Amitosis and endocycles in early cultured mouse trophoblast.

The possible occurrence of amitosis has been studied in nuclei of trophoblast outgrowths of mouse embryos placed in culture at the two-cell stage. By day 7 of culture, the inner cell mass has usually floated away, while the trophoblast outgrowth remains attached. Of 591 trophoblast cells from 25 embryos, 469 were uninucleate, 87 binucleate, 4 trinucleate, and in 31 the nuclei were attached to each other. In our interpretation, these come about through a process in which the nucleus stretches, then the nuclear membrane invaginates and finally constricts the nucleus into two parts. The resulting nuclei, asymmetric in size and in amount and arrangement of heterochromatin and nucleoli, lie side-by-side. We conclude that these cells with two or more attached or separate nuclei represent stages in true amitosis. In Table 1, amitosis is compared with mitosis without cytokinesis and with cell fusion, both of which can also give rise to binucleate and multinucleate cells. Mitosis without cytokinesis does not agree in any respect with the characteristics of amitosis, whereas at least a few similarities exist between cell fusion and amitosis. However, amitosis may give rise to near-haploid nuclei, which cannot be produced by mitosis or cell fusion. Simultaneously with amitosis, the nuclei grow through endocycles. In many nuclei, the heterochromatin is clearly underreplicated, while the nucleoli are numerous and often of enormous size, probably reflecting amplification of the rRNA genes.

The critical region on the human Xq.

Adult female carriers of balanced X; autosome translocations (118 cases) and of balanced X inversions (31 cases) have been collected from the literature. Forty-five of the 118 translocation carriers in whom the break was in the critical region (Xq13-q22, Xq22-q26, separated by a narrow region within Xq22) showed gonadal dysgenesis. Seven of the 31 inversion carriers in whom the break was in the same region also had gonadal dysgenesis, whereas the remaining 24 were normal in this respect. The critical region consists mainly of Q-bright material, and is the fifth brightest segment in the human genome. The region contains relatively few genes. It is possible that meiotic crossing-over, rarely, if ever, takes place in it. The critical region may therefore consist of two "supergenes" whose integrity must be maintained to allow normal ovarian development. The effect exerted by this region differs from other known position effects, in that it is independent of the breakpoint within the region and of the chromosome bands to which the broken ends are attached. One possible mechanism causing this effect might be a change in the replication order of the chromosome bands, which, in turn, might affect their function.

The similarity of phenotypic effects caused by Xp and Xq deletions in the human female: a hypothesis.

We have collected from the literature adult nonmosaic women with the following aberrant X chromosomes: Xp- (52), Xq- (67), idic(Xp-)(10), idic(Xq-)(9), and interstitial deletions (12). Lack of Xp, and especially Xcen-Xp11 (b region), may cause full-blown Turner syndrome. However, individual Turner symptoms, including gonadal dysgenesis, otherwise seem to be randomly distributed with respect to the different Xp and Xq deletions, although breakpoints distal to Xq25 do not give rise to any phenotypic anomalies except in a few cases of secondary amenorrhea or premature menopause. Of the carriers of an Xp- or Xq- chromosome, 65% and 93%, respectively, suffer from ovarian dysgenesis, whereas all idic(Xp-) and idic(Xq-) chromosomes cause primary or secondary amenorrhea. Xq deletions do not induce specific symptoms different from those caused by Xp deletions. Lack of the tip of Xp has led in 46/52 cases to short stature, but 43% of the Xq- carriers are also short. To explain these observations, we propose the following hypothesis. Since deletions of truly inactivated regions do not seem to cause any symptoms, we assume that the b region (Xcen-p11) always stays active in a normal inactive X, but is inactivated in deleted X chromosomes, especially in Xq- chromosomes. In some cases, inactivation may spread to the tip of Xp; this would explain the apparently variable behavior of the Xg and STS genes, and the short stature of some Xq- carriers. Full chromosome pairing seems to be a prerequisite for the viability of oocytes and thus for gonadal development. Deleted X chromosomes necessarily leave a portion of the normal X unpaired and isodicentrics probably interfere with pairing, resulting in atresia of oocytes. The role played by the "critical region" (Xq13-q24) in ovarian development is still unclear.

The nonrandom participation of human acrocentric chromosomes in Robertsonian translocations.

The present study explores the origin of human Robertsonian translocations (RT) and the causes of the nonrandom participation of the different acrocentrics in them. Satellite associations have been analysed in 966 cells from 8 persons, and 1266 RT with ascertainment have been collected from the literature. The observation that the chromosomes preferentially taking part in satellite associations vary between individuals is confirmed. However, since a preferred chromosome appears to associate at random with the others, this phenomenon should not add to the nonrandomness of the RT. Most RT presumably arise through adjacent chromatid exchanges corresponding to mitotic chiasmata, in the pericentric regions of the acrocentrics. Our working hypothesis is that there is a basic exchange rate between any two acrocentrics. The surplus of t(14q21q) is presumed to depend on these two chromosomes having a homologous pericentric region. The 10-20 times higher incidence of t(13q14q) as compared with other RT is best explained by crossing-over between homologous, but relatively inverted, segments in these chromosomes. Of the 246 RT ascertained through repeated abortions or infertility, 56 were found through the latter. Of these, chromosome 14 was involved in 51. The infertility may be caused by a small deletion of 14q, as is often the case in 15q in Prader-Willi syndrome. In all RT ascertained through 21 or 13 trisomy, respectively, the relevant chromosome is one of the participants. Our data thus do not give any support to the idea of interchromosomal effects exerted by RT.