Nonhomologous synapsis of the sex chromosomes in the heteromorphic bivalents of two X-7 translocations in male mice: R5 and R6

Electron microscopy of pachytene nuclei of mice heterozygous for either of two reciprocal X-7 translocations (R5 or R6) revealed a high frequency of heteromorphic bivalents involving the translocated chromosomes. In both translocations the break was in the proximal third of the 7 and the distal third of the X, but the R5 breaks were closer to the 7 centromere and X telomere than the R6 breaks. In both translocations the 7 frequently synapsed nonhomologously with the X7. In R5 the part of the X to which the 7 synapsed may include a region that synapses with the Y in normal mice. However, in R6 the 7 synapsed with a portion of the X that never synapses with the Y (Synapsis was clearl in the differentiated region). In both translocations the Y synapsed maximally with the X portion of the 7X in those nuclei in which there was nonhomologous synapsis of the 7 with the X7. The Y occasionally synapsed nonhomologously with the 7 portion of the 7X. The behavior of the bivalents suggests that the autosomal portions of the 7X and X7 may alter the behavior of the sex-chromosome portions. Both the nonhomologous synapsis of the Y with the 7X and the timing of events during pachytene have led us to question the homology between the X and Y in this species.     

Mapping of four translocation breakpoints within the Duchenne muscular dystrophy gene

There are over 20 females with Duchenne or Becker muscular dystrophy (DMD or BMD) who have X-autosome translocations that break the X chromosome within band Xp21. Several of these translocations have been mapped with genomic probes to regions throughout the large (approximately 2000 kb) DMD gene. In this report, a cDNA clone from the 5' end of the gene was used to further map the breakpoints in four X-autosome translocations. A t(X;21) translocation in a patient with BMD and a t(X;1) translocation in a patient with DMD were found to break within a large 110-kb intron between exons 7 and 8. Two other DMD translocations, t(X;5) and t(X;11), were found to break between the first and the second exon of the gene within a presumably large intron (greater than 100 kb). These results demonstrate that all four translocations have disrupted the DMD gene and make it possible to clone and sequence the breakpoints. This will in turn determine whether these translocations occur by chance in these large introns or whether there are sequences that predispose to translocations.     

Viability of X-autosome translocations in mammals: an epigenomic hypothesis from a rodent case-study

X-autosome translocations are highly deleterious chromosomal rearrangements due to meiotic disruption, the effects of X-inactivation on the autosome, and the necessity of maintaining different replication timing patterns between the two segments. In spite of this, X-autosome translocations are not uncommon. We here focus on the genus Taterillus (Rodentia, Gerbillinae) which provides two sister lineages differing by two autosome–gonosome translocations. Despite the recent and dramatic chromosomal repatterning characterising these lineages, the X-autosome translocated species all display intercalary heterochromatic blocks (IHBs) between the autosomal and the ancestral sexual segments. These blocks, composed of highly amplified telomeric repeats and rDNA clusters, are not observed on the chromosomes of the non-translocated species, nor the Y1 and Y2 of the translocated species. Such IHBs are found in all mammals documented for X-autosome translocation. We propose an epigenomic hypothesis which explains the viability of X-autosome translocations in mammals. This posits that constitutive heterochromatin is probably selected for in X-autosome translocations since it may (1) prevent facultative heterochromatinization of the inactivated X from spreading to the autosomal part, and (2) allow for the independent regulation of replication timing of the sex and autosomal segments.     

Chronology of the replication of sex chromosome bands in lymphocytes of normal subjects and patients]

The replication sequence of the bands carried by chromosomes X and Y has been studied in normal individuals and in patients with structural abnormalities of the X. By comparing the segment with that of the autosomal bands (which had been previously studied), it was shown that the normal early X replicates in early X-phase for its R-bands and in late S-phase for its Q bands. The late X replicates entirely in late S-phase, and the sequence of band replication is not as stringent as for the early X and the autosomes. The study of fourteen cases of anomalies of chromosome X in females showed the following: in balanced reciprocal X-autosome translocations the rearranged X most often replicates early and the normal X late. Both show a normal replication sequence of their bands. In non-balanced X-autosome translocations, inactivation of the autosome fragment attached to the AUTOSOME FRAGMENT ATTACHED TO THE X may take place. In Xq- or in ter rea (X;X) (pter;pter), band p22 has a delayed replication. In iso-Xor Xp-, the long-arm-band sequence of replication shows a variation comparable to that of the late X in fibroblasts. These replication modifications are likely to induce partial inactivations or changes in activity which correspond to the so-called position effect in Drosophila.     

Translocations, the Predominant Cause of Total Sterility in Sons of Mice Treated with Mutagens

Histological and cytological analyses of the testes were carried out in 42 sterile sons of males treated in the spermatozoal or spermatid stage with 250 mg/kg ethyl methanesulfonate (EMS) alone or after prefeeding with butylated hydroxytoluene (BHT); or treated with 200 R X-rays. Of the 42 sterile males, 17 had some mature spermatids, nine were blocked at diakinesis, 15 were blocked in pachytene, and one lacked spermatogenic cells altogether, having Sertoli cells only. Mitotic (spermatogonial) metaphases could therefore be analyzed in 41 of the males and meiotic configurations in 26.-(1) None of the males showed abnormalities in chromosome number, such as monosomy, trisomy, or mosaicism for either of these conditions. Certain classes of chromosome abnormalities that have been found associated with male sterility in other investigations, namely trisomies, XXY's, and X-autosome translocations, are not expected from treatment of 19A + Y cells when F(1) males are studied. (2) A very high percentage of the sterile males carried translocations. Direct meiotic evidence for this was found in 22 of the animals. In addition, 11 of the 16 that were blocked (or virtually blocked) in pachytene, and thus could be analyzed in mitosis only, consistently showed one abnormally short chromosome (or, one short plus one long), which presumably had resulted from unequal exchange (or sizable deficiency). Of the meiotically detected translocation males, 1 carried a T(A;Y), 17 had single autosomal translocations, and 4 had multiple autosomal rearrangements involving three, four, four, and six breaks, respectively. In addition, three males showed failure of X-Y pairing. (3) Translocations that cause sterility, rather than partial sterility, in males appear to be those in which at least one of the breaks occurs close to one end of a chromosome. The mitotic and meiotic evidences for this were found to be correlated. (4) It is proposed that many cases of induced F(1) male sterility may be the result of position effects produced when paracentromeric regions are translocated to euchromatic regions of certain other chromosomes. Since many translocations that produce partial sterility in the female cause complete sterility in the male, the male must be assumed to be more susceptible to disturbances of fertility by the postulated mechanism. (5) There is evidence that EMS, especially in the lower dose range, more often breaks chromosomes near one of their ends than does X-irradiation.     

Human X-autosome translocations: differential inactivation of the X chromosome in a kindred with an X-9 translocation.

A kindred with an X-autosome translocation and differential inactivation of the X chromosome is described. The phenotypically normal mother has a reciprocal translocation [46,X,rcp(X;9) (q11;q32)] while the daughter's karyotype is unbalanced [46,X,--X,+der(9),rcp(X;9) (q11;q32)mat], indicating adjacent-two type of segregation in the mother. In the mother's cells the normal X is late replicating, while in the daughter's cells almost the entire der(9) is late replicating, indicating the presence of autosomal inactivation. The daughter's abnormal phenotype can be explained by her sex chromosomal complement and the absence of effective trisomy 9. At this stage there is no simple explanation to account for all types of inactivation patterns encountered in the 14 balanced and 15 unbalanced cases of X-autosome translocations reported to date. Selection of X inactivation is not an inherent characteristic of the X chromosome per se, and it is not dependent on the direction of chromosomal exchange, as was suggested previously. Correlation of the phenotypic and cytogenetic features of these patients suggests a pattern of X and autosomal inactivation consistent with the least amount of genotypic and phenotypic imbalance in most cases. The data are most consistent with random X inactivation followed by selection of the most viable cell line.     

The Lyon and the LINE hypothesis

X-chromosome inactivation (XCI) was first suggested as an explanation for the variegated phenotypes in mice heterozygous for X-linked colour genes or for X-autosome translocations involving autosomal coat colour genes. The effects seen in X-autosome translocations led to the suggestion of an X-inactivation centre (Xic) from which the inactivation was initiated, and this suggestion has led to major advances in understanding. Another feature of X-autosome translocations is incomplete inactivation of the attached autosomal segment, implying that the X-chromosome is enriched in features favouring inactivation. Interspersed repeat elements, and in particular long interspersed elements (LINEs), have been suggested as the relevant enriching features. Recent evidence concerning this hypothesis is discussed.     

Sex chromosome-autosome translocations in the leaf-nosed bats, family Phyllostomidae. II. Meiotic analyses of the subfamilies Stenodermatinae and Phyllostominae

Analyses of meiotic pairing and synaptonemal complexes of the composite sex chromosomes of male phyllostomid bats with X-autosome or X- and Y-autosome translocations were performed using Giemsa and silver staining procedures. Typical mammalian sex vesicles were absent in all species analyzed. Stenodermatine species with X-autosome translocations possessed an open ring and tail configuration of the XY1Y2 trivalent. Species with both X- and Y-autosome translocations possessed a closed ring and tail configuration of the neo-XY bivalent. In both cases, the tail represented the autosomal short arm of the X paired with its homologue, either the Y2 in XY1Y2 species or the autosomal arm of the composite Y in neo-XY species. Autosomal pairing of the composite sex bivalent in neo-XY species replaced an association between the original X and Y in late prophase I. The absence of a sex vesicle, the unusual pairing configurations of the composite sex chromosomes, and the presumed absence of meiotic nondisjunction in these species is discussed in light of current hypotheses of sex chromosome behavior in male gametogenesis in mammals.     

Interaction of chromatid breaks induced by nitrosoguanidine in combination with some radiomimetics and X-rays

Experiments were carried out to study if chromatid breaks induced by nitrosoguanidine in combination with some known radiomimetics and X-rays interact with each other. It has been seen that nitrosoguanidine induced breaks exhibit full interaction in production of isochromatid breaks and interchanges with diepoxybutane, ethylmethane sulfonate and ethyleneimine but fail to do so with X-rays though the effects were additive. This has been interpreted to indicate that nitrosoguanidine produced aberrations have both, temporal and qualitative similarities with those of diepoxybutane, ethylmethane sulfonate and ethyleneimine and not with those induced by X-rays.     

Distribution and localization of induced breaks on the chromosomes of Bellevalia romana. IV. N-nitroso-N-methylurea, N,N''-dinitroso-N,N''-dimethylterephthalamide, and 1-nitroso-imidazolidone-2

Summary Chromosome breaks, mostly fragmentations and some translocations were induced in Bellevalia romana (2n=8) by N-nitroso-N-methylurea (NMH, 1499 breaks), N,N-dinitroso-N,N-dimethylterephthalamide (NMT, 1516 breaks) and 1-Nitrosoimidazolidone-2 (NIL, 2055 breaks).The mitotic rate is considerably reduced only by NMT; NIL induced the highest number of fragmentation and also, in contrast to NMH and NMT, about 3% translocations.There was no difference in the distribution over the four chromosome types of all the braks induced by NMH, NMT and NIL; fragmentations of the centromeres were more frequent than fragmentations of the chromosome arms; these peculiarities and the distribution of centromere-breaks correspond to the distributions, induced by agents investigated earlier.It is only the distribution of breaks over the three regions of chromosome arms, proximal, median and terminal which is mainly determined by the chemical nature of the agent; NMT shows an equidistribution of breaks over the regions of all chromosome arms, NMH and NIL revealed a pronounced decrease of the breakage frequency from the centromere-region towards the chromosome end in most of the chromosome arms. The breakage patterns induced by these two substances were not identical, in the shorter arm of the A-chromosome, NIL induced a pattern with the highest number of breaks in the median region.In the discussion the breakage patterns of 5 nitrosamides, nitrous acid, methylphenylnitrosamine, methylmethanesulfonate, diethylsulfate, and X-rays were compared. The methylating nitrosamides induced two opposite patterns: Breaks induced by the stable, slowly hydrolysing NMT and NMU tended to be equally distributed over the regions of the chromosome arms. The breaksinduced by rapidly hydrolysing NMH and NIL had the common property of following gradients of breakage frequencies.In conclusion, there have been evaluated three main factors, determining the kind of breakage patterns: the transport-and active form of the substances used, and the velocity of their degradation in aqueous solution.     

Patterns of replication in the neo-sex chromosomes ofDrosophila nasuta albomicans

Drosophila nasuta albomicans (with 2n = 6), contains a pair of metacentric neo-sex chromosomes. Phylogenetically these are products of centric fusion between ancestral sex (X, Y) chromosomes and an autosome (chromosome 3). The polytene chromosome complement of males with a neo-X- and neo-Y-chromosomes has revealed asynchrony in replication between the two arms of the neo-sex chromosomes. The arm which represents the ancestral X-chromosome is faster replicating than the arm which represents ancestral autosome. The latter arm of the neo-sex chromosome is synchronous with other autosomes of the complement. We conclude that one arm of the neo-X/Y is still mimicking the features of an autosome while the other arm has the features of a classical X/Y-chromosome. This X-autosome translocation differs from the other evolutionary X-autosome translocations known in certain species ofDrosophila.     

X-autosome translocation with a breakpoint in Xq22 in a fertile woman and her 47,XXX infertile daughter

Summary An unusual case is presented of a fertile woman heterozygous for a balanced X-autosome translocation t(X;12) (q22;p12) with a break-point (Xq22) in the critical region of the X chromosome. The karyotypes of her daughter, who is infertile, and one of her two sons are 47,XXX,t(X;12)(q22;p12) and 46,XY,t(X;12)(q22;p12) respectively. The literature on balanced X-autosome translocations in males and females involving both arms of the X chromosome is reviewed. All 23 of the 36 cases of females with balanced Xq-autosome translocation, that exhibited gonadal failure have a break-point between bands Xq13 and Xq26.     

Correlation between meiotic behavior and breakpoints with respect to G-bands in two X-4 mouse translocations: T(X;4)7R1 and T(X;4)8R1

The meiotic synaptic behavior of male mice heterozygous for one of two X-4 translocations was examined to test a recently advanced hypothesis (Ashley, 1988) suggesting that it is possible to predict the synaptic behavior (nonhomologous vs. homologous) and recombinational parameters (suppression vs. nonsuppression of crossing-over) of a chromosome aberration from mitotic G-band breakpoint data. The hypothesis was based on prior observations of synaptic behavior in a series of X-autosome translocations in mice. The breakpoints of the translocation T(X;4)7R1 are both in G-light bands. As predicted by the hypothesis, synapsis was restricted to homology. In contrast, one breakpoint of the translocation T(X;4)8R1 lies in a "stippled" band of the standard diagrams of Nesbitt and Francke (1981). As predicted (Ashley, 1988), "stippled" bands are shown here to synapse nonhomologously, i.e., they behave as "G-dark." The linkage data, as they relate to the synaptic data and the predictions of the hypothesis, are also discussed.     

Pattern of ribonucleic acid synthesis in vitro in primary spermatocytes from mouse testis carrying an X-autosome translocation

In an attempt to elucidate the mechanism of sterility of X-autosome translocations in the mouse, we studied the distribution of [³H]-uridine incorporation in sterile males carrying the balanced X-16 reciprocal translocation. The results failed to show an overall reactivation of the X as has been postulated by Lifschytz and Lindsley (1972) but there was some spreading of X inactivation along the translocated and normal chromosome 16 in those regions that were close to the X breakpoint. We feel that this process could be responsible for metabolic disturbances leading to degeneration of primary spermatocytes and, therefore, to sterility.     

Molecular analysis of X-autosome translocations in females with Duchenne muscular dystrophy.

To further an understanding of the mechanism of constitutional chromosomal rearrangement, the translocation breakpoints of two X-autosome translocations carried by females with Duchenne or Becker muscular dystrophy have been mapped, cloned and sequenced. Breakpoints were mapped to specific introns within the dystrophin gene and intron sequences spanning the two breakpoints were cloned and used as probes to identify DNA fragments containing the translocation junctions. The junction-containing fragments were cloned after amplification by inverse PCR or single-specific-primer PCR. Sequence through the junctions and the autosomal regions spanning the breakpoints identified the mechanism of rearrangement as non-homologous exchange with minor additions or deletions (0-8 nucleotides) at the breakpoints. Paternal origin of these X-autosome translocations, coupled with evidence for non-transmission of X-autosome translocations through male meiosis suggested that the translocations were the result of a post-meiotic rearrangement in spermiogenesis.     

Sex chromosome-autosome translocations in the leaf-nosed bats, family Phyllostomidae. I. Mitotic analyses of the subfamilies Stenodermatinae and Phyllostominae

Mitotic analyses using RBA- and C-banding were performed on Stenodermatine bats with X-autosome (XY1Y2) and X- and Y- autosome (neo-XY) translocations. RBA-banded metaphases of females revealed differential replication of the inactive X chromosome. An early replicating band comprises the short arm of the X, and an intermediate replicating band is located interstitially on the long arm. The early replicating short arm has a homologous counterpart either in the form of a free autosome (the Y2) or as part of the Y. Both the "autosomal" short arm of the X and its homologue fused to the Y are C-band negative and behave autonomously from the remainder of the sex chromosomes. They are separated from X and Y chromatin by centromeric heterochromatin which presumably acts as a barrier. The intermediate replicating region of the long arm of the X is also present in the subfamily Phyllostominae. In both subfamilies this region lacks a homologous counterpart. However, it may also represent a translocated autosome which, unlike the short arm of the X, is not separated from the inactive X by centromeric heterochromatin. Its intermediate replication time may represent a retarded replication due to its juxtaposition to late replicating X chromatin. These data are discussed in light of the theory of the evolution of sex chromosome heteromorphism, specifically as it applies to mammals.     

Synaptonemal complexes in Gerbillidae: probable role of intercalated heterochromatin in gonosome-autosome translocations

A study of sex chromosomes and synaptonemal complexes in male specimens of Gerbillus chiesmani, G. nigeriae, G. hoogstrali, and Taterillus pygargus is reported. In each of these Gerbillidae species there are two or three translocations of autosomes with X and Y chromosomes. Analysis of mitotic chromosomes consistently shows the presence of constitutive heterochromatin on the der t(X;autosome) at the X-autosome junction and on the der t(Y;autosome). Analysis of the synaptonemal complexes shows the existence of an unusual structure, lightly stained, at the X-autosome junction and at the Y-autosome junction, which is probably heterochromatic in nature, thus corresponding to the mitotic patterns. This heterochromatin separates the autosomal and gonosomal segments, which behave independently and normally. By analogy with findings from humans and other mammals, a general hypothesis is proposed on the role of intercalated heterochromatin between translocated gonosomes and autosomes. This hypothesis explains why the pathological consequences of these translocations may be very different in males and females. The role of intercalated heterochromatin would be to avoid the pathological consequences of gonosome-autosome translocations resulting from inactivation of the sex chromosomes in female somatic cells and male germinal cells.     

Genetic counselling in carriers of reciprocal chromosomal translocations involving short arm of chromosome X

A central concept in genetic counselling is the estimation of the probability of occurrence of unbalanced progeny at birth and other unfavourable outcomes of pregnancy (miscarriages, stillbirths and early death). The estimation of the occurrence probability for individual carriers of four different X-autosome translocations with breakpoints at Xp, namely t(X;5)(p22.2;q32), t(X;6)(p11.2;q21), t(X;7)(p22.2;p11.1), and t(X;22)(p22.1;p11.1), is presented. The breakpoint positions of chromosomal translocations were interpreted using GTG, RBG and FISH-wcp. Most of these translocations were detected in women with normal phenotype, karyotyped because of repeated miscarriages and/or malformed progeny. A girl with very rare pure trisomy Xp22.1-->pter and a functional Xp disomy was ascertained in one family and her clinical picture has been described in details. It has been suggested that not fully skewed X chromosome inactivation of X-autosome translocation with breakpoint positions at Xp22 (critical segment) could influence the phenotype and risk value. Therefore, the X inactivation status was additionally evaluated by analysis of replication banding patterns using RBG technique after incorporation of BrdU. In two carriers of translocations: t(X;5)(p22.2;q32) and t(X;7)(p22.2;p11.1), late replication state of der(X) was observed in 5/100 and 10/180 analysed cells, respectively. In these both cases the breakpoint positions were clustered at the critical segment Xp22.2. In two other cases, one with the breakpoint position within [t(X;22)(p22.1;p11.1)] and one outside the critical region [t(X;6)(p11.2;q21)], fully skewed inactivation was seen. Therefore, we suggest that neither the distribution of the breakpoint positions nor fully skewed inactivation influenced the phenotype of observed t(X;A) carriers. The occurrence probabilities of the unbalanced progeny were calculated according to Stene and Stengel-Rutkowski along with application of updated available empirical data. In the studied group the values of occurrence probability for unbalanced offspring at birth ranged from 2.1% to 17%. Information on the magnitude of the individual figures may be important for women carrying a reciprocal X;A translocation when deciding upon further family planning.     

The sensitivity of the mouse testis to the mutagenic action of triethylenemelamine

Summary The low dose of 0.2 mg/kg TEM allows the production of viable zygotes from the most sensitive stage of spermatogenesis. The frequency of translocations among offspring conceived during this peak period of sterility at 10–14 days p.i. is greater than among those conceived earlier, so that as the fertility of the treated males decreases (i.e. the percentage of dominant lethals increases) the frequency of translocations among their offspring increases. The results provide presumptive evidence that the spermatids are more sensitive to the mutagenic action of TEM than are the mature spermatozoa. A comparison of the incidence of translocations induced by TEM with that induced by X-rays is made and the significance of the occurrence of sterile animals among the F₁ is discussed.     

Action of streptomycin and dihydrostreptomycin on human chromosoms in vitro

Summary Comparative investigations concerning the action of streptomycin (SM) and dihydrostreptomycin (DHSM) on human chromosomes in vitro revealed a strong effectivity of SM in inducing achromatic lesions (AL) while DHSM is ineffective in this respect. Chromatid breaks (B) and isochromatid breaks (B) are not induced by the two streptomycins. Chromatid translocations (RB') were found only 3 times in all concentrations tested. The intrachromosomal distribution of the streptomycin-induced AL is very similar to the distribution of AL induced with the alkylating agent Chinon I and the thioxanthon derivative Miracil D. The view is discussed that the appearance of achromatic lesions cannot be interpreted as an indicator for a mutagenic activity of an agent.