Effects of platforms, size filter cutoffs, and targeted regions of cytogenomic microarray on detection of copy number variants and uniparental disomy in prenatal diagnosis: Results from 5026 pregnancies.

OBJECTIVE: We evaluated the effects of platforms, size filter cutoffs, and targeted regions of cytogenomic microarray (CMA) on the detection of copy number variants (CNVs) and uniparental disomy (UPD) in prenatal diagnosis. METHODS: Five thousand twenty-six consecutive prenatal specimens (>98% high-risk pregnancy) were studied by high-resolution CMA, with cutoffs of 50 kb for losses and 200 kb for gains in nontargeted regions and 20 kb for losses and 100 kb for gains in targeted regions. We assessed actual detection rates using the current assay as well as hypothetical detection rates using platforms with the same or lower resolution and smaller or larger cutoffs. RESULTS: The detection rate of our current assay was 11.2% (562 of 5026), including abnormal findings in 543 cases and likely pathogenic variants in 19. The hypothetical decrease in the overall detection of variants (excluding likely benign) and UPD ranged from 3.8% to 23.0%. For the subgroup of pathogenic and likely pathogenic CNVs < 1 Mb, the decrease of detection ranged from 2.7% to 24.3%. CONCLUSIONS: These findings underscore the significant effects of chosen CMA platform, as well as size filter cutoffs and targeted regions used in data analysis, on detection of CNVs and UPDs in a cohort of prenatal cases.

CMA analysis identifies homozygous deletion of MCPH1 in 2 brothers with primary Microcephaly-1.

BACKGROUND: Homozygous mutations and deletions of the microcephalin gene (MCPH1; OMIM *607117) have been identified as a cause of autosomal recessive primary microcephaly and intellectual disability (MIM #251200). Previous studies in families of Asian descent suggest that the severity of the phenotype may vary based on the extent of the genomic alteration. We report chromosome microarray (CMA) findings and the first described family study of a patient with primary microcephaly in a consanguineous Hispanic family. CASE PRESENTATION: The proband, a boy born at full-term to consanguineous parents from Mexico, presented at 35 months of age with microcephaly, abnormal brain MRI findings, underdeveloped right lung, almond-shaped eyes, epicanthal folds, bilateral esotropia, low hairline, large ears, smooth philtrum, thin upper lip, and developmental delay. MRI of the brain showed a small dermoid or lipoma (without mass effect) within the interpeduncular cistern and prominent arachnoid granulation. The underdeveloped right lung was managed with long-acting inhaled corticosteroids. Otherwise the proband did not have any other significant medical history. The proband had 2 older brothers, ages 14 and 16, from the same consanguineous parents. The 14-year-old brother had a phenotype similar to that of the proband, while both parents and the oldest brother did not have the same phenotypic findings as the proband. The SNP-based CMA analysis of the proband detected a homozygous 250-kb microdeletion at 8p23.2p23.1, extending from 6,061,169 to 6,310,738 bp [hg19]. This genomic alteration encompasses the first 8 exons of MCPH1. Follow-up studies detected the same homozygous deletion in the affected brother, segregating with microcephaly and intellectual disability. Regions of homozygosity (ROHs) were also observed in the affected brother. Since ROHs are associated with an increased risk for recessive disorders, presence of ROH may also contribute to the phenotype of the affected brothers. The parents were both hemizygous for the deletion. CONCLUSION: Here we report a homozygous deletion of multiple exons of the MCPH1 gene that was associated with primary microcephaly and intellectual disability in a Hispanic family. In the context of previous studies, our results support the idea that deletions involving multiple exons cause a more severe phenotype than point mutations.

Enrichment of small pathogenic deletions at chromosome 9p24.3 and 9q34.3 involving DOCK8, KANK1, EHMT1 genes identified by using high-resolution oligonucleotide-single nucleotide polymorphism array analysis.

BACKGROUND: High-resolution oligo-SNP array allowed the identification of extremely small pathogenic deletions at numerous clinically relevant regions. In our clinical practice, we found that small pathogenic deletions were frequently encountered at chromosome 9p and 9q terminal regions. RESULTS: A review of 531 cases with reportable copy number changes on chromosome 9 revealed142 pathogenic copy number variants (CNVs): 104 losses, 31 gains, 7 complex chromosomal rearrangements. Of 104 pathogenic losses, 57 were less than 1 Mb in size, enriched at 9p24.3 and 9q34.3 regions, involving the DOCK8, KANK1, EHMT1 genes. The remaining 47 cases were due to interstitial or terminal deletions larger than 1 Mb or unbalanced translocations. The small pathogenic deletions of DOCK8, KANK1 and EHMT1 genes were more prevalent than small pathogenic deletions of NRXN1, DMD, SHANK3 genes and were only second to the 16p11.2 deletion syndrome, 593-kb (OMIM #611913). CONCLUSIONS: This study corroborated comprehensive genotype-phenotype large scale studies at 9p24.3 and 9q24.3 regions for a better understanding of the pathogenicity caused by haploinsufficiency of the DOCK8, KANK1 and EHMT1 genes. TRIAL REGISTRATION NUMBER: None; it is not a clinical trial, and the cases were retrospectively collected and analyzed.

Interstitial Chromosome 3p14.1 Deletion due to a Maternal Insertion: Phenotype and Association with Balanced Parental Rearrangement.

Interstitial deletions of 3p14p12 are rare chromosome abnormalities. We present a patient with multiple congenital anomalies and a 15.4-Mb interstitial loss of chromosome 3p14p12 detected by chromosomal microarray (CMA). Our patient shared many phenotypic features with other reported cases involving the same region including prominent forehead, short palpebral fissures, hand and foot anomalies, genital abnormalities, and bilateral hearing loss. Given the clinical similarity of these cases with significant overlap of the deleted regions, it is likely that the phenotype is related to the deletion of specific genes within the region. Further molecular cytogenetic investigation revealed that our patient's rearrangement was derived from a cryptic insertion of a segment of chromosome 3p into chromosome 18q in the mother, which was balanced and therefore not visible on the mother's CMA. To our knowledge, this finding has not been previously reported. This case illustrates the importance of using molecular cytogenetics for structural analysis and parental studies. CMA is commonly the first-line study in patients with multiple congenital anomalies; however, it is not the appropriate modality to define a structural rearrangement that may be the cause of a deletion. The use of adjunct studies to define the mechanism of an identified copy number aberration has direct clinical application: to identify the underlying cause of the chromosomal abnormality and to define the recurrence risk. Additionally, this case adds to the current body of work regarding a recurrent phenotype that can be attributed to interstitial chromosome 3p deletions, which may help define the phenotypic implications of deletions in this region and support early clinical management.

Regions of homozygosity identified by oligonucleotide SNP arrays: evaluating the incidence and clinical utility.

Copy neutral segments with allelic homozygosity, also known as regions of homozygosity (ROHs), are frequently identified in cases interrogated by oligonucleotide single-nucleotide polymorphism (oligo-SNP) microarrays. Presence of ROHs may be because of parental relatedness, chromosomal recombination or rearrangements and provides important clues regarding ancestral homozygosity, consanguinity or uniparental disomy. In this study of 14 574 consecutive cases, 832 (6%) were found to harbor one or more ROHs over 10 Mb, of which 651 cases (78%) had multiple ROHs, likely because of identity by descent (IBD), and 181 cases (22%) with ROHs involving a single chromosome. Parental relatedness was predicted to be first degree or closer in 5%, second in 9% and third in 19%. Of the 181 cases, 19 had ROHs for a whole chromosome revealing uniparental isodisomy (isoUPD). In all, 25 cases had significant ROHs involving a single chromosome; 5 cases were molecularly confirmed to have a mixed iso- and heteroUPD15 and 1 case each with segmental UPD9pat and segmental UPD22mat; 17 cases were suspected to have a mixed iso- and heteroUPD including 2 cases with small supernumerary marker and 2 cases with mosaic trisomy. For chromosome 15, 12 (92%) of 13 molecularly studied cases had either Prader-Willi or Angelman syndrome. Autosomal recessive disorders were confirmed in seven of nine cases from eight families because of the finding of suspected gene within a ROH. This study demonstrates that ROHs are much more frequent than previously recognized and often reflect parental relatedness, ascertain autosomal recessive diseases or unravel UPD in many cases.

Concurrent triplication and uniparental isodisomy: evidence for microhomology-mediated break-induced replication model for genomic rearrangements.

Whole-genome oligonucleotide single-nucleotide polymorphism (oligo-SNP) arrays enable simultaneous interrogation of copy number variations (CNVs), copy neutral regions of homozygosity (ROH) and uniparental disomy (UPD). Structural variation in the human genome contributes significantly to genetic variation, and often has deleterious effects leading to disease causation. Co-occurrence of CNV and regions of allelic homozygosity in tandem involving the same chromosomal arm are extremely rare. Replication-based mechanisms such as microhomology-mediated break-induced replication (MMBIR) are recent models predicted to induce structural rearrangements and gene dosage aberrations; however, supportive evidence in humans for one-ended DNA break repair coupled with MMBIR giving rise to interstitial copy number gains and distal loss of heterozygosity has not been documented. We report on the identification and characterization of two cases with interstitial triplication followed by uniparental isodisomy (isoUPD) for remainder of the chromosomal arm. Case 1 has a triplication at 9q21.11-q21.33 and segmental paternal isoUPD for 9q21.33-qter, and presented with citrullinemia with a homozygous mutation in the argininosuccinate synthetase gene (ASS1 at 9q34.1). Case 2 has a triplication at 22q12.1-q12.2 and segmental maternal isoUPD 22q12.2-qter, and presented with hearing loss, mild dysmorphic features and bilateral iris coloboma. Interstitial triplication coupled with distal segmental isoUPD is a novel finding that provides human evidence for one-ended DNA break and replication-mediated repair. Both copy number gains and isoUPD may contribute to the phenotype. Significantly, these cases represent the first detailed genomic analysis that provides support for a MMBIR mechanism inducing copy number gains and segmental isoUPD in tandem.

Characterization of a complex chromosomal rearrangement using chromosome, FISH, and microarray assays in a girl with multiple congenital abnormalities and developmental delay.

Complex chromosomal rearrangements (CCRs) are balanced or unbalanced structural rearrangements involving three or more cytogenetic breakpoints on two or more chromosomal pairs. The phenotypic anomalies in such cases are attributed to gene disruption, superimposed cryptic imbalances in the genome, and/or position effects. We report a 14-year-old girl who presented with multiple congenital anomalies and developmental delay. Chromosome and FISH analysis indicated a highly complex chromosomal rearrangement involving three chromosomes (3, 7 and 12), seven breakpoints as a result of one inversion, two insertions, and two translocations forming three derivative chromosomes. Additionally, chromosomal microarray study (CMA) revealed two submicroscopic deletions at 3p12.3 (467 kb) and 12q13.12 (442 kb). We postulate that microdeletion within the ROBO1 gene at 3p12.3 may have played a role in the patient's developmental delay, since it has potential activity-dependent role in neurons. Additionally, factors other than genomic deletions such as loss of function or position effects may also contribute to the abnormal phenotype in our patient.

Short stature, digit anomalies and dysmorphic facial features are associated with the duplication of miR-17 ~ 92 cluster.

MicroRNAs (miRNAs) are key regulators of gene expression, playing important roles in development, homeostasis, and disease. Recent experimental evidence indicates that mutation or deregulation of the MIR17HG gene (miR-17 ~ 92 cluster) contributes to the pathogenesis of a variety of human diseases, including cancer and congenital developmental defects. We report on a 9-year-old boy who presented with developmental delay, autism spectrum disorder, short stature, mild macrocephaly, lower facial weakness, hypertelorism, downward slanting palpebral fissures, brachydactyly, and clinodactyly. SNP-microarray analysis revealed 516 kb microduplication at 13q31.3 involving the entire MIR17HG gene encoding the miR-17 ~ 92 polycistronic miRNA cluster, and the first five exons of the GPC5 gene. Family study confirmed that the microduplication was maternally inherited by the proband and one of his five half-brothers; digit and other skeletal anomalies were exclusive to the family members harboring the microduplication. This case represents the smallest reported microduplication to date at 13q31.3 and provides evidence supporting the important role of miR-17 ~ 92 gene dosage in normal growth and skeletal development. We postulate that any dosage abnormality of MIR17HG, either deletion or duplication, is sufficient to interrupt skeletal developmental pathway, with variable outcome from growth retardation to overgrowth.

Spectral Karyotyping for identification of constitutional chromosomal abnormalities at a national reference laboratory.

Spectral karyotyping is a diagnostic tool that allows visualization of chromosomes in different colors using the FISH technology and a spectral imaging system. To assess the value of spectral karyotyping analysis for identifying constitutional supernumerary marker chromosomes or derivative chromosomes at a national reference laboratory, we reviewed the results of 179 consecutive clinical samples (31 prenatal and 148 postnatal) submitted for spectral karyotyping. Over 90% of the cases were requested to identify either small supernumerary marker chromosomes (sSMCs) or chromosomal exchange material detected by G-banded chromosome analysis. We also reviewed clinical indications of those cases with marker chromosomes in which chromosomal origin was identified by spectral karyotyping. Our results showed that spectral karyotyping identified the chromosomal origin of marker chromosomes or the source of derivative chromosomal material in 158 (88%) of the 179 clinical cases; the identification rate was slightly higher for postnatal (89%) compared to prenatal (84%) cases. Cases in which the origin could not be identified had either a small marker chromosome present at a very low level of mosaicism (< 10%), or contained very little euchromatic material. Supplemental FISH analysis confirmed the spectral karyotyping results in all 158 cases. Clinical indications for prenatal cases were mainly for marker identification after amniocentesis. For postnatal cases, the primary indications were developmental delay and multiple congenital anomalies (MCA). The most frequently encountered markers were of chromosome 15 origin for satellited chromosomes, and chromosomes 2 and 16 for non-satellited chromosomes. We were able to obtain pertinent clinical information for 47% (41/88) of cases with an identified abnormal chromosome. We conclude that spectral karyotyping is sufficiently reliable for use and provides a valuable diagnostic tool for establishing the origin of supernumerary marker chromosomes or derivative chromosomal material that cannot be identified with standard cytogenetic techniques.

Inherited and de novo 22q11.2 distal duplications in two patients with autistic features, speech delay and no dysmorphology.

In a screen of patients by fluorescence in-situ hybridization and array comparative genomic hybridization in the past two years (July 2007--July 2009), we identified two patients with duplications in the 22q11.22-23, occurring outside the common DiGeorge syndrome/valocardiofacial syndrome region. Fluorescent in-situ hybridization, multiplex ligation-dependent probe amplification and high density bacterial artificial chromosomes and oligo arrays were used to identify the extent of the duplications. In one patient the duplication extended from LCR22-E/5 to LCR22-H/8, which is similar to recently described 22q11.2 distal duplications, while in the second patient, a de novo duplication was identified extending between LCR22-E/5 to LCR22-F/6. The second proband also harbored a de novo 15q14 duplication, complicating phenotype interpretation. The patients were affected with speech delay and autistic features, but neither reported cardiac concern or dysmorphic features.