A novel mechanism for the origin of supernumerary marker chromosomes

A ring chromosome 3 and a 47^th chromosome formed by the portions of 3p and 3q distal to the r(3) breakpoints were found in a girl with mental retardation and minor facial anomalies. The supernumerary chromosome 3, rea(3), had a primary constriction inside its 3p portion (3p23) and was consistently stable both in lymphocytes and fibroblasts. In situ hybridization with alphoid probes revealed that the r(3) maintained its wild-type centromere, whereas the rea(3) showed no alphoid-related signals. This case and a similar one recently reported demonstrate that acentric fragments can acquire a new centromere and become stable, and that supernumerary marker chromosomes can also originate by the junction of the acentric portions distal to the centric region forming a ring. The possibility of such a chromosome segregating will depend on its ability to (re)activate a new centromere.     

Tetrasomy 15q: two marker chromosomes with no detectable alpha-satellite DNA.

Two patients with specific and similar phenotypes were both found to have an unusual marker chromosome present in 70%-80% of their lymphocytes at routine cytogenetic examination. The marker chromosomes were isolated by flow sorting and were amplified by degenerate oligonucleotide-primed PCR. These libraries and a cosmid probe located at 15q26 were used to characterize the marker chromosomes by FISH. Both marker chromosomes were found to consist of duplicated chromosome material from the distal part of chromosome 15q and were identified as inv dup(15) (qter-->q23::q23-->qter) and inv dup(15) (qter-->q24::q24-->qter), respectively. Hence, the markers did not include any known centromere region, and no alpha-satellite DNA could be detected at the site of the primary constriction. Tetrasomy 15q may be a new syndrome, associated with a specific type of marker chromosome. In addition, further analyses of this type of marker chromosome might give new insight into the structure and function of the mammalian centromere.     

The same molecular mechanism at the maternal meiosis I produces mono- and dicentric 8p duplications.

We studied 16 cases of 8p duplications, with a karyotype 46,XX or XY,dup(8p), associated with mental retardation, facial dysmorphisms, and brain defects. We demonstrate that these 8p rearrangements can be either dicentric (6 cases) with the second centromere at the tip of the short arm or monocentric (10 cases). The distal 8p23 region, from D8S349 to the telomere, including the defensin 1 locus, is deleted in all the cases. The region spanning from D8S252 to D8S265, at the proximal 8p23 region, is present in single copy, and the remaining part of the abnormal 8 short arm is duplicated in the dicentric cases and partially duplicated in the monocentric ones. The distal edge of the duplication always spans up to D8S552 (8p23.1), while its proximal edge includes the centromere in the dicentric cases and varies from case to case in the monocentric ones. The analysis of DNA polymorphisms indicates that the rearrangement is consistently of maternal origin. In the deleted region, only paternal alleles were present in the patient. In the duplicated region, besides one paternal allele, some loci showed two different maternal alleles, while others, which were duplicated by FISH analysis, showed only one maternal allele. We hypothesize that, at maternal meiosis I, there was abnormal pairing of chromosomes 8 followed by anomalous crossover at the regions delimited by D8S552 and D8S35 and by D8S252 and D8S349, which presumably contain inverted repeated sequences. The resulting dicentric chromosome, 8qter-8p23.1(D8S552)::8p23.1-(D8S35)-8q ter, due to the presence of two centromeres, breaks at anaphase I, generating an inverted duplicated 8p, dicentric if the breakage occurs at the centromere or monocentric if it occurs between centromeres.     

Nucleotide,Cytogenetic and Expression Impact of the Human Chromosome 8p23.1 Inversion Polymorphism

Background

The human chromosome 8p23.1 region contains a 3.8–4.5 Mb segment which can be found in different orientations (defined as genomic inversion) among individuals. The identification of single nucleotide polymorphisms (SNPs) tightly linked to the genomic orientation of a given region should be useful to indirectly evaluate the genotypes of large genomic orientations in the individuals.

Results

We have identified 16 SNPs, which are in linkage disequilibrium (LD) with the 8p23.1 inversion as detected by fluorescent in situ hybridization (FISH). The variability of the 8p23.1 orientation in 150 HapMap samples was predicted using this set of SNPs and was verified by FISH in a subset of samples. Four genes (NEIL2, MSRA, CTSB and BLK) were found differentially expressed (p<0.0005) according to the orientation of the 8p23.1 region. Finally, we have found variable levels of mosaicism for the orientation of the 8p23.1 as determined by FISH.

Conclusion

By means of dense SNP genotyping of the region, haplotype-based computational analyses and FISH experiments we could infer and verify the orientation status of alleles in the 8p23.1 region by detecting two short haplotype stretches at both ends of the inverted region, which are likely the relic of the chromosome in which the original inversion occurred. Moreover, an impact of 8p23.1 inversion on gene expression levels cannot be ruled out, since four genes from this region have statistically significant different expression levels depending on the inversion status. FISH results in lymphoblastoid cell lines suggest the presence of mosaicism regarding the 8p23.1 inversion.     

Mosaicism for an ectopic NOR at 8pter and a complex rearrangement of chromosome 8 in a patient with severe psychomotor retardation

We describe a 3-year-old girl with severe delays in mental and motor skills, a history of generalized seizures, and subtle dysmorphic features. Conventional cytogenetics revealed a mosaic karyotype. A de novo ectopic NOR at the telomeric region of the short arm of one chromosome 8 (8ps) was found in 90% of lymphocyte and in 98% of fibroblast metaphases. A small NOR-bearing marker chromosome and a large derivative chromosome 8 without short arm satellites (der(8)) were present in the remaining cells. FISH with a probe specific for centromeres 14 and 22 labeled both the telomeric region of 8ps and the small marker centromere. Der(8) included an inverted duplication of 8p and a rearranged duplication of 8q but lacked a second centromere. A subtelomeric probe for 8p revealed a cryptic deletion in 8ps and der(8). Thus, the karyotype represents a combination of submicroscopic partial monosomy 8pter and mosaic trisomy 8.     

Prenatal molecular cytogenetic diagnosis of partial tetrasomy 10p due to neocentromere formation in an inversion duplication analphoid marker chromosome

Neocentromeres are fully functional centromeres found on rearranged or marker chromosomes that have separated from endogenous centromeres. Neocentromeres often result in partial tri- or tetrasomy because their formation confers mitotic stability to acentric chromosome fragments that would normally be lost. We describe the prenatal identification and characterization of a de novo supernumerary marker chromosome (SMC) containing a neocentromere in a 20-wk fetus by the combined use of comparative genomic hybridization (CGH) and fluorescence in situ hybridization (FISH). GTG-banding of fetal metaphases revealed a 47,XY,+mar karyotype in 100% of cultured amniocytes; parental karyotypes were both normal. Although sequential tricolor FISH using chromosome-specific painting probes identified a chromosome 10 origin of the marker, a complete panel of chromosome-specific centromeric satellite DNA probes failed to hybridize to any portion of the marker. The presence of a neocentromere on the marker chromosome was confirmed by the absence of hybridization of an all-human-centromere alpha-satellite DNA probe, which hybridizes to all normal centromeres, and the presence of centromere protein (CENP)-C, which is associated specifically with active kinetochores. Based on CGH analysis and FISH with a chromosome 10p subtelomeric probe, the marker was found to be an inversion duplication of the distal portion of chromosome 10p. Thus, the proband's karyotype was 47,XY,+inv dup(10)(pter-->p14 approximately 15::p14 approximately 15-->neo-->pter), which is the first report of partial tetrasomy 10p resulting from an analphoid marker chromosome with a neocentromere. This study illustrates the use of several molecular strategies in distinguishing centric alphoid markers from neocentric analphoid markers.     

A novel combined 15q11.2 duplication and a bisatellited supernumerary marker derived from chromosome 22: Molecular characterization of the marker

Supernumerary marker chromosomes (SMC) are heterogeneous group of chromosomes which are reported in variable phenotypes. Approximately 70% originate from acrocentric chromosomes. Here we report a couple with recurrent miscarriages and a SMC originating from an acrocentric chromosome. The cytogenetic analysis of the husband revealed a karyotype of 47,XY+marker whereas the wife had a normal karyotype. Analysis of SMC with C-banding showed the presence of a big centromere in the center and silver staining showed prominent satellites on both sides of the marker. Apparently, microarray analysis revealed a 2.1 Mb duplication of 15q11.2 region but molecular cytogenetic analysis by fluorescence in situ hybridization (FISH) with whole chromosome paint (WCP) 15 showed that the SMC is not of chromosome 15 origin. Subsequently, FISH with centromere 22 identified the SMC to originate from chromosome 22 which was also confirmed by WCP 22. Additional dual FISH with centromere 22 and Acro-p-arm probes confirmed the centromere 22 and satellites on the SMC. Further fine mapping of the marker with Bacterial Artificial Chromosome (BAC) clones; two on chromosome 22 and four on chromosome 15 determined the marker to possess only centromere 22 sequences and that the duplication 15 exists directly on chromosome 15. In our study, we had identified and characterized a SMC showing inversion duplication 22(p11.1) combined with a direct tandem duplication of 15q11.2. The possible genotype–phenotype in relation with the two rearrangements is discussed.     

Small marker chromosomes in two patients with segmental aneusomy for proximal 17p

We report a nine-year-old girl (patient 1934) and a five-year-old boy (patient 2170) with small, de novo supernumerary marker chromosomes (SMCs) derived from proximal 17p. The clinical features of patient 1934 include developmental delay, triangular face, prominent forehead, low set ears, dental abnormalities, a high arched palate, long, flexible fingers, and joint laxity. Patient 2170 is affected with developmental delay, oral-motor dyspraxia/verbal apraxia, thick upper and lower lips, bilateral fifth finger clinodactyly, joint laxity and mild hypotonia. G-banded chromosome analysis of patient 1934 revealed mosaicism for a SMC in 72% of peripheral lymphocytes analyzed, whereas analysis of patient 2170 identified a smaller SMC present in 100% of cells analyzed. Fluorescence in situ hybridization (FISH) studies demonstrated that both of the SMCs derived from 17p10-p11.2. Using FISH and array-CGH analysis, the proximal breakpoints mapped within the centromere and the distal breakpoints were both located within the Smith-Magenis syndrome (SMS) common deletion region. We compare the clinical characteristics of our patients with those previously reported to have either SMC including 17p or duplications of proximal 17p in an effort to further delineate the phenotype of trisomy 17p10-p11.2 and to elucidate genotype-phenotype correlations.     

Characterization of an analphoid, neocentromere-positive inv dup 8p marker chromosome using multiplex whole chromosome and sub-telomere FISH analyses

A 30-year-old male patient with mild mental retardation was found to have a small supernumerary marker chromosome (SMC) in 90% of his peripheral blood cells and in 100% of his fibroblast cells. Multiplex whole chromosome and sub-telomere FISH analyses were used to determine that this SMC is an inverted duplicated distal chromosome 8p fragment. Although it was negative for alpha-DNA sequences, this marker had a functional kinetochore (neocentromere) demonstrated by a positive signal with a CENP-C antibody. Apparently intact 8p telomeres at the marker's ends were demonstrated by using a telomere repeat FISH probe. The patient's phenotypically normal mother on G-banding analysis had a small marker chromosome in 8% of her peripheral blood cells in two cultures of the first specimen studied. The marker was not seen in any subsequent maternal peripheral blood or fibroblast specimens. Although it was impossible to further characterize the maternal SMC, it was suggested that the mother had the same marker as the one seen in the proband. Inverted duplicated chromosomal fragments are the most frequent type of analphoid markers. Stable inverted duplicated 8p marker chromosomes were previously reported in three other patients. They all apparently occurred de novo and were found to be positive for kinetochore-associated proteins. Evidence for the possible inheritance of an inverted-duplicated, analphoid SMC was not shown to-date. This study also demonstrates a practical, straightforward approach for analphoid marker characterization in clinical laboratory settings, using whole chromosome multiplex and subtelomere-specific FISH analyses. FISH probes for all sub-telomere chromosomal regions are commercially available and the large majority of analphoid marker chromosomes involve telomere regions.     

Molecular cytogenetic identification and characterization of a de novo supernumerary neocentromeric derivative chromosome 13

We report a young girl with microphthalmia, conductive deafness, aortic isthmus stenosis, laryngomalacia, and laryngeal stenosis carrying a de novo supernumerary neocentromeric derivative chromosome 13. For the precise identification and characterization of the eu- and heterochromatic content of the marker chromosome, straightforward molecular cytogenetic analyses were performed, such as chromosome microdissection, FISH with different probes (e.g. wcp, alphoid centromeric probes, BAC), centromere-specific multicolor FISH (cenM-FISH), and multicolor banding (MCB). The analyses demonstrated that the marker consisted of an inverted duplication (partial tetrasomy) of the distal portion of chromosome 13 that was separated from the endogenous chromosome 13 centromere. Using an all-centromere probe and multicolor cenM-FISH, no alpha-satellite DNA hybridization signal was detectable on any portion of the derivative chromosome. The presence of a functional and active neocentromere on the derivative chromosome 13 was confirmed by positive immunofluorescence signals with CENP-C antibodies. BAC-FISH confirmed the cytogenetic localization of the neocentromere in band 13q31.3. Thus the patient had a mosaic conventional karyotype mos 47,XX,+inv dup(13)(qter-->q21.3::q21.3-->q31.3-->neo-->q31.3-->qter)[6]/46,XX [49].     

p82H identifies sequences at every human centromere

Summary A cloned alphoid sequence, p82H, hybridizes in situ to the centromere of every human chromosome. After washing under stringent conditions, no more than 8% of the grains are located on any specific chromosome. p82H thus differs from other centromeric sequences which are reported to be chromosome specific, because it detects sequences that are conserved among the chromosomes. Two experimental approaches show that the p82H sequences are closely associated with the centromere. First, p82H remains with the relocated centromeres in an inv(19) and an inv(6) chromosome. Second, p82H hybridizes at the centromere but not to the centromeric heterochromatin of chromosomes 1, 9 and 16 that have elongated 1qh, 9qh and 16qh regions produced by short growth in 5-azacytidine. The only noncentromeric site of hybridization is at the distal end of the 9qh region.     

Molecular analyses of 17p11.2 deletions in 62 Smith-Magenis syndrome patients.

Smith-Magenis syndrome (SMS) is a clinically recognizable, multiple congenital anomalies/mental retardation syndrome caused by an interstitial deletion involving band p11.2 of chromosome 17. Toward the molecular definition of the interval defining this microdeletion syndrome, 62 unrelated SMS patients in conjunction with 70 available unaffected parents were molecularly analyzed with respect to the presence or absence of 14 loci in the proximal region of the short arm of chromosome 17. A multifaceted approach was used to determine deletion status at the various loci that combined (i) FISH analysis, (ii)PCR and Southern analysis of somatic cell hybrids retaining the deleted chromosome 17 from selected patients, and (iii) genotype determination of patients for whom a parent(s) was available at four microsatellite marker loci and at four loci with associated RFLPs. The relative order of two novel anonymous markers and a new microsatellite marker was determined in 17p11.2. The results confirmed that the proximal deletion breakpoint in the majority of SMS patients is located between markers D17S58 (EW301) and D17S446 (FG1) within the 17p11.1-17p11.2 region. The common distal breakpoint was mapped between markers cCI17-638, which lies distal to D17S71, and cCI17-498, which lies proximal to the Charcot Marie-Tooth disease type 1A locus. The locus D17S258 was found to be deleted in all 62 patients, and probes from this region can be used for diagnosis of the SMS deletion by FISH. Ten patients demonstrated molecularly distinct deletions; of these, two patients had smaller deletions and will enable the definition of the critical interval for SMS.     

Unbalanced translocation 8;Y (45,X,dic(Y;8)(q11.23;p23.1)): case report and review of terminal 8p deletions

A boy with a rare unbalanced de novo Y/autosome translocation is presented. Main clinical features in the boy comprised a psychomotor delay, talipes planus, a dolichocephalus, low set and retroverted ears, supraorbital fullness of subcutaneous tissue and a bulbous nasal tip. Chromosomal analysis on amniocytes showed a single X chromosome and a derivative 8p (Karyotype: 45,X,der(8)GTG). The following DAPI staining revealed the inactivated centromere of the chromosome Y located on 8p and the absence of heterochromatic material Yq. Microsatellite analysis on fetal blood DNA using markers between SRY on Yp and DYS 240 on Yq proved presence of the spermatogenetic relevant factors. A terminal deletion of 8p was confirmed by FISH postnatally. Molecular genetic reassessment revealed the monosomy 8p to be of maternal origin; the translocation can thus be proven to have occurred in the zygote. The breakpoint in 8p was localised distal to GATA4, a gene which is involved in heart development; the finding that our patient did not suffer from cardiac problems agrees with the disomic presence of GATA4. Only the application of FISH combined with microsatellite analysis allowed a precise correlation between clinical phenotype and a subtle deletion of terminal 8p; furthermore, a recurrence risk for the parents could be excluded.     

玉米mir1基因在玉米和薏苡中的比较物理定位

玉米基因mir1编码一种抗秋季黏虫的半胱氨酸蛋白酶。利用RFLP作图mir1基因被定位在玉米第 6号染色体短臂上 ,但它在第 6号染色体短臂上的物理位置还不知道。实验以mir1和 4 5SrDNA为探针 ,通过双色荧光原位杂交技术确定了mir1基因在玉米细胞分裂中期和粗线期第 6号染色体上的物理位置。Southern杂交结果表明 ,在薏苡基因组中存在mir1基因的同源序列 ,进一步利用荧光原位杂交的方法确定mir1基因的同源序列定位于薏苡第 7号染色体长臂的近末端 ,其信号与着丝粒的百分距离为 73 33± 0 15。     

Mechanisms of small ring formation suggested by the molecular characterization of two small accessory ring chromosomes derived from chromosome 4.

Molecular cloning of a microdissected small accessary ring chromosome 4 from a moderately retarded and dysmorphic patient has been performed to identify the origin of the ring chromosome. FISH was performed with cosmids identified with the cloned, microdissected products and with other markers from chromosome 4. The present study clearly demonstrates that the small ring in this patient originates from three discontinuous regions of chromosome 4: 4p13 or 14, the centromere, and 4q31. It is suggested that the origin of the ring chromosome is a ring involving the entire chromosome 4, which has then been involved in breakage and fusion events, as a consequence of DNA replication generating interlocked rings. A second severely retarded and dysmorphic patient also had a small accessary ring derived from chromosome 4. FISH studies of this ring are consistent with an origin from a contiguous region including the centromere to band 4q12. It is apparent that there are at least two mechanisms for the formation of small ring chromosomes. This adds a further complication in any attempt to ascertain common phenotypes between patients known to have morphologically similar markers derived from the same chromosome.     

An analphoid marker chromosome inv dup(15)(q26.1qter), detected during prenatal diagnosis and characterized via chromosome microdissection

A small, mosaic, C-band negative marker chromosome was detected in amniocyte cultures during prenatal diagnosis due to advanced maternal age. Following spontaneous premature labor at 29 weeks gestation, a dysmorphic infant was delivered, with flat nasal bridge, short palpebral fissures, micrognathia, high forehead, low-set ears, telecanthus and corneal dystrophy. Additional folds of skin were present behind the neck, and feet, fingers and toes were abnormally long. The child died at age five days, after two days of renal failure. The origin of the marker chromosome was subsequently identified from a cord blood sample, via chromosome microdissection. Through reverse FISH, we found the marker to be an inverted duplication of the region 15q26.1-->qter. FISH with alphoid satellite probe was negative, while whole chromosome 15 paint was positive. Both ends of the marker chromosome were positive for the telomeric TTAGGG probe. These data, plus the G-banding pattern, identified the marker as an analphoid, inverted duplicated chromosome, lacking any conventional centromere. We discuss the etiology and clinical effects of this marker chromosome, comparing it to the few reported cases of "tetrasomy 15q" syndrome. We also discuss the possible mechanisms that are likely responsible for this neocentromere formation.     

Genetic mapping of Prm-1, Igl-1, Smst, Mtv-6, Sod-1, and Ets-2 and localization of the Down syndrome region on mouse chromosome 16

Molecular probes were used as markers in the backcross (Czech II X BALB/cPt) X Czech II to determine the positions of six genes on mouse chromosome 16 (MMU 16). The order of the genes mapped is (centromere), protamine-1 (Prm-1), immunoglobulin lambda 1 light chain (Igl-1), preprosomatostatin (Smst), an endogenous mouse mammary tumor virus locus (Mtv-6), and two more distal sequences, superoxide dismutase, cytoplasmic form (Sod-1), and the proto-oncogene sequence Ets-2. The largest recombination frequency between any two adjacent markers is 24 cM, and thus the position of any marker on MMU 16 that is polymorphic between these two strains can be readily determined in this backcross. A region of MMU 16 which corresponds to the Down syndrome region of human chromosome 21 is located near the distal end of the chromosome.     

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.     

The use of a cell-cycle phase-marker may decrease the percentage of errors when using FISH in PGD

Fluorescent DNA probes are used to characterise the chromosome constitution of preimplantation embryos. FISH is used to select normal or balanced embryos in carriers of balanced chromosomal rearrangements, for embryo sexing or for aneuploidy screening in women of advanced age, who have had recurrent abortions or IVF failures. In most cases, FISH is performed on interphase blastomeres which are asynchronously dividing cells, that can be in G1, S or G2. However, a correct interpretation of a double FISH signal, which may correspond to a split signal, to a replicated chromosome region or to the presence of an extra chromosome is essential to establish an accurate diagnosis. To determine if the cell stage could influence the interpretation of FISH results, we compared the signal characteristics of one locus-specific probe, two different subtelomere region probes, and a centromere region probe in non-dividing Sertoli cells and in proliferating lymphocytes. Most cells had two signals per chromosome pair (i.e., a situation corresponding to G0 in Sertoli cells and to G1 or to a prereplication stage in lymphocytes). Nevertheless, in proliferating cells the percentage of nuclei with a number of signals different from the expected (two unreplicated chromosomes per pair) was different from that found in non-dividing cells (P < 0.05). It was estimated that 10.8% of double dots in dividing cells resulted from DNA replication. The sequence of replication was first the locus-specific region, second a telomere region, and third the centromere. In conclusion, the DNA replication process could result in errors of interpretation (misdiagnosis) in 7% of proliferating cells. Thus, the use of a cell cycle phase-specific marker could avoid errors by indicating the cell stage in which the nucleus analysed is found.