1/34. Chromosome 7 short arm deletion and craniosynostosis. A 7p-syndrome.A patient with craniosynostosis and a small deletion of part of the short arm of chromosome 7 is described. A review of the literature indicates that craniosynostosis has occurred in at least four of the five infants (the fifth having microcephaly) affected by structural changes (resulting in deletion) within the terminal region of the short arm of chromosome 7.- - - - - - - - - - ranking = 1keywords = chromosome (Clic here for more details about this article) |
2/34. Partial duplication of the long arm of chromosome 15: confirmation of a causative role in craniosynostosis and definition of a 15q25-qter trisomy syndrome.A syndrome of mental retardation and multiple congenital anomalies, including craniosynostosis and overgrowth, was observed in two related individuals from a large kindred. Both of them carried a 15q25.1-qter trisomy associated with a subtle 13qter monosomy resulting from unbalanced segregation of a familial t(13;15)(q34;q25.1) translocation. Reportedly, a further individual in this kindred has the same condition. The present report confirms previous claims that gene(s) in the distal 15q region play a role in suture formation. At the same time it adds new data to the delineation of a 15q25-qter trisomy syndrome.- - - - - - - - - - ranking = 2keywords = chromosome (Clic here for more details about this article) |
3/34. The 9p- syndrome.Six patients (4 females and 2 males) with terminal deletion of the short arm of chromosome 9 distal to band p22 are described. The disorder constitutes a clinically identifiable syndrome consisting of mental retardation, sociable personality, trigonocephaly, mongoloid eyes, wide flat nasal bridge, anteverted nostrils, long upper lip, short neck, long digits mostly secondary to long middle phalanges, and predominance of whorls on fingers. The findings suggest that the clinical features are antithetical to the trisomy 9p syndrome. The deleted chromosome segment is relatively small and could be easily overlooked. It is hoped that this delineation of clinical features seen in 9,p- patients may help in focusing attention on the small deletion.- - - - - - - - - - ranking = 1keywords = chromosome (Clic here for more details about this article) |
4/34. Saethre-Chotzen syndrome: review of the literature and report of a case.Saethre-Chotzen syndrome is an autosomal acrocephalosyndactyly syndrome whose gene has been assigned to chromosome 7p (TWIST). A case of a 13-year-old girl with Saethre-Chotzen syndrome (ACS III) is described. The features of the syndrome include: turriplagiocephaly with a cranial circumference of 52 cm, facial asymmetry, low hairline, proptosis, antimongoloid slanting of palpebral fissures, nasal deviation with high bridge, angled ears, scoliosis and torticollis, clinodactyly of the fourth and fifth toes, large halluxes, and neurosensorial hypoacusia. For correction of the deformity, a cranioorbital remodeling was performed. The craniofacial approach with remodeling of the frontal bar and reduction of the turricephaly resulted in a satisfactory morphological and functional outcome, with complete three-dimensional reshaping and remodeling of the frontonasoorbital area.- - - - - - - - - - ranking = 0.5keywords = chromosome (Clic here for more details about this article) |
5/34. Neurodevelopmental and behavioral abnormalities associated with deletion of chromosome 9p.We report a child with craniosynostosis, partial absence of the corpus callosum, developmental delay, precocious puberty, and deletion of chromosome 9(p12p13,3). A review of the literature did not reveal any previous combination of the same kind. Craniosynostosis and partial absence of the corpus callosum, separately or in conjunction, may be part of the spectrum of malformations in the chromosome 9p deletion syndrome, and its presence, in combination with other known features, should prompt a search for this particular deletion as part of the differential diagnosis.- - - - - - - - - - ranking = 3keywords = chromosome (Clic here for more details about this article) |
6/34. Roberts syndrome, normal cell division, and normal intelligence.Roberts-SC phocomelia syndrome (RS) is an autosomal recessive disorder of symmetric limb defects, craniofacial abnormalities, pre- and postnatal growth retardation, and mental retardation. patients with RS have been reported to have premature separation of heterochromatin of many chromosomes and abnormalities in the cell-division cycle. No case has been reported who had normal intelligence and normal cell division with typical clinical features of the RS. We report a case of a six-year-old male of clinical and radiologic findings of typical RS with normal cell division and normal intelligence.Although he showed growth retardation, his intelligence was normal. Van Den Berg and Francke later reported that 79 out of 100 cases of Roberts syndrome had premature cell separation (PCS). We think that this case may demonstrate severe expression of the Roberts syndrome even though PCS is not exhibited. The limb involvement of this case was symmetrical, and he showed phocomelia of upper limbs, equinus valgus deformity of ankle, aplasia of fibula, and shortness of fifth toes while his hands and feet were normal with 5 rays each. craniofacial abnormalities of this case were typical; he showed scaphocephaly, mild hypertelorism, mandibular hypoplasia, dysplastic helix of ear, narrowing of external auditory canal, and cleft palate with wide gap.This report supports the theory that normal intelligence can make social-personal adjustment possible even if all of the stigmata of Roberts syndrome is present.- - - - - - - - - - ranking = 0.5keywords = chromosome (Clic here for more details about this article) |
7/34. Clinical and genetic aspects of trigonocephaly: a study of 25 cases.We reviewed 25 patients ascertained through the finding of trigonocephaly/metopic synostosis as a prominent manifestation. In 16 patients, trigonocephaly/metopic synostosis was the only significant finding (64%); 2 patients had metopic/sagittal synostosis (8%) and in 7 patients the trigonocephaly was part of a syndrome (28%). Among the nonsyndromic cases, 12 were males and 6 were females and the sex ratio was 2 M:1 F. Only one patient with isolated trigonocephaly had an affected parent (5.6%). All nonsyndromic patients had normal psychomotor development. In 2 patients with isolated metopic/sagittal synostosis, FGFR2 and FGFR3 mutations were studied and none were detected. Among the syndromic cases, two had Jacobsen syndrome associated with deletion of chromosome 11q 23 (28.5%). Of the remaining five syndromic cases, different conditions were found including Say-Meyer syndrome, multiple congenital anomalies and bilateral retinoblastoma with no detectable deletion in chromosome 13q14.2 by G-banding chromosomal analysis and FISH, I-cell disease, a new acrocraniofacial dysostosis syndrome, and Opitz C trigonocephaly syndrome. The last two patients were studied for cryptic chromosomal rearrangements, with SKY and subtelomeric FISH probes. Also FGFR2 and FGFR3 mutations were studied in two syndromic cases, but none were found. This study demonstrates that the majority of cases with nonsyndromic trigonocephaly are sporadic and benign, apart from the associated cosmetic implications. Syndromic trigonocephaly cases are causally heterogeneous and associated with chromosomal as well as single gene disorders. An investigation to delineate the underlying cause of trigonocephaly is indicated because of its important implications on medical management for the patient and the reproductive plans for the family.- - - - - - - - - - ranking = 1keywords = chromosome (Clic here for more details about this article) |
8/34. Infantile spasms in a patient with williams syndrome and craniosynostosis.A patient with williams syndrome, craniosynostosis, and infantile spasms is described. At age 6 months, the infant demonstrated infantile spasms and craniosynostosis and was operated on for craniosynostosis and treated with adrenocorticotropic hormone (ACTH) for the infantile spasms. ACTH completely controlled the seizures, but was halted because of the progression of ventricular hypertrophy. The seizure returned, and he was found to have elfin face, failure-to-thrive, developmental delay, and dental malformation in addition to congenital heart defects. High-resolution chromosome analysis revealed interstitial deletion of 7q11.22-q11.23. Therefore his clinical and cytogenetic diagnosis was williams syndrome. thyrotropin-releasing hormone (TRH) therapy reduced his seizures and improved the findings of EEG without cardiac side effects. In addition, his psychomotor development was slightly improved.- - - - - - - - - - ranking = 0.5keywords = chromosome (Clic here for more details about this article) |
9/34. Balanced translocation in a patient with craniosynostosis disrupts the SOX6 gene and an evolutionarily conserved non-transcribed region.Craniosynostosis is a congenital developmental disorder involving premature fusion of cranial sutures, which results in an abnormal shape of the skull. Significant progress in understanding the molecular basis of this phenotype has been made for a small number of syndromic craniosynostosis forms. Nevertheless, in the majority of the approximately 100 craniosynostosis syndromes and in non-syndromic craniosynostosis the underlying gene defects and pathomechanisms are unknown. Here we report on a male infant presenting at birth with brachycephaly, proptosis, midfacial hypoplasia, and low set ears. Three dimensional cranial computer tomography showed fusion of the lambdoid sutures and distal part of the sagittal suture with a gaping anterior fontanelle. Mutations in the genes for FGFR2 and FGFR3 were excluded. Standard chromosome analysis revealed a de novo balanced translocation t(9;11)(q33;p15). The breakpoint on chromosome 11p15 disrupts the SOX6 gene, known to be involved in skeletal growth and differentiation processes. SOX6 mutation screening of another 104 craniosynostosis patients revealed one missense mutation leading to the exchange of a highly conserved amino acid (p.D68N) in a single patient and his reportedly healthy mother. The breakpoint on chromosome 9 is located in a region without any known or predicted genes but, interestingly, disrupts patches of evolutionarily highly conserved non-genic sequences and may thus led to dysregulation of flanking genes on chromosome 9 or 11 involved in skull vault development. The present case is one of the very rare reports of an apparently balanced translocation in a patient with syndromic craniosynostosis, and reveals novel candidate genes for craniosynostoses and cranial suture formation.- - - - - - - - - - ranking = 2keywords = chromosome (Clic here for more details about this article) |
10/34. FBN1, TGFBR1, and the Marfan-craniosynostosis/mental retardation disorders revisited.The recent identification of TGFBR2 mutations in marfan syndrome II (MFSII) [Mizuguchi et al. (2004); Nat Genet 36:855-860] and of TGFBR1 and TGFBR2 mutations in Loeys-Dietz aortic aneurysm syndrome (LDS) [Loeys et al. (2005); Nat Genet 37:275-281] [OMIM 609192] has provided direct evidence of abnormal signaling in transforming growth factors beta (TGF-beta) in the pathogenesis of marfan syndrome (MFS). In light of this, we describe the phenotypes and genotypes of five individuals. Patient 1 had MFS and abnormal cranial dura. Patient 2 had severe early onset MFS and an abnormal skull. patients 3 and 4 had probable Furlong syndrome (FS). Patient 5 had marfanoid (MD) features, mental retardation (MR), and a deletion of chromosome 15q21.1q21.3. All patients had a condition within the MFS, MD-craniosynostosis (CS) or MD-MR spectrum. The names of these entities may become redundant, and instead, come to be considered within the spectrum of TGF-beta signaling pathway disorders. Two recurrent heterozygous FBN1 mutations were found in patients 1 and 2, and an identical novel heterozygous de novo TGFBR1 mutation was found in patients 3 and 4, in whom altered fibrillin-1 processing was demonstrated previously [Milewicz et al. (2000); Am J Hum Genet 67:279]. A heterozygous FBN1 deletion was found in Patient 5. These findings support the notion that perturbation of extracellular matrix homeostasis and/or remodeling caused by abnormal TGF-beta signaling is the core pathogenetic mechanism in MFS and related entities including the MD-CS syndromes.- - - - - - - - - - ranking = 0.5keywords = chromosome (Clic here for more details about this article) |
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