Comparative analysis of Met-enkephalin, galanin and GABA immunoreactivity in the developing trout preoptic–hypophyseal system

Salinity and its variations are among the key factors that affect survival, metabolism and distribution during the fish development. The successful establishment of a fish species in a given habitat depends on the ability of each developmental stage to cope with salinity through osmoregulation. It is well established that adult teleosts maintain their blood osmolality close to 300 mosM kg(-1) due to ion and water regulation effected at several sites: tegument, gut, branchial chambers, urinary organs. But fewer data are available in developing fish. We propose a review on the ontogeny of osmoregulation based on studies conducted in different species. Most teleost prelarvae are able to osmoregulate at hatch, and their ability increases in later stages. Before the occurrence of gills, the prelarval tegument where a high density of ionocytes (displaying high contents of Na+/K+-ATPase) is located appears temporarily as the main osmoregulatory site. Gills develop gradually during the prelarval stage along with the numerous ionocytes they support. The tegument and gill Na+/K+-ATPase activity varies ontogenetically. During the larval phase, the osmoregulatory function shifts from the skin to the gills, which become the main osmoregulatory site. The drinking rate normalized to body weight tends to decrease throughout development. The kidney and urinary bladder develop progressively during ontogeny and the capacity to produce hypotonic urine at low salinity increases accordingly. The development of the osmoregulatory functions is hormonally controlled. These events are inter-related and are correlated with changes in salinity tolerance, which often increases markedly at the metamorphic transition from larva to juvenile. In summary, the ability of ontogenetical stages of fish to tolerate salinity through osmoregulation relies on integumental ionocytes, then digestive tract development and drinking rate, developing branchial chambers and urinary organs. The physiological changes leading to variations in salinity tolerance are one of the main basis of the ontogenetical migrations or movements between habitats of different salinity regimes.

Whereas adult neurogenesis appears to be a universal phenomenon in the vertebrate brain, enormous differences exist in neurogenic potential between "lower" and "higher" vertebrates. Studies in the gymnotiform fish Apteronotus leptorhynchus and in zebrafish have indicated that the relative number of new cells, as well as the number of neurogenic sites, are at least one, if not two, orders of magnitude larger in teleosts than in mammals. In teleosts, these neurogenic sites include brain regions homologous to the mammalian hippocampus and olfactory bulb, both of which have consistently exhibited neurogenesis in all species examined thus far. The source of the new cells in the teleostean brain are intrinsic stem cells that give rise to both glial cells and neurons. In several brain regions, the young cells migrate, guided by radial glial fibers, to specific target areas where they integrate into existing neural networks. Approximately half of the new cells survive for the rest of the fish's life, whereas the other half are eliminated through apoptotic cell death. A potential mechanism regulating development of the new cells is provided by somatic genomic alterations. The generation of new cells, together with elimination of damaged cells through apoptosis, also enables teleost fish rapid and efficient neuronal regeneration after brain injuries. Proteome analysis has identified a number of proteins potentially involved in the individual regenerative processes. Comparative analysis has suggested that differences between teleosts and mammals in the growth of muscles and sensory organs are key to explain the differences in adult neurogenesis that evolved during phylogenetic development of the two taxa.

Zones containing actively dividing cells (proliferation zones: PZs), in the brain of adult three-spined sticklebacks, were identified by autoradiographic detection of (3)H-thymidine and immunocytochemical detection of the thymidine analogue 5'-bromodeoxyuridine (BrdU), singly or in combination, and by immunocytochemical detection of proliferating cell nuclear antigen (PCNA) by monoclonal antibodies. The PZs are associated with boundaries between adult brain regions, as well as with defined morphofunctional subdivisions. PZs are located at the border between the telencephalon and diencephalon, and at the border between the mesencephalon and the rhombencephalon. In the midbrain, the PZ follows the dorsomedial, caudal, and ventrolateral aspects of each tectal hemisphere, extending over the caudal aspect of the torus semicircularis to the nucleus lateralis valvulae. In the hindbrain, the major PZ apparently represents the persisting embryonic secondary matrix layer of the developing cerebellum. In the forebrain, the PZs are associated with the ventricular zones of the olfactory bulbs and ventral telencephalic area ("subpallium"), dorsal telencephalic area ("pallium"), preoptic region, ventral thalamus, dorsal thalamus, epithalamus, pretectum, posterior tuberculum, and the hypothalamus. The diencephalic PZs are parcellated according to a neuromeric organisation (a synencephalic, a posterior, and an anterior parencephalic neuromere: p1, p2, and p3). The PZs of the secondary prosencephalon (telencephalon and hypothalamus) thus would belong to neuromeres p4-6, but do not form an immediately recognised serial pattern. The prosencephalic PZs correlate well with parts of embryonic migration areas as defined by Bergquist and Källén ([1954] J. Comp. Neurol. 100:627-659), morphogenetic fields from which postmitotic neurones migrate to their final destination.