Maternal sex chromosome non-disjunction: evidence for X chromosome-specific risk factors

Human trisomy is attributable to many different mechanisms and the relative importance of each mechanism is highly chromosome specific. The association between altered recombination and maternal non-disjunction is well documented: reductions in recombination have been reported for maternal meiosis I (MI) errors involving chromosomes 15, 16, 18 and 21 and increased recombination has been reported for meiosis II (MII) errors involving chromosome 21. We therefore investigated maternal X chromosome non-disjunction, to determine whether the effects of recombination are unique to the X chromosome or similar to any of the autosomes thus far studied. We genotyped 45 47,XXX females and 95 47,XXY males of maternal origin. Our results demonstrate that 49% arose during MI, 29% during MII and 16% were postzygotic events; a further 7% were meiotic but could not be assigned as either MI or MII because of recombination at the centromere. Among the MI cases, a majority (56%) had no detectable transitions and so absent recombination is an important factor for X chromosome non-disjunction. However, similar to trisomy 15 and unlike trisomy 21, we observed a significant increase in the mean maternal age of transitional MI errors compared with nullitransitional cases. In our studies of MII errors, recombination appeared normal and there was no obvious effect of maternal age, distinguishing our results from MII non-disjunction of chromosomes 18 or 21. Thus, surprisingly, the risk factors associated with both MI and MII non-disjunction appear to be different for virtually every chromosome that has been adequately studied.     

Non-disjunction of chromosome 18

A sample of 100 trisomy 18 conceptuses analysed separately and together with a published sample of 61 conceptuses confirms that an error in maternal meiosis II (MII) is the most frequent cause of non-disjunction for chromosome 18. This is unlike all other human trisomies that have been studied, which show a higher frequency in maternal meiosis I (MI). Maternal MI trisomy 18 shows a low frequency of recombination in proximal p and medial q, but not the reduction in proximal q observed in chromosome 21 MI non-disjunction. Maternal MII non-disjunction does not fit the entanglement model that predicts increased recombination, especially near the centromere. Whereas recent data on MII trisomy 21 show the predicted increase in recombination proximally, maternal MII trisomy 18 has non-significantly reduced recombination. Therefore, chromosome-specific factors must complicate the simple model of susceptible chiasma distributions interacting with age-dependent deterioration of the meiotic mechanism. For chromosome 18, 30% of tetrads are nullichiasmate in maternal MI non-disjunction, but nullichiasmates are not observed in maternal MII non-disjunction. Chiasma distributions from normal chromosome 18 meioses provide no evidence for normal disjunction from nullichiasmate tetrads. We extend this study to examine the remaining autosomes and find no evidence for normal disjunction from nullichiasmate tetrads generally.      

Non-disjunction of chromosome 13

We performed a molecular study with 21 microsatellites on a sample of 82 trisomy 13 conceptuses, the largest number of cases studied to date. The parental origin was determined in every case and in 89% the extra chromosome 13 was of maternal origin with an almost equal number of maternal MI and MII errors. The latter finding is unique among human autosomal trisomies, where maternal MI (trisomies 15, 16, 21, 22) or MII (trisomy 18) errors dominate. Of the nine paternally derived cases five were of MII origin but none arose from MI errors. There was some evidence for elevated maternal age in cases with maternal meiotic origin for liveborn infants. Maternal and paternal ages were elevated in cases with paternal meiotic origin. This is in contrast to results from a similar study of non-disjunction of trisomy 21 where paternal but not maternal age was elevated. We find clear evidence for reduced recombination in both maternal MI and MII errors and the former is associated with a significant number of tetrads (33%) that are nullichiasmate, which do not appear to be a feature of normal chromosome 13 meiosis. This study supports the evidence for subtle chromosome-specific influences on the mechanisms that determine non-disjunction of human chromosomes, consistent with the diversity of findings for other trisomies.     

Maternal meiosis I non-disjunction of chromosome 15: dependence of the maternal age effect on level of recombination

Non-disjoined chromosomes 15 from 115 cases of uniparental disomy (ascertained through Prader-Willi syndrome) and 13 cases of trisomy of maternal origin were densely typed for microsatellite loci spanning chromosome 15q. Of these 128 cases a total of 97 meiosis I (MI) errors, 19 meiosis II (MII) errors and 12 mitotic errors were identified. The genetic length of a map created from the MI errors was 101 cM, as compared with a maternal length of 137 cM based on CEPH controls. No significant differences were detected in the distribution of recombination events along the chromosome arm and a reduction was seen for most of the chromosome 15 intervals examined. It was estimated that 21% of tetrads leading to MI non-disjunction were achiasmate, which may account for most or all of the reduction in recombination noted. The mean age of mothers of cases involving MI errors which showed no transitions from heterodisomy to isodisomy was significantly lower (32.7) than cases showing one or more observable transitions (36.3) (P < 0.003, t -test). However, even among chiasmate pairs the highest mean maternal age was seen for multiple exchange tetrads. Chromosome- specific differences in maternal age effects may be related to the normal distribution of exchanges (and their individual susceptibilities) for each chromosome. However, they may also reflect the presence of multiple factors which act to ensure normal segregation, each affected by maternal age in a different way and varying in importance for each chromosome.      

Reduced recombination in maternal meiosis coupled with non-disjunction at meiosis II leading to recurrent 47,XXX

We determined the meiotic origin and the stage of non-disjunction of the extra X chromosomes in two sisters with 47,XXX chromosomal complements. Segregation of the X chromosomes in all family members was analyzed using X-linked short tandem repeat polymorphic (STRP) markers. Densitometric analysis of two STRP markers confirmed that both sisters had three copies of the X chromosome and the extra X chromosomes were maternally derived. Both sisters did not share the same maternal homologue suggesting that the recurrent trisomy is non-homologous X chromosome-specific. Haplotype analysis demonstrated a reduction to homozygosity for markers examined, covering most of the length of the X chromosomes in both sisters. These findings suggested that the extra X chromosomes have derived from meiotic II non-disjunction following a nullitransitional meiosis I (MI). A lack of recombination in the X chromosomes of both sisters suggests a possible maternal genetic defect leading to an erratic recombination at MI. This information may contribute to further understanding of mechanisms leading to X chromosome non-disjunction and may assist in counseling of families with this chromosomal rearrangement.     

Aberrant recombination and the origin of Klinefelter syndrome

Trisomy is the most commonly identified chromosome abnormality in humans, occurring in at least 4% of all clinically recognized pregnancies; it is the leading known cause of pregnancy loss and of mental retardation. Over the past decade, molecular studies have demonstrated that most human trisomies originate from errors at maternal meiosis I. However, Klinefelter syndrome is a notable exception, as nearly one-half of all cases derive from paternal non-disjunction. In this review, the data on the origin of sex chromosome trisomies are summarized, focusing on the 47,XXY condition. Additionally, the results of recent genetic mapping studies are reviewed that have led to the identification of the first molecular correlate of autosomal and sex chromosome non-disjunction; i.e. altered levels and positioning of meiotic recombinational events.     

Aberrant interchromosomal exchanges are the predominant cause of the 22q11.2 deletion

Chromosome 22q11.2 deletions are found in almost 90% of patients with DiGeorge/velocardiofacial syndrome (DGS/VCFS). Large, chromosome-specific low copy repeats (LCRs), flanking and within the deletion interval, are presumed to lead to misalignment and aberrant recombination in meiosis resulting in this frequent microdeletion syndrome. We traced the grandparental origin of regions flanking de novo 3 Mb deletions in 20 informative three-generation families. Haplotype reconstruction showed an unexpectedly high number of proximal interchromosomal exchanges between homologs, occurring in 19/20 families. Instead, the normal chromosome 22 in these probands showed interchromosomal exchanges in 2/15 informative meioses, a rate consistent with the genetic distance. Meiotic exchanges, visualized as MLH1 foci, localize to the distal long arm of chromosome 22 in 75% of human spermatocytes tested, also reflecting the genetic map. Additionally, we found no effect of proband gender or parental age on the crossover frequency. Parental origin studies in 65 de novo 3 Mb deletions (including these 20 patients) demonstrated no bias. Unlike Williams syndrome, we found no chromosomal inversions flanked by LCRs in 22 sets of parents of 22q11 deleted patients, or in eight non-deleted patients with a DGS/VCFS phenotype using FISH. Our data are consistent with significant aberrant interchromosomal exchange events during meiosis I in the proximal region of the affected chromosome 22 as the likely etiology for the deletion. This type of exchange occurs more often than is described for deletions of chromosomes 7q11, 15q11, 17p11 and 17q11, implying a difference in the meiotic behavior of chromosome 22.     

Ageing-associated aberration in meiosis of oocytes from senescence-accelerated mice

BACKGROUND: The senescence-accelerated mouse (SAM) has been shown to exhibit ageing-associated mitochondrial dysfunction and oxidative stress, and early decline in fertility. METHODS: We compared meiotic progression of germinal vesicle oocytes between young (2-3 months) and old (10-14 months) SAM mice using triple immunostaining and fluorescence microscopy as well as Pol-Scope imaging. RESULTS: At 8-9 h of in-vitro maturation (IVM), most young SAM oocytes (86%, 32/37) were at meiosis I (MI) stage, with chromosomes aligned in the mid-region of MI spindles, whereas disrupted MI spindles and/or chromosome misalignments (45%, 18/40) and a few oocytes (20%, 8/40) with abnormal MII spindles were found in old SAM oocytes. At 15-17 h of IVM, old SAM oocytes, despite errors at MI stage, extruded a first polar body at an incidence of 88% (n = 85), which did not differ from that (92%, n = 106) of young SAM oocytes. However, oocytes from old SAM (64%, 32/50) showed aberrant MII, with chromosome misalignment and dispersal, in contrast to normal MII in most young SAM oocytes (87%, 65/75), showing chromosome alignment at the metaphase plate of MII spindles. Moreover, Pol-Scope imaging non-invasively detected disrupted or absent visible spindles and possibly aberrant chromosome alignment. CONCLUSIONS: Spindle disruption and/or chromosome misalignments at both MI and MII are associated with maternal ageing in the SAM mouse. Our findings also suggest that meiotic division lacks a competent checkpoint for spindle integrity and chromosome alignment during reproductive ageing-associated oocyte senescence.     

Molecular studies of non-disjunction in trisomy 16.

The origin of the additional chromosome in 26 trisomy 16 spontaneous abortions was studied using DNA probes for chromosome 16, including a probe for centromeric alpha sequences. We were able to determine the parent and meiotic stage of origin of trisomy in 22 cases, with all being attributable to maternal meiosis I non-disjunction. Furthermore, in each of the remaining four cases the results were compatible with this origin. Thus, it is likely that the high incidence of trisomy 16 results from an abnormal process acting at maternal meiosis I which more frequently involves chromosome 16 than other similar sized chromosomes. In studies of recombination, we found little evidence for an association between reduced or absent recombination and chromosome 16 non-disjunction; however, we were unable to rule out an effect of hyperrecombination.     

The oxidizing agent tertiary butyl hydroperoxide induces disturbances in spindle organization, c-meiosis, and aneuploidy in mouse oocytes

It has been recently proposed that a concomitant generationof oxidative stress of oocytes with increasing maternal agemay be a major factor responsible for the age-related increasein aneuploid conceptions. As a preliminary step in the testingof this hypothesis, we need to confirm that oxidative stressin itself can induce errors in chromosome segregation. In orderto achieve this goal, germinal vesicle (GV)-stage mouse oocytesfrom unstimulated ICR and (C57BLxCBA) F₁ hybrid female micewere matured in vitro for 9 h for metaphase I (MI) oocytes or16 h for metaphase II (MII) oocytes in the presence of varyingconcentrations of the oxidizing agent tertiary-butyl hydroperoxide(tBH). MII oocytes from (C57BLxCBA) F₁ hybrid mice were fixedand C-banded for karyotyping analysis. MI and MII oocytes fromICR mice were fixed and stained with the DNAfluorescent probe4',6-diamidino-2-phenylindole (DAPI) to detect abnormalitiesin chromosomal distribution. Meiosis I and meiosis II spindlesfrom ICR mice were visualized by confocal immunofluorescencemicroscopy. Data from these experiments demonstrate that in-vitroexposure of mouse oocytes to tBH during meiosis I reduces thelength (pole-to-pole distance) and width (diameter at the equatorof the spindle) of meiosis I and meiosis II spindles. This reductionis associated with an increase in the percentage of oocytesshowing chromosome scattering and clumping on the MII plate,and of aneuploidy (hyperhaploidy) in MII oocytes. However, tBHat the concentrations used in the present study has only a minimalnegative effect on the frequency of meiotic maturation. Theseresults suggest that oxidative stress during meiotic maturationin vitro may induce chromosomal errors that are undetectablein the living oocyte and whose developmental consequences maybecome manifest after fertilization. aneuploidy/meiosis/mouse oxidative stress/spindle/tertiary butyl hydroperoxide     

Discontinuities and unsynapsed regions in meiotic chromosomes have a cis effect on meiotic recombination patterns in normal human males

During meiosis, homologous chromosome pairing is essential for subsequent meiotic recombination (crossover). Discontinuous chromosome regions (gaps) or unsynapsed chromosome regions (splits) in the synaptonemal complex (SC) indicate anomalies in chromosome synapsis. Recently developed immunofluorescence techniques (using antibodies against SC proteins and the crossover-associated MLH1 protein) were combined with fluorescence in situ hybridization (using centromere-specific DNA probes) to identify bivalents with gaps/splits and to examine the effect of gaps/splits on meiotic recombination patterns during the pachytene stage of meiotic prophase from three normal human males. Gaps were observed only in the heterochromatic regions of chromosomes 9 and 1, with 9q gaps accounting for 90% of these events. Most splits were also found in chromosomes 9 and 1, with 58% of splits occurring on 9q. Gaps and splits significantly altered the distribution of MLH1 foci on the SC. On gapped SC 9q, the frequency of MLH1 foci was decreased compared with controls, and single 9q crossovers tended toward a more distal distribution. Furthermore, the larger the gap the more distal the location of the MLH1 focus closest to the q arm's telomere. MLH1 foci on split SC 9 had distributions similar to those of gapped SC 9; however, splits did not change the frequencies of MLH1 foci on SC 9. This is the first demonstration that gaps and splits have an effect on meiotic recombination in humans.     

Meiotic recombination and germ cell aneuploidy

Data on human trisomic conceptuses suggest that the extra chromosome commonly has a maternal origin, and the amount and position of crossing-over on nondisjoined chromosomes is commonly altered. These observations may provide important clues to the etiology of human germ cell aneuploidy, especially in regard to evaluating whether environmental factors play a role. There is concordance of effects of environmental agents on fungi, plants, and animals, which suggests that the overall process of meiosis is well conserved and that chemical and physical agents can affect meiotic recombination, leading to aneuploidy. It seems likely that meiosis in humans will fit the general pattern of meiosis in terms of sensitivity to radiation and chemicals. Thus studies on other organisms provide some insight into the procedures necessary for obtaining useful human data. For example, frequencies of spontaneous meiotic recombination are not uniform per physical length in Drosophila, and different regions of a chromosome respond differently to treatment. Treatments that relieve constraints on the distribution of meiotic exchange, without changing greatly the overall frequency of exchange, may increase the number of univalents and give the impression that there are chromosome- specific responses. Recombination studies that monitor one or a few relatively short genetic regions may also give a false impression of the effects of a treatment on recombination. In addition, meiotic mutants in Saccharomyces and Drosophila highlight a number of processes that are important for production of an exchange event and the utility of that event in the proper segregation of both homologues and sisters. They also suggest that tests for pairing at pachytene, chiasmata at diplotene, and genetic crossing-over may give different results. © 1996 Wiley-Liss, Inc.     

Origin of uniparental disomy 15 in patients with Prader-Willi or Angelman syndrome

Maternal uniparental disomy (UPD) accounts for approximately 25% of Prader-Willi patients (PWS) and paternal UPD for about 2-5% of Angelman syndrome (AS) patients. These findings and the parental origin of deletions are evidence of genomic imprinting in the cause of PWS and AS. The natural occurrence of UPD individuals allows the study of meiotic mechanisms resulting in chromosomal nondisjunction (ND). We selected patients with UPD15 from our sample of 30 PWS and 40 AS patients to study the origin of ND and the recombination along chromosome 15. These patients were analyzed with 10 microsatellites throughout the entire chromosome 15 (D15S541, D15S542, D15S11, D15S113, GABRB3, CYP19, D15S117, D15S131, D15S984, D15S115). The analysis disclosed seven heterodisomic PWS cases originating by meiosis I (MI) ND (four showed recombination and three no recombination), and one isodisomic PWS UPD15 originating by postzygotic duplication. Among the five paternal UPD15, we detected four isodisomies, three of which showed homozigosity for all markers, corresponding to a mitotic error, and one case originating from a paternal MII ND. Our results indicate that besides maternal MI and MII ND, paternal ND occurs when a PWS UPD15 patient originates from mitotic duplication of the maternal chromosome 15. ND events in AS are mainly due to mitotic errors, but paternal MII ND can occur and give origin to an AS UPD15 individual by two different mechanisms: rescue of a trisomic fetus or fertilization of a nullisomic egg with the disomic sperm, and in this case paternal and maternal ND are necessary.     

The origin of 47, XXY and 47, XXX aneuploidy: heterogeneous mechanisms and role of aberrant recombination

We Investigated the parent and cell division of origin of theadditional sex chromosome in 142 males with a 47,XXY constitutionand 50 females with a 47,XXX constitution. In 66 of the 47,XXYmales the additional chromosome was paternal In origin and in76 It was maternal in origin, while among the 47, XXX femalesonly 5 had an additional paternal X chromosome, the remaining45 having an additional maternal chromosome. Among the 107 maternallyderived aneuploids for whom It was possible to determine thecell division of origin, 73 were the result of a mat Ml error,24 the result of a mat Mil error and 10 the result of a postzygotlc mitotlc (PZM) error Involving the maternal X chromosome.Among those In which the non-disjunction was attributable toan error at the first melotlc division (Ml) we observed threedifferent mechanisms of origin. Approximately 30% were associatedwith complete absence of recombination (nullichiasmate); approximately24% were associated with a normal number of recombinant eventsbut an abnormal distribution of exchanges (perturbed recombination),while approximately 45% were associated with a normal numberand distribution of recombinant events (normochiasmate). Non-disjunctiondue to an error at the second melotic division (Mll) was associatedwith a slight reduction in the total number of recomblnant eventsand an abnormal distribution of exchanges. Thus of the fourdifferent meiotic mechanisms of origin, three were associatedwith an abnormal number and/or distribution of exchange events.There was no evidence of an Increased paternal age in the aneuploidsof paternal origin. Among those of maternal origin there wasa significantly increased maternal age In the aneuplofds resultingfrom an error of mat Ml, but this was restricted to the nullichiasmateand the normochiasmate sub groups. The maternal ages of theMl perturbed recombination sub group, the Mil and the PZM groupwere not increased.     

A role for centromere pairing in meiotic chromosome segregation

In meiosis I, exchanges provide a connection between homologous chromosome pairs that facilitates their proper attachment to the meiotic spindle. In many eukaryotes, homologous chromosomes that fail to become linked by exchanges exhibit elevated levels of meiotic errors, but they do not segregate randomly, demonstrating that mechanisms beyond exchange can promote proper meiosis I segregation. The experiments described here demonstrate the existence of a meiotic centromere pairing mechanism in budding yeast. This centromere pairing mediates the meiosis I bipolar spindle attachment of nonexchange chromosome pairs and likely plays the same role for all homologous chromosome pairs.     

Local and sex-specific biases in crossover vs. noncrossover outcomes at meiotic recombination hot spots in mice

Meiotic recombination initiated by programmed double-strand breaks (DSBs) yields two types of interhomolog recombination products, crossovers and noncrossovers, but what determines whether a DSB will yield a crossover or noncrossover is not understood. In this study, we analyzed the influence of sex and chromosomal location on mammalian recombination outcomes by constructing fine-scale recombination maps in both males and females at two mouse hot spots located in different regions of the same chromosome. These include the most comprehensive maps of recombination hot spots in oocytes to date. One hot spot, located centrally on chromosome 1, behaved similarly in male and female meiosis: Crossovers and noncrossovers formed at comparable levels and ratios in both sexes. In contrast, at a distal hot spot, crossovers were recovered only in males even though noncrossovers were obtained at similar frequencies in both sexes. These findings reveal an example of extreme sex-specific bias in recombination outcome. We further found that estimates of relative DSB levels are surprisingly poor predictors of relative crossover frequencies between hot spots in males. Our results demonstrate that the outcome of mammalian meiotic recombination can be biased, that this bias can vary depending on location and cellular context, and that DSB frequency is not the only determinant of crossover frequency.     

Origin of uniparental disomy 15 in patients with Prader‐Willi or Angelman syndrome

Maternal uniparental disomy (UPD) accounts for ∼25% of Prader‐Willi patients (PWS) and paternal UPD for about 2–5% of Angelman syndrome (AS) patients. These findings and the parental origin of deletions are evidence of genomic imprinting in the cause of PWS and AS. The natural occurrence of UPD individuals allows the study of meiotic mechanisms resulting in chromosomal nondisjunction (ND). We selected patients with UPD15 from our sample of 30 PWS and 40 AS patients to study the origin of ND and the recombination along chromosome 15. These patients were analyzed with 10 microsatellites throughout the entire chromosome 15 (D15S541, D15S542, D15S11, D15S113, GABRB3, CYP19, D15S117, D15S131, D15S984, D15S115). The analysis disclosed seven heterodisomic PWS cases originating by meiosis I (MI) ND (four showed recombination and three no recombination), and one isodisomic PWS UPD15 originating by postzygotic duplication. Among the five paternal UPD15, we detected four isodisomies, three of which showed homozigosity for all markers, corresponding to a mitotic error, and one case originating from a paternal MII ND. Our results indicate that besides maternal MI and MII ND, paternal ND occurs when a PWS UPD15 patient originates from mitotic duplication of the maternal chromosome 15. ND events in AS are mainly due to mitotic errors, but paternal MII ND can occur and give origin to an AS UPD15 individual by two different mechanisms: rescue of a trisomic fetus or fertilization of a nullisomic egg with the disomic sperm, and in this case paternal and maternal ND are necessary. Am. J. Med. Genet. 94:249–253, 2000. © 2000 Wiley‐Liss, Inc.     

Meiosis induced by inactivation of Pat1 kinase proceeds with aberrant nuclear positioning of centromeres in the fission yeast Schizosaccharomyces pombe

Nuclear organization of chromosomes proceeds with significant changes during meiosis. In the fission yeast Schizosaccharomyces pombe, centromeres are clustered at the spindle-pole body (SPB) during the mitotic cell cycle; however, during meiotic prophase telomeres become clustered to the SPB and centromeres dissociate from the SPB. We followed the movement of telomeres, centromeres and sister chromatids in living S. pombe cells that were induced to meiosis by inactivation of Pat1 kinase (a key negative regulator of meiosis). Time-course observation in living cells determined the temporal order of DNA synthesis, telomere clustering, centromere separation and meiotic chromosome segregation. When meiosis was induced by Pat1 inactivation at the G1 phase of mitosis, telomeres clustered to the SPB as per normal meiosis, but in most cells the centromeres remained partially associated with the SPB. When meiosis was initiated at the G2 phase by Pat1 inactivation, both telomeres and centromeres retained their mitotic nuclear positions in the majority of cells. These results indicate that the progression of meiosis induced by Pat1 inactivation is aberrant from normal meiosis in some events. As Pat1 inactivation is often useful to induce S. pombe cells synchronously into meiosis, the temporal order of chromosomal events determined here will provide landmarks for the progression of meiosis downstream the Pat1 inactivation.     

Premature separation of sister chromatids in human male meiosis

BACKGROUND: Meiotic disorders result in meiotic arrest and aneuploid spermatozoa,leading to male infertility, spontaneous abortions or affectedoffspring. We carried out meiotic studies in an infertile maleto detect meiotic nondisjunction mechanisms leading to aneuploidyin spermatogenesis. METHODS AND RESULTS: Meiotic studies were performed in testicular and semen samplesfrom a 38-year-old teratozoospermic male with normal somatickaryotype and a history of spontaneous abortions. We analysed262 spermatocytes (69 pachytene cells, 106 metaphases I (MI),87 metaphases II (MII)) by multiplex-fluorescence in situ hybridizationand 20 193 spermatozoa by multicolour-FISH with probes for chromosomes9, 10, 15, 21, X and Y. The results indicate high increase of21 and XY disomies, as well as diploidy in both spermatocytesat MII and spermatozoa (P < 0.0001). Achiasmate segregationof sex chromosomes was found in 3.4% of spermatocytes II, precededby early-dissociated XY bivalent at MI (41.5% of cells). Wealso detected premature separation of sister chromatids (PSSC)in 4.6% of MII. CONCLUSIONS: This individual presents high levels of numerical abnormalitiesin germ cells, caused by two different nondisjunction mechanismsduring meiosis I. To our knowledge, this work represents thefirst time that PSSC has been demonstrated in human male germcells.     

Non-disjunction of chromosome 21 in maternal meiosis I: evidence for a maternal age-dependent mechanism involving reduced recombination

Over 300 cases of trisomy 21 were analyzed to characterize thecauses of maternal non-disjunction and to evaluate the basisfor maternal age-dependent trisomy 21. We confirmed the observationthat recombination along 21q is reduced among non-disjoinedchromosomes 21 and further demonstrated that the alterationsin recombination are restricted to meiosis I origin. Analysisof the crossover distribution Indicates that reduction In recombinationis not due simply to failure of pairing and/or absence of recombinationIn a proportion of cases. Instead, we observed an increase inboth zero- and one-exchange events among trisomy 21-generatingmeloses suggesting that an overall reduction In recombinationmay be the underlying cause of non-disjunction. Lastly, we observedan age-related reduction In recombination among the melosisI cases, with older women having less recombination along 21qthan younger women. Thus, reduced genetic recombination maybe responsible, at least in part, for the association betweenadvancing maternal age and trisomy 21.