Receptor mechanisms in fish chromatophores-II. Evidence for beta adrenoceptors mediating melanosome dispersion in guppy melanophores

Behavior and histopathology as biomarkers for evaluation of the effects of paracetamol and propranolol in the neotropical fish species Phalloceros harpagos

Pharmaceutical drugs in the aquatic environment can induce adverse effects on nontarget organisms. This study aimed to assess the short-term effects of sublethal concentrations of both paracetamol and propranolol on the fish Phalloceros harpagos, specifically light/dark preference, swimming patterns, skin pigmentation, histopathology, and liver glycogen levels. Fish were acutely exposed to sublethal concentrations of both paracetamol (0.008, 0.08, 0.8, 8, 80 mg L^-1) and propranolol (0.0001, 0.001, 0.01, 0.1, 1 mg L^-1) under controlled conditions. For scototaxis, a significant preference for the dark compartment was observed for the group exposed to the highest concentration of paracetamol (80 mg L^-1). Propranolol exposure significantly altered the swimming pattern, especially in fish exposed to the 0.001 mg L^-1 concentration. Pigmentation was reduced in propranolol-exposed fish (0.1, 1 mg L^-1). The lowest concentration of propranolol (0.0001 mg L^-1) induced a decrease of histochemical reaction for hepatic glycogen. These data demonstrate that pharmaceuticals can induce sublethal effects in nontarget organisms, even at low concentrations, compromising specific functions of the individual with ecological relevance, such as energy balance and behavior.

Beta2-adrenoceptors mediate melanosome dispersion in winter flounder (Pleuronectes americanus))

Although the melanosome-aggregating mediation of catecholamines through alpha -adrenoceptors is well established for teleost melanophores, the regulation of the dispersive process is not as clearly understood. The melanosome-aggregating effect of high concentrations of catecholamines in vitro is reversed at low concentrations with melanophores of the winter flounder, Pleuronectes americanus. In vitro incubation in low concentrations of isoproterenol ( <<= 10-7 M) and noradrenaline ( <<= 10-8 M) enhances Na + -induced melanosome dispersion in balanced salt solution, which can be depressed by propranolol (10-4 M), indicating beta -adrenoceptor mediation in pigment dispersion. The subtype of this adrenoceptor appears to be the beta 2 conformation, since the beta 2-adrenoceptor agonist terbutaline (>=>3.15 times 10-6 M) reverses the melanosome-aggregating effect associated with higher concentrations of noradrenaline and with electrical stimulation. It is concluded that in this species there is adrenergic neuronal control of melanosome aggregation through alpha -adrenoceptors on release of noradrenaline and of dispersion through beta 2-adrenoceptors during a subsequent decrease in concentration.

Physiological responses of melanophores and xanthophores of hypophysectomized and spinal winter flounder, Pseudopleuronectes americanus Walbaum

The relative roles of neural and pituitary elements in controlling the chromatic behaviour of winter flounder, Pseudopleuronectes americanus , are analysed with reference to background-related physiological responses of both epidermal and dermal melanophores and of xanthophores. The effects of spinal section and of hypophysectomy on chromatic responses demonstrate that melanosome aggregation in epidermal and dermal melanophores is under neural control, and that the pituitary has no involvement in melanosome dispersion. However, injection of pituitary extract into hypophysectomized flounder elicited a melanophore concentrating hormone effect, epidermal melanophores being particularly responsive, but its physiological significance has not been established. The differential responses of melanophores, which are associated with patterning in this species, are a function of neural control. In xanthophores the pituitary influence is strong in pigment dispersion, although there is neural mediation in pigment aggregation. These contrasting roles of neural and pituitary elements in controlling melanophore and xanthophore responses provide a basis for both patterning and hue adaptations in this species.

Intracellular cyclic AMP not calcium, determines the direction of vesicle movement in melanophores: direct measurement by fluorescence ratio imaging

Intracellular movement of vesiculated pigment granules in angelfish melanophores is regulated by a signalling pathway that triggers kinesin and dyneinlike microtubule motor proteins. We have tested the relative importance of intracellular Ca2+ ([Ca2+]i) vs cAMP ([cAMP]i) in the control of such motility by adrenergic agonists, using fluorescence ratio imaging and many ways to artificially stimulate or suppress signals in these pathways. Fura-2 imaging reported a [Ca2+]i elevation accompanying pigment aggregation, but this increase was not essential since movement was not induced with the calcium ionophore, ionomycin, nor was movement blocked when the increases were suppressed by withdrawal of extracellular Ca2+ or loading of intracellular BAPTA. The phosphatase inhibitor, okadaic acid, blocked aggregation and induced dispersion at concentrations that suggested that the protein phosphatase PP-1 or PP-2A was continuously turning phosphate over during intracellular motility. cAMP was monitored dynamically in single living cells by microinjecting cAMP-dependent kinase in which the catalytic and regulatory subunits were labeled with fluorescein and rhodamine respectively (Adams et al., 1991. Nature (Lond.). 349:694- 697). Ratio imaging of F1CRhR showed that the alpha 2-adrenergic receptor-mediated aggregation was accompanied by a dose-dependent decrease in [cAMP]i. The decrease in [cAMP]i was both necessary and sufficient for aggregation, since cAMP analogs or microinjected free catalytic subunit of A kinase-blocked aggregation or caused dispersal, whereas the cAMP antagonist RpcAMPs or the microinjection of the specific kinase inhibitor PKI5-24 amide induced aggregation. Our conclusion that cAMP, not calcium, controls bidirectional microtubule dependent motility in melanophores might be relevant to other instances of non-muscle cell motility.

Reactivated melanophore motility: differential regulation and nucleotide requirements of bidirectional pigment granule transport

To study the molecular basis for organized pigment granule transport, procedures were developed to lyse melanophores of Tilapia mossambica under conditions in which pigment granule movements could be reactivated. Gentle lysis of the melanophores resulted in a permeabilized cell model, which, in the absence of exogenous ATP, could undergo multiple rounds of pigment granule aggregation and dispersion when sequentially challenged with epinephrine and cAMP. Both directions of transport required ATP, since aggregation or dispersion in melanophores depleted of nucleotides could be reactivated only upon addition of MgATP or MgATP plus cAMP, respectively. Differences between the nucleotide sensitivities for aggregation and dispersion were demonstrated by observations that aggregation had a lower apparent Km for ATP than did dispersion and could be initiated at a lower ATP concentration. Moreover, aggregation could be initiated by ADP, but only dispersion could be reactivated by the thiophosphate ATP analog, ATP gamma S. The direction of pigment transport was determined solely by cAMP, since pigment granules undergoing dispersion reaggregated when cAMP was removed, and those undergoing aggregation dispersed when cAMP was added. These results provide evidence that pigment granule motility may be based on two distinct mechanisms that are differentially activated and regulated to produce bidirectional movements.