Inherited amyloids of the nervous system.

A diverse group of biochemically distinct proteins give rise to amyloids, each of which is associated with a different disease. These amyloid proteins share numerous properties and typically arise from the abnormal processing of an amyloid precursor protein. The classification, mechanisms and biochemistry of amyloid fibril formation are reviewed here, and two inherited types of amyloid affecting the nervous system are described.     

The renin-angiotensin system and the central nervous system.

One of several factors affecting the secretion of renin by the kidneys is the sympathetic nervous system. The sympathetic input is excitatory and is mediated by beta-adrenergic receptors, which are probably located on the membranes of the juxtaglomerular cells. Stimulation of sympathetic areas in the medulla, midbrain and hypothalamus raises blood pressure and increases renin secretion, whereas stimulation of other parts of the hypothalamus decreases blood pressure and renin output. The centrally active alpha-adrenergic agonist clonidine decreases renin secretion, lowers blood pressure, inhibits ACTH and vasopressin secretion, and increases growth hormone secretion in dogs. The effects on ACTH and growth hormone are abolished by administration of phenoxybenzamine into the third ventricle, whereas the effect on blood pressure is abolished by administration of phenoxybenzamine in the fourth ventricle without any effect on the ACTH and growth hormone responses. Fourth ventricular phenoxybenzamine decreases but does not abolish the inhibitory effect of clonidine on renin secretion. Circulating angiotensin II acts on the brain via the area postrema to raise blood pressure and via the subfornical organ to increase water intake. Its effect on vasopressin secretion is debated. The brain contains a renin-like enzyme, converting enzyme, renin substrate, and angiotensin. There is debate about the nature and physiological significance of the angiotensin II-generating enzyme in the brain, and about the nature of the angiotensin I and angiotensin II that have been reported to be present in the central nervous system. However, injection of angiotensin II into the cerebral ventricles produces drinking, increased secretion of vasopressin and ACTH, and increased blood pressure. The same responses are produced by intraventricular renin. Angiotensin II also facilitates sympathetic discharge in the periphery, and the possibility that it exerts a similar action on the adrenergic neurons in the brain merits investigation.     

Ganglia formation of the peripheral nervous system.

Embryologic studies have shown that the ganglions of the peripheral nervous system are formed by the neuroblasts from the central nervous system. The histotopography of the neurons and their segmental communications with the central nervous system are established experimentally (segmental section of the ventral roots and resection of the spinal nodes: 100 experiments). It is proved that the neurons, which communicate with the definite segment of the spinal cord, are diffusely distributed in the ganglion mass.     

Development of the mammalian enteric nervous system.

The mammalian enteric nervous system is derived from neural crest cells which invade the foregut and hindgut mesenchyme. It has been established that signalling molecules produced by the mesenchyme of the gut wall play a critical role in the development of the mammalian enteric nervous system. Recent studies have characterised further the role of such molecules and have identified novel extracellular and intracellular signals that are critical for enteric ganglia formation.     

Prostaglandins--modulation of adrenergic nervous system.

Prostaglandins (PGs) affect vascular tone by a direct action on the vascular smooth muscle and by influencing vascular reactivity to adrenergic simuli and several vasoactive substances. Thus, in the isolated Tyrode's perfused rabbit renal, mesenteric and splenic vasculature PGE2 inhibited adrenergically induced vasoconstriction. Since the vasoconstrictor responses to renal nerve stimulation were enhanced by the blockade of PG synthesis and were reduced by stimulation of PG synthesis with arachidonic acid, this suggests that PGE2 functions as an inhibitory modulator of the adrenergic nervous system. However, our demonstration that PGE2 enhanced adrenergically induced vasoconstriction in the renal and mesenteric vasculature of the rat, but had opposite effects in the rat splenic vasculature indicates that the modulatory-effect of PGE-compounds on the adrenergic neuromuscular junction is species dependent and varies in different vascular beds within the same species. Prostaglandins, the release of which is evoked by several vasoactive substances including angiotensins, kinins, and adenine nucleotides, may also contribute to the regulation of vascular tone by either opposing or amplifying the vascular actions of vasoactive substances.     

Oxygen-sensing neurons in the central nervous system.

This mini-review summarizes the present knowledge regarding central oxygen-chemosensitive sites with special emphasis on their function in regulating changes in cardiovascular and respiratory responses. These oxygen-chemosensitive sites are distributed throughout the brain stem from the thalamus to the medulla and may form an oxygen-chemosensitive network. The ultimate effect on respiratory or sympathetic activity presumably depends on the specific neural projections from each of these brain stem oxygen-sensitive regions as well as on the developmental age of the animal. Little is known regarding the cellular mechanisms involved in the chemotransduction process of the central oxygen sensors. The limited information available suggests some conservation of mechanisms used by other oxygen-sensing systems, e.g., carotid body glomus cells and pulmonary vascular smooth muscle cells. However, major gaps exist in our understanding of the specific ion channels and oxygen sensors required for transducing central hypoxia by these central oxygen-sensitive neurons. Adaptation of these central oxygen-sensitive neurons during chronic or intermittent hypoxia likely contributes to responses in both physiological conditions (ascent to high altitude, hypoxic conditioning) and clinical conditions (heart failure, chronic obstructive pulmonary disease, obstructive sleep apnea syndrome, hypoventilation syndromes). This review underscores the lack of knowledge about central oxygen chemosensors and highlights real opportunities for future research.     

Calcium channelopathies in the central nervous system.

The recent discovery that familial hemiplegic migraine, episodic ataxia type 2, and spinocerebellar ataxia type 6 are allelic disorders caused by different mutations in CACNA1A, a calcium-channel-encoding gene, adds to a growing list of channelopathies causing paroxysmal neurologic disturbance and progressive neurodegeneration. Calcium channelopathies in the central nervous system provide a model to study the important roles that calcium channels play in neuronal function.