Paraneuronal pseudobranchial neurosecretory system in tank goby Glossogobius giuris with special reference to novel neurohaemal contact complex.

Various putative oxygen chemosensory cells are reported to be present throughout the vertebrate body performing pivotal roles in respiration by initiating responses during acute hypoxia. Since air-breathing fishes often are exposed to the oxygen-deficient milieu, in such conditions various chemosensory cells operate in an orchestrated fashion. The Pseudobranchial neurosecretory system (PSNS) a newly discovered system, is one of these. It has been placed in the category of "Diffuse NE systems (DNES)". It is found in all the catfish species and in some other non-catfish group of teleosts. In catfishes, it is present in close association with the carotid labyrinth- a chemosensory structure, known in fish and amphibians. The presence of this system in Glossogobius giuris, in association with the pseudobranch, a structure considered to be precursor of carotid labyrinth, is a significant finding. In an attempt to study the structure and organization of the pseudobranchial neurosecretory system in a non-catfish species of teleost, the present investigation was undertaken on a goby G. giuris. The histological observations, using a neurosecretion-specific stain, revealed the presence of this system in G. giuris. The findings are discussed in the light of the association of PSNS with pseudobranch and the type of "neurohaemal contact complex" formed between this neurosecretory system and the elements of the circulatory system.

The paraneuronal gill neuroendocrine system in ocellated puffer fish Leiodon cutcutia.

Pseudobranchial neurosecretory system (PSNS) is the third Neuroendocrine (NE) system found in the gill region of fishes in close association with pseudobranch/carotid labyrinth/carotid gland and can suitably be placed under the category of "Diffused NE system (DNES)." The cells belonging to this system fall under the category of "Paraneurons," a concept proposed by Fujita and coworkers. It is found uniformly in all the catfish species and some other noncatfish group of teleosts as Atheriniformes, Channiformes, Perciformes, and Clupeiformes. The fishes, in which the PSNS is present, belong to different breathing habits. Most of these have the capacity to tolerate low O2 conditions. Leiodon cutcutia although not an air-breathing fish, is known to retain air in its stomach for varied periods when threatened. In an attempt to verify the veracity of this system in a fish of another peculiar breathing habit, ocellated puffer fish L. cutcutia (order Tetradontiformes) was investigated. The histological observations undertaken on L. cutcutia revealed the presence of a well-developed extrabranchial NE system. The findings are discussed in the light of the association of PSNS with chemosensory system and its evolution in fishes, especially in the view of the transition from aquatic to terrestrial life.

Morphology and innervation of the teleost physostome swim bladders and their functional evolution in non-teleostean lineages.

Swim bladders and lungs are homologous structures. Phylogenetically ancient actinopterygian fish such as Cladistians (Polypteriformes), Ginglymods (Lepisosteids) and lungfish have primitive lungs that have evolved in the Paleozoic freshwater earliest gnathostomes as an adaptation to hypoxic stress. Here we investigated the structure and the role of autonomic nerves in the physostome swim bladder of the cyprinid goldfish (Carassius auratus) and the respiratory bladder of lepisosteids: the longnose gar and the spotted gar (Lepisosteus osseus and L. oculatus) to demonstrate that these organs have different innervation patterns that are responsible for controlling different functional aspects. The goldfish swim bladder is a richly innervated organ mainly controlled by cholinergic and adrenergic innervation also involving the presence of non-adrenergic non-cholinergic (NANC) neurotransmitters (nNOS, VIP, 5-HT and SP), suggesting a simple model for the regulation of the swim bladder system. The pattern of the autonomic innervation of the trabecular muscle of the Lepisosteus respiratory bladder is basically similar to that of the tetrapod lung with overlapping of both muscle architecture and control nerve patterns. These autonomic control elements do not exist in the bladders of the two species studied since they have very different physiological roles. The ontogenetic origin of the pulmonoid swim bladder (PSB) of garfishes may help understand how the expression of these autonomic control substances in the trabecular muscle is regulated including their interaction with the corpuscular cells in the respiratory epithelium of this bimodal air-breathing fish.