A jumping translocation (5p;15q), (8q;15q), and (12q;15q) (author's transl)]

Three balanced karyotypes (5p;15q), (8q;15q), and (12q;15q) were found simultaneously in a child with the Willi-Prader syndrome. The hypothesis is presented of a "jumping# translocation by affinity of telomeric and interstitial palindromes. The relationship between the Willi-Prader syndrome and a juxtacentric anomaly of the long arm of chromosome 15 is discussed.     

Exceptional complex chromosomal rearrangement and microdeletions at the 4q22.3q23 and 14q31.1q31.3 regions in a patient with azoospermia

In this report we describe the first patient ever found to have azoospermia in association with both exceptional complex chromosomal rearrangements and microdeletions at two translocation breakpoints. A 36-year-old male who had been suffering from male factor infertility was admitted to our clinic. The patient also displayed mild dysmorphia. An analysis of the patient's semen revealed azoospermia. GTG banding revealed the presence of an exceptional complex chromosomal rearrangement involving chromosomes 1, 4, 10 and 14. Using subtelomeric FISH analysis, the patient's karyotype was designated as 46,XY,t(1;10)(q43q44;q21q26.1)(CEB108/T7+,D1S3738-;10PTEL006+,D10S2290+, D1S3738+), ins(14;4) (q31.3;q23q33)(D14S1420+; D4S3359+, D4S2930+). Array-CGH analysis revealed two microdeletions at the 4q22.3q23 and 14q31.1q31.3 chromosomal regions. We suggest that microdeletions at the 4q22.3q23 and 14q31.1q31.3 chromosomal regions associated with both an exceptional complex chromosomal rearrangement and the Homo sapiens chromosome 4 open reading frame 37 (C4orf37) gene located at the 4q22.3q23 region might be associated with male factor infertility.     

Translocation (13q21q)

Summary A (13q21q) translocation was found in an infant with Down's syndrome. The 17-year-old mother and the grandmother carried the translocation 45,XX,t(13;21)(p12;q11). The great grandparents had normal karyotypes. Fluorescence marker studies suggested that the translocation originated in the great grandmother. The hypothesis was supported by satellite association studies which showed a significant excess of 13–21 and 13–15 associations in the great grandmother.     

Macrophage C1q: characterization of a membrane form of C1q and of multimers of C1q subunits

It has been shown recently that C1q, a subcomponent of the first component of the classical complement pathway, is synthesized by macrophages and that endogenous C1q is detectable on the macrophage membrane. In this report, we demonstrate that membrane-associated C1q, which contains the A, B, and C chains of C1q, is structurally distinct from fluid-phase C1q in that the B chain of the membrane species is approximately 1000 m.w. less than its fluid-phase counterpart. By using biosynthetically ([3H]proline) labeled C1q from guinea pig peritoneal macrophages, we found that the membrane form of C1q is derived from already secreted C1q. The demonstration of a distinct membrane form of C1q supports earlier functional studies which implicated C1q as a membrane-associated molecule with receptor functions for those molecules which also interact with fluid-phase C1q, such as polyanions, immune complexes, and bacteria. Furthermore, we show that, in the vicinity of macrophages, C1q is very susceptible to oxidation manifested by the formation of disulfide bonds. By SDS-PAGE (nonreduced and reduced), we demonstrate the existence of disulfide-linked multimers (180,000 m.w., 360,000 m.w.) which are composed of the A, B, and C chains of C1q.     

Isochromosome not translocation in trisomy 21q21q

Summary After primary trisomy, de novo 21q21q trisomy is the most frequent chromosomal aberration responsible for Down syndrome. This rearrangement is more commonly referred to as a Robertsonian translocation or centric fusion product than as an isochromosome, e.g., t(21q;21q) instead of i(21q); however, in practice, it has not so far proved possible to distinguish between these alternatives. The aim of this work was to establish which of the two alternatives is acceptable.     

Localization of subtelomeric sequences of human chromosomes 1q, 11p, 13q, and 16q in the higher primates

Relative phylogenetic divergence of the members of the Pongidae family has been based on genetic evidence. The recent isolation of subtelomeric probes specific for human (HSA) chromosomes 1q, 11p, 13q, and 16q has prompted us to cross hybridize these to the chromosomes of the chimpanzee (Pan troglodytes, PTR), gorilla (Gorilla gorilla, GGO), and orangutan (Pongo pygmaeus, PPY) to search for their equivalent locations in the great apes. Hybridization signals to the 1q subtelomeric DNA sequence probe were observed at the termini of human (HSA) 1q, PTR 1q, GGO 1q, PPY 1q, while the fluorescent signals to the 11p subtelomeric DNA sequence probe were observed at the termini of HSA 11p, PTR 9p, GGO 9p, and PPY 8p. Fluorescent signals to the 13q subtelomeric DNA sequence probe were observed at the termini of HSA 13q, PTR 14q, GGO 14q, and PPY 14q, and positive signals to the 16p subtelomeric DNA sequence probe were observed at the termini of HSA 16q, PTR 18q, GGO 17q, and PPY 19q. These findings apparently suggest sequence homology of these DNA families in the ape chromosomes. Obviously, analogous subtelomeric sequences exist in apes' chromosomes that apparently have been conserved through the course of differentiation of the hominoid species. This revised version was published online in July 2006 with corrections to the Cover Date.     

Sperm rates of 7q11.23, 15q11q13 and 22q11.2 deletions and duplications: a FISH approach

Genomic disorders are human diseases caused by meiotic chromosomal rearrangements of unstable regions flanked by Low Copy Repeats (LCRs). LCRs act as substrates for Non-Allelic Homologous Recombination (NAHR) leading to deletions and duplications. The aim of this study was to assess the basal frequency of deletions and duplications of the 7q11.23, 15q11-q13 and 22q11.2 regions in spermatozoa from control donors to check differences in the susceptibility to generate anomalies and to assess the contribution of intra- and inter-chromatid NAHR events. Semen samples from ten control donors were processed by FISH. A customized combination of probes was used to discriminate among normal, deleted and duplicated sperm genotypes. A minimum of 10,000 sperm were assessed per sample and region. There were no differences in the mean frequency of deletions and duplications (del + dup) among the 7q11.23, 15q11-q13 and 22q11.2 regions (frequency ± SEM, 0.37 ± 0.02; 0.46 ± 0.07 and 0.27 ± 0.07%, respectively) (P = 0.122). Nevertheless, hierarchical cluster analysis reveals interindividual differences suggesting that particular haplotypes could be the main source of variability in NAHR rates. The mean frequency of deletions was not different from the mean frequency of duplications in the 7q11.23 (P = 0.202) and 15q11-q13 (P = 0.609) regions, indicating a predominant inter-chromatid NAHR. By contrast, in the 22q11.2 region the frequency of deletions slightly exceed duplications (P = 0.032), although at the individual level any donor showed differences. Altogether, our results support the inter-chromatid NAHR as the predominant mechanism involved in the generation of sperm deletions and duplications.     

Precocious puberty associated with partial trisomy 18q and monosomy 11q

We report a 10-years-old female patient with a partial trisomy 18q and monosomy 11q due to a maternal translocation. The phenotype of our proband is partially common with Jacobsen syndrome and duplication 18q but she has also some atypical anomalies such as precocious puberty, a retinal albinism and hypermetropia. Based on cytogenetics and FISH analysis, the karyotype of the proband was 46,XX,der(11)t(11;18)(q24;q13). To the best of our knowledge, this is the first report of precocious puberty associated with either dup(18q) or del(11q) syndromes.     

t(21q21q)/r[t(21q21q)] mosaic in two unrelated patients with mild stigmata of Down's syndrome

Two cases of t(21q21q)/r[t(21q21q)] mosaic in unrelated infants, 17 and 14 months old respectively are reported. The proportion of cells with the ring chromosome was 45% in the former, 80% in the latter. Both cases had mild manifestations of the Down's syndrome. The origin of this unusual mosaicism as well as the significance of the difference in the proportions of the ring chromosome in the two have been discussed.     

Partial trisomy 21 (21q21 - 21q22.2)]

An abnormal chromosome 21 is reported in a child with a phenotype strongly reminiscent of trisomy 21 syndrome. It is shown to result from duplication of the segment 21q21 leads to 21q22.2. Comparison of the phenotype with that of other partial and total trisomics shows that the characteristic features of the trisomy 21 syndrome (mongolism), the mental retardation in particular - is due to trisomy 21q22.2 and perhaps 21q22.2.     

Partial duplication 14q/deletion 2q in two sibs due to t(2;14) (q37.1;q31.2) pat

Two siblings are described with duplication 14q/deletion 2q due to a paternal translocation (2;14) (q37.1;q31.2). The first one, a boy, born at term, lived 14 days. The second one, a female foetus, was born after induced labour when the anomaly was discovered by way of amniocentesis. They both had almost identical phenotypes. From a study of the literature it is inferred that a typical asymmetric head form, low set abnormal ears, micrognathia, long upper lip, rib anomalies, camptodactyly, long fingers and contractures are prominent features of the syndrome.     

Trisomy 4q26--4qter by t(4;18)(q26;q23)mat translocation]

Partial trisomy 4q and perhaps monosomy 8qter was observed in a malformed girl, due to malsegregation of a t(4;18)(q26;q23)mat. Her phenotype was in agreement with the partial trisomy 4q syndrome, and she died 5 months after birth.     

Trisomy 11 q (q23.1 - qter) through maternal translocation t(11;22) (q23.1;q11.1). A new case]

A 4-year-old boy with partial trisomy 11q resulting from malsegregation of a maternal translocation, t(11;22)(q23.1;q11.1), exhibits the following malformations: severe mental deficiency; growth retardation and hypotonia; brachycephaly with flattened occiput and forehead; facial dysmorphia; pre-auricular fistula. These features are in good agreement with the syndrome recently described for partial trisomy 11q. The translocation appears to be identical in that in three other families already reported.     

Partial trisomy 11q syndrome (11q23.1-->11qter) due to de novo t (11q; 13q) detected by multicolor fluorescence in situ hybridisation

In this report we describe the identification of a de novo 46, XX, 13q + by multicolour fluorescence in situ hybridisation (M-FISH), as a partial distal 11q trisomy (11q23.1-->11qter). The clinical phenotype association with this distal 11q trisomy is briefly reviewed.     

Trisomy 13 with a 13q14q translocation.

A sporadic case of Patau syndrome with 46,XY,14-,t(13q14q)+ karyotype is reported in a 2-month-old child. Dermatoglyphic and cytogenetic findings of the propositus and cytogenetic study of his parents are presented.     

Del (13) (q33). Exclusion of esterase D (ESD) from 13q33 and q34]

A de novo del (13) (q33) was found in a 14-month-old boy with hypospadias. Phenotype anomalies included growth retardation, psychomotor retardation (QD = 64), microcephaly with brachycephaly, a round, flat and asymmetrical facies, a normal nose bridge, a small, pointed chin. The patient is heterozygous ESD 2-1. The gene localization may thus be excluded from bands 13q33 and q34 and assigned to bands q31 or q32, if its previous assignment to the q3 region is confirmed.     

Homozygosity for a Robertsonian translocation (13q14q) in three offspring of heterozygous parents

A family containing three homozygous carriers for a Robertsonian (13q14q) translocation, 44,XX or XY,t(13q14q),t(13q14q), is reported. Their parents are first cousins, and both are heterozygous carriers of the same (13q14q) translocation. The fertility of both the heterozygous and homozygous carriers is discussed.     

Replication timing of extremely large genes on human chromosomes 11q and 21q

Many human genes have been mapped precisely in the genome. These genes vary from a few kb to more than 1 Mb in length. Previously, we measured replication timing along the entire lengths of human chromosomes 11q and 21q at the sequence level. In the present study, we used the newest information for human chromosomes 11q and 21q to analyze the replication timing of 30 extremely large genes (>250 kb) in two human cell lines (THP-1 and Jurkat). The timing of replication differed between the 5'- and 3'-ends of each of extremely large genes on 11q and 21q, and the time interval between their replication varied among genes of different lengths. The large genes analyzed here included several tissue-specific genes associated with neural diseases and genes encoding cell adhesion molecules: some of these genes had different patterns of replication timing between the two cell lines. The amyloid precursor protein gene (APP), which is associated with familial Alzheimer's disease (AD1), showed the largest difference in timing of replication between its 5'- and 3'-ends in relation to gene length of all the large genes studied on 11q and 21q. These extremely large genes were concentrated in and around genomic regions in which replication timing switches from early to late on both 11q and 21q. The differences of replication timing between the 5'- and 3'-terminal regions of large genes may be related to the molecular mechanisms that underlie tissue-specific expression.     

Partial trisomy 10q

Summary Five cases from two nonrelated families with partial trisomy 10q due to a reciprocal translocation t(10;17)(q25;p13) and t(10;11)(q24;q23), respectively, are reported. The phenotypic findings are compared with those of 17 previously published cases; the clinical data justify the conclusion that cases with trisomy 10q show a specific syndrome of mental retardation and malformation characterized by psychomotor retardation, growth retardation, hypotonia, high forehead, flat face, fine and arched eyebrows, antimongoloid slant of the eyes, narrow palpebral fissures, hypertelorism, short nose, bowshaped mouth, short neck, (kypho)scoliosis, and in some cases microcephaly.