Inherited Interstitial Duplications of Proximal 15q: Genotype-Phenotype Correlations

We present the cytogenetic, molecular cytogenetic, and molecular genetic results on 20 unrelated patients with an interstitial duplication of the proximal long arm of chromosome 15. Multiple probes showed that the Prader-Willi/Angelman critical region (PWACR) was included in the duplication in 4/20 patients, each ascertained with developmental delay. The duplication was also found in two affected but not in three unaffected sibs of one of these patients. All four probands had inherited their duplication from their mothers, three of whom were also affected. Two of the affected mothers also carried a maternally inherited duplication, whereas the duplication in the unaffected mother and in an unaffected grandmother was paternal in origin, raising the possibility of a parental-origin effect. The PWACR was not duplicated in the remaining 16 patients, of whom 4 were referred with developmental delay. In the 14 families for which parental samples were available, the duplication was inherited with equal frequency from a phenotypically normal parent, mother or father. Comparative genomic hybridization undertaken on two patients suggested that proximal 15q outside the PWACR was the origin of the duplicated material. The use of PWACR probes discriminates between a large group of duplications of no apparent clinical significance and a smaller group, in which a maternally derived PWACR duplication is consistently associated with developmental delay and speech difficulties but not with overt features of either Prader-Willi syndrome or Angelman syndrome.     

Autism or atypical autism in maternally but not paternally derived proximal 15q duplication.

Duplications of proximal 15q have been found in individuals with autistic disorder (AD) and varying degrees of mental retardation. Often these abnormalities take the form of a supernumerary inverted duplicated chromosome 15, more properly described as an isodicentric chromosome 15, or idic(15). However, intrachromosomal duplications also have been reported. In a few cases, unaffected mothers, as well as their affected children, carry the same duplications. During the course of the genotyping of trios of affected probands with AD and their parents, at the positional candidate locus D15S122, an intrachromosomal duplication of proximal 15q was detected by microsatellite analysis in a phenotypically normal mother. Microsatellite and methylation analyses of the pedigree in the following report show that, among three children, the two with autism or atypical autism have maternal inheritance of a 15q11-q13 duplication whereas the third child, who is unaffected, did not inherit this duplication. Their mother's 15q11-q13 duplication arose de novo from her father's chromosomes 15. This finding documents, for the first time, the significance of parental origin for duplications of 15q11-q13. In this family, paternal inheritance leads to a normal phenotype, and maternal inheritance leads to autism or atypical autism.     

Rescue from the Abnormal Oocyte Maternal-Effect Lethality by Abo Heterochromatin in Drosophila Melanogaster

The euchromatic maternal-effect mutation abnormal oocyte (abo), of Drosophila melanogaster interacts with regions of heterochromatin known as ABO, which reside on the X, Y and second chromosomes. Here, we show that survival of progeny from abo females depends in part upon the maternal dosage of ABO heterochromatin. A comparison was made of the recovery of genotypically identical progeny from abo mothers bearing sex chromosomes of various ABO contents. The results show that the recovery of daughters was decreased if mothers were ABO-/ABO-. However, no decrease was observed if mothers were ABO+/ABO-. In addition, the survival of daughters was greater when they received an ABO-X chromosome from an ABO-/ABO+ mother rather than the father. We suggest that these results reflect a complementation or interaction between the ABO-deficient X and the ABO heterochromatin in the maternal genome. This proposed interaction could occur early in oogenesis in the mother or prior to completion of meiosis I in the fertilized egg. To determine if zygotic dosage of ABO heterochromatin might also be important at very early stages of embryogenesis, we examined the timing of zygotic rescue by paternally donated ABO heterochromatin using a second mutation, paternal loss (pal). Homozygous pal males produce progeny which lose paternally derived chromosomes during the early zygotic divisions. Zygotes that have lost a paternal sex chromosome in a fraction of their nuclei will be mosaic for the amount of ABO heterochromatin. By monitoring the recovery of pal-induced mosaics from abo and abo+ females, we could determine the temporal and spatial requirements for ABO function. Results show that the survival of progeny from the abo maternal-effect lethality was increased if ABO heterochromatin was present prior to the pal-induced loss event. Analysis of mosaic patterns did not reveal a specific lethal focus. We conclude from these results that ABO heterochromatin serves its vital function prior to completion of the early cleavage divisions in progeny of abo mothers.     

Uniparental heterodisomy for chromosome 14 in a phenotypically abnormal familial balanced 13/14 Robertsonian translocation carrier.

A 9-year-old mentally retarded girl with multiple congenital anomalies was found to carry a balanced 13/14 Robertsonian translocation [45,XX,t(13q14q)] which was also present in her father. Her mother carried a balanced reciprocal translocation between chromosomes 1 and 14 [46,XX,t(1;14) (q32;q32)]. Both of her parents were phenotypically normal. Molecular studies were carried out to determine the parental origin of chromosomes 1, 13, and 14 in the patient. Using probes for D14S13 and D14S22, we could show that the patient inherited both chromosomes 14 from her father and none from her mother. Similar studies using probes for chromosomes 1 (D1S76) and 13 (D13S37) loci showed the presence of both maternal and paternal alleles in the patient. Our findings indicate that paternal uniparental heterodisomy for chromosome 14 most likely accounts for the phenotypic abnormalities observed in our patient. It is suggested that uniparental disomy may be the basis for abnormal development in at least some phenotypically abnormal familial balanced-translocation carriers.     

Duplication of 7p12.1-p13, including GRB10 and IGFBP1, in a mother and daughter with features of Silver-Russell syndrome

Silver-Russell syndrome (SRS) has been associated with maternal uniparental disomy (UPD) of chromosome 7 in approximately 10% of cases, suggesting that at least one imprinted gene on chromosome 7 is involved in the pathogenesis of the disease. We report a proximal 7p interstitial inverted duplication in a mother and daughter both of whom have features of SRS, including marked short stature, low birth weight, facial asymmetry and 5th finger clinodactyly. Fluorescence in situ hybridisation (FISH) with YAC probes enabled delineation of the duplicated region to 7p12.1-p13. This region of proximal chromosome 7 is known to be homologous to an imprinted region in the mouse chromosome 11 and contains the growth-related genes GRB10 (growth factor receptor-bound protein 10), EGFR (epidermal growth factor receptor) and IGFBP1 (insulin-like growth factor binding protein 1), all of which have been suggested as candidate genes for SRS. Molecular analysis showed that the duplication in both mother and daughter spanned a distance of approximately 10 cM and included GRB10 and IGFBP1 but not EGFR. The de novo duplication in the proband's mother was shown to be of paternal origin. In order to test the hypothesis that sub-microscopic duplications of 7p, whether maternal or paternal in origin, are responsible for at least some cases of SRS, we screened a further eight patients referred to our laboratory for SRS. None were found to have duplications of either GRB10 or IGFBP1. The hypothesis that sub-microscopic duplications including GRB10 and IGFBP1 is a cause of SRS remains a possibility and warrants further investigation. Importantly, in contrast to current thinking, our results suggest that imprinted genes may not underlie the SRS phenotype, and we propose an alternative hypothesis to explain the occurrence of maternal UPD 7 seen in some cases of SRS.     

Partial trisomy of chromosome 21 by maternal translocation t(15;21) (q26.2; q21)]

A balanced reciprocal translocation, t(15;21) (q262;q21) was observed in the mother and maternal grandfather of two patients. The propositus, who received the abnormal chromosome 15 from his mother, is trisomic for the distal part of chromosome 21, and his phenotype is that of classical trisomy 21. His sister, who is trisomic for the proximal part of 21q, is slightly retarded but developmentally normal otherwise.     

Two doses of the paternal Tme gene do not compensate the lethality of the Thp deletion

The hairpin-tail (Thp) deletion in chromosome 17 is lethal when it is inherited from the mother, whereas heterozygotes with Thp deletion that is paternal in origin are viable. The lethal effect of maternal Thp is due to a deficiency of the Tme gene that is located in the Thp-deleted region. In this article we describe analysis of the viability of mice with tertiary trisomy of chromosome 17, Ts(17(16]43H, with different doses of the paternal and maternal Tme alleles. We demonstrate that the presence of an additional copy of the region with the Tme gene in the female gamete entirely compensates maternal Thp lethality. We failed to compensate the absence of the Tme gene from the chromosome of maternal derivation by two doses of Tme derived from the father. Thus evidence was obtained indicating that there are significant differences between the activities of the paternal and maternal alleles of the Tme gene due to chromosome imprinting.     

46,XX, der(15),t(Y;15)(q12;p11) karyotype in an azoospermic male

We report on a Yq/15p translocation in a 23-year-old infertile male referred for Klinefelter Syndrome testing, who had azoospermia and bilateral small testes. Hormonal studies revealed hypergonadotropic hypogonadism. Conventional cytogenetic procedures giemsa trypsin giemsa (GTG) and high resolution banding (HRB) and molecular cytogenetic techniques Fluorescence In Situ Hybridization (FISH) performed on high-resolution lymphocyte chromosomes revealed the karyotype 46,XX, t(Y;15)(q12;p11). SRY-gene was confirmed to be present by classical Polymerase Chain Reaction (PCR) methods. His father carried de novo derivative chromosome 15 [45,X, t(Y;15)(q12;p11)] and was fertile; the karyotype of the father using G-band technique confirmed a reciprocal balanced translocation between chromosome Y and 15. In the proband, the der (15) has been inherited from the father because the mother had a normal karyotype (46,XX). In the proband, the der (15) could have produced genetic imbalance leading to unbalanced robertson translocation between chromosome Y and 15, which might have resulted in azoospermia and infertility in the proband. The paternal translocation might have lead to formation of imbalanced ova, which might be resulted infertility in the proband. Sister''s karyotypes was normal (46,XX) while his brother was not analyzed.     

A candidate model for angelman syndrome in the mouse

Prader-Willi syndrome (PWS) and Angelman syndrome (AS) are well-recognized examples of imprinting in humans. They occur most commonly with paternal and maternal 15q11-13 deletions, but also with maternal and paternal disomy. Both syndromes have also occurred more rarely in association with smaller deletions seemingly causing abnormal imprinting. A putative mouse model of PWS, occurring with maternal duplication (partial maternal disomy) for the homologous region, has been described in a previous paper but, although a second imprinting effect that could have provided a mouse model of AS was found, it appeared to be associated with a slightly different region of the chromosome. Here, we provide evidence that the same region is in fact involved and further demonstrate that animals with paternal duplication for the region exhibit characteristics of AS patients. A mouse model of AS is, therefore, strongly indicated. Received: 15 December 1996 / Accepted: 31 January 1997     

The Albino-Deletion Complex of the Mouse: Molecular Mapping of Deletion Breakpoints That Define Regions Necessary for Development of the Embryonic and Extraembryonic Ectoderm

Previous complementation analyses with five (c11DSD, c5FR60Hg, c2YPSj, c4FR60Hd, c6H) of the mouse albino deletions defined at least two genes on chromosome 7, known as eed and exed, which are necessary for development of the embryonic and extraembryonic ectoderm, respectively, of early postimplantation embryos. The region of chromosome 7 containing these two genes has now been accessed at the molecular level by cloning two of the deletion breakpoint-fusion fragments. The c2YPSj breakpoints were isolated by cloning an EcoRI fragment containing a copy of an albino region-specific repeat unique to c2YPSj DNA. Similarly, the c11DSD breakpoints were isolated by cloning a c11DSD EcoRI fragment detected by a unique-sequence probe mapping proximal to the albino-coat-color locus. By mapping the cloned breakpoints relative to the remaining three deletions, the c11DSD distal breakpoint was found to define the distal limit of the region containing eed, whereas the c2YPSj and c6H distal breakpoints were found to define the proximal and distal limits, respectively, of the region containing exed.     

The imprinted mouse Igf2r/Air cluster--a model maternal imprinting system

Every diploid organism inherits a complete chromosome set from its father and mother in addition to the sex chromosomes, so that all autosomal genes are available in two copies. For most genes, both copies are expressed without preference. Imprinted genes, however, are expressed depending on their parental origin, being active on the paternal or maternal allele only. To date 73 imprinted genes are known in mouse (www.mgu.har.mrc.ac.uk/research/imprinting), 37 show paternal expression while 36 show maternal expression, indicating no bias for imprinting to occur in one sex or the other. Therefore, two different parental-specific imprinting systems may have evolved in mammals, acting specifically in the paternal or maternal gamete. Similarities and differences between the two imprinting systems will be reviewed, with specific reference to the role of non-coding RNAs and chromatin modifications. The mouse Igf2r/Air cluster is presented as a model of the maternal imprinting system.     

Aneuploidy induction in mice: construction and use of a tester stock with 100% nondisjunction

A new murine tester stock for primary nondisjunction incorporates three genetically marked Robertsonian translocations with tribrachial homology (TBH): Rb(6.15)1Ald, Rb(4.6)2Bnr, and Rb(4.15)4Rma. The resultant tricentromeric meiotic configuration leads to 100% aneuploid gametes, but the TBH stock can be maintained by intercrossing, through the complementation of nullisomic and disomic gametes. The only neonatal survivors from tescrosses to wild type come from complementation of aneuploid gametes and genetic tests allow wild type gains or losses of Chromosomes 4, 6, and 15 to be distinguished. Alternatively, cytogenetic examination allows products of wild type chromosome gain, with one metacentric, to be separated from chromosome loss with two metacentrics. A pilot study, with 0-2 Gy X-irradiation of oocytes at diakinesis, revealed twelve examples of chromosome loss in wild type gametes but none of chromosome gain and thus provided no evidence for the induction of nondisjunction.     

Partial trisomy for the long arm of chromosome 7 due to familial balanced translocation

Summary A partial trisomy for the distal segment of the long arm of chromosome 7 (bands q32qter) was observed in a severely retarded child with somatic and CNS anomalies. The phenotypically normal father and paternal grandmother had a balanced reciprocal translocation between the long arm of a chromosome 2 and the long arm of a chromosome 7: 46,XX-XY,t(2;7) (q37;q32). The clinical features of the child at birth and at the ages of 5 months and 2 years are compared with those previously reported in cases of partial trisomy 7q.     

The euchromatic 9p+ polymorphism is a locus-specific amplification caused by repeated copies of a small DNA segment mapping within 9p12

A large duplication involving the proximal euchromatic region of chromosome 9p was detected by conventional cytogenetics in a healthy 33-year-old woman and in two unrelated foetuses; both of them received the rearrangement from their healthy father. The duplicated segment was R(RBG) and C(CBG)-negative and G(GTG)-positive and was also positive for a 9-specific painting probe. It was preliminarily interpreted as a pathological quantitative change of the genome in the foetuses. FISH analyses allowed us to characterise the chromosome boundaries of this polymorphism, being identified by the RP11-15E1 BAC clone, proximally, and by the RP11-402N8 clone, distally, both probes falling within the 9p12 region. The contiguous, distally, RP11-916H19 probe was not included in the amplification, and may represent the discriminating genetic locus between chromosome polymorphism and chromosome mutation. The 9p12 amplification was approximately 12, 7 and 8 Mb in the three different families and was stable through generations. Our observations confirm the already provided evidence that proximal 9p duplications represent a benign euchromatic polymorphism. However, we demonstrated that these variants are not a simple duplication of the region 9p11.2-p13.1, as already suggested, but that they result from a many-fold amplification of a segment mapping within 9p12. These results provide important insights both in the genetic counselling and in the prenatal diagnosis of rare euchromatic chromosome variants and in understanding the architecture of the human genome.     

Inheritance of Mitochondrial DNA and Plasmids in the Ascomycetous Fungus, Epichloe Typhina

We analyzed the inheritance of mitochondrial DNA (mtDNA) species in matings of the grass symbiont Epichloe typhina. Eighty progeny were analyzed from a cross in which the maternal (stromal) parent possessed three linear plasmids, designated Callan-a (7.5 kb), Aubonne-a (2.1 kb) and Bergell (2.0 kb), and the paternal parent had one plasmid, Aubonne-b (2.1 kb). Maternal transmission of all plasmids was observed in 76 progeny; two progeny possessed Bergell and Callan-a, but had the maternal Aubonne-a replaced with the related paternal plasmid Aubonne-b; two progeny lacked Callan-a, but had the other two maternal plasmids. A total of 34 progeny were analyzed from four other matings, including a reciprocal pair, and in each progeny the plasmid transmission was maternal. The inheritance of mitochondrial genomes in all progeny was analyzed by profiles of restriction endonuclease-cleaved mtDNA. In most progeny the profiles closely resembled those of the maternal parents, but some progeny had nonparental mtDNA profiles that suggested recombination of mitochondrial genomes. These results indicate that the fertilized stroma of E. typhina is initially heteroplasmic, permitting parental mitochondria to fuse and their genomes to recombine.     

Partial trisomy 7q and monosomy 13q in a child with disorder of sex development: Phenotypic and genotypic findings

Terminal 7q duplication and terminal 13q deletion are two conditions with variable phenotypes including microcephaly, thumb a-/hypoplasia, cortical dysplasia, microphtalmia, intellectual disability and dysmorphic features. We describe a boy born to a mother with a reciprocal t (7;13) who combines both a terminal 7q33-qter duplication and terminal 13q33-qter deletion through the inheritance of a derivative chromosome 13 (der (13)). The patient presented with developmental delay, facial and non-facial dysmorphic features, hypertonia, genital abnormality and skeletal malformation but no thumb a-/hypoplasia or microphtalmia. Knowing the exact breakpoints of his chromosomal aberrations using high resolution array CGH (aCGH) and comparison of his phenotypes with those of 24 and 59 previously published cases of 7q duplication and 13q deletion, respectively, allow us to further narrow the size of the proposed critical regions for microcephaly, thumb a-/hypoplasia and hypo/hypertonia on chromosome 13.     

Partial isodisomy for maternal chromosome 7 and short stature in an individual with a mutation at the COL1A2 locus.

Uniparental disomy for chromosome 7 has been described previously in two individuals with cystic fibrosis. Here, we describe a third case that was discovered because the proband was homozygous for a mutation in the COL1A2 gene for type I procollagen, although his mother was heterozygous and his father did not have the mutation. Phenotypically, the proband was similar to the two previously reported cases with uniparental disomy for chromosome 7, in that he was short in stature and growth retarded. Paternity was assessed with five polymorphic markers. Chromosome 7 inheritance in the proband was analyzed using 12 polymorphic markers distributed along the entire chromosome. Similar analysis of the proband's two brothers established the phase of the alleles at the various loci, assuming minimal recombination. The proband inherited only maternal alleles at five loci and was homozygous at all loci examined, except one. He was heterozygous for an RFLP at the IGBP-1 locus at 7p13-p12. The results suggest that the isodisomy was not complete because of a recombination event involving the proximal short arms of two maternal chromosomes. In addition, the phenotype of proportional dwarfism in the proband suggests imprinting of one or more growth-related genes on chromosome 7.     

Trisomy 21 Down syndrome

Summary In a series of 374 families with Down syndrome progeny, structural chromosome rearrangements were detected in the parents of six children with regular trisomy. The aberrations were reciprocal translocations and inversions. In all three informative families, the parent who transmitted the extra chromosome was not the one with the structural rearrangement. Among the three non-informative families there was one in which both parents carried different reciprocal translocations. In two other families a chromosome aberration was detected: a triple X mother and a father with a Philadelphia chromosome. Omitting the four parents with possible biased asccrtainment, 0.4% had a chromosome rearrangement. When the parents with constitutional chromosome aberrations and those with mosaicism, described previously, are combined, the frequency of chromosomally abnormal parents lies between 1.9% and 3.2%. When correlated with parental transmission of the extra chromosome, mosaicism rather than structural rearrangements appears to be of ctiologic significance.     

No evidence for a paternal interchromosomal effect from analysis of the origin of nondisjunction in Down syndrome patients with concomitant familial chromosome rearrangements.

The parental origin of the extra chromosome 21 was determined with DNA polymorphisms in seven families in whom the proband and one of the parents carried an additional chromosome rearrangement (balanced translocation or pericentric inversion) not involving chromosome 21. The balanced rearrangement was inherited from the mother in two families and from the father in five families, whereas the additional chromosome 21 was derived from the mother in all seven families. These findings are not in agreement with the hypothesis of a paternal interchromosomal effect. The latter would imply that a balanced rearrangement in the father would favor nondisjunction during meiosis in the germ cells.