鱼类肠道营养物质转运对饮食的遗传和表型适应
Genetic and phenotypic adaptation of intestinal nutrient transport to diet in fish.
作者信息
Buddington R K, Chen J W, Diamond J
机构信息
Department of Physiology, University of California Medical School, Los Angeles 90024.
出版信息
J Physiol. 1987 Dec;393:261-81. doi: 10.1113/jphysiol.1987.sp016823.
Abstract
- Herbivores have higher rates of intestinal sugar transport and lower rates of amino acid transport than carnivores, if each are studied while eating their respective natural diets. It was unclear whether these species differences involve a genetic contribution, since when omnivores are switched from a high-protein to a high-carbohydrate diet they reversibly increase sugar transport and suppress amino acid transport. Hence we studied eight fish species of differing natural diets while all were eating the same manufactured diet. 2. Na+-dependent L-proline uptake and active D-glucose uptake, measured in vitro by the everted intestinal sleeve technique, followed Michaelis-Menten kinetics. Values of the apparent Michaelis-Menten constant increased with values of the maximal transport rate, probably as a result of unstirred layer effects. 3. The ratio of proline to glucose uptake decreased in the sequence: carnivores greater than omnivores greater than herbivores. The intestine's uptake capacity for the non-essential nutrient glucose was much higher in herbivores than in carnivores, correlated with species differences in carbohydrate content of the natural diet. Proline uptake varied much less among species, since species with different natural diets still have similar protein requirements. 4. Since all species were studied while eating the same diet, these species differences in uptake are not phenotypic but genetic adaptations to the different natural diets. 5. In two fish species which normally switch from carnivory towards herbivory or omnivory as they mature, we observe a 'hard-wired' developmental change in intestinal uptake. Larger animals had lower proline uptake relative to glucose uptake than did smaller animals, even though both were being maintained on the same diet in the laboratory. 6. Carnivorous fish tend to allocate absorptive tissue to pyloric caeca or a thick mucosa, while herbivorous fish tend towards a long thin intestine.
摘要
- 如果在食草动物和食肉动物食用各自天然食物时进行研究,会发现食草动物的肠道糖转运速率较高,而氨基酸转运速率较低。尚不清楚这些物种差异是否涉及遗传因素,因为当杂食动物从高蛋白饮食转变为高碳水化合物饮食时,它们会可逆地增加糖转运并抑制氨基酸转运。因此,我们研究了八种具有不同天然食物的鱼类,而它们都食用相同的人工饲料。2. 通过外翻肠段技术在体外测量的钠离子依赖性L-脯氨酸摄取和活性D-葡萄糖摄取遵循米氏动力学。表观米氏常数的值随最大转运速率的值增加,这可能是由于未搅拌层效应。3. 脯氨酸与葡萄糖摄取的比率按以下顺序降低:食肉动物大于杂食动物大于食草动物。食草动物肠道对非必需营养素葡萄糖的摄取能力比食肉动物高得多,这与天然食物中碳水化合物含量的物种差异相关。不同物种间脯氨酸摄取的变化要小得多,因为具有不同天然食物的物种仍有相似的蛋白质需求。4. 由于所有物种都是在食用相同饲料时进行研究的,这些摄取方面的物种差异不是表型差异,而是对不同天然食物的遗传适应。5. 在两种随着成熟通常从食肉转变为食草或杂食的鱼类中,我们观察到肠道摄取存在“固定的”发育变化。即使在实验室中两种鱼都维持相同的饮食,较大的动物相对于葡萄糖摄取的脯氨酸摄取比较小的动物低。6. 肉食性鱼类倾向于将吸收组织分配到幽门盲囊或厚黏膜处,而草食性鱼类则倾向于拥有长而细的肠道。
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