Pontine Tegmental Cap Dysplasia in an Extremely Preterm Infant and Review of the Literature.

Pontine tegmental cap dysplasia is a rare hindbrain malformation syndrome with a hypoplastic pons, a tissue protrusion into the fourth ventricle, and cranial nerve dysfunction. We here report clinical, imaging, and genetic findings of the first extremely low-birth-weight preterm infant with pontine tegmental cap dysplasia born at 25 weeks of gestation and provide an overview of 29 sporadic cases. A prenatally diagnosed hypoplastic and rostrally shifted cerebellum was indicative of a hindbrain defect and later identified as an early sign of pontine tegmental cap dysplasia in our patient. The neonate exhibited severe muscle hypotonia, persistent thermolability, and clinical signs of an involvement of facial, cochlear, and hypoglossal nerves. Furthermore, paroxysmal episodes of agonizing pain with facial tics, tonic and clonic muscle contractions, blepharospasm, and singultus are highlighted as new phenotypic features of pontine tegmental cap dysplasia. With our report, we present a severe case of pontine tegmental cap dysplasia and provide a brief overview of current knowledge on this rare disease.

Clinical and Genetic Heterogeneity of the 15q13.3 Microdeletion Syndrome.

The 15q13.3 microdeletion is a recurrent CNV, presumably mediated by NAHR between segmental duplications in chromosome 15. The 15q13.3 deletion and duplication are associated with a wide range of clinical manifestations, such as intellectual deficits, seizures, autism, language and developmental delay, neuropsychiatric impairments, and behavioral problems illustrating incomplete penetrance and expressivity. This study comprises an evaluation of 106 symptomatic patients carrying the heterozygous deletion, as well as of 21 patients carrying the duplication, who have been described in previous studies. The analysis shows considerable heterogeneity for the manifestation of different key symptoms and familiar occurrence. Furthermore, 8 new patients are introduced. Convoluted familiar connections give new insights into the complexity of symptomatic manifestation. In previous studies, different opinions have been expressed as to the nature and precise location of the deletion breakpoints. Here, we show that not CHRNA7 and CHRFAM7A, but rather FAM7A or GOLGA8, serve as breakpoint regions concerning our patients. The deletion is described as heterogeneous in size. However, we assume that not only different breakpoints but also the imprecision of aCGH analysis on chromosome 15 due to segmental duplications accounts for the variability in size.

Mutations in CERS3 cause autosomal recessive congenital ichthyosis in humans.

Autosomal recessive congenital ichthyosis (ARCI) is a rare genetic disorder of the skin characterized by abnormal desquamation over the whole body. In this study we report four patients from three consanguineous Tunisian families with skin, eye, heart, and skeletal anomalies, who harbor a homozygous contiguous gene deletion syndrome on chromosome 15q26.3. Genome-wide SNP-genotyping revealed a homozygous region in all affected individuals, including the same microdeletion that partially affects two coding genes (ADAMTS17, CERS3) and abolishes a sequence for a long non-coding RNA (FLJ42289). Whereas mutations in ADAMTS17 have recently been identified in autosomal recessive Weill-Marchesani-like syndrome in humans and dogs presenting with ophthalmologic, cardiac, and skeletal abnormalities, no disease associations have been described for CERS3 (ceramide synthase 3) and FLJ42289 so far. However, analysis of additional patients with non-syndromic ARCI revealed a splice site mutation in CERS3 indicating that a defect in ceramide synthesis is causative for the present skin phenotype of our patients. Functional analysis of patient skin and in vitro differentiated keratinocytes demonstrated that mutations in CERS3 lead to a disturbed sphingolipid profile with reduced levels of epidermis-specific very long-chain ceramides that interferes with epidermal differentiation. Taken together, these data present a novel pathway involved in ARCI development and, moreover, provide the first evidence that CERS3 plays an essential role in human sphingolipid metabolism for the maintenance of epidermal lipid homeostasis.

Multigene deletions on chromosome 20q13.13-q13.2 including SALL4 result in an expanded phenotype of Okihiro syndrome plus developmental delay.

Okihiro syndrome results from truncating mutations in the SALL4 locus on the chromosome 20q13.13-q13.2. Deletions of the whole SALL4 coding region as well as single exon deletions are also a common cause of Okihiro syndrome and indicate haploinsufficiency as the disease causing mechanism. The phenotypes caused by SALL4 deletions are not different from those caused by point mutations. No multigene deletion including SALL4 has been documented to date. Here we report the detection and molecular characterization of four novel, overlapping microdeletions, all spanning SALL4 and flanking genes, in four unrelated cases with features of Okihiro syndrome and variable degrees of psychomotor delay. All deletions were first identified and mapped by quantitative Real Time PCR. Subsequently, three of four deletions were mapped in further detail by high-resolution array CGH (244k oligo-arrays). All cases had larger deletions of varying size (1.76-1.78 Mb, 2.01-2.05 Mb, 2.16-2.17 Mb, and 1.3-2.8 Mb, respectively), which included SALL4 plus 3 to 7 additional functional genes. While three cases with largely overlapping deletions are mildly developmentally delayed, the only patient with a more centromeric deletion is clearly mentally retarded. In this patient, four genes (MOCS3, DPM1, ADNP, BCAS4) are deleted, which were not affected in the other three cases, suggesting that the deletion of one or more of these genes contributes to the mental retardation. Since two of the four cases presented with choanal atresia, large deletions including SALL4 should be considered in the differential diagnosis of children with suspected CHARGE syndrome but without detectable CHD7 mutations.

Detection of heterozygous SALL1 deletions by quantitative real time PCR proves the contribution of a SALL1 dosage effect in the pathogenesis of Townes-Brocks syndrome.

Townes-Brocks syndrome (TBS) is an autosomal dominantly inherited disorder characterized by ear, anal, limb, and renal malformations, and results from mutations in the gene SALL1. All SALL1 mutations previously found in TBS patients create preterminal termination codons. In accordance with the findings of pericentric inversions or balanced translocations, TBS was initially assumed to be caused by SALL1 haploinsufficiency. This assumption was strongly contradicted by a Sall1 mouse knock-out, because neither hetero- nor homozygous knock-out mutants displayed a TBS-like phenotype. A different mouse mutant mimicking the human SALL1 mutations, however, showed a TBS-like phenotype in the heterozygous situation, suggesting a dominant-negative action of the mutations causing TBS. We applied quantitative real time PCR to detect and map SALL1 deletions in 240 patients with the clinical diagnosis of TBS, who were negative for SALL1 mutations. Deletions were found in three families. In the first family, a 75 kb deletion including all SALL1 exons had been inherited by two siblings from their father. A second, sporadic patient carried a de novo 1.9-2.6 Mb deletion including the whole SALL1 gene, and yet another sporadic case was found to carry an intragenic deletion of 3384 bp. In all affected persons, the TBS phenotype is rather mild as compared to the phenotype resulting from point mutations. These results confirm that SALL1 haploinsufficiency is sufficient to cause a mild TBS phenotype but suggest that it is not sufficient to cause the severe, classical form. It therefore seems that there is a different contribution of SALL1 gene function to mouse and human embryonic development.