耳垂形成中的基因、锰和锌:标记、恢复和母体效应。

Scanning electron microscopy Pub Date : 1986-01-01
L C Erway, N A Purichia, E R Netzler, M A D'Amore, D Esses, M Levine
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引用次数: 0

摘要

已发表的研究表明,基因和膳食锰缺乏导致前庭功能缺陷和共济失调行为。发育过程中缺乏锰会导致小鼠、大鼠、豚鼠和雏鸡的耳廓缺陷。突变基因导致小鼠、水貂和家禽的耳锥体缺陷。锰的补充可防止某些突变小鼠和水貂的耳锥体缺陷。在耳孔结晶之前,锰是合成粘多糖和耳孔基质所必需的。在胎儿发育期间耳聋结晶后,可通过饮食缺锌和磺胺治疗(抑制碳酸酐酶,一种需要锌的酶)诱导这种缺陷。锰和/或锌补充剂可改善苍白和致死乳(锌缺乏)小鼠的耳锥体缺陷。本研究表明:发育中的耳聋可以定量标记45钙。这可能为长期研究耳聋中的钙代谢以及确定饮食、药物和其他因素对耳聋的可能影响提供了一种手段。在新生小鼠中观察到胎儿耳锥形成后引起的耳锥缺陷,但在出生后2天消失。内耳状况可能导致耳郭钙化。通过酸化饮水补充锰和锌比膳食补充更有效地预防灰质小鼠耳孔缺损。锌的有效性与母源基因型(+/pa vs. pa/pa)有关,而锰的有效性与母源基因型无关。在连续的凋落物中,添加锌而不添加锰的效果增加。这些研究表明,基因和微量矿物质的相互作用可能影响耳锥的形成和维持。
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Genes, manganese, and zinc in formation of otoconia: labeling, recovery, and maternal effects.

Published studies indicate that genes and dietary manganese deficiency cause vestibular defects and ataxic behaviors. Manganese deficiency during development causes otoconial defects in mice, rats, guinea pigs, and chicks. Mutant genes cause otoconial defects in mice, mink, and poultry. Manganese supplementation prevents the otoconial defects in some mutant mice and mink. Manganese is essential, before crystallization of the otoconia, for synthesis of mucopolysaccharides and otoconial matrix. Such defects can be induced, after otoconia are crystallized during fetal development, by dietary zinc deficiency and sulfonamide treatment (inhibits carbonic anhydrase, a zinc-requiring enzyme). Manganese and/or zinc supplementation ameliorates otoconial defects in pallid and lethal-milk (zinc-deficient) mice. Studies herein show that: Developing otoconia can be quantitatively labeled with 45 Ca. This may provide a means for studying calcium metabolism in otoconia over a prolonged period of time and for determining the possible effects of diet, drugs, and other factors on otoconia. Otoconial defects, induced after otoconia form in the fetus, were observed in newborn mice, but disappeared by two days after birth. Conditions of the inner ear may contribute to the calcification of otoconia. Manganese and zinc supplementation of pallid mice via acidified drinking water is more effective than dietary supplementation in preventing otoconial defects. The effectiveness of zinc but not of manganese is related to maternal genotype (+/pa vs. pa/pa). The effect of supplementation of the dams with zinc but not with manganese increases over successive litters. These studies indicate the potential for interaction of genes and trace minerals on otoconial formation and maintenance.

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