Short stature, hearing loss, retinitis pigmentosa, and distinctive facies syndrome: A case report.

Short stature, hearing loss, retinitis pigmentosa, and distinctive facies (SHRF) Syndrome is a syndrome recently identified among three German patients. Clinical characteristics include eye disease, sensorineural hearing loss, distinct facial and phalangeal features, short stature, developmental delay, and cerebellar atrophy. In this case report, we discuss a fourth identified patient with genomic mutations in the EXOSC2 gene which codes for a cap protein in the RNA exosome. Whole exome sequencing identified two mutations of unknown clinical significance including: a heterozygous maternal variant, missense mutation NM_014285.7: c427G>A (p.Ala143Thr) in exon 6 and a heterozygous paternal variant, splice donor NM_014285.5: c.801+1G>A in intron 8. Our patient demonstrates a novel clinical presentation within the SHRF disease spectrum.

UBA2 variants underlie a recognizable syndrome with variable aplasia cutis congenita and ectrodactyly.

PURPOSE: The human chromosome 19q13.11 deletion syndrome is associated with a variable phenotype that includes aplasia cutis congenita (ACC) and ectrodactyly as specific features. UBA2 (ubiquitin-like modifier-activating enzyme 2) lies adjacent to the minimal deletion overlap region. We aimed to define the UBA2-related phenotypic spectrum in humans and zebrafish due to sequence variants and to establish the mechanism of disease. METHODS: Exome sequencing was used to detect UBA2 sequence variants in 16 subjects in 7 unrelated families. uba2 loss of function was modeled in zebrafish. Effects of human missense variants were assessed in zebrafish rescue experiments. RESULTS: Seven human UBA2 loss-of-function and missense sequence variants were detected. UBA2-phenotypes included ACC, ectrodactyly, neurodevelopmental abnormalities, ectodermal, skeletal, craniofacial, cardiac, renal, and genital anomalies. uba2 was expressed in zebrafish eye, brain, and pectoral fins; uba2-null fish showed deficient growth, microcephaly, microphthalmia, mandibular hypoplasia, and abnormal fins. uba2-mRNAs with human missense variants failed to rescue nullizygous zebrafish phenotypes. CONCLUSION: UBA2 variants cause a recognizable syndrome with a wide phenotypic spectrum. Our data suggest that loss of UBA2 function underlies the human UBA2 monogenic disorder and highlights the importance of SUMOylation in the development of affected tissues.

Gorlin-like phenotype in a patient with a PTCH2 variant of uncertain significance.

Gorlin syndrome, also known as Nevoid Basal-Cell Carcinoma Syndrome (NBCCS), is an autosomal dominant tumor predisposition syndrome that presents early in life with characteristic congenital malformations and tumors. This syndrome most commonly results from germline mutations of the PTCH1 tumor suppressor gene, which shows high penetrance and great intra and interfamilial phenotypic variability, as well as the SUFU tumor suppressor gene. Recently, the PTCH2 gene has also been implicated as a cause of Gorlin syndrome. Notably, these patients displayed milder phenotypes of Gorlin syndrome when considered against PTCH1 and SUFU-related disease. We report a patient with a novel PTCH2 mutation inherited from his father. The proband displays several minor diagnostic features of Gorlin syndrome, supporting the pathogenic role of this gene. Features in the proband include macrocephaly, a wide face, prominent forehead, hypertelorism/telecanthus, large eyes, cleft lip and palate, thin vertical palmar creases, penoscrotal inversion, and a hyperpigmented spot on his penis. His father displays macrocephaly, several nevi on his back and shoulders, and a single palmar pit on his left hand, raising suspicion for Gorlin syndrome. Whole exome sequence (trio) found that the proband and father are heterozygous for NM_003738.4:c.3347C>T;p.(Pro1116Leu) in exon 21 of PTCH2, found also in his mildly affected brother. This semi-conservative amino acid substitution has been reported in the literature, but its significance is unclear. Notably, the proband, brother, and father do not meet clinical criteria for Gorlin syndrome. However, the clinical findings described in this family support the association between PTCH2 mutations and Gorlin-like phenotypes.

Neonatal mucolipidosis type II alpha/beta due to compound heterozygosity for a known and novel GNPTAB mutation, and a concomitant heterozygous change in SERPINF1 inherited from the mother.

We report on a newborn with IUGR, rhizomelic dwarfism, and suspected chondrodysplasia punctata. At birth, OI was suspected; however, a skeletal survey suggested ML II alpha/beta. Sequencing revealed compound heterozygosity for a reported pathogenic and novel but expected pathogenic GNPTAB variant. Molecular testing for autosomal recessive OI identified a SERPINF1 variant.

Variable developmental delays and characteristic facial features-A novel 7p22.3p22.2 microdeletion syndrome?

Isolated 7p22.3p22.2 deletions are rarely described with only two reports in the literature. Most other reported cases either involve a much larger region of the 7p arm or have an additional copy number variation. Here, we report five patients with overlapping microdeletions at 7p22.3p22.2. The patients presented with variable developmental delays, exhibiting relative weaknesses in expressive language skills and relative strengths in gross, and fine motor skills. The most consistent facial features seen in these patients included a broad nasal root, a prominent forehead a prominent glabella and arched eyebrows. Additional variable features amongst the patients included microcephaly, metopic ridging or craniosynostosis, cleft palate, cardiac defects, and mild hypotonia. Although the patients' deletions varied in size, there was a 0.47 Mb region of overlap which contained 7 OMIM genes: EIP3B, CHST12, LFNG, BRAT1, TTYH3, AMZ1, and GNA12. We propose that monosomy of this region represents a novel microdeletion syndrome. We recommend that individuals with 7p22.3p22.2 deletions should receive a developmental assessment and a thorough cardiac exam, with consideration of an echocardiogram, as part of their initial evaluation.

Neonatal severe hyperparathyroidism caused by homozygous mutation in CASR: A rare cause of life-threatening hypercalcemia.

Neonatal severe hyperparathyroidism (NSHPT) is a rare, life-threatening condition that presents with severe hypercalcemia, hyperparathyroidism, and osteopenia in the newborn period. Treatment of NSHPT traditionally includes hydration and bisphosphonates; however newer calcimimetic agents, such as cinacalcet, are now being utilized to prevent or delay parathyroidectomy which is technically difficult in the newborn. Medical treatment success is related to calcium sensing receptor (CaSR) genotype. We report a 4-day-old infant who presented with hyperbilirubinemia, poor feeding, weight loss, severe hypotonia and was ultimately diagnosed with NSHPT. The patient's total serum calcium level of 36.8 mg/dL (reference range: 8.5-10.4 mg/dL) is, to our knowledge, the highest ever documented in this setting. Exome data previously obtained on the infant's parents was re-analyzed demonstrating bi-parental heterozygosity for a mutation of the CASR gene: c.206G > A, and Sanger sequencing data confirmed the patient was a homozygote for the same mutation. Though a patient with the same CaSR gene mutation described here has responded to cinacalcet, our patient did not respond and required parathyroidectomy. Though this case has previously been published as a surgical case report, a full report of the medical management and underlying genetic etiology is warranted; this case underscores the importance of disclosing bi-parental heterozygosity for a gene causing severe neonatal disease particularly when treatment is available and illustrates the need for further in vitro studies of this CaSR mutation.

Unbalanced translocation 9;16 in two children with dysmorphic features, and severe developmental delay: Evidence of cross-over within derivative chromosome 9 in patient #1.

We describe 2 children with dysmorphic features, and severe developmental delay presenting with overlapping unbalanced translocations of 9q34.3 and 16p13. Patient #1: A 4 year old African-American female with normal karyotype with a pericentric inversion on one chromosome 9 known to be a benign variant. Low resolution array CGH revealed a single BAC clone loss at 9q34.3 and a single BAC clone gain at 16p13.3, confirmed by FISH. Whole genome SNP array analysis refined these findings, identifying a terminal 1.28 Mb deletion (138,879,862-140,164,310) of 9q34.3 and a terminal 1.62 Mb duplication (45,320-1,621,753) of 16p13.3. Sub-telomeric FISH showed an unbalanced cryptic translocation involving the inverted chromosome 9 and chromosome 16. FISH of the father showed a balanced t(9;16)(q34.3;p13.3) involving the non-inverted chromosome 9, and a pericentric inversion on the normal 9 homologous chromosome. The presence of two rearrangements on chromosome 9, both an unbalanced translocation and a pericentric inversion, indicates recombination between the inverted and derivative 9 homologues from her father. Patient #2: A 1 year old Iraqi-Moroccan female with normal karyotype. Array-CGH identified a 0.56 Mb deletion of 9q34.3 (139,586,637-140,147,760) and an 11.31 Mb duplication of 16p13.3p13.13 (31,010-11,313,519). Maternal FISH showed a balanced t(9;16)(q34.3;p13.13). Both patients present with similar clinical phenotype.