Stewart John, Hughes Julian M
Cronulla Fisheries Research Centre of Excellence, Cronulla, Australia,
Fish Physiol Biochem. 2014 Apr;40(2):335-46. doi: 10.1007/s10695-013-9846-y. Epub 2013 Aug 25.
Physoclist fish are able to regulate their buoyancy by secreting gas into their hydrostatic organ, the swim bladder, as they descend through the water column and by resorbing gas from their swim bladder as they ascend. Physoclists are restricted in their vertical movements due to increases in swim bladder gas volume that occur as a result of a reduction in hydrostatic pressure, causing fish to become positively buoyant and risking swim bladder rupture. Buoyancy control, rates of swim bladder gas exchange and restrictions to vertical movements are little understood in marine teleosts. We used custom-built hyperbaric chambers and laboratory experiments to examine these aspects of physiology for two important fishing target species in southern Australia, pink snapper (Pagrus auratus) and mulloway (Argyrosomus japonicus). The swim bladders of pink snapper and mulloway averaged 4.2 and 4.9 % of their total body volumes, respectively. The density of pink snapper was not significantly different to the density of seawater (1.026 g/ml), whereas mulloway were significantly denser than seawater. Pink snapper secreted gas into their swim bladders at a rate of 0.027 ± 0.005 ml/kg/min (mean ± SE), almost 4 times faster than mulloway (0.007 ± 0.001 ml/kg/min). Rates of swim bladder gas resorption were 11 and 6 times faster than the rates of gas secretion for pink snapper and mulloway, respectively. Pink snapper resorbed swim bladder gas at a rate of 0.309 ± 0.069 ml/kg/min, 7 times faster than mulloway (0.044 ± 0.009 ml/kg/min). Rates of gas exchange were not affected by water pressure or water temperature over the ranges examined in either species. Pink snapper were able to acclimate to changes in hydrostatic pressure reasonably quickly when compared to other marine teleosts, taking approximately 27 h to refill their swim bladders from empty. Mulloway were able to acclimate at a much slower rate, taking approximately 99 h to refill their swim bladders. We estimated that the swim bladders of pink snapper and mulloway ruptured after decreases in ~2.5 and 2.75 times the hydrostatic pressure to which the fish were acclimated, respectively. Differences in buoyancy, gas exchange rates, limitations to vertical movements and acclimation times between the two species are discussed in terms of their differing behaviour and ecology.
闭鳔鱼类能够通过在水柱中下降时向其静水器官(鳔)中分泌气体,以及在上升时从鳔中重新吸收气体来调节自身浮力。由于静水压力降低导致鳔内气体体积增加,闭鳔鱼类的垂直运动受到限制,这会使鱼变得正浮力,并有鳔破裂的风险。在海洋硬骨鱼类中,浮力控制、鳔气体交换速率以及垂直运动的限制还鲜为人知。我们使用定制的高压舱和实验室实验,研究了澳大利亚南部两种重要的捕捞目标物种——紫红笛鲷(Pagrus auratus)和斑尾鲈(Argyrosomus japonicus)的这些生理方面。紫红笛鲷和斑尾鲈的鳔平均分别占其总体积的4.2%和4.9%。紫红笛鲷的密度与海水密度(1.026克/毫升)无显著差异,而斑尾鲈比海水密度大得多。紫红笛鲷向其鳔中分泌气体的速率为0.027±0.005毫升/千克/分钟(平均值±标准误),几乎是斑尾鲈(0.007±0.001毫升/千克/分钟)的4倍。紫红笛鲷和斑尾鲈鳔气体重新吸收的速率分别比气体分泌速率快11倍和6倍。紫红笛鲷以0.309±0.069毫升/千克/分钟的速率重新吸收鳔内气体,比斑尾鲈(0.044±0.009毫升/千克/分钟)快7倍。在所研究的两种鱼的范围内,气体交换速率不受水压或水温的影响。与其他海洋硬骨鱼类相比,紫红笛鲷能够相当快地适应静水压力的变化,从排空状态重新充满鳔大约需要27小时。斑尾鲈适应速度要慢得多,重新充满鳔大约需要99小时。我们估计,紫红笛鲷和斑尾鲈的鳔在其适应的静水压力分别下降约2.5倍和2.75倍后会破裂。根据这两种鱼不同的行为和生态习性,讨论了它们在浮力、气体交换速率、垂直运动限制和适应时间方面的差异。
