ASPP2 deficiency causes features of 1q41q42 microdeletion syndrome.

Chromosomal abnormalities are implicated in a substantial number of human developmental syndromes, but for many such disorders little is known about the causative genes. The recently described 1q41q42 microdeletion syndrome is characterized by characteristic dysmorphic features, intellectual disability and brain morphological abnormalities, but the precise genetic basis for these abnormalities remains unknown. Here, our detailed analysis of the genetic abnormalities of 1q41q42 microdeletion cases identified TP53BP2, which encodes apoptosis-stimulating protein of p53 2 (ASPP2), as a candidate gene for brain abnormalities. Consistent with this, Trp53bp2-deficient mice show dilation of lateral ventricles resembling the phenotype of 1q41q42 microdeletion patients. Trp53bp2 deficiency causes 100% neonatal lethality in the C57BL/6 background associated with a high incidence of neural tube defects and a range of developmental abnormalities such as congenital heart defects, coloboma, microphthalmia, urogenital and craniofacial abnormalities. Interestingly, abnormalities show a high degree of overlap with 1q41q42 microdeletion-associated abnormalities. These findings identify TP53BP2 as a strong candidate causative gene for central nervous system (CNS) defects in 1q41q42 microdeletion syndrome, and open new avenues for investigation of the mechanisms underlying CNS abnormalities.

Novel congenital myopathy locus identified in Native American Indians at 12q13.13-14.1.

BACKGROUND: Native American myopathy (NAM) is an autosomal recessive congenital myopathy first reported in the Lumbee Indian people. Features of NAM include congenital weakness, cleft palate, ptosis, short stature, and susceptibility to malignant hyperthermia provoked by anesthesia. METHOD: We identified five individuals with NAM from the Lumbee population, and hypothesized that these affected individuals have disease alleles shared identical-by-descent inherited from common ancestry. To identify a NAM disease locus, homozygosity mapping methods were employed on a genomewide 10K single-nucleotide polymorphism (SNP) screen. To confirm regions of homozygosity identified in the SNP screen, microsatellite repeat markers were genotyped within those homozygous segments. RESULTS: The SNP data demonstrated five regions of shared homozygosity in individuals with NAM. The additional genotyping data narrowed the region to one common segment of homozygosity spanning D12S398 to rs3842936 mapping to 12q13.13-14.1. Notably, loss of heterozygosity estimates from the SNP data also detected this same 12q region in the affected individuals. CONCLUSION: This study reports the first gene mapping of Native American myopathy (NAM) using single-nucleotide polymorphism-based homozygosity mapping in only a few affected individuals from simplex families and identified a novel NAM locus. Identifying the genetic basis of NAM may suggest new genetic etiologies for other more common conditions such as congenital myopathy and malignant hyperthermia.

New chromosome 11p15 epigenotypes identified in male monozygotic twins with Beckwith-Wiedemann syndrome.

Beckwith-Wiedemann syndrome (BWS) is an overgrowth syndrome demonstrating heterogeneous molecular alterations of two imprinted domains on chromosome 11p15. The most common molecular alterations include loss of methylation at the proximal imprinting center, IC2, paternal uniparental disomy (UPD) of chromosome 11p15 and hypermethylation at the distal imprinting center, IC1. An increased incidence of female monozygotic twins discordant for BWS has been reported. The molecular basis for eleven such female twin pairs has been demonstrated to be a loss of methylation at IC2, whereas only one male monozygotic twin pair has been reported with this molecular defect. We report here two new pairs of male monozygotic twins. One pair is discordant for BWS; the affected twin exhibits paternal UPD for chromosome 11p15 whereas the unaffected twin does not. The second male twin pair is concordant for BWS and both twins of the pair demonstrate hypermethylation at IC1. Thus, this report expands the known molecular etiologies for BWS twins. Interestingly, these findings demonstrate a new epigenotype-phenotype correlation in BWS twins. That is, while female monozygotic twins with BWS are likely to show loss of imprinting at IC2, male monozygotic twins with BWS reflect the molecular heterogeneity seen in BWS singletons. These data underscore the need for molecular testing in BWS twins, especially in view of the known differences among 11p15 epigenotypes with respect to tumor risk.

A molecular approach to dominance in hypophosphatasia.

Hypophosphatasia is an inherited disorder characterized by defective bone mineralization and a deficiency of tissue-nonspecific alkaline phosphatase (TNSALP) activity. The disease is highly variable in its clinical expression, because of various mutations in the TNSALP gene. In approximately 14% of the patients tested in our laboratory, only one TNSALP gene mutation was found, despite exhaustive sequencing of the gene, suggesting that missing mutations are harbored in intron or regulatory sequences or that the disease is dominantly transmitted. The distinction between these two situations is of importance, especially in terms of genetic counseling, but dominance is sometimes difficult to conclusively determine by using familial analysis since expression of the disease may be highly variable, with parents of even severely affected children showing no or extremely mild symptoms of the disease. We report here the study of eight point mutations (G46 V, A99T, S164L, R167 W, R206 W, G232 V, N461I, I473F) found in patients with no other detectable mutation. Three of these mutations, G46 V, S164L, and I473F, have not previously been described. Pedigree and/or serum alkaline phosphatase data suggested possible dominant transmission in families with A99T, R167 W, and G232 V. By means of site-directed mutagenesis, transfections in COS-1 cells, and three-dimensional (3D) modeling, we evaluated the possible dominant effect of these eight mutations. The results showed that four of these mutations (G46 V, A99T, R167 W, and N461I) exhibited a negative dominant effect by inhibiting the enzymatic activity of the heterodimer, whereas the four others did not show such inhibition. Strong inhibition resulted in severe hypophosphatasia, whereas partial inhibition resulted in milder forms of the disease. Analysis of the 3D model of the enzyme showed that mutations exhibiting a dominant effect were clustered in two regions, viz., the active site and an area probably interacting with a region having a particular biological function such as dimerization, tetramerization, or membrane anchoring.

Clinical aspects of defects in the determination of laterality.

Of individuals in the human population, 99.99% have developed identical thoracoabdominal asymmetry with the cardiac apex, a bilobed lung, the stomach, and the spleen on the left side of the midline, and the vena cavae, a trilobed lung, the appendix, and the larger liver lobe on the right. This arrangement of organs is situs solitus. Occasionally, individuals have a complete, mirror-image reversal of this asymmetry called situs inversus, and 20-25% of those individuals have an autosomal recessive condition, Kartagener syndrome, with ciliary dyskinesia, bronchiectasis, sinusitis, and infertility. Between these extremes of situs solitus and situs inversus lies the spectrum of situs ambiguus, characterized by isomerism, heterotaxy, and multiple malformations in one or more thoracic or abdominal organs. Although most abnormal situs in humans occurs sporadically, growing evidence suggests that interference with normal genetic mechanisms and pathways may be responsible for most cases. Familial cases suggest major effects of both autosomal and X-linked genes with both dominant and recessive expression. Situs inversus and situs ambiguus (SI/SA) occurring in probands who have close relatives with "isolated," nonsyndromic birth defects suggests that some of the pathways important in situs determination may also be involved in causing sporadic malformations not obviously associated with a defect in laterality determination. Human phenotypes of interest include the association of SI/SA with short rib-polydactyly syndromes and renal-hepatic-pancreatic dysplasia, and with agnathia and holoprosencephaly. Further elucidation of the developmental pathways involved in left-right axis determination should shed light on the causes of and relationships among these human phenotypes.

Type I diabetes mellitus in a patient with chromosome 22q11.2 deletion syndrome.

We describe a patient with type I diabetes, clinical findings consistent with velocardiofacial syndrome, and a chromosome 22q11.2 deletion. A nine-year-old boy presented with a history of polyuria, polydipsia, weight loss, hyperglycemia, ketosis, serum insulin antibodies, and a low C-peptide level. He had distinctive facial features, learning disabilities, short stature, and a history of glottic web and clubfoot. Although a normal karyotype was obtained, fluorescence in situ hybridization (FISH) revealed a submicroscopic deletion in the DiGeorge/velocardiofacial syndrome critical region at 22q11.2. His maternal half-brother also carried a chromosome 22q11.2 deletion. His mother has similar facial features and hypoparathyroidism. Autoimmune problems associated with chromosome 22q11.2 deletions have been reported. We suggest that the defects in immune regulation due to T-cell deficiency in chromosome 22q11.2 deletion syndrome may predispose to autoimmune disorders, including type I diabetes mellitus.

Oculoauriculovertebral abnormalities in children of diabetic mothers.

Maternal diabetes is known to have teratogenic effects. Malformations including neural tube defects, caudal dysgenesis, vertebral defects, congenital heart defects, femoral hypoplasia, and renal anomalies are described in infants of diabetic mothers. However, craniofacial anomalies have rarely been reported in such infants. Here we document craniofacial anomalies of patients born to diabetic mothers. We describe two patient populations: individuals evaluated through our genetics services for multiple malformations and individuals identified through a database search in our craniofacial clinic. The first group consists of 14 individuals evaluated in our genetics clinics who were born to diabetic mothers and had craniofacial anomalies. The second group consists of seven individuals who were identified from a craniofacial database search of patients with hemifacial microsomia and who were born to diabetic mothers. Thus, both groups were born to diabetic mothers and had hemifacial microsomia (67%), microtia (52%), hearing loss (43%), epibulbar dermoids (24%), and fused cervical vertebrae (24%). Therefore, the teratogenic effects of maternal diabetes probably include such craniofacial malformations as the oculoauriculovertebral/Goldenhar complex. Infants of diabetic mothers should be evaluated for craniofacial anomalies. Conversely, mothers of infants with craniofacial anomalies should be evaluated for diabetes to aid in counseling concerning cause and recurrence risks.

Genetic studies of autistic disorder and chromosome 7.

Genome-wide scans have suggested that a locus on 7q is involved in the etiology of autistic disorder (AD). We have identified an AD family in which three sibs inherited from their mother a paracentric inversion in the chromosome 7 candidate region (inv(7)(q22-q31.2)). Clinically, the two male sibs have AD, while the female sib has expressive language disorder. The mother carries the inversion, but does not express AD. Haplotype data on the family suggest that the chromosomal origin of the inversion was from the children's maternal grandfather. Based on these data, we have genotyped 76 multiplex (>/=2 AD affecteds/family) families for markers in this region of 7q. Two-point linkage analysis yielded a maximum heterogeneity lod score of 1.47 and maximum lod score (MLS) of 1.03 at D7S495. Multipoint MLS and NPL analyses resulted in peak scores of 1.77 at D7S2527 and 2.01 at D7S640. Examination of affected sibpairs revealed significant paternal (P = 0.007), but not maternal (P = 0. 75), identity-by-descent sharing at D7S640. Significant linkage disequilibrium was detected with paternal (P = 0.02), but not maternal (P = 0.15), transmissions at D7S1824 in multiplex and singleton families. There was also evidence for an increase in recombination in the region (D7S1817 to D7S1824) in the AD families versus non-AD families (P = 0.03, sex-averaged; and P = 0.01, sex-specific). These results provide further evidence for the presence of an AD locus on chromosome 7q, as well as provide evidence suggesting that this locus may be paternally expressed.

Mutation analysis of core binding factor A1 in patients with cleidocranial dysplasia.

Cleidocranial dysplasia (CCD) is a dominantly inherited disorder characterized by patent fontanelles, wide cranial sutures, hypoplasia of clavicles, short stature, supernumerary teeth, and other skeletal anomalies. We recently demonstrated that mutations in the transcription factor CBFA1, on chromosome 6p21, are associated with CCD. We have now analyzed the CBFA1 gene in 42 unrelated patients with CCD. In 18 patients, mutations were detected in the coding region of the CBFA1 gene, including 8 frameshift, 2 nonsense, and 9 missense mutations, as well as 2 novel polymorphisms. A cluster of missense mutations at arginine 225 (R225) identifies this residue as crucial for CBFA1 function. In vitro green fluorescent protein fusion studies show that R225 mutations interfere with nuclear accumulation of CBFA1 protein. There is no phenotypic difference between patients with deletions or frameshifts and those with other intragenic mutations, suggesting that CCD is generally caused by haploinsufficiency. However, we were able to extend the CCD phenotypic spectrum. A missense mutation identified in one family with supernumerary teeth and a radiologically normal skeleton indicates that mutations in CBFA1 can be associated exclusively with a dental phenotype. In addition, one patient with severe CCD and a frameshift mutation in codon 402 had osteoporosis leading to recurrent bone fractures and scoliosis, providing first evidence that CBFA1 may help maintain adult bone, in addition to its function in bone development.

A silent mutation, C924T (G308G), in the L1CAM gene results in X linked hydrocephalus (HSAS).

The L1 cell adhesion molecule (L1CAM) is a neuronal gene involved in the development of the nervous system. Mutations in L1CAM are known to cause several clinically overlapping X linked mental retardation conditions: X linked hydrocephalus (HSAS), MASA syndrome (mental retardation, aphasia, shuffling gait, adducted thumbs), spastic paraplegia type I (SPG1), and X linked agenesis of the corpus callosum (ACC). In an analysis of a family with HSAS, we identified a C-->T transition (C924T) in exon 8 that was initially thought to have no effect on the protein sequence as the alteration affected the third base of a codon (G308G). Extensive analysis of the other 27 exons showed no other alteration. A review of the sequence surrounding position 924 indicated that the C-->T transition created a potential 5' splice site consensus sequence, which would result in an in frame deletion of 69 bp from exon 8 and 23 amino acids of the L1CAM protein. RT-PCR of the RNA from an affected male fetus and subsequent sequence analysis confirmed the use of the new splice site. This is the first report of a silent nucleotide substitution in L1CAM giving rise to an alteration at the protein level. Furthermore, it shows that as mutation analysis plays an ever more important role in human genetics, the identification of a synonymous base change should not be routinely discounted as a neutral polymorphism.

Mutations involving the transcription factor CBFA1 cause cleidocranial dysplasia.

Cleidocranial dysplasia (CCD) is an autosomal-dominant condition characterized by hypoplasia/aplasia of clavicles, patent fontanelles, supernumerary teeth, short stature, and other changes in skeletal patterning and growth. In some families, the phenotype segregates with deletions resulting in heterozygous loss of CBFA1, a member of the runt family of transcription factors. In other families, insertion, deletion, and missense mutations lead to translational stop codons in the DNA binding domain or in the C-terminal transactivating region. In-frame expansion of a polyalanine stretch segregates in an affected family with brachydactyly and minor clinical findings of CCD. We conclude that CBFA1 mutations cause CCD and that heterozygous loss of function is sufficient to produce the disorder.

Maternal uniparental disomy of chromosome 2 and confined placental mosaicism for trisomy 2 in a fetus with intrauterine growth restriction, hypospadias, and oligohydramnios.

We present a case of maternal uniparental heterodisomy for chromosome 2 (UPD 2) detected after trisomy 2 mosaicism was found on placental biopsy. This case presented prenatally with severe intrauterine growth restriction (IUGR) and oligohydramnios. The diploid newborn had hypospadias and features consistent with oligohydramnios sequence. He died shortly after birth of severe pulmonary hypoplasia. The term placenta had high levels of trisomy 2 in both the trophoblast and the stroma. A comparison of this case with others reported in the literature suggests that the IUGR and oligohydramnios are likely related to placental insufficiency due to the high levels of trisomy 2 present in the trophoblast of the term placenta and the presence of UPD 2 in the diploid placental line.

Locus heterogeneity, anticipation and reduction of the chromosome 2p minimal candidate region in autosomal dominant familial spastic paraplegia.

We examined 11 Caucasian pedigrees with autosomal dominant 'uncomplicated' familial spastic paraplegia (SPG) for linkage to the previously identified loci on chromosomes 2p, 14q and 15q. Chromosome 15q was excluded for all families. Five families showed evidence for linkage to chromosome 2p, one to chromosome 14q, and five families remained indeterminate. Homogeneity analysis of combined chromosome 2p and 14q data gave no evidence for a fourth as yet unidentified SPG locus. Recombination events reduced the chromosome 2p minimum candidate region (MCR) to a 3 cM interval between D2S352 and D2S367 and supported the previously reported 7 cM MCR for chromosome 14q. Age of onset (AO) was highly variable, indicating that subtypes of SPG are more appropriately defined on a genetic basis than by AO. Comparison of AO in parent-child pairs was suggestive of anticipation, with a median difference of 9.0 years (p<0.0001).

Prenatal exposure to disulfiram implicated in the cause of malformations in discordant monozygotic twins.

Female monozygotic (MZ) twins were discordant for congenital structural anomalies: Twin A had a reduction defect of the right forearm; Twin B had a cleft palate. Both infants were small for gestational age. Specific prenatal exposures were identified at different times in the first trimester of pregnancy: crack cocaine, marijuana, disulfiram, heavy ethanol exposure, and cigarettes. The mother's hospitalization in a drug abuse program and incarceration allowed for identification of exposure timing. The cleft palate could have been related to either disulfiram or alcohol exposure; the limb abnormality most likely corresponded to the timing of disulfiram exposure. Discordance of anomalies in these twins may reflect differences in developmental timing, differences in susceptibility to one or more teratogens, or random events occurring within very complex developmental programs, with the thresholds for malformation affected by one or multiple teratogenic compounds.

Similarities of EEG and seizures in del(1q) and benign rolandic epilepsy.

We studied the seizure disorders manifested by three previously reported children with "de novo" terminal deletions of the long arm of chromosome 1 (46,XX,del(1)(q43)) and similar clinical phenotypes. In late infancy, two of these children developed partial seizures characterized by tonic-clonic movements of the ipsilateral face and arm with occasional involvement of the leg. In both children, the seizure frequency decreased with increasing age. Electroencephalograms of these two children demonstrated centrotemporal spike discharges morphologically similar to rolandic spikes. Although these cases present significant similarities to benign rolandic epilepsy, they also express many manifestations not detected in benign rolandic epilepsy that may reflect the extensive deletion of chromosome 1. Based on the seizure semiology and centrotemporal epileptiform discharges, we suggest that the distal portion of the long arm of chromosome 1 is a potential site for a candidate gene for benign rolandic epilepsy.

Multiple congenital malformations in an infant prenatally diagnosed with mosaicism for dup(lq) and del(Xq).

After ultrasound diagnosis of a fetus with severe hydrocephalus and Dandy-Walker malformation, amniocentesis revealed chromosomal mosaicism for dup(lq) and del(Xq). The neonate had dysmorphic facial features, vertebral abnormalities, and pulmonary hypoplasia, and expired shortly after birth. This report confirms the poor prognosis reported for partial trisomies involving the long arm of chromosome number 1.

Preliminary phenotypic map of chromosome 4p16 based on 4p deletions.

We have collected and analyzed clinical information from 11 patients with chromosome 4p deletions or rearrangements characterized by various molecular techniques. Comparing the extent of these patients' deletions with their respective clinical presentations led to the proposal of a preliminary phenotypic map of chromosome 4p. This map consists of regions which, when deleted, are associated with specific clinical manifestations. Nonspecific changes such as mental and growth retardation are not localized, and probably result from the deletion of more than one gene or region. The region associated with most of the facial traits considered typical in Wolf-Hirschhorn syndrome (WHS) patients coincides with the currently proposed WHS critical region (WHSCR), but some anomalies commonly seen in WHS appear to map outside of the WHSCR. The observation of clinodactyly in 2 patients with nonoverlapping deletions allows assignment of these defects to at least 2 separate regions in 4p16. These initial observations and attempts at genotype/phenotype correlation lay the groundwork for identifying the genetic basis of these malformations, a common objective of gene mapping efforts and chromosome deletion studies.

A recurrent mutation in the tyrosine kinase domain of fibroblast growth factor receptor 3 causes hypochondroplasia.

Hypochondroplasia (MIM 146000) is an autosomal dominant skeletal dysplasia with skeletal features similar to but milder than those seen in achondroplasia. Within the past year, the achondroplasia locus has been mapped to 4p 16.3 (refs 5-7) and mutations in the fibroblast growth factor receptor 3 (FGFR3) gene have been identified in patients with the disorder. More than 95% of 242 cases reported so far are accounted for by a single Gly380Arg mutation. McKusick et al. proposed that achondroplasia and hypochondroplasia are allelic based on the similarities in phenotype between the two disorders and the identification of a severely dwarfed individual whose father had achondroplasia and whose mother had hypochondroplasia. There is also genetic linkage evidence that hypochondroplasia and achondroplasia map to the same locus. We therefore began a systematic screening of FGFR3 to detect mutations in patients with hypochondroplasia. We now report a single FGFR3 mutation found in 8 out of 14 unrelated patients with hypochondroplasia. This mutation causes a C to A transversion at nucleotide 1620, resulting in an Asn540Lys substitution in the proximal tyrosine kinase domain.

Distribution of 13 truncating mutations in the neurofibromatosis 1 gene.

Neurofibromatosis 1 (NF1) is a common genetic disorder characterized by abnormalities of tissues derived from the neural crest. To define germ-line mutations in the NF1 gene, we studied 20 patients with familial or sporadic cases of NF1 diagnosed clinically and one patient with only café-au-lait spots and no other diagnostic criteria. A protein truncation assay identified abnormal polypeptides synthesized in vitro from five RT-PCR products that represented the entire NF1 coding region. Truncated polypeptides were observed in 14 individuals. The mutations responsible for the generation of abnormal polypeptides were characterized by DNA sequencing. Thirteen previously unpublished mutations were characterized in the 14 individuals. The mutation 2027insC was observed in two unrelated individuals; the other 12 mutations were unique. The sequence changes included seven nonsense and four frameshift mutations that created premature translation termination signals, and two large in-frame deletions that led to the synthesis of truncated polypeptides. One of the mutations was found in the child with a single clinical diagnostic criterion, providing her with a presumptive diagnosis of NF1. Our results confirm that truncating mutations are frequent in both familial and sporadic NF1 cases. The identification of mutations in 14 of 21 individuals studied (67%) suggests that the use of protein truncation assays will rapidly accelerate the rate of identification of NF1 mutations. Because we scanned the entire NF1 coding region in each individual, the distribution of NF1 truncating mutations was discerned for the first time. The mutations were relatively evenly distributed throughout the coding region with no evidence for clustering.