Shane C. Quinonez

Human HOX gene disorders

The Hox genes are an evolutionarily conserved family of genes, which encode a class of important transcription factors that function in numerous developmental processes. Following their initial discovery, a substantial amount of information has been gained regarding the roles Hox genes play in various physiologic and pathologic processes. These processes range from a central role in anterior-posterior patterning of the developing embryo to roles in oncogenesis that are yet to be fully elucidated. In vertebrates there are a total of 39 Hox genes divided into 4 separate clusters. Of these, mutations in 10 Hox genes have been found to cause human disorders with significant variation in their inheritance patterns, penetrance, expressivity and mechanism of pathogenesis. This review aims to describe the various phenotypes caused by germline mutation in these 10 Hox genes that cause a human phenotype, with specific emphasis paid to the genotypic and phenotypic differences between allelic disorders. As clinical whole exome and genome sequencing is increasingly utilized in the future, we predict that additional Hox gene mutations will likely be identified to cause distinct human phenotypes. As the known human phenotypes closely resemble gene-specific murine models, we also review the homozygous loss-of-function mouse phenotypes for the 29 Hox genes without a known human disease. This review will aid clinicians in identifying and caring for patients affected with a known Hox gene disorder and help recognize the potential for novel mutations in patients with phenotypes informed by mouse knockout studies.

Leigh Syndrome in a Girl With a Novel DLD Mutation Causing E3 Deficiency

We present the biochemical and molecular diagnosis of dihydrolipoamide dehydrogenase deficiency (also known as E3 deficiency) and Leigh syndrome in a 14-year-old girl with learning disability and episodic encephalopathy and ketoacidosis. The diagnosis was based on values of plasma amino acids and urine organic acids, obtained during acute encephalopathy, lactic ketoacidosis, and liver failure, precipitated by infectious mononucleosis. Enzymatic and molecular analyses confirmed dihydrolipoamide dehydrogenase deficiency. E3 activity from cultured skin fibroblasts ranged from 9-29% of the mean. Molecular analysis revealed compound heterozygosity for novel and known pathogenic mutations (p.I353T and p.G136del, respectively). The patient received dietary augmentation and continuous renal replacement therapy, given her severe, persistent lactic acidosis. Acute decompensation resulted in magnetic resonance imaging changes involving the posterior aspect of the putamen, lateral, and medial thalami, substantia nigra, lateral geniculate bodies, and splenium of the corpus callosum. The cortex and subcortical white matter of the right and left occipital lobes and perirolandic region were also affected. In our review of molecularly confirmed patients with dihydrolipoamide dehydrogenase deficiency, Leigh syndrome was common. Our patient, whose most severe decompensation occurred at a more advanced age than previously reported, provides further evidence of the heterogeneous presentations of dihydrolipoamide dehydrogenase deficiency.

9p partial monosomy and disorders of sex development: Review and postulation of a pathogenetic mechanism

Deletion of the distal segment of 9p causes a syndrome comprising trigonocephaly, minor anomalies, and intellectual disability. Patients with this condition also frequently present with genitourinary abnormalities including cryptorchidism, hypospadias, ambiguous genitalia, or 46,XY testicular dysgenesis. The region responsible for the gonadal dysgenesis has been localized to 9p24.3 with the likely responsible gene identified as DMRT1. Similar to patients with other molecular causes of 46,XY gonadal dysgenesis, patients with partial del 9p have an increased risk of gonadoblastoma. We present two patients with 46,XY gonadal dysgenesis due to partial 9p monosomy. Both patients were also diagnosed with gonadoblastoma following gonadectomy at an early age. Chromosomal microarray analyses refined the cytogenetic abnormalities and allowed potential genotype–phenotype relationships to be determined. We also review the literature as it pertains to partial 9p monosomy, genital abnormalities and gonadoblastoma and note that a large percentage of affected patients present with two copy number variations. We propose that a two‐hit mechanism may be involved in the incomplete penetrance and variable expressivity of partial 9p monosomy and an abnormal genital phenotype. The significant percentage of gonadoblastoma in patients with 46,XY complete gonadal dysgenesis due to partial 9p monosomy also continues to support the necessity of gonadectomy in this patient population.

Multiple congenital anomalies and developmental delay in a boy associated with a de novo 16p13.3 deletion

We describe a patient with multiple congenital anomalies including tracheobronchomalacia, CT‐proven metopic craniosynostosis, glandular hypospadias and severe ventral chordee, torticollis, esotropia, strabismus, fifth finger clinodactyly, hallux valgus, and global developmental delay. Using high resolution chromosomal microarray analysis, we identified a de novo deletion of 555 kb on chromosome 16p13.3, 444 kb telomeric to the CREBBP gene and 623 kb centromeric of PKD1. Review of the literature revealed numerous reports of individuals with deletions involving adjacent regions including CREBBP, but only one overlapping with this isolated region of 16p13.3. Haploinsufficiency for one or more of the 25 candidate genes in the deleted genomic region may be responsible for these clinical features. No copy number variants (CNVs) span the entire region, but several small CNVs within the 555 kb genomic region reduce the likelihood for effects due to haploinsufficiency to 18 genes.

Maternal intrachromosomal insertional translocation leads to recurrent 1q21.3q23.3 deletion in two siblings

We identified a novel 6.33 Mb deletion of 1q21.3q23.3 (hg18; chr1: 153035245–159367106) in two siblings presenting with blepharophimosis, ptosis, microbrachycephaly, severe psychomotor, and intellectual disability. Additional common features include small corpus callosum, normal birth length and head circumference, postnatal growth restriction, low anterior hairline, upturned nose, bilateral preauricular pits, widely spaced teeth, gingival hypertrophy, left ventricular dilatation with decreased biventricular systolic function, delayed bone age, 5th finger clinodactyly, short 3rd digit, hyperconvex nails, obstructive and central sleep apnea, and bilateral heel contractures. Fluorescence in situ hybridization (FISH) performed in the mother of both children showed an apparently balanced, intrachromosomal insertional translocation of 1q21.3q23.3 to 1q42.12. The sibling recurrence likely arose by a maternal meiotic crossing over on the rearranged chromosome 1 between the deleted region and the insertion. We hypothesize that the decreased cardiac function and contractures may be related to LMNA haploinsufficiency. This case illustrates the importance of FISH when attempting to determine inheritance of a copy‐number variation and emphasize the value of evaluating known haploinsufficiency phenotypes for genes in deleted regions.

Analysis of De Novo HOXA13 Polyalanine Expansions Supports Replication Slippage Without Repair in Their Generation

Polyalanine repeat expansion diseases are hypothesized to result from unequal chromosomal recombination, yet mechanistic studies are lacking. We identified two de novo cases of hand‐foot‐genital syndrome (HFGS) associated with polyalanine expansions in HOXA13 that afforded rare opportunities to investigate the mechanism. The first patient with HFGS was heterozygous for a de novo nine codon polyalanine expansion. Haplotype investigation showed that the expansion arose on the maternally inherited chromosome but not through unequal crossing over between homologs, leaving unequal sister chromatid exchange during mitosis or meiosis or slipped mispairing as possible explanations. The asymptomatic father of the second patient with HFGS was mosaic for a six codon polyalanine expansion. Multiple tissue PCR and clonal analysis of paternal fibroblasts showed only expansion/WT and WT/WT clones, and haplotype data showed that two unaffected offspring inherited the same paternal allele without the expansion, supporting a postzygotic origin. Absence of the contracted allele in the mosaic father does not support sister chromatid exchange in the origin of the expansion. Mosaicism for HOXA13 polyalanine expansions may be associated with a normal phenotype, making examination of parental DNA essential in apparently de novo HFGS cases to predict accurate recurrence risks. We could not find an example in the literature where unequal sister chromatid exchange has been proven for any polyalanine expansion, suggesting that the principal mechanism for polyalanine expansions (and contractions) is slipped mispairing without repair or that the true frequency of unequal sister chromatid exchange involving these repeats is low.

A Marfan syndrome-like phenotype caused by a neocentromeric supernumerary ring chromosome 15

Small supernumerary marker chromosomes (sSMC) are abnormal chromosomes that cannot be characterized by standard banding cytogenetic techniques. A minority of sSMC contain a neocentromere, which is an ectopic centromere lacking the characteristic alpha‐satellite DNA. The phenotypic manifestations of sSMC and neocentromeric sSMC are variable and range from severe intellectual disability and multiple congenital anomalies to a normal phenotype. Here we report a patient with a diagnosis of Marfan syndrome and infertility found to have an abnormal karyotype consisting of a chromosome 15 deletion and a ring‐type sSMC likely stabilized by a neocentromere derived via a mechanism initially described by Barbara McClintock in 1938. Analysis of the sSMC identified that it contained the deleted chromosome 15 material and also one copy of FBN1, the gene responsible for Marfan syndrome. We propose that the patients diagnosis arose from disruption of the FBN1 allele on the sSMC. To date, a total of 29 patients have been reported with an sSMC derived from a chromosomal deletion. We review these cases with a specific focus on the resultant phenotypes and note significant difference between this class of sSMC and other types of sSMC. Through this review we also identified a patient with a clinical diagnosis of neurofibromatosis type 1 who lacked a family history of the condition but was found to have a chromosome 17‐derived sSMC that likely contained NF1 and caused the patients disorder. We also review the genetic counseling implications and recommendations for a patient or family harboring an sSMC.

Introducing medical genetics services in Ethiopia using the MiGene Family History App

PurposeAlmost all low-income countries and many middle-income countries lack the capacity to deliver medical genetics services. We developed the MiGene Family History App (MFHA), which assists doctors with family history collection and population-level epidemiologic analysis. The MFHA was studied at St. Paul’s Hospital in Addis Ababa, Ethiopia.MethodsA needs assessment was used to assess Ethiopian physicians’ experience with genetics services. The MFHA then collected patient data over a 6-month period.ResultsThe majority of doctors provide genetics services, with only 16% reporting their genetics knowledge is sufficient. A total of 1699 patients from the pediatric ward (n = 367), neonatal intensive care unit (NICU) (n = 477), and antenatal clinic (n = 855) were collected using the MFHA with a 4% incidence of a MFHA-screened condition present. The incidence was 11.7% in the pediatric ward, 3% in the NICU, and 0.5% in the antenatal clinic. Heart malformations (5.5% of patients) and trisomy 21 (4.4% of patients) were the most common conditions in the pediatric ward.ConclusionMedical genetics services are needed in Ethiopia. As other countries increase their genetics capacity, the MFHA can provide fundamental genetics services and collect necessary epidemiologic data.

The Genetics Journey: A Case Report of a Genetic Diagnosis Made 30 Years Later

Mandibulofacial dysostosis with microcephaly (MFDM) is a rare autosomal dominant condition that was first described in 2006. The causative gene, EFTUD2, identified in 2012. We report on a family that initially presented to a pediatric genetics clinic in the 1980s for evaluation of multiple congenital anomalies. Re-evaluation of one member thirty years later resulted in a phenotypic and molecularly confirmed diagnosis of MFDM. This family’s clinical histories and the novel EFTUD2 variant identified, c.1297_1298delAT (p.Met433Valfs*17), add to the literature about MFDM. This case presented several genetic counseling challenges and highlights that “the patient” can be multiple family members. We discuss testing considerations for an unknown disorder complicated by the time constraint of the patient’s daughter’s pregnancy and how the diagnosis changed previously provided recurrence risks. Of note, 1) the 1980s clinic visit letters provided critical information about affected family members and 2) the patient’s husband’s internet search of his wife’s clinical features also yielded the MFDM diagnosis, illustrating the power of the internet in the hands of patients. Ultimately, this case emphasizes the importance of re-evaluation given advances in genetics and the value of a genetic diagnosis for both patient care and risk determination for family members.

A new POT1 germline mutation—expanding the spectrum of POT1-associated cancers

Melanomas are associated with several hereditary conditions. We present a large family with several family members affected with primary melanomas and dysplastic nevi as well as thyroid cancer and other malignant tumors. Clinical work-up did not reveal a mutation in any of the genes usually considered with evaluation for predisposition to melanoma (BRCA1/2, CDKN2A, CDK4, PTEN, TP53). Whole exome sequencing of five affected family members showed a new variant in POT1. POT1 is associated with the telomere shelterin complex that regulates telomere protection and telomerase access. Germline mutations in POT1 were recently shown to be associated with hereditary predisposition to melanoma. Our findings support a role of POT1 germline mutations in cancer predisposition beyond melanoma development, suggesting a broader phenotype of the POT1-associated tumor predisposition syndrome that might also include thyroid cancer as well as possibly other malignant tumors.