Localization of the human erbB-2 gene on normal and rearranged chromosomes 17 to bands q12-21.32

Through the use of a cDNA probe, the human erbB-2 gene was localized by in situ hybridization of normal human chromosomes at 17q11-q21. In situ hybridization of chromosomes derived from fibroblasts carrying a constitutional 15;17t(q22.3;q11.21) translocation showed that the erbB-2 gene was relocated on the rearranged chromosome 15. These results as well as grain localization on prophase chromosomes locate the erbB-2 gene at 17q12-q21.32. This localization may facilitate the search for human malignancies with chromosome changes involving the erbB-2 gene.     

Sister chromatid exchange analysis of the 15q11 region in Prader-Willi syndrome patients

Summary Prader-Willi syndrome (PWS) is a sporadic disorder in which about half of cases have a 15q12 deletion. Although a small number of cases have other rearrangements involving 15q12, the rest of the cases appear to have normal chromosomes. Clinical similarities among all these patients regardless of the karyotype strongly suggests a common etiology. To investigate the nature of this common etiology, we analyzed sister chromatid exchange (SCE) at the 15q11-13 region in 10 PWS patients with the chromosome deletion, 12 PWS patients with normal chromosomes, and 11 normal control individuals. While SCE at the q11-13 region was absent on the 15q12 deleted chromosome, the percentage of SCE on chromosome 15 at q11 was statistically higher for PWS with normal chromosomes (10.1%) compared to that for normal controls (1.9%) and the normal homologue (2.2%) in deleted patients (²=7.7982, df=2, P<0.025). The data suggest relative instability of DNA at the 15q11 region in PWS patients.     

Mosaic and non-mosaic trisomy 15q2

Two unrelated patients are presented. In the first mosaicism with normal cells and cells trisomic for the distal long arm (q2) of chromosome 15 was found. The 15q2 trisomy was due to a chromosome 14, to the long arm of which an extra 15q2 region was attached (14pter----14q32::15q22----15qter). In the second trisomy 15q2 was present as a consequence of a balanced t(7;15)(p22;q15) translocation in the mother.     

Flow cytometry of normal and abnormal pig karyotypes. Preliminary report

Flow cytometry technique was applied to normal pig chromosomes and to three different reciprocal translocations: trcp (4q-; 14p), trcp (3p+;7q-) and trcp (1q-;15q+). The rearranged chromosomes generate new peaks which seem to correspond to their relative lengths. Therefore, it is necessary to confirm these results by banding analysis and/or by hybridization on these chromosomes with probes of genes known to be localized on them.     

An unexpected recurrence of Angelman syndrome suggestive of maternal germ-line mosaicism of del(15)(q11q13) in a Finnish family

Angelman syndrome is a neuro-developmental disorder caused by genetic abnormalities affecting the maternal gene expression in the chromosome region 15q11-q13. In a study group of 45 Finnish Angelman patients, a recurrence of a del(15)(q11q13) was detected in one family. The mother's chromosomes 15 were structurally normal, whereas the patients and their unaffected brother shared an identical maternally derived haplotype outside the deletion region. These findings are suggestive of maternal germ-line mosaicism of del(15)(q11q13).     

A cytogenetic survey of 200 unclassifiable mentally retarded children with congenital anomalies and 200 normal controls

Summary A cytogenetic survey was carried out on 200 patients with mental retardation and multiple congenital anomalies, and on 200 normal adult controls. Patients with a known syndrome were excluded from the survey. Chromosome analyses were carried out on blind-coded slides using the ASG banding technique as the routine stain. After the initial analyses (at least 15 cells per person) the slides were decoded, destained and reused for C and Q band polymorphism studies.Five major chromosome abnormalities were detected in the patient group during the survey. They included three patients with de novo, apparently balanced, reciprocal translocations, karyotypes 46,XY,rcp(3;16)(q21;p12); 46,XX,rcp(5;8)(p15;q22); and 46,XX,rcp(5;12)(p11;q24); one with karyotype 47,XX,+mar and one with karyotype 46,XX,der(13),t(13;?)(q34;?). One additional patient whose karyotype in lymphocytes was 46,XX,inv(9)(p11;q13) was found to have a mosaic karyotype 46,XX,inv(9)(p11;q13)/46,XX,inv(9) (p11;q13),der(12),t(12;?)(p13;?) in cultured skin fibroblasts. None of the 200 controls had a major chromosome abnormality.From the combined results of this and previous surveys it is now apparent that about 6.2% of the unclassifiable mentally retarded patients with three or more congenital anomalies and about 0.7% of the controls reveal major chromosome abnormalities.     

A Somatic Origin of Homologous Robertsonian Translocations and Isochromosomes

One t(14q14q), three t(15q15q), two t(21q21q), and two t(22q22q) nonmosaic, apparently balanced, de novo Robertsonian translocation cases were investigated with polymorphic markers to establish the origin of the translocated chromosomes. Four cases had results indicative of an isochromosome: one t(14q14q) case with mild mental retardation and maternal uniparental disomy (UPD) for chromosome 14, one t(15q15q) case with the Prader-Willi syndrome and UPD(15), a phenotypically normal carrier of t(22q22q) with maternal UPD(22), and a phenotypically normal t(21q21q) case of paternal UPD(21). All UPD cases showed complete homozygosity throughout the involved chromosome, which is supportive of a postmeiotic origin. In the remaining four cases, maternal and paternal inheritance of the involved chromosome was found, which unambiguously implies a somatic origin. One t(15q15q) female had a child with a ring chromosome 15, which was also of probable postmeiotic origin as recombination between grandparental haplotypes had occurred prior to ring formation. UPD might be expected to result from de novo Robertsonian translocations of meiotic origin; however, all de novo homologous translocation cases, so far reported, with UPD of chromosomes 14, 15, 21, or 22 have been isochromosomes. These data provide the first direct evidence that nonmosaic Robertsonian translocations, as well as isochromosomes, are commonly the result of a mitotic exchange.     

A familial extra small marker autosome in persons with normal phenotype

The propositus was referred because of sterility and oligospermia. His karyotype was 45, XY, t(13q14q). His father was dead; his mother and the only brother, who was fertile, both had 47 chromosomes, but a normal phenotype and normal intelligence. The additional chromosome was three quarters the size of a G chromosome and had satellites on the short and long arms.     

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.     

Cloning and characterization of the complementary DNA for the B chain of normal human serum C1q

Normal human C1q is a serum glycoprotein of 460 kDa containing 18 polypeptide chains (6A, 6B, 6C) each 226 amino acids long and each containing an N-terminal collagen-like domain and a C-terminal globular domain. Two unusual forms of C1q have been described: a genetically defective form, which has a molecular mass of approximately 160 kDa and is found in the sera of homozygotes for the defect who show a marked susceptibility to immune complex related disease; a fibroblast form, shown to be synthesized and secreted, in vitro, with a molecular mass of about 800 kDa and with chains approximately 16 kDa greater than those of normal C1q. A higher than normal molecular mass form of C1q has also been described in human colostrum and a form of C1q has been claimed to represent one of the types of Fc receptor on guinea-pig macrophages. To initiate studies, at the genomic level, on these various forms of C1q, and to investigate the possible relation between the C1q genes and the procollagen genes, the complementary DNA corresponding to the B chain of normal C1q has been cloned and characterized.     

Parental Imbalances Involving Chromosomes 15q and 22q May Predispose to the Formation of De Novo Pathogenic Microdeletions and Microduplications in the Offspring

Microarray-based comparative genomic hybridization (array-CGH) led to the discovery of genetic abnormalities among patients with complex phenotype and normal karyotype. Also several apparently normal individuals have been found to be carriers of cryptic imbalances, hence the importance to perform parental investigations after the identification of a deletion/duplication in a proband. Here, we report the molecular cytogenetic characterization of two individuals in which the microdeletions/duplications present in their parents could have predisposed and facilitated the formation of de novo pathogenic different copy number variations (CNVs). In family 1, a 4-year-old girl had a de novo pathogenic 10.5 Mb duplication at 15q21.2q22.2, while her mother showed a 2.262 Mb deletion at 15q13.2q13.3; in family 2, a 9-year-old boy had a de novo 1.417 Mb deletion at 22q11.21 and a second paternal deletion of 247 Kb at 22q11.23 on the same chromosome 22. Chromosome 22 at band q11.2 and chromosome 15 at band q11q13 are considered unstable regions. We could hypothesize that 15q13.2q13.3 and 22q11.21 deletions in the two respective parents might have increased the risk of rearrangements in their children. This study highlights the difficulty to make genetic counseling and predict the phenotypic consequences in these situations.     

Biosynthesis of normal and low-molecular-mass complement component C1q by cultured human monocytes and macrophages.

High levels of low-molecular-mass complement component C1q (LMM-C1q), a haemolytically inactive form of C1q, are found in serum of individuals with inherited complete (functional) C1q deficiency and in serum of patients with systemic lupus erythematosus, whereas lower levels are present in normal serum [Hoekzema, Hannema, Swaak, Paardekooper & Hack (1985) J. Immunol. 135, 265-271]. To investigate whether LMM-C1q is a (by-)product of C1q synthesis or the result of degradation of C1q, cultures of blood monocytes and of alveolar macrophages, which secrete functional C1q, were studied. A considerable portion of C1q-like protein secreted by these cells was found to be LMM-C1q. In contrast with the C1q fragments that resulted from degradation of normal C1q during phagocytosis, culture-derived LMM-C1q appeared to be identical with LMM-C1q found in serum, as judged by sedimentation behaviour, subunit structure and recognition by poly- and mono-clonal antibodies raised against C1q. The presence of LMM-C1q in cytoplasmic organelles compatible with the Golgi apparatus and the inability to generate LMM-C1q by impeding hydroxylation and triple-helix formation of C1q further argues against degradation as its source. Monocyte cultures of homozygous probands from two families with complete functional C1q deficiency reflected the abnormalities in serum, i.e. absence of functional C1q, but increased levels of LMM-C1q. By contrast, secretion of C1q and LMM-C1q by cells from healthy individuals was clearly co-ordinate, indicating that LMM-C1q in serum may provide a unique marker of C1q synthesis in vivo.     

Post-mortem studies on two patients with 1-2 band cytogenetic deletions: 10q26----qter and r(9)(p24q34)

Two severely retarded males with unbalanced karyotypes Case 1--(45,XY,--10,--15, + der(10)t,(10; 15) (q26; q13) and Case 2--46,XY,r(9) (p24q34) died at the ages of 24 and 38 years respectively. At post-mortem, a post-ductal coarctation of the aorta and a lump kidney were found in the first case. Brain pathology was normal in the first case and apart from a smaller size, was structurally normal in the second case.     

A girl with the Prader-Willi Syndrome and Robertsonian translocation 45,XX,t(14;15)(p11;q11) which was present in three normal family members

Summary A 21-year-old girl with classical Prader-Willi Syndrome was found to have a 14;15 Robertsonian translocation—45,XX,t(14;15)(p11;q11). This type of Robertsonian translocation was not found in any patient from 8 surveys covering 6144 patients with mental retardation. Chromosome 15 has been involved in translocations in patients with the Prader-Willi Syndrome with greater than expected frequency. This is the first report of a 14;15 translocation and the Prader-Willi Syndrome. The same balanced translocation was present in the patient's mother and 2 normal siblings. Future genetic counselling for these 2 siblings will be difficult.     

Nuclear skeleton structures in some normal and tumor cells

Nuclear protein fractions, described earlier, were identified as constituents of the nuclear sap (the globulin fraction), that of the nucleoli and ribonucleoprotein network (the acidic protein), and of the nuclear envelope (the residual protein). The latter two fractions compose the protein skeleton of the cell nucleus.An essential difference between electrophoretic profiles of nuclear skeleton structures in experimental tumors and those of normal tissues was revealed. Tumor preparations contained more high molecular weight polypeptides and, in earlier stages of growth, low molecular weight components as well. Fractionation of the nuclear matrix proteins showed that the bulk of them are soluble in diluted alkali. The alkali-insoluble fraction retains the shape of the nucleus and appears in the electron microscope as a spongy nuclear skeleton. A finely dispersed fraction sedimenting from the alkaline suspension is enriched with the pore complexes. The fractions obtained differ in protein composition and probably contain protein components which are similar in molecular weights but non-identical.Abbreviations KD kilodaltons - NM nuclear matrix - PAAG polyacrylamide gel - PC pore complex - RP residual protein     

Neurofibromatosis pseudogene amplification underlies euchromatic cytogenetic duplications and triplications of proximal 15q

Cytogenetically visible interstitial duplications of proximal 15q, which lack the Prader-Willi Angelman critical region (PWACR) frequently segregate in families without phenotypic effect, but the nature of the extra euchromatin has remained unclear. We used comparative genome hybridisation to confirm that the extra material in a cytogenetic triplication originated from proximal 15q. A PAC clone containing sequences specific for the type-1 neurofibromatosis (NF-1) pseudogenes, which map to 15q11.2, hybridised along the length of the enlarged region between the PWACR and the centromere. Computerised measurement of the fluorescent signal from the enlarged and normal chromosomes gave an average ratio of 9.85:1, consistent with amplification. In a second family, an amplified P1–4 signal co-segregated with a cytogenetic duplication and the average ratio between amplified and normal signals in the proband was 8.22:1. Ratios in non-carrier family members and control individuals were close to unity in most cases, but significantly greater than one in at least one instance. Our results provide a novel explanation for cytogenetic variation in 15q11.2. They also suggest that NF-1 pseudogene copy number may be polymorphic in the normal population, and that high copy numbers can produce G bands which do not reflect those of the normal constitutional karyotype. Received: 7 May 1998 / Accepted: 22 July 1998     

Localization of the human gene for 230-kDal bullous pemphigoid autoantigen (BPAG1) to chromosome 6pter----q15.

Chromosome mapping of the human gene encoding the 230-kDal autoantigen of an autoimmune skin disease, bullous pemphigoid, was performed using flow-sorted human chromosomes of cells of normal karyotype and cells carrying a reciprocal translocation t(6;16)(q15;q24). The cDNA of the autoantigen hybridized with intact chromosome 6 and translocation chromosome 6p- (6pter----q15::16q24----qter). The gene (BPA230) was located to the chromosome region 6pter----q15.     

A partial trisomy 15q due to 15;17 translocation detected by conventional cytogenetic and FISH techniques

We report a case having multiple abnormalities including the simultaneous presence of the heart defect and central nerve system abnormalities, which has been reported in a few cases, and with a partial trisomy 15q. Partial trisomy 15q has been inherited from a balanced translocation carried by his phenotypically normal father, detected by traditional banding and fluorescence in situ hybridization (FISH). Application of FISH using whole chromosome specific library probes, locus specific and repetitive probes allowed us to detect the translocation between chromosomes 15q and 17q. Simultaneous application of probes revealed the position of the translocation. Interestingly, in addition to the chromosomes 15 pericentromeric signals, the use of chromosome 15 beta-satellite III probe demonstrated an extra signal on chromosome 14 in both metaphase, and lighted three signals interphase nuclei which was inherited from his father. This patient is compared with other partial trisomy 15q patients reported in the literature. The results are also discussed in relation to genetic counselling for the possible relation of chromosome abnormality and clinical findings.     

In situ localization of enzymes and mucin in normal rat colon embedded in plastic

Summary Several enzymes were investigated histochemically in the colons of normal male F344 rats in order to understand the function of different types of cells in this tissue. Serial methacrylate-embedded sections (2–4 µm) allowed the precise localizations of several enzymes including acid phosphatase, alkaline phosphatase, -glutamyl transpeptidase,N-acetyl--d-glucosaminidase (hexosaminidase), -naphthyl butyrate esterase and 5-nucleotidase. Sites reactive with periodic acid-Schiff were also localized. Gradients of enzyme activity were observed between caecum and rectum and/or from the luminal surfaces to the bases of the crypts for hexosaminidase, esterase and -glutamyl transpeptidase. To our knowledge this is the first histochemical demonstration of -glutamyl transpeptidase in normal rat colonic epithelial cells. The utilization of the methacrylate-embedding technique has revealed previously undescribed gradients of enzyme activity and has allowed the localization of enzyme activities not previously reported in normal rat colonic mucosa.     

Familial deletion

We report a retarded male with an unbalanced karyotype 45,XY,t(8;15) (p23;q12) showing small deletion of chromosome 8(p23 leads to pter) and 15(pter leads to q12). The same chromosome complement was also present in 4 normal family members over 3 generations.