Familial D/E translocation

Summary A familial D/E translocation is described. The proposita, a girl with features of the trisomy-E₁ syndrome, had 47 chromosomes. The extra chromosome was a small acrocentric one. Her mother and little brother had 46 chromosomes, and showed a missing chromosome in the groups D and E, and an extra chromosome in the groups C and G. The former had a subterminal centromere. The latter could not be dinstinguished morphologically from the other small acrocentrics.The morphology and the autoradiographic analysis of the chromosomes concerned in the translocation, indicated that it was a (17q+; 14q-) translocation. It could also be proved that the extra chromosome of the proposita represented mainly a partial trisomy 14. The father and little sister of the patient had a normal karyotype.A comparison of the karyotypes, found in the children of the present family and in cases of D/E-translocation reported in the literature, pointed to a high frequency of non-disjunction in D/E-translocation carriers. As a possible explanation, a convergent orientation of a trivalent at metaphase I of meiosis is proposed.     

Maternal origin of extra marker chromosome 1Q31.1-qter and 13pter-q12.12 in a child with dysmorhic features

Maternal origin of extra marker chromosome Iq31.l-qter and 13pter-q12.12 in a child with dysmorphic features: We describe a twenty-days-old female child with dysmorphic features and chromosomal analysis with GTG-banding revealed an extra marker chromosome. Fluorescence in situ hybridization (FISH) study of extra marker chromosome confirmed to be maternal der(13) chromosome, contained 1q31.1-qter and 13pter-q11 chromosomal material and resulted from a maternal balanced translocation t(1;13)(q31.1; q12.12). The child had the majority of trisomy 1q clinical features: dysmorphic features, micropthalmia, high arched palate, long philthrum, micrognathia, hypertelorism, low set ears, short sternum, overlapping fingers, valgus of wrists, right knee and ankle joints were in flexion contractures. This is the first case of trisomy 1q with an extra marker chromosome which also contained chromosome 13pter-q12.12 material.     

Partial D 15 trisomy. A case and general review.

A profoundly retarded girl with cyanotic congenital heart disease, recurrent myoclonic seizures, an external strabismus and not very unusual facial features was found to have a 47, XX chromosome complement. The extra chromosome is a small G-size chromosome with small projections extending from the ends of the long arms and no satellites observed on the short arms. By Geimsa-trypsin banding techniques this aberrant chromosome appears to be a partially deleted D 15 chromosome. A comparison of the clinical features is made with those described in the nine other reported specifically identifies cases of 'partial trisomy 15'. For clinical and chromosome morphology reasons, this was felt not to be trisomy in the G group nor an extra Y. We speculate that the long arm projections are satellites derived from a ring-type intrachromosomal translocation.     

Valproic acid and lamotrigine treatment during pregnancy. The risk of chromosomal abnormality

A baby born to an epileptic mother had dysmorphological features associated with 47,XXX karyotype. The mother had been treated with valproic acid (1800mg per day) and lamotrigine (100mg per day) throughout pregnancy. Dysmorphological features detected in baby were intrauterine growth retardation, hypertelorism, flattened nasal bridge, low set malformed auriculas, micrognathia, very small an bow-shaped mouth with thin upper lip, cleft palate, arachnodactyly, camptodactyly, secundum atrial septal defect, bilateral hammer toes and decreased creases on the soles. At 6 months old she showed motor retardation. The molecular analysis of parents revealed that extra X chromosome was inherited from the mother. In this case whether the dysmorphological features and 47,XXX karyotype were caused by lamotrigine and valproic acid treatment during pregnancy or coincidence is in question.     

Mauritius type black rats with peculiar karyotypes derived from robertsonian fission of small metacentrics

All seventeen black rats collected from Mauritius Island were characterized by having many extra small acrocentric autosomes. Their basic karyotype was of Oceanian type, because of the presence of the large metacentric M₁ and M₂ pairs, but chromosome numbers in 13 specimens among them were 42, those of 3 specimens 43, and those of the remaining one specimen 44. Although the Oceanian type rat had 2 small acrocentric autosomes (pair no. 13), 16 Mauritius rats had 10 small acrocentrics, and the remaining one had 8 small acrocentrics. Comparative karyotype analysis between Oceanian and Mauritius type rats showed that the extra small acrocentrics found in Mauritius rats were due to Robertsonian fission of small metacentric pairs no. 14 and 18 of the original Oceanian type rat. Only one rat with 8 small acrocentrics showed the heteromorphic pair no. 18 consisting of one metacentric and two acrocentrics. The large metacentric M₁ chromosome in 13 of 17 rats examined showed homologous pair, but two of them were heteromorphic by involving one metacentric M₁ and two acrocentrics. In the remaining two rats M₁ chromosome was not observed, but acrocentric pairs no. 4 and 7 were included. These acrocentrics were also suggested to be originated from Robertsonian fission of the large metacentric M₁ chromosome. Robertsonian fission seemed to be one of the important mechanism found in karyotype evolution.     

Valproic acid and lamotrigine treatment during pregnancy: The risk of chromosomal abnormality

A baby born to an epileptic mother had dysmorphological features associated with 47,XXX karyotype. The mother had been treated with valproic acid (1800 mg per day) and lamotrigine (100 mg per day) throughout pregnancy. Dysmorphological features detected in baby were intrauterine growth retardation, hypertelorism, flattened nasal bridge, low set malformed auriculas, micrognathia, very small an bow-shaped mouth with thin upper lip, cleft palate, arachnodactyly, camptodactyly, secundum atrial septal defect, bilateral hammer toes and decreased creases on the soles. At 6 months old she showed motor retardation. The molecular analysis of parents revealed that extra X chromosome was inherited from the mother. In this case whether the dysmorphological features and 47,XXX karyotype were caused by lamotrigine and valproic acid treatment during pregnancy or coincidence is in question.     

Partial tetrasomy 9(9pter to 9q2101) due to an extra iso-dicentric chromosome.

A 3-year-old boy with partial No. 9 tetrasomy is described. The patient showed markedly retarded physical and mental development as well as multiple congenital anomalies. Routine chromosome analysis revealed an extra C-group chromosome. It had a pronounced secondary constriction at the proximal part of its long arm. Based on studies by a variety of banding techniques, the extra chromosome was identified to be an iso-dicentric No. 9 chromosome with inactivation of one of the two centromeres, the karyotype being 47,XY, + DIC (9)(Q2101). The value of BrdUrd treatment was emphasized in the detection of a very small piece of euchromatin within a long stretch of constitutive heterochromatin.     

Partial trisomy 13 as a result of de novo (6p;13q) translocation

Summary A newborn infant with the clinical features of the Patau syndrome was found to have excess chromosome 13 material present as a tandem translocation involving the short arm of chromosome 6 and the long arm of an extra chromosome 13: 46,XY,t(6;13)(p24;q12). The major part of the long arm of the extra chromosome 13 was attached linearly (tandem translocation) to the short arm of chromosome 6. Both parents were phenotypically and karyotypically normal.     

Aneuhaploids and tetrasomics in rice (Oryza sativa L.) derived from anther culture of trisomics.

Eight types of aneuhaploids (Aneuhaplo 4, 5, 6, 8, 9, 10, 11, and 12) and eight types of tetrasomics (Tetraplo 4, 5, 6, 7, 8, 9, 10, and 12) of rice have been obtained from anther culture of trisomics. This paper reports the plant morphology of these aneuploids and their chromosome behavior at metaphase I. Aneuhaploids for different chromosomes are distinguishable from each other and are morphologically similar to the parental trisomics, suggesting that the extra chromosome has similar genetic effects on plant morphology at the haploid level as at the diploid level. Similarly, tetrasomics with different extra chromosomes are distinguishable from each other and are similar morphologically to the parental trisomic. However, stronger changes in morphological characters were observed in tetrasomics compared with trisomics having the same extra chromosome, as a result of a dosage effect of the extra chromosomes. Comparing plant size between aneuhaploid, tetrasomic, and trisomic with the same extra chromosome, it was shown that the trisomic was the largest, the tetrasomic was of medium size, and the aneuhaploid was the smallest, except for those plants with an extra chromosome 8 in which plant size is dramatically decreased in both the aneuhaploid and the tetrasomic. At metaphase I, aneuhaploids showed chromosome configurations of 1 II + 11 I and 13 I. The frequency of the 1 II + 11 I configuration is higher than 70%, indicating that homologous chromosomes in aneuhaploids tend to stay associated in meiosis. Intragenome chromosome pairing (2 II + 9 I), so called secondary association, was observed in the aneuhaploid for chromosome 5. Tetrasomic plants showed 5 kinds of chromosome configurations: 1 IV + 11 II, 1 III + 11 II + 1 I, 13 II, 12 II + 2 I, and 11 II + 4 I. A chromosome configuration of 13 II was often observed in tetrasomics with shorter extra chromosomes and a chromosome configuration of 1 IV + 11 II was often observed in tetrasomics with longer extra chromosomes. Aneuhaploids had complete seed sterility. Tetrasomics showed very poor pollen fertility and complete seed sterility, except for a few shriveled seeds that were observed in Tetraplo 6 and 9. This is the first report in rice where many aneuhaploids and tetrasomics have been characterized. This information will help to further unravel rice aneuploidy and cytogenetics. The aneuploids obtained here will be very useful tools for the study of genetics and breeding in rice.     

A new case of a severe clinical phenotype of the cat-eye syndrome

A new case of severe clinical phenotype of the cat-eye syndrome: We report on a female infant with severe clinical phenotype of Cat-Eye Syndrome (CES). At birth, she had respiratory distress and marked hypotonia. Physical examination showed major craniofacial anomalies including microcephaly, bilateral total absence of the external ears, hypertelorism, bilateral ocular coloboma of iris and micrognathia. In addition, she had anal stenosis, a patent ductus arteriosus and intra- and extra- hepatic biliary atresia. She deteriorated with the development of bradycardia. She died at age one month of cardiac failure. Cytogenetic analysis of the proband showed an extra de novo small bisatelllited marker chromosome in all cells examined. Molecular cytogenetic analysis with fluorescence in situ hybridization (FISH) identified the marker as a CES chromosome. Thus, the patient's karyotype was: 47, XX, +idic(22)(pter-->q11.2 ::q11.2-->pter). The duplication breakpoints giving rise to the CES chromosome were distal to the DiGeorge Syndrome (DGS) locus 22q11.2. The marker could be classed as a type 11 symmetrical (10). According to a recent review of CES literature (1) only 41 % of the CES patients have the combination of iris coloboma, anal anomalies and preauricular anomalies. Almost 60% are hard to recognize by their phenotype alone. Only twelve patients showed a severe clinical phenotype leading to the death of the child. This phenotypic variability increases the difficulties of genetic counseling.     

额外小染色体的分子细胞遗传学研究

本文应用’H标记的7.3kb的rRNA基因探针进行染色体原位杂交技术,并结合多种细胞遗传学技术对一个额外小染色体的家族进行分析研究。在该家族调查的三代人中有8名成员带有相同的额外小染色体,携带者表型均正常。结果证实该额外小染色体是D组或G组染色体的短臂。并就其额外小染色体的起源,遗传效应及生育等问题进行了扼要的讨论。     

FISH Variants with D15Z1

We present our experience with cross-hybridization of D15Z1, used in combination with D15S10, D15S11 or SNRPN, in 109 clinical cases referred for Angelman syndrome (AS), Prader-Willi syndrome (PWS), for autism to rule out duplication of 15q11.2, or to identify structural chromosome abnormalities thought to involve chromosome 15. Nine cases with normal karyotypes studied with at least one of these probe mixtures showed an extra signal with D15Z1 on a chromosome 14. One case showed absence of the D15Z1 signal from 15p and one case showed an extra signal with D15Z1 on both chromosome 14s. Sixteen cases from this series had structural abnormalities, which included ten cases with supernumerary markers, three of which had a D15Z1 signal on a chromosome 14. The remaining cases did not have an extra signal on chromosome 14, but included rearrangements between Y and 15, 15 and 19, and a r(15), all with breakpoints in 15p11.1 or p11.2. Of the three cases with a supernumerary marker and an extra D15Z1 signal on a chromosome 14, one was a maternally derived marker, while the variant 14 was paternal in origin. The other two markers were de novo. The high frequency of variant 14 in cases with supernumerary markers (30%) was not significant by Chi-square analysis compared to the overall frequency in 109 cases of 11.9%. The overall frequency is consistent with a previous report by Stergianou et al. (1993). We can now add that a false-negative result may occur slightly less than 1% of the time. The chance that both chromosome 14 homologs will be positive for D15Z1 is theoretically about 1 in 300. If associated with an abnormal phenotype, the possibility of uniparental disomy should be ruled out.     

Hairy cell leukemia: an analysis of the chromosomes of 26 patients.

We studied the chromosomes from 26 patients with hairy cell leukemia (HCL) to ascertain the frequency and types of consistent chromosomal abnormalities. Samples from 21 patients were obtained from peripheral blood cultures grown 24 and 48 h without phytohemagglutinin, or from bone marrow samples. Two male patients had similar, consistent abnormalities; one patient's karyotype was 46, X, +12; that of the second was 46, X, +C marker. In the latter case, the distal long arm of the C marker most closely resembled chromosome No. 12 from band q14 to q terminal, but the short arm and proximal long arm were of undetermined origin. Both karyotypes lacked the Y chromosome. Nine of the 21 patients had abnormalities in single cells. One patient had, in one sample, a single abnormal cell with an extra No. 3 and an extra No. 12 (48, XY, +3, +12), and in a later sample, a second cell of poor morphology which also could have been trisomic for No. 12. Another patient had one cell with an unusually bright short arm, as well as two cells, with different abnormalities, both involving the short arm of chromosome No. 1. The two patients with consistent chromosome abnormalities had rapidly progressive disease in spite of splenectomy, and their clinical course from the time of diagnosis was relatively short (5 and 7 months, respectively).     

Observations which indicate heterochromatinization of an extra chromosome in the salivary gland cells of Drosophila hybrids

Salivary gland cells of Drosophila mulleri/D. arizonensis aneuploid male hybrids carrying 3 microchromosomes exhibited morphological features which indicate heterochromatinization of one of the small polytene chromosomes. The process apparently changes the chromosome surface producing a coating with a net-like structure and a strong affinity for lacto-acetic orcein. The possibility of a dosage compensatory mechanism operating to counteract the effect of the extra chromosome is discussed on the basis of previous data which indicated that the microchromosomes of these species have ribosomal cistrons and are controlled by regulatory mechanisms especially evident in hybrids.     

Executive dysfunction and the relation with behavioral problems in children with 47,XXY and 47,XXX

Neuroimaging studies have shown that having an extra X chromosome is associated with abnormal structure and function of brain areas in the frontal lobe, which is crucially involved in executive functioning. However, there is little of knowledge of the type and severity of executive dysfunction, and the impact on emotional and behavioral problems. The present study aims to provide in this. In total, 40 children (23 boys with 47,XXY and 17 girls with 47,XXX) with an extra X chromosome and 100 non‐clinical controls (47 boys and 53 girls) participated in the study. The participants were 9–18 years old. Processing speed and executive functioning were assessed using the Amsterdam Neuropsychological Testbattery (ANT) and the Dysexecutive Questionnaire (DEX). Problems in emotional and behavioral functioning were assessed with the Childhood Behavior Checklist (CBCL). Children with an extra X chromosome showed deficits in inhibition, mental flexibility, sustained attention and visual working memory. Parental report showed high levels of everyday manifestations of executive dysfunction. More severe inhibition difficulties were associated with higher levels of thought problems, aggression and rule breaking behavior. Boys and girls with an extra X chromosome could not be differentiated based on severity of executive dysfunction, however, girls had lower information processing speed than boys. These findings suggest that executive dysfunction may be part of the phenotype of children with an extra X chromosome, impacting the ability to function adequately in everyday life. Furthermore, children with impairments in inhibition may have more problems in regulating their thinking, emotions and behavior.     

Karyotypic diversity in polyploid gibel carp,Carassius auratus gibelio Bloch

Polyploid gibel carp, Carassius auratus gibelio, is an excellent model system for evolutionary genetics owing to its specific genetic background and reproductive modes. Comparative karyotype studies were performed in three cultured clones, one artificially manipulated group, and one mated group between two clones. Both the clones A and P had 156 chromosomes in their karyotypes, with 36 metacentric, 54 submetacentric, 36 subtelocentric, 24 acrocentric, and six small chromosomes. The karyotype of clone D contained 162 chromosomes, with 42 metacentric, 54 submetacentric, 36 subtelocentric, 24 acrocentric, and six small chromosomes. All the three clones had six small chromosomes in common. Group G, being originated from the clone D by artificial manipulation, showed supernumerary microchromosomes or chromosomal fragments, in addition to the normal chromosome complement that was identical to the clone D. The offspring from mating between clones D and A had 159 chromosomes. Comparing with the clone A, the DA offspring showed three extra metacentric chromosomes. In addition, variable RAPD fingerprint patterns and unusual SCAR marker inheritance were, respectively, detected among individuals of artificial group G and in the mated DA offspring. Both the chromosome and molecular findings suggest that genome reshuffling might have occurred by manipulation or mating of the clones.     

Use of repetitive DNA for diagnosis of chromosomal rearrangements

Summary We have used two repeated DNA fragments (3.4 and 2.1 kb) released from Y chromosome DNA by digestion with the restriction endonuclease Hae III to analyze potential Y chromosome/autosome translocations. Two female patients were studied who each had an abnormal chromosome 22 with extra quinacrine fluorescent material on the short arm. The origin of the 22p+ chromosomes was uncertain after standard cytologic examinations. Analysis of one patient's DNA with the Y-specific repeated DNA probes revealed the presence of both the 3.4 and 2.1 kb Y-specific fragments. Thus, in this patient, the additional material was from the Y chromosome. Analysis of the second patient's DNA for Y-specific repeated DNA was negative, indicating that the extra chromosomal segment was not from the long arm of the Y chromosome. These two cases demonstrate that repeated DNA can distinguish between similar appearing aberrant chromosomes and may be useful in karyotypic and prenatal diagnosis.     

Trisomics from triploid-diploid crosses in self-incompatible Lycopersicum peruvianum

Summary An attempt was carried out to produce trisomics of the wild tomato L. peruvianum, to define their essential features, and to detect relationships between trisomy and the expression of self-compatibility.Triploid-diploid crosses in L. peruvianum yielded nearly 40% aneuploids. Of these, 18% were single trisomics, and the rest had 2, 3 and 4 extra chromosomes. Almost all the trisomics occurred in crosses where the triploid was used as female parent. Vigour and fertility of trisomics were not much different from those of disomics, and morphologically they were very similar.The extra chromosome was identified in three self-compatible trisomic plants through somatic and pachytene chromosome morphology. One of these plants was trisomic for chromosome 1, while the other two were trisomic for chromosome 3. In these trisomics a positive correlation was found between chromosome length and trivalent formation, but no relationship between chromosome length and frequency of laggards was observed.A series of test-crosses revealed that the capacity of the trisomics to produce seed upon selfing always resulted from alterations of the incompatibility phenotype of the style and not from competitive interaction in the pollen. Progeny analyses showed that the self-compatibility features of the trisomics were not transmitted from one generation to the next. The implications of these findings are discussed.This work has been supported by a contract between the European Communities and the CNEN. This publication is contribution no. 1458 from the Biology Division of the European Communities and contribution no. 472 from the Divisione Applicazioni delle Radiazioni del CNEN.     

A boy with small supernumerary marker chromosome X identified by FISH

Marker or ring X chromosomes are frequently seen in Ullrich-Turner Syndrome with 46,X,r(X) karyotype, but only 8 children were reported with an extra marker X chromosome in at least some of their cell lines, we describe a 5 years old male patient who is mosaic (17%) for a cell line with an extra ring shaped marker X chromosome in addition to a normal 46,XY cell line. He had mild motor mental retardation, a dysmorphic face, dysplastic ears, high arched palate, cryptorchidism and brachydactyly. G-banding showed 46,XY[83]/47,XY,+r?[17] karyotype. NOR banding revealed no satellite region but its centromere was intact in C-banding. By fluorescent in situ hybridization (FISH) technique, dual X/Y alpha-satellite probes were used to detect the origin of ring shaped marker chromosome and 17% of his cells had two X chromosome signals due to marker X; hybridization with X chromosome inactivation center (XIST) specific probe revealed the absence of the locus on the ring chromosome. In this report, clinical features of our patient are compared with previously reported cases and the cytogenetic and molecular cytogenetic techniques used to detect origin of marker chromosome are discussed.     

Down's syndrome in the male. Reproductive pathology and meiotic studies

Studies on testicular histology and meiosis were carried out by the use of light and electron microscopy in an 18-year-old Down's syndrome male in an attempt to follow the fate of the extra chromosome 21 and to evaluate the effects of this condition on spermatogenesis and the reproductive functions. The histological changes in the testes corresponded to spermatogenic arrest. Electron microscopic whole-mount spreadings of meiotic cells in the pachytene stage showed that in most nuclei an extra chromosome 21 was not detectable. Only in a small number of nuclei, univalents or trivalents with segmental pairing structures of an extra chromosome could be discovered. In contrast, the great majority of (C-banded) diakinesis figures showed the presence of a supernumerary G (no. 21) chromosome. The absence of a traceable extra chromosome 21 in most pachytene cells is explained by the assumption that it is intimately connected with and hidden in the sex vesicle, whose complex structure does not allow the identification of single elements. Strong support for this assumption is seen (a) in the general tendency of narrow spatial association of unpaired segments with the XY complex and (b) in close structural similarities occurring between univalents or nonsynapsed segments of trivalents and the nonpaired segments of the sex chromosomes. It is suggested that the association or connection of an extra chromosome with the XY complex during pachytene interferes with the phenomenon of X inactivation. In animal systems such abnormal interference is related with spermatogenic breakdown and, in a general way, with male hybrid type sterility. So far, the range of sterility vs. fertility in cases of male Down's syndrome is not yet fully clear, but it appears that impairment of fertility, and sterility are most frequent. If so, it is proposed that the effect of the trisomy 21 condition on spermatogenesis (and fertility) is a consequence of the behavior of the extra chromosome in the meiotic prophase.