintenance of hypertension in the spontaneously hypertensive rat (SHR) model of human essential hypertension. Oral treatment with angiotensin-converting enzyme inhibitors, which interfere with the formation of angiotensin II, prevents the development of hypertension in young SHR by acting, at least in part, upon the brain RAS. Delivery of converting enzyme inhibitors or specific angiotensin receptor antagonists into the brain significantly reduces blood pressure in adult SHR. Thus, if the SHR is an appropriate model of human essential hypertension (there is controversy concerning its usefulness), the potential contribution of the brain RAS to this dysfunction must be considered during the development of future antihypertensive compounds.

Discovery of a distinct binding site for angiotensin II (3–8), a putative angiotensin IV receptor

We report here the discovery of a unique and novel angiotensin binding site and peptide system based upon the C-terminal 3-8 hexapeptide fragment of angiotensin II (NH3(+)-Val-Tyr-Ile-His-Pro-Phe-COO-) (AII(3-8) (AIV)). This fragment binds saturably, reversibly, specifically, and with high affinity to membrane-binding sites in a variety of tissues and from many species. The binding site is pharmacologically distinct from the classic angiotensin receptors (AT1 or AT2) displaying low affinity for the known agonists (AII and AIII) and antagonist (Sar1,Ile8-AII). Although a definitive function has not been assigned to this system in many of the tissues in which it resides, AIVs interaction with endothelial cells may involve a role in endothelial cell-dependent vasodilation. Consequent to this action, AIV is a potent stimulator of renal cortical blood flow.

Brain angiotensin receptor subtypes in the control of physiological and behavioral responses.

This review summarizes emerging evidence that supports the notion of a separate brain renin-angiotensin system (RAS) complete with the necessary precursors and enzymes for the formation and degradation of biologically active forms of angiotensins, and several binding subtypes that may mediate their diverse functions. Of these subtypes the most is known about the AT1 site which preferentially binds angiotensin II (AII) and angiotensin III (AIII). The AT1 site appears to mediate the classic angiotensin responses concerned with body water balance and the maintenance of blood pressure. Less is known about the AT2 site which also binds AII and AIII and may play a role in vascular growth. Recently, an AT3 site was discovered in cultured neoblastoma cells, and an AT4 site which preferentially binds AII(3-8), a fragment of AII now referred to as angiotensin IV (AIV). The AT4 site has been implicated in memory acquisition and retrieval, and the regulation of blood flow. In addition to the more well-studied functions of the brain RAS, we review additional less well investigated responses including regulation of cellular function, the modulation of sensory and motor systems, long term potentiation, and stress related mechanisms. Although the receptor subtypes responsible for mediating these physiologies and behaviors have not been definitively identified research efforts are ongoing. We also suggest potential contributions by the RAS to clinically relevant syndromes such as dysfunctions in the regulation of blood flow and ischemia, changes in cognitive affect and memory in clinical depressed and Alzheimers patients, and angiotensins contribution to alcohol consumption.

Important roles for angiotensin III and IV in the brain renin-angiotensin system

Considerable evidence now suggests that the precursors and enzymes necessary for the formation and degradation of biologically active forms of angiotensins are present in brain tissues, accompanied by at least three specific binding sites. It also appears that several forms of angiotensin may serve as signaling agents at these sites. There is accumulating support for the notion that AngII must be converted to AngIII in order to bind at the AT1 and AT2 receptor subtypes, and AngIII must be converted to AngIV in order to activate the AT4 receptor subtype. Further, AngII(1–7) may activate a separate binding site concerned with antidiuresis, however, characterization of this site has not been completed. The AT1 site appears to mediate the classic angiotensin functions concerned with body water balance, maintenance of blood pressure, and cyclicity of reproductive hormones and sexual behaviors. This receptor site also exerts some control over the secretion of pituitary hormones. Less is known about the functional importance of the AT2 site, however, it has been implicated in vascular growth, control of blood flow, and perhaps modulation of NMDA receptors. The AT4 site is heavily distributed in neocortex, hippocampus, cerebellum, and basal ganglia structures, as well as several peripheral tissues. This site appears to mediate memory acquisition and retrieval, the regulation of blood flow, neurite outgrowth, angiogenesis, and kidney function. In addition to the well-studied functions of the brain renin-angiotensin system, additional less well investigated responses are reviewed. These include electrophysiological activation, tachyphylaxis, long term potentiation, learning and memory, and cognitive affect.

Effects of extracellular matrix-degrading proteases matrix metalloproteinases 3 and 9 on spatial learning and synaptic plasticity

Rats learning the Morris water maze exhibit hippocampal changes in synaptic morphology and physiology that manifest as altered synaptic efficacy. Learning requires structural changes in the synapse, and multiple cell adhesion molecules appear to participate. The activity of these cell adhesion molecules is, in large part, dependent on their interaction with the extracellular matrix (ECM). Given that matrix metalloproteinases (MMPs) are responsible for transient alterations in the ECM, we predicted that MMP function is critical for hippocampal‐dependent learning. In support of this, it was observed that hippocampal MMP‐3 and ‐9 increased transiently during water maze acquisition as assessed by western blotting and mRNA analysis. The ability of the NMDA receptor channel blocker MK801 to attenuate these changes indicated that the transient MMP changes were in large part dependent upon NMDA receptor activation. Furthermore, inhibition of MMP activity with MMP‐3 and ‐9 antisense oligonucleotides and/or MMP inhibitor FN‐439 altered long‐term potentiation and prevented acquisition in the Morris water maze. The learning‐dependent MMP alterations were shown to modify the stability of the actin‐binding protein cortactin, which plays an essential role in regulating the dendritic cytoskeleton and synaptic efficiency. Together these results indicate that changes in MMP function are critical to synaptic plasticity and hippocampal‐dependent learning.

THE ANGIOTENSIN IV SYSTEM: FUNCTIONAL IMPLICATIONS

The brain renin-angiotensin system has been implicated in the central regulation of the cardiovascular system, body water balance, and cyclic regulation of reproductive hormones and behaviors. It also exerts some influence over the secretion of pituitary hormones. This system appears to be complete with the necessary precursors and enzymes for the formation and degradation of biologically active forms of angiotensins and several binding subtypes that are presumed to mediate these and other functions. Much information is now available on the AT1 site which preferentially binds angiotensin II (AngII), but also binds angiotensin III (AngIII), and appears to be responsible for mediating the above described classic angiotensin physiologies and behaviors. Less is known about the functional importance of the AT2 site which also binds AngII but preferentially binds AngIII. This site has been implicated in vascular growth and cerebral blood flow. Recently, an AT4 site has been discovered and characterized that preferentially binds AngII (3-8), a fragment of AngII referred to as angiotensin IV (AngIV). This AT4 site is prominent in cerebral cortex, hippocampus, basal ganglia, cerebellum, and spinal cord, as well as several peripheral tissues including kidney, bladder, heart, spleen, prostate, adrenals, and colon. The AT4 site may mediate memory acquisition and recall and the regulation of blood flow. The function(s) of the AT4 receptor subtype in peripheral tissues is currently unknown, although it does appear to be involved in kidney blood flow.

Effects of discrete kainic acid-induced hippocampal lesions on spatial and contextual learning and memory in rats

Substantial information is available concerning the influence of global hippocampal lesions on spatial learning and memory, however the contributions of discrete subregions within the hippocampus to these functions is less well understood. The present investigation utilized kainic acid to bilaterally lesion specific areas of the rat hippocampus. These animals were subsequently tested on a spatial orientation task using a circular water maze, and on an associative/contextual task using passive avoidance conditioning. The results indicate that both the dorsal CA1 and the ventral CA3 subregions play important roles in learning. Specifically, CA1 lesions produced a deficit in the acquisition of the water maze task and a significant memory impairment on the passive avoidance task. CA3 lesions also caused learning deficits in the acquisition of the water maze task, and produced even greater impairments in performance on the passive avoidance task. We conclude that CA1 and CA3 hippocampal subregions each play significant roles in the overall integration of information concerning spatial and associative learning.

Angiotensin II(3–8) (ANG IV) hippocampal binding: Potential role in the facilitation of memory

The present research characterizes a newly discovered ANG II(3-8) (ANG IV) binding site localized in structures associated with memory function (hippocampus, neocortex, cerebellum), as well as other brain stem structures (thalamus, inferior olivary nucleus). This site is not the AT1 or AT2 site that binds angiotensins II (ANG II) and III (ANG III) nor does it bind the nonpeptide AT1 or AT2 receptor antagonists DuP753 and PD123177, respectively. The intracerebroventricular (ICV) infusion of ANG IV was ineffective at inducing drinking in rats as compared with equivalent doses of ANG II and III. Although not as effective as ANG II or ANG III, ICV infusion of ANG IV did provoke a pressor response at the highest dose (100 pmol/min), which appeared to be mediated by ANG II (AT1)-type receptors and not the specific AIV binding site described here. By contrast, the ICV infusion of ANG IV resulted in greater effects upon retention and retrieval of a passive avoidance task as compared with ANG II. Specifically, ANG II was not different from the ICV infusion of artificial cerebrospinal fluid, while ANG IV improved retention and retrieval of this task.

Brain renin-angiotensin--a new look at an old system.

The classic renin-angiotensin system (RAS) is described as a circulating hormone system focused on cardiovascular and body water regulation, with angiotensin II as its major effector. Detlef Gantens discovery some years ago of an independent local brain RAS composed of the necessary functional components (angiotensinogen, peptidases, angiotensins and specific receptor proteins) significantly expanded the possible physiological and pharmacological functions of this system. This review first describes the enzymatic pathways resulting in active angiotensin ligands and their interaction with AT(1), AT(2) and AT(4) receptor proteins. We discuss the characterization and distribution of the AT(1) and AT(2) receptor subtypes and the current controversy over the identity of the AT(4) receptor subtype. Research findings favoring the candidates insulin-regulated aminopeptidase (IRAP) and the type 1 tyrosine kinase receptor c-Met, are presented. Next, we summarize current research efforts directed at the use of angiotensin analogues in the treatment of clinical disorders such as memory dysfunction, cerebral blood flow and cerebroprotection, stress, depression, alcohol consumption, seizure, Alzheimers and Parkinsons diseases, and diabetes. The use of ACE inhibitors, and AT(1) and/or AT(2) receptor blockers, has shown promise in the treatment of several of these pathologies. The development of blood-brain barrier penetrant AT(4) receptor agonists and antagonists is of major importance regarding the continuing evaluation of the efficacy of new treatment approaches.

Identification of an AII(3-8) [AIV] binding site in guinea pig hippocampus.

A unique angiotensin binding site specific for the hexapeptide, AII(3-8), has been identified in guinea pig hippocampus. This binding site, which is present in the pyramidal cell layer of CA1, CA2, CA3 of the hippocampus and dentate gyrus, binds AII(3-8) with high affinity (KD = 1.29 +/- 0.18 nM) in a saturable manner (Bmax = 449 +/- 62 fmol/mg protein). The N-terminal structure of the binding ligand is paramount in determining the binding affinity. The C-terminal requirements seem less stringent as evidenced by the binding affinity of AII(3-7) (KD = 20.9 +/- 2.1 nM). Neither AII, AIII,Sar1, Ile8-AII, Dup 753 nor CGP42112A appear to bind, indicating that this binding site is neither the AT1 nor AT2 sites described for AII/AIII. Autoradiographic analysis of hippocampus binding confirms the inability of Sar1,Ile8-AII to compete for [125I]AII(3-8) binding. Conversely AII(3-8) was unable to displace [125I]Sar1,Ile8-AII binding.