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     

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.     

Duplications of proximal 16q flanked by heterochromatin are not euchromatic variants and show no evidence of heterochromatic position effect

Extra euchromatic material was found within the major heterochromatic block of chromosome 16 (16qh) in one de novo case and seven members of two families. In contrast to the euchromatic variants of chromosome 9 (9qh), which are derived from pericentromeric euchromatin, molecular cytogenetics confirmed that these duplications were of 16q11.2-->q12.2 in the de novo case, of 16q11.2-->q13 in three members of family 1 and 16q11.2-->q12.1 in four members of family 2. The duplication had arisen as a post-zygotic mitotic event in the mother of family 1 and been transmitted paternally in family 2. An insertional mechanism of origin is proposed for the duplications in case 1 and family 1. Expression at the 16q13 matrix metalloproteinase-2 (MMP2)locus in families 1 and 2 was proportional to genomic copy number and not therefore consistent with position effect silencing due to the flanking blocks of heterochromatin. We conclude that proximal 16q duplications within 16qh are not novel euchromatic variants but associated with a variable phenotype including developmental delay, speech delay, learning difficulties and behavioural problems. The behavioural problems in families ascertained through affected children are much less severe than those encountered in previous patients ascertained as adults.     

Breakpoint cloning and haplotype analysis indicate a single origin of the common Inv(10)(p11.2q21.2) mutation among northern Europeans

The pericentric inv(10)(p11.2q21.2) mutation has been frequently identified in cytogenetic laboratories, is phenotypically silent, and is considered to be a polymorphic variant. Cloning and sequencing of the junction fragments on 10p11 and 10q21 revealed that neither inversion breakpoint directly involved any genes or repetitive sequences, although both breakpoint regions contain a number of repeats. All 20 apparently unrelated inv(10) families in our study had identical breakpoints, and detailed haplotype analysis showed that the inversions were identical by descent. Thus, although considered a common variant, inv(10)(p11.2q21.2) has a single ancestral founder among northern Europeans.     

Structural variation of chromosomes in autism spectrum disorder

Structural variation (copy number variation [CNV] including deletion and duplication, translocation, inversion) of chromosomes has been identified in some individuals with autism spectrum disorder (ASD), but the full etiologic role is unknown. We performed genome-wide assessment for structural abnormalities in 427 unrelated ASD cases via single-nucleotide polymorphism microarrays and karyotyping. With microarrays, we discovered 277 unbalanced CNVs in 44% of ASD families not present in 500 controls (and re-examined in another 1152 controls). Karyotyping detected additional balanced changes. Although most variants were inherited, we found a total of 27 cases with de novo alterations, and in three (11%) of these individuals, two or more new variants were observed. De novo CNVs were found in approximately 7% and approximately 2% of idiopathic families having one child, or two or more ASD siblings, respectively. We also detected 13 loci with recurrent/overlapping CNV in unrelated cases, and at these sites, deletions and duplications affecting the same gene(s) in different individuals and sometimes in asymptomatic carriers were also found. Notwithstanding complexities, our results further implicate the SHANK3-NLGN4-NRXN1 postsynaptic density genes and also identify novel loci at DPP6-DPP10-PCDH9 (synapse complex), ANKRD11, DPYD, PTCHD1, 15q24, among others, for a role in ASD susceptibility. Our most compelling result discovered CNV at 16p11.2 (p = 0.002) (with characteristics of a genomic disorder) at approximately 1% frequency. Some of the ASD regions were also common to mental retardation loci. Structural variants were found in sufficiently high frequency influencing ASD to suggest that cytogenetic and microarray analyses be considered in routine clinical workup.     

Paracentric inversion of chromosome 15(q15q24): description of three families

Three unrelated families with paracentric inversion of chromosome 15(q15q24) are reported. An additional pericentric inversion of chromosome 9 with breakpoints in p11.2q13 was also observed in one of the three families. Reproductive problems, such as stillbirths, spontaneous abortions and two live-born children with multiple abnormalities, were present.     

Identification of two paralogous regions mapping to the short and long arms of human chromosome 2 comprising LIS1 pseudogenes

Reiner et al. (1995b) reported on the existence of a gene with a coding region virtually identical to LIS1, the gene responsible for Miller-Dieker lissencephaly. This gene, LIS2, was mapped to chromosome 2p11.2, and a related pseudogene, LIS2P, was mapped to 2q13-->q14. By sequencing genomic clones that were mapped by means of 2p and 2q-only hybrids, we now demonstrate the existence of two LIS1 processed pseudogenes mapping to 2p11.2 and 2q13 (PAFAH1P1 and PAFAH1P2, respectively). The two sequences appear to lie within larger paralogous regions and share a 98.6% degree of identity. Comparative mapping data by cytogenetic analysis on great apes indicate that the duplication of the genomic region comprising the LIS1 pseudogenes occurred in humans. We also demonstrate that the cDNA sequence shown as part of the LIS2 gene and marking its chromosome 2 specificity belongs to the 3' untranslated region of a different gene (C1orf6) that we mapped to 1q21 by FISH analysis.     

Ring chromosome 15: characterization by array CGH

Ring chromosome 15 [r(15)] is an uncommon finding with less than 50 patients reported. Precise genotype–phenotype correlations are problematic because of the difficulties in determining the extent of euchromatic loss, the level of mosaicism, and the influence of the timing of ascertainment. We report two discordant examples of r(15) patients. In the first case, prenatal diagnosis of a de novo r(15) was made during the second trimester: mos 46,XX,r(15)(p11.2q26)[32]/45,XX,-15[13]/47,XX,r(15)(p11.2q26)x2[3]/46,XX,dic r(15)(p11.2q26p11.2q26[1]/46,XX[2]. Postnatal follow-up revealed extremely small stature, heart defects, and developmental delay. Patient 2 was a 31-year-old short-statured female who was living independently: 46,XX,r(15)(p11q26). Both cases showed loss of the 15q subtelomeric region by fluorescence in situ hybridization (FISH). To investigate the discordance in phenotypes between the two patients, we undertook array comparative genomic hybridization (array CGH) analyses to more fully characterize the deletions associated with these otherwise structurally indistinguishable r(15) chromosomes from conventional cytogenetic analyses and fluorescence in situ hybridization (FISH) studies. By array CGH, patient 1 showed deletion of multiple contiguous clones predicting an approximately 6 Mb deletion of distal 15q. In contrast, patient 2 showed loss of just the 15q subtelomeric clone and an interstitial clone by array CGH confirming that the severity of the phenotype correlated with the size of the deletion at the molecular level. These cases illustrate the utility of array CGH characterization for determining the size of the associated deletion in ring chromosomes and for facilitating phenotype–genotype correlations.     

Small supernumerary marker chromosomes (SMCs): genotype-phenotype correlation and classification

Small supernumerary marker chromosomes (SMCs) are present in about 0.05% of the human population. In approximately 30% of SMC carriers (excluding the ~60% SMC derived from one of the acrocentric chromosomes), an abnormal phenotype is observed. The clinical outcome of an SMC is difficult to predict as they can have different phenotypic consequences because of (1) differences in euchromatic DNA-content, (2) different degrees of mosaicism, and/or (3) uniparental disomy (UPD) of the chromosomes homologous to the SMC. Here, we present 35 SMCs, which are derived from all human chromosomes, apart from chromosome 6, as demonstrated by the appropriate molecular cytogenetic approaches, such as centromere-specific multicolor fluoresence in situ hybridization (cenM-FISH), multicolor banding (MCB), and subcentromere-specific multicolor FISH (subcenM-FISH). In nine cases without an aberrant phenotype, neither partial proximal trisomies nor UPD could be detected. Abnormal clinical findings, such as psychomotoric retardation and/or craniofacial dysmorphisms, were associated with seven of the cases in which subcentromeric single-copy probes were proven to be present in three copies. Conversely, in eight cases with a normal phenotype, proximal euchromatic material was detected as partial trisomy. UPD was studied in 12 cases and subsequently detected in two of the cases with SMC (partial UPD 4p and maternal UPD 22 in a der(22)-syndrome patient), indicating that SMC carriers have an enhanced risk for UPD. At present, small proximal trisomies of 1p, 1q, 2p, 6p, 6q, 7q, 9p, and 12q seem to lead to clinical manifestations, whereas partial proximal trisomies of 2q, 3p, 3q, 5q, 7p, 8p, 17p, and 18p may not be associated with significant clinical symptoms. With respect to clinical outcome, a classification of SMCs is proposed that considers molecular genetic and molecular cytogenetic characteristics as demonstrated by presently available methods.Electronic database information: accession numbers and URLs for the data in this article are as follows:ENSEMBL-database, National Center for Biotechnology Information (NCBI), Genome Database (GDB), OMIM (Online Mendelian Inheritance in Man) Database,     

Pericentric inversion inv(7)(p11q21.1): report on two cases and genotype-phenotype correlations

We report on two unrelated cases of pericentric inversion 46,XY,inv(7)(p11q21.1) associated with distinct pattern of malformation including mental retardation, development delay, ectrodactyly, facial dismorphism, high arched palate. Additionally, one case was found to be characterized by mesodermal dysplasia. Cytogenetic analysis of the families indicated that one case was a paternally inherited inversion whereas another case was a maternally inherited one. Molecular cytogenetic studies have shown paternal inversion to have a breakpoint within centromeric heterochromatin being the cause of alphoid DNA loss. Maternal inversion was also associated with a breakpoint within centromeric heterochromatin as well as inverted euchromatic chromosome region flanked by two disrupted alphoid DNA blocks. Basing on molecular cytogenetic data we hypothesize the differences of clinical manifestations to be produced by a position effect due to localization of breakpoints within variable centromeric heterochromatin and, alternatively, due to differences in the location breakpoints, disrupteding different genes within region 7q21-q22. Our results reconfirm previous linkage analyses suggested 7q21-q22 as a locus of ectrodactily and propose inv (7)(p11q21.1) as a cause of recognizable pattern of malformations or a new chromosomal syndrome.     

Selective staining of pericentromeric heterochromatin regions in chromosomes of spontaneously dividing cells with the use of the acridine orange fluorochrome

A novel phenomenon of unusual selective acridine orange (AO) staining ofpericentromeric heterochromatin regions (HRs) in chromosomal preparations from tissue with known spontaneous mitotic activity (chorionic villi, placenta, embryonic tissues, bone marrow, and testes), as well as embryonic stem cells, is described. Staining with 0.01% AO in a citric-phosphate (pH 5.5) or sodium phosphate (pH 7.0) buffer solution allows the HRs of human chromosomes (1q12, 9q12, 13p11.2, 14p11.2, 15p11.2, 16q11.2, 21p11.2, 22p11.2, and Yq12) and pericentromeric HRs of mouse chromosomes to be reliably detected by the red fluorescence of AO. This method of AO staining does not require any pretreatment. Explanations for metachromatic AO staining of polymorphic pericentromeric HRs in chromosomes of spontaneously dividing cells are suggested. A high reproducibility of the specific AO staining makes it possible to suggest its use as a reliable quick method for detection of polymorphic HRs of human chromosomes in cytogenetic prenatal diagnosis and oncohematology.     

Investigation of 15q11-q13, 16p11.2 and 22q13 CNVs in Autism Spectrum Disorder Brazilian Individuals with and without Epilepsy

Copy number variations (CNVs) are an important cause of ASD and those located at 15q11-q13, 16p11.2 and 22q13 have been reported as the most frequent. These CNVs exhibit variable clinical expressivity and those at 15q11-q13 and 16p11.2 also show incomplete penetrance. In the present work, through multiplex ligation-dependent probe amplification (MLPA) analysis of 531 ethnically admixed ASD-affected Brazilian individuals, we found that the combined prevalence of the 15q11-q13, 16p11.2 and 22q13 CNVs is 2.1% (11/531). Parental origin could be determined in 8 of the affected individuals, and revealed that 4 of the CNVs represent de novo events. Based on CNV prediction analysis from genome-wide SNP arrays, the size of those CNVs ranged from 206 kb to 2.27 Mb and those at 15q11-q13 were limited to the 15q13.3 region. In addition, this analysis also revealed 6 additional CNVs in 5 out of 11 affected individuals. Finally, we observed that the combined prevalence of CNVs at 15q13.3 and 22q13 in ASD-affected individuals with epilepsy (6.4%) was higher than that in ASD-affected individuals without epilepsy (1.3%; p<0.014). Therefore, our data show that the prevalence of CNVs at 15q13.3, 16p11.2 and 22q13 in Brazilian ASD-affected individuals is comparable to that estimated for ASD-affected individuals of pure or predominant European ancestry. Also, it suggests that the likelihood of a greater number of positive MLPA results might be found for the 15q13.3 and 22q13 regions by prioritizing ASD-affected individuals with epilepsy.     

Genomic imbalances in esophageal squamous cell carcinoma identified by molecular cytogenetic techniques

This review summarizes the chromosomal changes detected by molecular cytogenetic approaches in esophageal squamous cell carcinoma (ESCC), the ninth most common malignancy in the world. Whole genome analyses of ESCC cell lines and tumors indicated that the most frequent genomic gains occurred at 1, 2q, 3q, 5p, 6p, 7, 8q, 9q, 11q, 12p, 14q, 15q, 16, 17, 18p, 19q, 20q, 22q and X, with focal amplifications at 1q32, 2p16-22, 3q25-28, 5p13-15.3, 7p12-22, 7q21-22, 8q23-24.2, 9q34, 10q21, 11p11.2, 11q13, 13q32, 14q13-14, 14q21, 14q31-32, 15q22-26, 17p11.2, 18p11.2-11.3 and 20p11.2. Recurrent losses involved 3p, 4, 5q, 6q, 7q, 8p, 9, 10p, 12p, 13, 14p, 15p, 18, 19p, 20, 22, Xp and Y. Gains at 5p and 7q, and deletions at 4p, 9p, and 11q were significant prognostic factors for patients with ESCC. Gains at 6p and 20p, and losses at 10p and 10q were the most significant imbalances, both in primary carcinoma and in metastases, which suggested that these regions may harbor oncogenes and tumor suppressor genes. Gains at 12p and losses at 3p may be associated with poor relapse-free survival. The clinical applicability of these changes as markers for the diagnosis and prognosis of ESCC, or as molecular targets for personalized therapy should be evaluated.     

DNA copy number amplifications in sarcomas with homogeneously staining regions and double minutes

To identify DNA amplifications in sarcomas, comparative genomic hybridization was performed on 27 cases that were likely to display high-level DNA copy number gains. In all cases, chromosome banding analysis had revealed homogeneously staining regions or double minutes, i.e., cytogenetic signs of gene amplification. In most cases, gains predominated over losses. Low-level amplifications (ratio 1.3:1.5) were seen in 20 cases. High-level amplifications (ratio >1.5) exceeded the frequencies seen in published, unselected sarcomas of similar histotypes and were detected in 16 tumors: 4/4 osteosarcomas, 5/8 malignant fibrous histiocytomas, 3/7 leiomyosarcomas, 1/2 myosarcomas, 0/1 liposarcoma, 0/1 rhabdomyosarcoma, 1/1 pleomorphic sarcoma, 0/1 myxofibrosarcoma, 1/1 malignant mesenchymona, and 1/1 malignant schwannoma, with two to four chromosomal regions involved in nine tumors. Recurrent amplifications involved 1p33-p32, 5p15-p14, 7pter-p12, 7q21-qter, 8q21.3-qter, 11q22-q23, 16p13.2-p12, 19q12-q13.1, 20q11.2-qter, and 22q12-q13. Most of the recurrent gains/amplifications we detected have been reported in sarcomas previously. A novel gain/amplification was seen at 2q14.3-q21 in five cases of four sarcoma types. The disparate pattern of amplified sequences, the poor correspondence between the localization of low- and high-level amplifications, and the chromosomal position of homogeneously staining regions suggest the involvement of many genes in the amplifications and that the genes rarely maintain their native position in these tumors.     

Chromosome abnormalities without phenotypic consequences

Some changes in chromosome morphology, detected during cytogenetic analysis, are not associated with clinical defects. Therefore a proper discrimination of harmless variants from true abnormalities, especially during prenatal diagnosis, is crucial to allow precise counseling. In this review we described chromosome variants and examples of chromosome anomalies that are considered to be unrelated to phenotypic consequences. The correlation between the presence of marker chromosomes and a risk of clinical signs is also discussed. Structural rearrangements of heterochromatic material, satellite polymorphism, or fragile sites, are well-known examples of common chromosome variation. However, the absence of clinical effects has also been reported in some cases of chromosome abnormalities concerning euchromatin. Such euchromatic anomalies were divided into 2 categories: unbalanced chromosome abnormalities (UBCAs), such as deletions or duplications, and euchromatic variants (EVs). Recently so-called molecular karyotyping, especially whole-genome screening by the use of high-resolution array-CGH technique, contributed to revealing a high number of previously unknown small genomic variations, which seem to be asymptomatic, as they are present in phenotypically normal individuals.     

Phenomenon of selective staining of pericentromeric heterochromatin regions in chromosomes from spontaneously dividing cells by the acridine orange fluorochrome

A novel phenomenon of unusual selective acridine orange (AO) staining of pericentromeric heterochromatin regions (HRs) in chromosomal preparations from tissue with known spontaneous mitotic activity (chorionic villi, placenta, embryonic tissues, bone marrow, and testes), as well as embryonic stem cells, is described. Staining with 0.01% AO in a citric-phosphate (pH 5.5) or sodium phosphate (pH 7.0) buffer solution allows the HRs of human chromosomes (1q12, 9q12, 13p11.2, 14p11.2, 15p11.2, 16q11.2, 21p11.2, 22p11.2, and Yq12) and pericentromeric HRs of mouse chromosomes to be reliably detected by the red fluorescence of AO. This method of AO staining does not require any pretreatment. Explanations for metachromatic AO staining of polymorphic pericentromeric HRs in chromosomes of spontaneously dividing cells are suggested. A high reproducibility of the specific AO staining makes it possible to suggest its using as a reliable quick method for detection of polymorphic HRs of human chromosomes in cytogenetic prenatal diagnosis and oncohematology.     

A third neurofibromatosis type 1 (NF1) pseudogene at chromosome 15q11.2

Sequences related to the neurofibromatosis type 1 (NF1) gene have been identified on several human chromosomes. In the centromeric region of chromosomes 14 and 15, two NF1 pseudogenes have been described. Sequence comparison between NF1-related exons amplified from two yeast artificial chromosome clones hybridizing to chromosomal region 15q11.2 and published NF1-related sequences localized at 15q11.2 suggested that a third NF1 pseudogene resides in this chromosomal region. The previous localization of an NF1-related locus to the telomeric part of chromosome 15 could not be confirmed by us. Our findings further support pericentromeric spreading of partial NF1 gene copies at chromosome 15q11.2 during evolution. Received: 27 January 1996 / Accepted: 26 May 1997     

Prenatal diagnosis and molecular cytogenetic characterization of an unusual complex structural rearrangement in a pregnancy following intracytoplasmic sperm injection (ICSI).

We report on a balanced complex chromosomal aberration detected in a fetus after amniocentesis. The pregnancy was achieved after intracytoplasmic sperm injection. GTG-banding revealed a complex structurally rearranged karyotype with a translocation between chromosomes 5 and 15 and an additional paracentric inversion in the der(15) between bands 5q11.2 and 5q15. Ag-NOR staining showed an interstitial active nuclear organizer region in the der(15). Molecular cytogenetic analyses using whole-chromosome-painting probes, comparative genomic hybridization, and multicolor banding did not point to further structural aberrations or imbalances. Therefore, a complex rearrangement with three breakpoints has occurred, and the karyotype can be described as 46,XX,der(5)t(5;15) (q11.2;p12),der(15)t(5;15)(q11.2;p12)inv(5)(q11.2q15).