Proust J, Prudhommeau C, Ladevèze V, Gotteland M, Fontyne-Branchard M C
Laboratoire de Biologie Générale, Université Paris-Sud, Orsay, France.
Mutat Res. 1992 Aug;268(2):265-85. doi: 10.1016/0027-5107(92)90233-r.
The purpose of this paper is the genetic visualization by in situ hybridization of 130 sex-linked recessive lethals plus a non-lethal induced by I-R dysgenesis. This collection of lethals involves inducer strains which differ in the position of the I elements on the X chromosomes. The I-R interaction was strong. Our previous results have shown that about 30% of the induced recessive lethals are associated with cytologically visible chromosomal rearrangements. (1) The rearrangements induced by I-R-type hybrid dysgenesis often exhibit homology with the I factor at the level of one or both junction points, depending on the types of chromosome rearrangements. These results suggest that the chromosome rearrangements arise directly from the transposition of I elements. However, the breakpoints of some types of cytologically non-visible deficiencies and of 2 small cytologically visible deficiencies do not present detectable homology with the I factor. (2) The majority of rearrangements do not involve the I elements already present on the paternal X chromosome. (3) The hybridization signal distributions on the X chromosome are not uniform. They present peaks of various heights which may correspond to specific anchoring areas of copies of I in the course of integration. (4) The data presented here agree with the literature with respect to the mean number of copies of I per X chromosome and to the excess of copies of I at locus 1A. Two rearrangement formation mechanisms are envisaged: crossing-over and 'target' exchanges.
本文的目的是通过原位杂交对130个X连锁隐性致死基因以及1个由I-R杂种不育诱导产生的非致死基因进行遗传可视化。这组致死基因涉及诱导菌株,这些菌株在X染色体上I元件的位置不同。I-R相互作用很强。我们之前的结果表明,约30%的诱导隐性致死基因与细胞学上可见的染色体重排有关。(1)由I-R型杂种不育诱导产生的重排,根据染色体重排的类型,在一个或两个连接点水平上常常与I因子表现出同源性。这些结果表明,染色体重排直接源于I元件的转座。然而,某些类型细胞学上不可见的缺失以及2个细胞学上可见的小缺失的断点,与I因子不存在可检测到的同源性。(2)大多数重排不涉及父本X染色体上已有的I元件。(3)X染色体上的杂交信号分布不均匀。它们呈现出不同高度的峰值,这可能对应于整合过程中I拷贝的特定锚定区域。(4)本文给出的数据在每个X染色体上I的平均拷贝数以及1A位点I拷贝的过量方面与文献一致。设想了两种重排形成机制:交叉互换和“靶标”交换。