Medical Laboratory Techniques Department, Al-maarif University College, Al-anbar-Ramadi, Iraq.
Department of Fisheries, Faculty of Natural Resources, University of Tehran, Tehran, Iran.
Comp Biochem Physiol C Toxicol Pharmacol. 2022 Aug;258:109361. doi: 10.1016/j.cbpc.2022.109361. Epub 2022 May 5.
The gray mullet, Mugil cephalus is an inshore and bottom-feeding fish species of Oman sea. Therefore, the gray mullet may be more exposed to heavy metal contamination, as the toxic impacts of heavy metals mullet has been reported in various studies. This study was conducted to evaluate the toxic effects of the heavy metal, nickel (as NiCl) on osmoregulation of the gray mullet by measuring blood biochemicals, hormones, minerals and gill histology. Fish (10 fish/tank) were experimentally exposed to NiCl at three environmentally relevant concentrations of 5, 10 and 15 μg/l for 96 h. Then, fish were challenged with seawater (35 mg/l) for a period of 120 min. The samples (blood and gill tissue) were collected After 96 exposure to NiCl2 and during salinity challenge (30, 60 and 120 min post challenge). The plasma levels of cortisol and glucose significantly increased in NiClexposed fish. In addition, cortisol increased in all experimental groups 30 min after salinity challenge and then returned gradually to the same levels as the control at 120 min post salinity challenge (PSC). The triiodothyronine (T3) and thyroxine (T4) levels significantly decreased in response to 10 and 15 μg/l NiCl. In all groups, the thyroid hormones significantly elevated at 30 min PSC. After 30 min PSC, T3 levels in all NiClexposed fish and T4 in the treatment, 10 μg/l NiCl remained unchanged throughout the salinity challenge. In the treatment, 5 μg/l NiCl, T4 levels were recovered at 120 min PSC and reached the same levels as the control. Exposure of fish to high concentrations of NiCl and salinity stress increased the lactate levels. However, lactate levels in 5 and 10 μg/l NiCl groups were recovered at 120 min PSC and reached the same levels as the control. Furthermore, plasma protein increased in response to 10 and 15 μg/l NiCl. At 30 PSC, the protein levels decreased in control and 5 μg/l NiCl group, while it remained unchanged in fish exposed to 10 and 15 μg/l NiCl throughout the salinity challenge. Exposure of fish to NiCl disrupted the electrolyte (Na, Cl) balance both before and after salinity challenge, which may be due to gill lesions induced by the heavy metal and following alternations in gill permeability. However, fish in 5 μg/l NiCl re-established the ionic balance in the blood at the end of salinity challenge period. The malondialdehyde (MDA) levels significantly increased in response to 10 and 15 μg/l NiCl. The MDA levels returned to the same levels as the control group at 120 min PSC. The results of the present study showed that nickel-induced toxicity (especially at high concentrations) can reduce the osmoregulation capabilities of mullet. However, fish are able to recover from the toxic effects over time, if contamination be eliminated.
褐牙鲆是阿曼海域的近岸底层鱼类。因此,褐牙鲆可能更容易受到重金属污染,因为重金属对褐牙鲆的毒性影响在各种研究中都有报道。本研究通过测量血液生化指标、激素、矿物质和鳃组织学,评估重金属镍(以 NiCl 的形式)对褐牙鲆渗透调节的毒性作用。将鱼(每缸 10 条)在三种环境相关浓度(5、10 和 15μg/l)下暴露于 NiCl 中 96 小时。然后,将鱼暴露于海水中(35mg/l)120 分钟。在 96 小时暴露于 NiCl2 和盐度挑战期间(挑战后 30、60 和 120 分钟)采集样本(血液和鳃组织)。在 NiCl 暴露的鱼中,皮质醇和葡萄糖的血浆水平显著升高。此外,所有实验组在盐度挑战后 30 分钟时皮质醇增加,然后在盐度挑战后 120 分钟(PSC)时逐渐恢复到与对照组相同的水平。三碘甲状腺原氨酸(T3)和甲状腺素(T4)水平对 10 和 15μg/l NiCl 的反应显著降低。在所有组中,甲状腺激素在 PSC 后 30 分钟时显著升高。在 PSC 后 30 分钟,所有 NiCl 暴露的鱼和 10μg/l NiCl 的处理组中的 T4 水平在整个盐度挑战过程中保持不变。在 5μg/l NiCl 的处理组中,T4 水平在 PSC 后 120 分钟恢复,并达到与对照组相同的水平。暴露于高浓度 NiCl 和盐度应激会增加乳酸水平。然而,5 和 10μg/l NiCl 组的乳酸水平在 PSC 后 120 分钟恢复,并达到与对照组相同的水平。此外,血浆蛋白对 10 和 15μg/l NiCl 的反应增加。在 PSC 后 30 分钟,对照组和 5μg/l NiCl 组的蛋白水平下降,而暴露于 10 和 15μg/l NiCl 的鱼在整个盐度挑战过程中蛋白水平保持不变。NiCl 的暴露会破坏盐度挑战前后的电解质(Na、Cl)平衡,这可能是由于重金属引起的鳃损伤以及随后的鳃通透性改变。然而,在盐度挑战结束时,5μg/l NiCl 组的鱼重新建立了血液中的离子平衡。10 和 15μg/l NiCl 会导致丙二醛(MDA)水平显著升高。MDA 水平在 PSC 后 120 分钟恢复到与对照组相同的水平。本研究结果表明,镍诱导的毒性(尤其是在高浓度下)会降低褐牙鲆的渗透调节能力。然而,如果消除污染,鱼类可以随着时间的推移从毒性影响中恢复。
