Diagnostic utility of microarray testing in pregnancy loss.

OBJECTIVES: To determine the frequency of clinically significant chromosomal abnormalities identified by chromosomal microarray in pregnancy losses at any gestational age and to compare microarray performance with that of traditional cytogenetic analysis when testing pregnancy losses. METHODS: Among 535 fetal demise specimens of any gestational age, clinical microarray-based comparative genomic hybridization (aCGH) was performed successfully on 515, and a subset of 107 specimens underwent additional single nucleotide polymorphism (SNP) analysis. RESULTS: Overall, clinically significant abnormalities were identified in 12.8% (64/499) of specimens referred with normal or unknown karyotypes. Detection rates were significantly higher with earlier gestational age. In the subset with normal karyotype, clinically significant abnormalities were identified in 6.9% (20/288). This detection rate did not vary significantly with gestational age, suggesting that, unlike aneuploidy, the contribution of submicroscopic chromosomal abnormalities to fetal demise does not vary with gestational age. In the 107 specimens that underwent aCGH and SNP analysis, seven cases (6.5%) had abnormalities of potential clinical significance detected by the SNP component, including female triploidy. aCGH failed to yield fetal results in 8.3%, which is an improvement over traditional cytogenetic analysis of fetal demise specimens. CONCLUSIONS: Both the provision of results in cases in which karyotype fails and the detection of abnormalities in the presence of a normal karyotype demonstrate the increased diagnostic utility of microarray in pregnancy loss. Thus, chromosomal microarray testing is a preferable, robust method of analyzing cases of pregnancy loss to better delineate possible genetic etiologies, regardless of gestational age.

Clinical and molecular characterization of individuals with recurrent genomic disorder at 10q22.3q23.2.

The identification of genomic imbalances in young patients can affect medical management by allowing early intervention for developmental delay and by identifying patients at risk for unexpected medical complications. Using a 105K-feature oligonucleotide array, we identified a 7.25 Mb deletion at 10q22.3q23.2 in six unrelated patients. Deletions of this region have been described in individuals with cognitive and behavioral abnormalities, including autistic features, and may represent a recurring genetic syndrome. All four patients in this study for whom clinical information was available had mild dysmorphic features and three had developmental delay. Of note is the emerging clinical phenotype in these individuals with similar dysmorphic features such as macrocephaly, hypertelorism, and arachnodactyly, and neurodevelopmental delay that includes failure to thrive, hypotonia, and feeding difficulties in the neonatal period, and receptive and expressive language delay with global neurodevelopmental delay after the neonatal period. However, there is no pattern of abnormalities, craniofacial, behavioral, or otherwise, that would have aroused clinical suspicion of a specific syndrome. Finally, the patients' deletions encompass BMPR1A but not PTEN, and these patients may be at risk for colon cancer and should be referred for appropriate prophylactic care and surveillance. Of the two patients in this study who had colonoscopy following the array results, neither had polyps. Therefore, the magnitude of the increased risk for colon cancer is currently unknown.

Refinement of the Region for Split Hand/Foot Malformation 5 on 2q31.1.

Background: Deletions that encompass 2q31.1 have been proposed as a microdeletion syndrome with common clinical features, including intellectual disability/developmental delay, microcephaly, cleft palate, growth delay, and hand/foot anomalies. In addition, several genes within this region have been proposed as candidates for split hand-foot malformation 5 (SHFM5). Methods: To delineate the genotype-phenotype correlation between deletions of this region, we identified 14 individuals with deletions at 2q31.1 detected by microarray analysis for physical and developmental disabilities. Results: All subjects for whom detailed clinical records were available had neurological deficits of varying degree. Seven subjects with deletions encompassing the HOXD cluster had hand/foot anomalies of varying severity, including syndactyly, brachydactyly, and ectrodactyly. Of 7 subjects with deletions proximal to the HOXD cluster, 5 of which encompassed DLX1/DLX2, none had clinically significant hand/foot anomalies. In contrast to previous reports, the individuals in our study did not display a characteristic gestalt of dysmorphic facial features. Conclusion: The absence of hand/foot anomalies in any of the individuals with deletions of DLX1/DLX2 but not the HOXD cluster supports the hypothesis that haploinsufficiency of the HOXD cluster, rather than DLX1/DLX2, accounts for the skeletal abnormalities in subjects with 2q31.1 microdeletions.

Region-specific FISH probes used to identify and characterize an interstitial paracentric inv(21)(q22.1q22.3).

Region-specific probes developed for the diagnosis of specific syndrome, can be adapted to elucidate the exact nature of certain chromosomal structural anomalies. We describe the use of FISH probes in characterizing a prenatally diagnosed chromosome rearrangement. An abnormal chromosome 21 was detected during amniocentesis for maternal age indication, and a similar appearing chromosome 21 was found in the mother. The exact nature of the rearrangement was not immediately evident from G-banded karyotypes. FISH was performed using a whole chromosome painting probe, as well as the region-specific probes D21S65 (21q21-22.1), D21S55 (21q22.3) and D21S1219/D21S1220 (21q22.3-qter) (Oncor). Results showed an interstitial paracentric inversion, with breakpoints in bands 21q22.1 and 21q22.3, which was identical in the mother and the fetus: 46,XX,?inv(21)(q).ish inv(21)(q22.1q22.3)(wcp+.D21S65 mv, D21S55 mv, D21S1219/D21S1220 st). In this case, FISH using region-specific probes was helpful in characterizing the inversion and aided in the genetic counselling of risk assessment for the family.

The human NTT gene: identification of a novel 17-kb noncoding nuclear RNA expressed in activated CD4+ T cells.

We describe the cloning and characterization of the NTT gene (noncoding transcript in T cells), identified by differential display RT-PCR based on the differential presence of its transcript in a subset of activated, human CD4+ T-cell clones. The full-length cDNA and genomic sequences were cloned and found to produce a 17-kb transcript that is polyadenylated, but is not spliced. Consistent with the transcript's nuclear predominance, NTT has no open reading frame larger than 270 bp. It is transcribed in a select subset of CD4+ T-cell clones propagated in vitro. Its transcription can also be induced in freshly isolated T cells by in vitro activation with PHA or with PMA and ionomycin. In vivo, NTT transcripts are found only in activated, but not resting, T cells. Transcripts were absent in a variety of lymphoid cell lines and transformed lines from other tissues. NTT is a new member of the small group of genes including XIST (X-specific transcript), H19, and IPW (imprinted gene in the Prader-Willi syndrome region), which are transcribed but not translated, and may have a role in the regulation of neighboring genes. XIST, H19, and IPW exhibit monoallelic expression, but both NTT alleles are expressed in CD4+ T-cell clones. Southern blot and fluorescence in situ hybridization analyses show that NTT is a single-copy gene residing in chromosome 6q23-q24, near the interferon-gamma receptor gene (IFN-gamma R). Their proximity and shared expression pattern suggest a possible functional relationship.

Lack of X inactivation associated with maternal X isodisomy: evidence for a counting mechanism prior to X inactivation during human embryogenesis.

We have previously reported functional disomy for X-linked genes in females with tiny ring X chromosomes and a phenotype significantly more abnormal than Turner syndrome. In such cases the disomy results from failure of these X chromosomes to inactivate because they lack DNA sequences essential for cis X inactivation. Here we describe a novel molecular mechanism for functional X disomy that is associated with maternal isodisomy. In this case, the severe mental retardation and multiple congenital abnormalities in a female with a mosaic 45,X/ 46,X,del(X)(q21.3-qter)/ 46X,r(X) karyotype are associated with overexpression of the genes within Xpter to Xq21.31 in many of her cells. Her normal X, ring X, and deleted linear X chromosomes originate from the same maternal X chromosome, and all are transcriptionally active. None expresses X inactive specific transcript (XIST), although the locus and region of the putative X inactivation center (XIC) are present on both normal and linear deleted X chromosomes. To our knowledge, this is the first report of a functional maternal X isodisomy, and the largest X chromosome to escape inactivation. In addition, these results (1) show that cis inactivation does not invariably occur in human females with two X chromosomes, even when the XIC region is present on both of them; (2) provide evidence for a critical time prior to the visible onset of X inactivation in the embryo when decisions about X inactivation are made; and (3) support the hypothesis that the X chromosome counting mechanism involves chromosomal imprinting, occurs prior to the onset of random inactivation, and is required for subsequent inactivation of the chromosome.

The XIST locus replicates late on the active X, and earlier on the inactive X based on FISH DNA replication analysis of somatic cell hybrids.

We have recently reported results of DNA replication analysis of three X-linked loci (FRAXA, F8C and XIST) on the X chromosomes in male and female fibroblasts using fluorescence in situ hybridization (FISH) (1). Although our findings that XIST replicates later on the active X than on the inactive X are similar to those of Boggs & Chinault (2) based on a FISH assay in female lymphoblasts, they are the opposite of observations recently reported by Hansen et al. (3) using a different technique. Because our conclusions about the inactive X were deduced from the behavior of the active X in male cells, we reexamined the time when these loci replicate on the human inactive X chromosome isolated from its homolog in somatic cell hybrids. We also studied the same chromosome as an active X in related hybrids. The results provide direct evidence that the expressed XIST locus on the inactive X replicates earlier than its repressed homolog on the active X and earlier than the FRAXA locus which is repressed on this chromosome. The silent XIST locus on the active X replicates late along with F8C which is also not transcribed in these cells. Possible reasons for the different results obtained by Hansen et al. (3) are discussed.

Molecular characterization of tiny ring X chromosomes from females with functional X chromosome disomy and lack of cis X inactivation.

Small ring X chromosomes were first described in mosaic karyotypes of females with the relatively benign phenotype of Turner syndrome. The presence of these rings in association with more severe phenotypes including mental retardation has raised the possibility that they lack sequences necessary for X chromosome inactivation, specifically genes within the X inactivation center (XIC) essential for cis X-inactivation. We recently showed that ring X chromosomes ascertained because of the severe phenotype do not express XIST, a candidate for the relevant gene, and that they are in fact active chromosomes. We now report studies of the genetic content of 11 of these ring X chromosomes (9 associated with severe phenotypes). Our results indicate that these chromosomes contain contiguous segments of DNA and have variable proximal and distal breakpoints and some include mainly long arm or mainly short arm sequences. As expected for ring chromosomes, they lack telomeric sequences. Many of the ring chromosomes lack the XIST locus, consistent with XIST being necessary for cis inactivation. However, the breakpoints in four ring chromosomes that have XIST sequences but do not express XIST suggest that other sequences within the XIC distal to XIST as it is now defined are also needed.

XIST expression is repressed when X inactivation is reversed in human placental cells: a model for study of XIST regulation.

Considerable evidence suggests that the X inactive transcript gene, XIST/Xist, has a role in the initial steps of X chromosome inactivation in the female mammalian embryo. It is transcribed exclusively from inactive X chromosomes, and its noncoding transcript seems to be essential for cis inactivation. Unexpected for a developmental gene, XIST continues to be expressed in adult somatic cells. To determine the effect of reversal of inactivation on the expression of XIST, we studied human X chromosomes that had been induced to reverse X inactivation by hybridization of chorionic villi cells from term placentas with mouse A9 cells. In nine hybrids with a reactivated X chromosome, XIST was either not expressed or expressed much less than the locus on the inactive X chromosome in the chorionic villi cells from which they were derived. The repressibility of XIST by reversal of inactivation in these placental cells mirrors events that occur during the ontogeny of oocytes and indicates that the locus is subject to regulation in somatic cells long after inactivation is established in the embryo. The small residual XIST activity from these active chromosomes suggests that low levels of XIST expression do not interfere with chromosome activity and raises the possibility that the induction of cis inactivation requires a certain level of XIST transcription. The chorionic villi hybrids provide an experimental system to study the developmental regulation of XIST.

DNA replication analysis of FMR1, XIST, and factor 8C loci by FISH shows nontranscribed X-linked genes replicate late.

The relationship between the transcriptional state of a locus and the time when it replicates during DNA synthesis is increasingly apparent. Active autosomal genes tend to replicate early, whereas inactive ones are more permissive and frequently replicate later. Although the inactive X chromosome replicates later than its active homologue, little is known about the replication of X-linked genes. We have used FISH to examine the replication of loci on the active X chromosome that are not transcribed, either because the tissue analyzed was not the expressing tissue (F8C), because the locus is silent on all active X chromosomes (XIST), or because it has been mutated by expansion and methylation of a CpG island (FMR1). In this assay, an unreplicated locus is characterized by a single hybridization signal, and a replicated locus is characterized by a doublet hybridization signal. The percentage of doublets is used as a measure of relative time of replication in S phase. The validity of this approach has been established elsewhere, since results compare favorably with those obtained using traditional methods for studying DNA replication. Our results show that the FMR1 gene replicates relatively later in fragile X (fraX) males with the full mutation than in normal males, irrespective of the probe used. The F8C locus is late replicating in both normal and fraX males and replicates at nearly the same time on active and inactive X in females. The XIST locus replicates late in all the males studied and asynchronously in female cells.(ABSTRACT TRUNCATED AT 250 WORDS)