Alfred Arnason

The T-box transcription factor gene TBX22 is mutated in X-linked cleft palate and ankyloglossia.

Formation of the secondary palate is a complex step during craniofacial development. Disturbance of the events affecting palatogenesis results in a failure of the palate to close. As a consequence of deformity, an affected child will have problems with feeding, speech, hearing, dentition and psychological development. Cleft palate occurs frequently, affecting approximately 1 in 1,500 births; it is usually considered a sporadic occurrence resulting from an interaction between genetic and environmental factors. Although several susceptibility loci have been implicated, attempts to link genetic variation to functional effects have met with little success. Cleft palate with ankyloglossia (CPX; MIM 303400) is inherited as a semidominant X-linked disorder previously described in several large families of different ethnic origins and has been the subject of several studies that localized the causative gene to Xq21 (refs. 10–13). Here we show that CPX is caused by mutations in the gene encoding the recently described T-box transcription factor TBX22 (ref. 14). Members of the T-box gene family are known to play essential roles in early vertebrate development, especially in mesoderm specification. We demonstrate that TBX22 is a major gene determinant crucial to human palatogenesis. The spectrum of nonsense, splice-site, frameshift and missense mutations we have identified in this study indicates that the cleft phenotype results from a complete loss of TBX22 function.

Mutation in cystatin C gene causes hereditary brain haemorrhage

Hereditary cystatin C amyloid angiopathy (HCCAA) is an autosomal dominant disorder in which a cysteine proteinase inhibitor, cystatin C, is deposited as amyloid fibrils in the cerebral arteries of patients and leads to massive brain haemorrhage and death in young adults. A full length cystatin C cDNA probe revealed a mutation in the codon for leucine at position 68 which abolishes an Alu I restriction site in the cystatin C gene of HCCAA patients. The Alu I marker has been used to show that this mutation is transmitted only in affected members of all eight families investigated, and that the mutated cystatin C gene causes HCCAA.

Abnormal Metabolism of γ-Trace Alkaline Microprotein : The Basic Defect in Hereditary Cerebral Hemorrhage with Amyloidosis

ALTHOUGH the total incidence of cerebral hemorrhage is high, comparatively few reports concerning the familial occurrence of this disease have been published.1 , 2 In 1935 Arnason described 10 fami...

Hereditary cystatin C (γ-trace) amyloid angiopathy of the CNS causing cerebral hemorrhage

Abstract Hereditary CNS amyloid angiopathy occurring in Icelanders is the first human disorder known to be caused by deposition of cystatin C amyloid fibrils in the walls of the brain arteries leading to single or or multiple strokes with fatal outcome. One or more affected members have been verified by histological examination in 8 families containing 127 affected. These originated from the same geographic area. Abnormally low value of cystatin C found in the cerebrospinal fluid of those affected can be used to support or make diagnosis of this disease, also in asymptomatic relatives. By amino acid sequence analysis the amyloid fibrils in the patients are found to be a variant of cystatin C (γ‐trace), a major cysteine proteinase inhibitor. The variant protein has an amino acid substitution (glutamine for leucine) at position 58 in the amyloid molecule. It is postulated that a point mutation has occurred leading to production of amyloidogenic protein causing the disorder.

Linkage of an X-chromosome cleft palate gene

Many congenital malformations, such as cleft palate and neural tube defects, have a multifactorial origin involving both environmental and genetic factors. Conditions such as these may be exclusively monogenic, polygenic or environmental, but in most cases both genetic and environmental factors are involved1. This study describes the sub-chromosomal localization of a single gene defect causing cleft palate and ankyloglossia (tongue-tied) in a large Icelandic family. This defect is a model for the analysis of other neural-crest malformations that show a more complex multi-factorial inheritance pattern.

Limited MHC polymorphism in whales

Little is known about disease and genetic variation in aquatic mammalian species such as whales. In this paper human HLA class I and class 11 probes were used to study major histocompatibility complex (MHC) genes from two species of whale: Fin (Balaenoptera physalus) and Sei (B. borealis). Stronger signals were obtained on whale than on equivalent concentrations of mouse DNA. Evidence was obtained for severalDRB-related genes, aDNA gene, oneDQA gene, and multiple class I genes in whales. Interestingly, the whale genes, from the small panel studied, were less polymorphic than those of humans or mice. The aquatic environment of this mammalian species may be a unique factor in shaping its immune response through the MHC.

Heterogeneity of human C4 gene size

In this article we present a study showing that the human C4 genes differ in length because of the presence or absence of a 6.5 kb intron near the 5′ end of the gene. DNA from individuals of known HLA, factor B, and C4 haplotypes was analyzed for restriction fragment length polymorphism (RFLP) by Southern blot analysis with C4-specific cDNA probes. The RFLP patterns obtained showed that the C4 genes are either 22.5 kb or 16 kb in length. They are referred to as long and short C4 genes, respectively. A population study was carried out to examine the distribution of the gene size according to C4 allotypes and haplotypes. Long C4 genes included all C4A genes studied and also some C4B allotypes, e. g., B1 on most C4 A3B1 haplotypes. Similarly, C4B null genes were found to be of the long form. Other C4B allotypes tested were found to be coded for by short C4 genes, including B2, B1 in C4 A6B1 and C4 AQOB1 (with a single C4B gene haplotype).

Gene organization of haplotypes expressing two different C4A allotypes.

SummaryThe gene organization of C4 haplotypes expressing two different C4A allotypes with a C4B null allele (C4A3A2-BQ0 and C4A3A6BQO) was studied using Southern blot analysis with cDNA probes and restriction enzymes which give C4A and C4B locus-specific restriction fragments. These haplotypes were shown to have both a C4A and a C4B locus present, suggesting that the C4B locus expresses a C4A protein. The finding of a 21-OH A and a 21-OH B gene on the C4A3A6BQO haplotype further suggests that this haplotype has the common gene organization C4A, 21-OH A, C4B, 21-OH B. A model explaining C4 null alleles on haplotypes found to have two C4 loci is presented.

causing amyloid angiopathy and brain hemorrhage - clinical genetics in Iceland

Firstly, we review investigations of hereditary cystatin C amyloid angiopathy, which is caused by a mutation in the cystatin C gene. Symptoms of brain haemorrhages, which lead to death in young adults, are the hallmark of this disorder. The mutation can now be detected by the RFLP method using Alu I restriction enzyme and cystatin C cDNA probe. Secondly, we give an overview of other clinical genetic studies in Iceland with emphasis on activities initiated or sponsored by the Genetical Committee of the University of Iceland. The list of references covers most publications on genetic studies of Icelanders.

Refinement of the X-linked cleft palate and ankyloglossia (CPX) localisation by genetic mapping in an Icelandic kindred

The gene responsible for X-linked cleft palate and ankyloglossia (CPX) has previously been localized to the proximal region of the q arm of the X chromosome in both Icelandic and North American Indian kindreds. In this study, further linkage analysis has been performed on the Icelandic family and has resulted in a significant reduction in the size of the interval containing the mutated gene. A new polymorphism at DXS95, together with DXS1002 and DXS349, defines the proximal boundary of the CPX interval, whereas DXYS1X defines the distal boundary. Multipoint analysis supports this localisation with a peak lod score of 12.7, more than 2 lod score units higher than the next most likely position. In order to assess the physical size of the CPX interval prior to initiating yeast artificial chromosome cloning, metaphase fluorescence in situ hybridisation analysis was performed with the closest flanking markers. The size of the interval between DXS95 and DXYS1X was estimated to be approximately 2–3 Mb.