Center for Demographic and Population Genetics, University of Texas Health Science Center, P. O. Box 20334, Houston Texas 77025.
Genetics. 1980 Jan;94(1):185-201. doi: 10.1093/genetics/94.1.185.
The stepwise mutation model of Ohta and Kimura (1973) was proposed to explain patterns of genetic variability revealed by means of electrophoresis. The assumption that electrophoretic mobility was principally determined by unit changes in net molecular charge has been criticized by Johnson (1974, 1977). This assumption has been tested directly using hemoglobin. Twenty-seven human hemoglobin variants with known amino acid substitutions, and 26 nonhuman hemoglobins with known sequences were studied by starch gel electrophoresis. Of these hemoglobins, 60 to 70% had electrophoretic mobilities that could be predicted solely on the basis of net charge calculated from the amino acid composition alone, ignoring tertiary structure. Only four hemoglobins showed a mobility that was clearly different from an expected mobility calculated using only the net charge of the molecule. For the remaining 30% of hemoglobins studied, mobility was determined by a combination of net charge and other unidentified components, probably reflecting changes in ionization of some amino acid residues as a result of small alterations in tertiary structure due to the amino acid substitution in the variant. For the nonhuman hemoglobins, the deviation of a sample from its expected mobility increased with increasing amino acid divergence from human hemoglobin A.-It is concluded that the net electrostatic charge of a molecule is the principal determinant of electrophoretic mobility under the conditions studied. However, because of the significant deviation from strict stepwise mobility detected for 30 to 40% of the variants studied, it is further concluded that the infinite-allele model of Kimura and Crow (1964) or a "mixed model" such as that proposed by Li (1976) may be more appropriate than the stepwise mutation model for the analysis of much of the available electrophoretic data from natural populations.
Ohta 和 Kimura(1973)提出的逐步突变模型旨在解释通过电泳揭示的遗传变异性模式。Johnson(1974、1977)批评了电泳迁移率主要由净分子电荷的单位变化决定的假设。已经使用血红蛋白直接测试了该假设。使用淀粉凝胶电泳研究了 27 种具有已知氨基酸取代的人类血红蛋白变体和 26 种具有已知序列的非人类血红蛋白。在这些血红蛋白中,有 60%至 70%的电泳迁移率仅根据氨基酸组成计算出的净电荷即可预测,而忽略了三级结构。只有四种血红蛋白的迁移率明显不同于仅根据分子的净电荷计算出的预期迁移率。对于研究的其余 30%的血红蛋白,迁移率由净电荷和其他未识别的成分决定,这可能反映了由于变体中氨基酸取代导致三级结构的微小变化,一些氨基酸残基的电离发生变化。对于非人类血红蛋白,样品与其预期迁移率的偏差随着与人类血红蛋白 A 的氨基酸差异的增加而增加。得出的结论是,在研究条件下,分子的净静电荷是电泳迁移率的主要决定因素。然而,由于研究的变体中有 30%至 40%检测到与严格逐步迁移率的显著偏差,因此进一步得出结论,Kimura 和 Crow(1964)的无限等位基因模型或 Li(1976)提出的“混合模型”可能比逐步突变模型更适合分析来自自然种群的大部分可用电泳数据。