秦岭细鳞鲑耗氧率和窒息点的初步研究

对两种不同体重规格的秦岭细鳞鲑(Brachymystax lenok tsinlingensis)的耗氧率、耗氧量及窒息点进行了测定,结果表明,秦岭细鳞鲑的耗氧率随温度的升高而增加,随体重的增加而减小;耗氧量和窒息点随温度的升高和体重的增加而增加。温度在10~18℃范围内,平均体重25.15 g的秦岭细鳞鲑的平均耗氧率为1.113 mg/g.h,平均耗氧量为9.244 mg/尾.h;平均体重45.93 g的秦岭细鳞鲑平均耗氧率为0.856mg/g.h,平均耗氧量为13.104 mg/尾.h。在10~20℃温度范围内,体重15.30 g的秦岭细鳞鲑,窒息点为(1.487±0.04)mg/L,平均体重48.36 g的秦岭细鳞鲑窒息点为(1.830±0.03)mg/L。在同一适温(14℃)条件下,秦岭细鳞鲑耗氧率呈明显的昼夜变化规律,夜间耗氧率明显大于白天。     

体重和时间节律对俄罗斯鲟(Acipenser gueldenstaedti Brandt)幼鱼耗氧率和窒息点的影响

采用流水法研究了在温度(20.7±0.55)℃下体重和时间节律对俄罗斯鲟(Acipenser gueldenstaedti Brandt)幼鱼耗氧率和窒息点的影响。结果表明,俄罗斯鲟的耗氧率、窒息点与体重负相关,耗氧量与体重正相关。俄罗斯鲟体重(1.39±0.24)g时平均耗氧率为(0.51±0.06)mg/h.g,平均耗氧量为(0.68±0.03)mg/h.ind;体重(3.16±0.22)g时,平均耗氧率为(0.35±0.04)mg/h.g,平均耗氧量为(0.97±0.10)mg/h.ind;体重(6.20±0.36)g时平均耗氧率为(0.28±0.04)mg/h.g,平均耗氧量为(1.46±0.33)mg/h.ind。3种规格俄罗斯鲟的窒息点分别为2.38、2.35和1.98 mg/L。     

pH值对厚颌鲂幼鱼的耗氧率及窒息点的影响

在密封式流水呼吸室内,对厚颌鲂Megalobrama pellegrini幼鱼在pH值分别为5.5、6.0、6.5、7.0、7.5、8.0和8.5试验用水条件下的耗氧率进行了测定.结果 显示:厚颌鲂幼鱼耗氧率存在明显的昼夜变化,白天高于晚上,下午高于上午,夜间变化不大.不同pH值的平均耗氧率为0.7135 mg/g · h,平均耗氧率最高是在pH7.5时,为0.8665 mg/g · h,平均耗氧率最低是在pH5.5时,为0.5397 mg/g · h.在密封式呼吸室内测定pH值在5.5、6.0、6.5、7.0、7.5、8.0和8.5试验用水条件下的厚颌鲂幼鱼的窒息点,分别为1.3920、1.3067、1.1547、1.0683、1.0933、1.1733和1.2331 mg/L,平均窒息点为1.2008 mg/L.     

瓦氏黄颡鱼与黄颡鱼的耗氧率及窒息点

在平均水温25℃条件下,测得平均体重10.0 g的瓦氏黄颡鱼(Pelteobagrus vachelli)及平均体重12.6g的黄颡鱼(P.fulvidraco)耗氧率分别为0.21和0.23 mg/g.h,窒息点分别为0.91和0.75 mg/L;平均体重75.8 g的瓦氏黄颡鱼及平均体重85.4 g的黄颡鱼耗氧率分别为0.16和0.12 mg/g.h,窒息点分别为0.77和0.54 mg/L。分析表明,瓦氏黄颡鱼的耗氧率和窒息点都高于黄颡鱼。     

厚颌鲂和圆口铜鱼耗氧率与窒息点的测定

用封闭静水式装置测定了体重2.3-4.7g厚颌鲂幼鱼的耗氧率和窒息点,用封闭静水式和封闭流水式装置测定了体重9.9-55.1g圆口铜鱼的耗氧率和窒息点。结果表明:在15-27℃条件下,厚颌鲂的耗氧率随着温度的升高而升高,耗氧率与水温呈线性关系;在水温24.8℃时厚颌鲂的窒息点为(0.91±0.08)mg/L。在水温23-27℃、封闭静水实验条件下,圆口铜鱼的耗氧率随体重增加而降低,两者呈指数关系;圆口铜鱼耗氧率昼夜变化明显,夜间耗氧率大于白天,推测圆口铜鱼夜间活动较多。在水温24.5-26.0℃条件下,体重21.8-46.3g圆口铜鱼的窒息点变幅较小,平均(1.14±0.23)mg/L。研究表明两种鱼都为耗氧率和窒息点较高的鱼类。       

水环境中不同浓度K+、Ca2+对大鳞鲃幼鱼存活率、耗氧率和窒息点的影响

通过单因子静态急性毒性试验和呼吸生理试验,研究了盐度10的水体中不同K+、Ca2+浓度对大鳞鲃(Barbus capito)幼鱼存活率、耗氧率和窒息点的影响.结果表明:在K+浓度3.78 ～ 435.30 mg-L-1(对照组为117.55 mg· L-1)和Ca2+浓度11.01 ～ 1535.90 mg·L-1(对照组为116.59 mg· L-1)水质条件下,大鳞鲃幼鱼存活率均为100％.96 h高浓度K+的LC50为515.01 mg· L-1,低浓度Ca2+的LC50为5.47 mg·L-1.在耗氧率和窒息点试验中,低浓度K+组[(3.75±0.17) mg·L-1]大鳞鲃幼鱼在整个试验过程中的耗氧率和窒息点均未出现显著性变化(P＞0.05);高浓度K+组[(451.67±10.23) mg· L-1]耗氧率在前48 h未出现显著性变化(P＞0.05),72和96 h与对照组[(115.29±0.68) mg·L-1]相比,耗氧率显著提高(P＜0.05);临界窒息点和绝对窒息点与对照组相比均显著升高(P＜0.05).Ca2+试验中,高Ca2+组[(1290.10±15.75) mg·L-1]和低Ca2+组[(8.87±0.34) mg·L-1]表现为相同趋势,即前24 h时高浓度Ca2+组和低浓度Ca2+组耗氧率均比对照组[(117.57±1.68) mg·L-1]有显著升高(P＜0.05),48 h后,高浓度Ca2+组和低浓度Ca2+组耗氧率恢复到对照组水平并持续至96 h试验结束.无论低浓度Ca2+组还是高浓度Ca2+组,大鳞鲃幼鱼的临界窒息点与绝对窒息点都显著升高(P＜0.05).综上所述,大鳞鲃幼鱼对水体中K+、Ca2+具有较强的耐受性,尤其是低浓度K+和高浓度Ca2+.     

黄鳝气呼吸代谢的研究

测定了黄鳝气呼吸状态下 ,2 5～ 2 7℃时的能量代谢情况。结果 ,表明平均耗氧率为 6 3 6 4mg/kg·h ,平均耗氧量 2 .81mg/尾·h ,体重与耗氧量之间的直线回归方程为 y =1.32 +0 .0 3x ;个体越大 ,耗氧量越大 ,个体越小 ,耗氧率越高。同时发现 ,黄鳝的耗氧率随环境温度变化及昼夜节律交替而变化。     

温度、盐度和体长对西藏拟溞耗氧率的影响

在实验室内研究了盐度(S=5、10、15、20和25)、温度(T=3、8、14、20和22℃)和体长(L=0.83、1.25、1.49、1.87和2.42mm)对西藏拟耗氧率的影响。结果表明,在试验盐度内该的个体耗氧率(IO)和比耗氧率(SO)均随盐度(S)升高而升高,其回归方程分别为IO=0.0014S 0.0126和SO=0.115S0.5612,数值范围为0.02～0.045μg/(indh)和0.31～0.67μg/(mg·h)。个体耗氧率和比耗氧率在温度试验中有同样的趋势,回归方程分别为IO=0.0049e0.1574T和SO=0.0678e0.1605T,数值分别为0.0076～0.13μg/(ind·h)和0.10～1.71μg/(mg·h)。体长试验中个体耗氧率随体长增大而增大,而比耗氧率则降低,回归方程分别为:IO=0.0545L2.5962和SO=-0.2059L 0.7908,数值范围为0.036～0.68μg/(ind·h)和0.38～0.63μg/(mg·h)。讨论了盐度、温度和体长对西藏拟耗氧率的影响。     

盐度与体重对台湾红罗非鱼耗氧率的影响

在盐度为淡水、7、14、21、28和35的条件下,测定了3个体重组(1.57～4.87g,7.07～18.23g和31.50～52.41g)的台湾红罗非鱼的耗氧率,方差分析表明,盐度对台湾红罗非鱼的耗氧率有极显著的影响(P＜0.01).体重范围为1.57～18.24g时,盐度7实验组的耗氧率最高,分别为0.41mg O2*g-1*h-1(1.57～4.78g)和0.34mg O2*g-1*h-1(7.07～18.23g),体重范围为31.50～52.41g时,耗氧率最高值出现在盐度35组,为0.30mg O2*g-1*h-1.耗氧率最低值也因体重范围的不同而出现在不同的盐度,体重范围为1.57～4.78g时,盐度14组的耗氧率最低,为0.28mg O2*g-1*h-1,体重范围在7.07～52.41g时, 耗氧率的最低值均出现在盐度21组, 其中体重范围7.07～18.23g的最低值为0.22mg O2*g-1*h,而体重范围31.50～52.41g的最低耗氧率为0.13mg O2*g-1*h-1.协方差分析表明,盐度和体重对台湾红罗非鱼的耗氧率存在极显著的交互作用(P＜0.01).     

温度、盐度对强壮箭虫耗氧率和窒息点的影响

研究了不同温度、盐度下强壮箭虫的耗氧率和窒息点.结果表明:温度和盐度均对强壮箭虫的耗氧率和比耗氧率有显著影响.试验温度在5℃-25℃,强壮箭虫个体耗氧率(IO)和比耗氧率(SO)开始随温度的升高而升高,之后呈明显下降趋势.其回归方程分别为y=0.0058x3 -0.2956x2+4.415x-8.7816(R2=0.99,P＜0.05)和y=0.0011x3 -0.0546x2+0.8161x-1.6232(R2=0.99,P＜0.05),数值分别为6.30～11.71μg·ind-1·h-1和1.22 ～2.16μg· mg-1·h-1,窒息点为4.18～6.87 mg·L-1.盐度10 ～40条件下,IO和SO随盐度的升高逐渐下降,回归方程分别为y=-0.0068x2 -0.1412x+21.702(R2=0.89,P＜0.05)和y=-0.0013x2-0.0261x+4.0114( R2 =0.89,P＜0.05),数值分别为4.98～17.73μg ·ind-1·h-1和0.92～3.56 μg·mg-1 ·h-1,窒息点为4.02～6.24 mg·L-1.对强壮箭虫与其他水生动物的耗氧率和窒息点进行比较得出,强壮箭虫是一种狭氧性浮游动物.     

Investigation of the mechanism of temperature sensitivity of the electroreceptors of ampullae of lorenzini

In experiments on Black Sea skates (Raja clavata), the potential of the receptor epithelium of the ampullae of Lorenzini and spike activity of single nerve fibers connected to them were investigated during electrical and temperature stimulation. Usually the potential within the canal was between 0 and –2 mV, and the input resistance of the ampulla 250–400 k. Heating of the region of the receptor epithelium was accompanied by a negative wave of potential, an increase in input resistance, and inhibition of spike activity. With worsening of the animal's condition the transepithelial potential became positive (up to +10 mV) but the input resistance of the ampulla during stimulation with a positive current was nonlinear in some cases: a regenerative spike of positive polarity appeared in the channel. During heating, the spike response was sometimes reversed in sign. It is suggested that fluctuations of the transepithelial potential and spike responses to temperature stimulation reflect changes in the potential difference on the basal membrane of the receptor cells, which is described by a relationship of the Nernst's or Goldman's equation type.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. I. M. Sechenov, Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Pacific Institute of Oceanology, Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Neirofiziologiya, Vol. 12, No. 1, pp. 67–74, January–February, 1980.     

Determination of stoichiometry of radioiodination of proteins

A sensitive method for the detection of small quantities of hydrophobic antioxidant free radical scavengers such as butylatedhydroxytoluene (BHT) and butylatedhydroxyanisole (BHA) in aqueous samples is described. The procedure involves extraction of the hydrophobic free radical scavenger into an organic solvent phase, followed by the subsequent reaction of an aliquot of this extract with the stable cation radical tris(p-bromophenyl)amminium hexachloroantimonate (TBACA). In experiments with BHT and BHA, the loss of TBACA absorbance at 730 nm was found to be linearly proportional to the amount of antioxidant added, with quantities of BHT as small as 200 pmol being easily detectable. In aqueous suspensions of dimyristoylphosphatidylcholine vesicles, assays of the aqueous BHT concentration showed that BHT partitioned strongly into the membrane phase, achieving very high BHT/phospholipid ratios. For a given concentration of BHT, partitioning into the membrane phase was greater in large, multilamellar liposomes than in either small, single-walled vesicles or in purified rat brain synaptic vesicle membranes. Direct assay of BHT and BHA in phospholipid membranes, however, was complicated by a nonspecific interaction between TBACA and the phospholipid.