An unstable dicentric Robertsonian translocation in a markedly discordant twin.

Karyotypes from independent amniocenteses reflected a rare, unstable, functionally dicentric Robertsonian translocation chromosome in most cells in male Twin B who grew more slowly than the chromosomally normal female sib (Twin A). Twin B's balanced de novo Robertsonian translocation dic(13;14)(p11.1;p11.1), present in 81% of cells, underwent recurrent centromeric fission in 6 out of 30 independent colonies that explains a balanced 46,XY,-13,+fis(13)(p11.1),-14,+fis(14)(p11.1) karyotype. Aneuploidy for chromosomes 13q or 14q was present in 5% of cells. Instability of the Robertsonian translocation was evident because nine of the 30 colonies (30%) grown from single amniocytes had metaphase cells with more than one chromosome complement. Although uniparental disomy was excluded and a targeted ultrasound was normal, the couple was advised of the uncertain but real risk of abnormalities in Twin B and the risk to Twin A of terminating Twin B. The pregnancy proceeded and at 31 weeks gestation Twin A was in the 33rd percentile for size and Twin B in the 1st percentile. At 32 weeks, chromosome analysis revealed a balanced 45,XY,dic(13;14)(p11.1;p11.1) karyotype in all of Twin B's newborn cord blood cells with no evidence of fission or aneuploidy. Selection against unbalanced mitotic products of the unstable, functionally dicentric chromosome in early fetal development is proposed to result in Twin B's highly discordant small birth size.

C455R notch3 mutation in a Colombian CADASIL kindred with early onset of stroke.

Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is caused by mutations in the notch3 epidermal growth factor-like repeats. A Colombian kindred carries a novel C455R mutation located in the predicted ligand-binding domain. Stroke occurred in the patients at an unusually early age (median age: 31 years) in comparison to the more frequent onset in the fourth decade of life in other CADASIL populations, including a second Colombian kindred with an R1031C mutation.

Highly polymorphic short tandem repeat analyses clarify complex molecular test results.

Judicious application of highly polymorphic short tandem repeat (STR) analyses and modification of assay conditions readily distinguished nonparentage from true parentage, with occasional failure to transmit one parentally derived allele. These categories were resolved with a reliability of >99.9%, the standard applied to most DNA evidence presented in a U.S. court of law. While completing a single prenatal diagnosis submitted at 19 weeks gestation, the authors found that one polymorphic grandpaternal allele did not amplify, a duplicate control propositus' DNA sample had been switched by an outside laboratory, and recombination occurred in maternal meiosis within the mutant gene region. In two parentage cases with one available parent, a Y-linked STR or an autosomal STR was modified when transmitted to the offspring. In contrast, some apparently inconsistent results between parental DNA and offspring were resolved by purifying or diluting the original extracted DNA samples. Thus, the source of each complex molecular test result was characterized unambiguously by testing a sufficient number of highly polymorphic STR loci and by purifying or diluting troublesome DNA samples to diminish polymerase chain reaction amplification artifact.

Rett syndrome from quintuple and triple deletions within the MECP2 deletion hotspot region.

Rett syndrome results from mutations in the X-linked methyl-CpG-binding protein 2 (MECP2) gene, which are nearly always lethal in males and lead to regression and reduced life expectancy in females. Herein we report one propositus with five tandem deletions and a second propositus with three tandem deletions within MECP2 exon 4 that encode truncated protein products resulting in classic Rett syndrome. These deletion breakpoints and single deletions in 3 other patients were all found within a 185-bp region along with 64 of 69 other reported deletion breakpoints in the MECP2 gene. Illegitimate recombination resulting in deletion at a substantial proportion of the shared MECP2 sites is enhanced by repeated guanosine (G) DNA sequences in the antisense direction, consistent with reports at other gene loci that polypurine (multiple guanosine or adenosine (A)) basepairs enhance sequence deletion. Multiple deletions at the same poly G recombination sites confirm the existence of deletion hotspots in this gene region with numerous repeated antisense sites that are enriched 26- to 161-fold. Deletion by illegitimate recombination within a single allele can occur during mitotic or meiotic cell cycles. Although prone to disease-causing deletion, this region is unique in humans and highly conserved among mammals for the last 75 000 000 years to maintain the MECP2 gene's critical function.

Mutation analysis in Rett syndrome.

Rett syndrome is an X-linked dominant neurodevelopmental disorder caused by mutations in the MECP2 gene. Mutations have been demonstrated in more than 80% of females with typical features of Rett syndrome. We identified mutations in the MECP2 gene and documented the clinical manifestations in 65 Rett syndrome patients to characterize the genotype-phenotype spectrum. Bidirectional sequencing of the entire MECP2 coding region was performed. We diagnosed 65 patients with MECP2 mutations. Of these, 15 mutations had been reported previously and 13 are novel. Two patients have multiple deletions within the MECP2 gene. Eight common mutations were found in 43 of 65 patients (66.15%). The majority of patients with identified mutations have the classic Rett phenotype, and several had atypical phenotypes. MECP2 analysis identified mutations in almost all cases of typical Rett syndrome, as well as in some with atypical phenotypes. Eleven (20.4%) of the 54 patients with defined mutations and in whom phenotypic data were obtained did not develop acquired microcephaly. Hence, microcephaly at birth or absence of acquired microcephaly does not obviate the need for MECP2 analysis. We have initiated cascade testing starting with PCR analysis for common mutations followed by sequencing, when necessary. Analysis of common mutations before sequencing the entire gene is anticipated to be the most efficacious strategy to identify Rett syndrome gene mutations.

Rare etiology of autosomal recessive disease in a child with noncarrier parents.

A child with maple syrup urine disease type 2 (MSUD2) was found to be homozygous for a 10-bp MSUD2-gene deletion on chromosome 1. Both purported parents were tested, and neither carries the gene deletion. Polymorphic simple-sequence repeat analyses at 15 loci on chromosome 1 and at 16 loci on other chromosomes confirmed parentage and revealed that a de novo mutation prior to maternal meiosis I, followed by nondisjunction in maternal meiosis II, resulted in an oocyte with two copies of the de novo mutant allele. Fertilization by a sperm that did not carry a paternal chromosome 1 or subsequent mitotic loss of the paternal chromosome 1 resulted in the propositus inheriting two mutant MSUD2 alleles on two maternal number 1 chromosomes.

Tandem duplication/deletion in a maternally derived chromosome 9 supernumerary derivative resulting in 9p trisomy and partial 9q tetrasomy.

A 19-week stillborn female fetus with bilateral cleft palate, horseshoe kidney, bicornuate uterus, low-set ears, and intrauterine growth retardation (IUGR) was found to have a supernumerary derivative chromosome 9 (der(9)) with an apparent tandem duplication in the long arm. PCR analysis at five polymorphic loci confirmed the duplication and showed an adjacent deletion, while whole chromosome FISH demonstrated only chromosome 9 to be involved. Further FISH studies of der(9) found the 9qh region to be duplicated, telomeric sequences to be intact, and subtelomeric sequences to be absent. Thus, the fetus was determined to be trisomic for 9pter-->9q12 and 9q34.3-->9qter, tetrasomic for 9q12--> 9q33, and disomic for 9q33-->9q34.3. These results are consistent with a tandem duplication of 9q12-->9q33 and adjacent distal deletion as designated by the karyotype, 47,XX,+der(9)dup(9) (q12q33)del(9) (q33q34.3).ish der(9)(WCP9+,D9Z1x2,STP9q-, AHT+) de novo. In addition to characterizing der(9), the combined PCR and cytogenetic studies refined the Genome Database Map of three loci (D9S907, D9S155, and D9S302) approximately to the distal 9q33 region. Without the attempt to refine breakpoints by PCR analysis, the deletion in distal 9q would not have been detected. Tandem direct duplication/deletion chromosomes have been reported in fewer cases than inverted duplication/deletions. We propose mechanisms of origin, consistent with those for recurrent inter stitial microdeletion and microduplication syndromes, shown to arise by recombination at homologous, flanking DNA sequences.

Preimplantation diagnosis of the beta1 integrin knockout mutation as a model for aneuploid gene testing.

The autosomal beta1 integrin knockout mouse mutation was selected as a model to experimentally determine preimplantation diagnosis test reliability for autosomal gene deletions and duplications. In experiment 1, which analyzed 198 individually disaggregated single blastomeres, the observed test frequencies matched the mathematically predicted frequencies calculated from the independently derived values of 90% normal allele amplification, 92% mutant allele amplification, 4% alternate allele contamination, and 4% failure to transfer amplifiable target DNA into the PCR reaction mix. This experiment correctly predicted a normal embryonic phenotype in 143 (99.3%) of the 144 phenotypically normal autosomal recessive results. Experiment 2 compared single biopsied blastomere test results to test results on the remaining embryonic cells cultured 1 week until trophoblast outgrowth. Single biopsied blastomere analysis correctly predicted a normal autosomal recessive phenotype in 87 (98%) of the 89 embryos that would have been selected for implantation. Experiment 3 compared the PCR results of two biopsied blastomeres tested independently to the PCR result from the remaining cultured blastomeres to improve test reliability. Given that embryos would have been implanted only when two normal results were obtained, 17 of 17 phenotypically normal embryos would have been implanted from among the 44 embryos tested. These experiment 3 results are consistent with the mathematical prediction that about 99.9% of embryos implanted with two unaffected biopsied blastomere results would have had a phenotypically normal genotype.

Symmetric replication of an unstable isodicentric Xq chromosome derived from isolocal maternal sister chromatid recombination.

An amniocyte culture was found to be mosaic for 45,X/46,X, idic(X)(p11.2)/ 47,X, idic(X)(p11.2),idic(X)(p11.2) cell lines, reflecting mitotic nondisjunction of the idic(X)(p11.2) chromosome. Upon learning of abnormal karyotype and ultrasound findings, the parents decided to discontinue the pregnancy. Subsequent cultures of fetal skin, kidney, and lung were mosaic 45,X/46,X,idic(X)(p11.2) reflecting mitotic loss of the unstable idic(X)(p11.2) chromosome. C-banding and in situ hybridization of X chromosome-specific alpha-satellite probe to metaphase fetal cells confirmed two centromeres on the idic(X)(p11.2) chromosome with both centromeres appearing to be active in two-thirds of cells. This result was confirmed by centromere protein-E (CENP-E) antibody staining which delineated 80% of scored cells with two active centromeres and 20% with 1 active centromere. Bromodeoxyuridine (BrdU) incorporation and acridine orange staining characterized the DNA replication pattern of the idic(X)(p11.2) chromosome as late and symmetrically replicating. Polymerase chain reaction analysis of highly polymorphic loci determined that the normal X chromosome carried paternal alleles and the idic(X)(p11.2) chromosome carried maternal alleles from only one grandparental chromosome. Overall, the results suggest that recombination occurred between two maternal sister chromatids both in the same chromosome band Xp11.2 (isolocal) prior to maternal meiosis II anaphase to generate an unstable maternal idic(X)(p11.2) chromosome. Additional factors that could contribute to i(Xq) and idic(X) formation and instability are discussed along with a mechanism to explain the high frequency of intrauterine loss in 45,X pregnancies.

Calculating posterior cystic fibrosis risk with echogenic bowel and one characterized cystic fibrosis mutation: avoiding pitfalls in the risk calculations.

We describe a general approach to derive fetal risk following two separate test results that each raise the likelihood of the same fetal abnormality without clearly determining whether the abnormality exists. Echogenic bowel observed on fetal ultrasonography may have multiple causes, including an a priori risk of approximately 1% of cystic fibrosis (CF). On numerous occasions our laboratory tests have detected only normal cystic fibrosis transmembrane regulator (CFTR) alleles in fetuses with echogenic bowel. This result indicates that another cause most likely explains the abnormal ultrasound finding. One of our tested fetuses was heterozygous for the deltaF508 CFTR mutation and had a normal karyotype. Over 770 CFTR mutations have been described, and a significant proportion of parental mutant alleles could not be detected by our 25-mutation test. Further mutation analysis demonstrated that the fetus' mother carried the deltaF508 mutation but the father (of different ethnic background than the mother) did not carry a detectable mutation. Thus, this test result substantially increased the risk of the fetus having CF, while still not giving a definitive answer to whether the fetus was affected. A rigorous mathematical analysis determined that the 1% risk of CF following ultrasound study was increased to slightly under 12% following DNA analysis. The case is described, and the mathematical formulas are explained and illustrated with examples, along with a review of conditional probability (Appendix 2).

Dual blastomere analysis improves reliability of preimplantation trembler mouse diagnosis.

Dual blastomere biopsy and independent blastomere analysis dramatically improved preimplantation diagnostic reliability as confirmed by testing the remaining biopsied eight-cell mouse embryo. The autosomal dominant trembler mouse point mutation was selected as a model for human preimplantation diagnosis because: (1) single cell assay failure is predicted to be the highest when testing autosomal dominant mutations; (2) point mutations represent the most common of all mutation categories and the most demanding mutation to assay reliably; and (3) the trembler mouse point mutation in peripheral myelin protein 22 (Pmp22) is a model of human Charcot-Marie-Tooth type 1A disease. Mathematical models predict our experimental results assuming amplification of 80% of each target allele as well as trembler sperm DNA contamination in 1 of 44 normal biopsied single blastomeres. Single blastomere analysis correctly predicted the genotype in only 84% of embryos that would have been implanted as normal. In contrast, when independent tests of both biopsied blastomeres agreed, test results were confirmed in 20 of 21 (95.2%) of the remaining six-cell biopsied embryos designated as normal. Thus, biopsied six-cell embryo confirmation demonstrated that dual biopsied blastomere analysis improved test reliability remarkably.

DNA amplification determines donor-cell fate in cryopreserved skin allografts.

Cryopreserved donor skin-cell survival was tested after allo- and isotransplantation by DNA amplification of male donor-cell genes which detects trace quantities of cells. Essentially, all cryopreserved allograft skin cells were rejected at the recipient site. Fine-haired, cryopreserved, belly skin of male BALB/c mice was transplanted onto the coarser-haired back of either female Swiss-Webster mice (allograft) or female BALB/c mice (isograft). Six weeks later, skin samples from the graft sites were tested by DNA polymerase chain reaction (PCR) amplification. Although allografts initially engrafted, more than 99.9 percent of male allograft skin cells were subsequently rejected, and gradually replaced by hairless host scar tissue. Clinically, all isografts, including hair follicles, engrafted permanently and maintained donor-cell SRY gene sequences in fine-haired graft site cells. Thus, cryopreservation maintained both the viability and antigenicity of mouse skin cells, because allografts were rejected and isografts survived. Furthermore, DNA amplification, quantified at multiple control dilutions and amplification cycles, can conclusively determine the fate of transplanted cells.

True trisomy 2 mosaicism in amniocytes and newborn liver associated with multiple system abnormalities.

Among 58,000 amniocenteses completed, our laboratories found one case of true cytogenetic trisomy 2 mosaicism in a fetus with multiple abnormalities. In contrast, 11 fetuses phenotypically normal at birth were found to have true trisomy 2 mosaicism in their chorionic villus cells among the 10,500 fetuses tested by chorionic villus sampling (CVS). In our single abnormal case, amniocentesis performed at 19 weeks after finding an elevated maternal serum AFP found two independent cultures with trisomy 2 karyotypes in 8 of 25 and 7 of 31 amniocytes, respectively. Although oligohydramnios was noted by ultrasound, the mother elected to continue the pregnancy. At 26 weeks the fetus had intrauterine growth retardation (IUGR), hydronephrosis, and cardiac abnormalities. When delivered by Cesarean section at 30 weeks, the infant had multiple anomalies and developed necrotizing enterocolitis and severe cholestasis. At 5 months coronal magnetic resonance imaging (MRI) displayed delayed myelination and abnormal brain morphology. The patient also exhibited significant growth failure and developmental delay. Although chromosomes were normal in blood, skin fibroblasts, and ascites fluid cells, 4 of 100 hepatic biopsy fibroblasts were 47,XY,+2. Molecular analysis excluded uniparental disomy (UPD) of chromosome 2 in the 46,XY cell line. This and other reports of rare phenotypically abnormal trisomy 2 mosaic fetuses identified by karyotyping amniocytes emphasizes the substantially higher fetal risk of abnormal development than when trisomy 2 is found only in chorionic villus cells.

Objective aneuploidy detection for fetal and neonatal screening using comparative genomic hybridization (CGH).

Comparative genomic hybridization (CGH) allows entire genomes to be scanned for whole and segmental aneuploidy and thus may be an appropriate tool for the detection of clinically important abnormalities during fetal and neonatal screening. Criteria to distinguish between significant aberrations and experimental artifacts are essential for these applications. This report describes the use of a t-statistic to detect changes in CGH profiles that differ significantly from variations that occur in CGH profiles of normal samples. Eleven cell lines derived from fetal or neonatal patients were analyzed in this study. Aneuploidies in these lines included trisomies for chromosomes 13, 16, 18, and 21 and monosomy for distal 5p and tetrasomy 18p. Aneuploidy was detected in all samples by using the t-statistic, although the extent of the aneuploid region was not correctly estimated in some cases. A detailed description of the t-statistic fused for making these CGH comparisons is described in a companion paper (Moore et al., Cytometry 28:183-190, 1997.

Chromosome 22q11.2 microdeletions in velocardiofacial syndrome patients with widely variable manifestations.

Velocardiofacial syndrome (VCFS) and the DiGeorge sequence (DGS) are caused by 22q11.2 deletions. Fluorescence in situ hybridization (FISH) using the DiGeorge chromosome region (DGCR) probe (Oncor) was used to detect 31 deletions in 100 patients with possible VCFS. Retrospective FISH analysis of archived slides from 14 patients originally studied only by high-resolution G banding detected 6 patients with a DGCR deletion, and only 2 of these 6 had a microscopically visible chromosome deletion. The 4 familial deletions found exhibited a wide range of clinical presentations within each family. Comparison of clinical characteristics of patients with and without the DGCR deletion determined findings predictive of the deletion: abundant or unruly scalp hair; narrow palpebral fissures; a laterally "built-up" nose; velopharyngeal inadequacy; thymic hypoplasia; and congenital heart defects, specifically tetralogy of Fallot, ventriculoseptal defect, and interrupted aortic arch.

Rapid aneuploid diagnosis of high-risk fetuses by fluorescence in situ hybridization.

OBJECTIVE: Our purpose was to develop fluorescence in situ hybridization to repetitive chromosome-specific sequences to detect chromosome aneuploidy faster than hybridization to unique targets or karyotyping. STUDY DESIGN: Aneuploidy involving chromosomes 13, 18, 21, X, and Y comprises 70% of chromosome abnormalities in 10- to 12-week fetuses, 95% of the phenotypically significant newborn chromosome abnormalities. Our improved 8-hour protocol used repetitive probes to label and count the number of these centromeric chromosome domains. RESULTS: This protocol correctly determined chromosome 13, 18, and 21 status in 50 of 50 unselected direct amniocyte samples and found abnormal patterns in 27 of 27 archived trisomy 21 cases. Altogether karyotyping confirmed 744 of 745 chromosome-specific repetitive sequence test results. CONCLUSION: This protocol rapidly tests abnormal fetuses and newborn infants in whom diagnosis is made at the initiation of labor or before urgent surgery when a cytogenetic result cannot be completed.

Point mutation analysis of archived cytogenetic slide DNA.

Archived Giemsa-stained cytogenetic slide repositories represent valuable DNA resources for medical, scientific, and forensic studies. Sequencing readily identified a Charcot-Marie-Tooth disease point mutation in a 209-bp PCR amplified product. With optimal PCR primers and amplification conditions, our protocol quickly and reliably isolated sufficient DNA for at least 12 independent PCR amplification reactions for forensic and medical applications from single slides up to 5 years old.

Asian hereditary neuropathy patients with peripheral myelin protein-22 gene aneuploidy.

Japanese hereditary neuropathy with liability to pressure palsy (HNPP) patients have a deletion of one peripheral myelin protein-22 (PMP22) gene region in distal chromosome band 17p11.2 as do Caucasian patients. Japanese and Asiatic Indian CMT1A patients have a PMP22 gene duplication that results in Charcot-Marie-Tooth disease type IA (CMT1A; HMSNIA) in patients of European and Middle Eastern ancestry. About 70% of Japanese CMT1 patients have a PMP22 duplication as do Caucasians, while Japanese CMT1B, CMT2 and Dejerine-Sottas patients to not have PMP22 gene region aneuploidy. Although HNPP and CMT1A genotypes are generated simultaneously by unequal recombination that results in PMP22 gene aneuploidy in each daughter cell, only 3 Japanese HNPP probands with PMP22 deletion from a large patient population were referred to a single center compared to 18 referred CMT1A probands with PMP22 duplication. This lower HNPP frequency more likely reflects lower HNPP reproductive fitness than patient ascertainment bias because disease severity and variation in severity is about the same in CMT1A and HNPP patients and because all patients of both types were referred regardless of disease severity. These results, along with an apparently high de novo CMT1A mutation rate, suggest that common ancestors of Japanese, Asian Indians, and Caucasians carried PMP22 geneflanking sequences that enhance unequal crossing over.