Peter M. Green

Haemophilia B: database of point mutations and short additions and deletions, 7th edition

The seventh edition of the haemophilia B database lists in easily accessible form all known factor IX mutations due to small changes (base substitutions and short additions and/or deletions of <30 bp) identified in haemophilia B patients. The 1535 patient entries are ordered by the nucleotide number of their mutation. Where known, details are given on: factor IX activity, factor IX antigen in circulation, presence of inhibitor and origin of mutation. References to published mutations are given and the laboratories generating the data are indicated.

BRCA1 RING function is essential for tumor suppression but dispensable for therapy resistance.

Hereditary breast cancers are frequently caused by germline BRCA1 mutations. The BRCA1(C61G) mutation in the BRCA1 RING domain is a common pathogenic missense variant, which reduces BRCA1/BARD1 heterodimerization and abrogates its ubiquitin ligase activity. To investigate the role of BRCA1 RING function in tumor suppression and therapy response, we introduced the Brca1(C61G) mutation in a conditional mouse model for BRCA1-associated breast cancer. In contrast to BRCA1-deficient mammary carcinomas, tumors carrying the Brca1(C61G) mutation responded poorly to platinum drugs and PARP inhibition and rapidly developed resistance while retaining the Brca1(C61G) mutation. These findings point to hypomorphic activity of the BRCA1-C61G protein that, although unable to prevent tumor development, affects response to therapy.

Haemophilia B: Database of point mutations and short additions and deletions—eighth edition

The eighth edition of the haemophilia B database (http://www.umds.ac. uk/molgen/haemBdatabase.htm ) lists in an easily accessible form all known factor IX mutations due to small changes (base substitutions and short additions and/or deletions of <30 bp) identified in haemophilia B patients. The 1713 patient entries are ordered by the nucleotide number of their mutation. Where known, details are given on: factor IX activity, factor IX antigen in circulation, presence of inhibitor and origin of mutation. References to published mutations are given and the laboratories generating the data are indicated.

Brown-Vialetto-Van Laere Syndrome, a Ponto-Bulbar Palsy with Deafness, Is Caused by Mutations in C20orf54

Brown-Vialetto-Van Laere syndrome is a rare neurological disorder with a variable age at onset and clinical course. The key features are progressive ponto-bulbar palsy and bilateral sensorineural deafness. A complex neurological phenotype with a mixed picture of upper and lower motor neuron involvement reminiscent of amyotrophic lateral sclerosis evolves with disease progression. We identified a candidate gene, C20orf54, by studying a consanguineous family with multiple affected individuals and subsequently demonstrated that mutations in this gene were the cause of disease in other, unrelated families.

Genomewide Linkage Analysis of Celiac Disease in Finnish Families

Celiac disease (CD), or gluten-sensitive enteropathy, is a common multifactorial disorder resulting from intolerance to cereal prolamins. The only established genetic susceptibility factor is HLA-DQ, which appears to explain only part of the overall genetic risk. We performed a genomewide scan of CD in 60 Finnish families. In addition to strong evidence for linkage to the HLA region at 6p21.3 (Z(max)>5), suggestive evidence for linkage was found for six other chromosomal regions--1p36, 4p15, 5q31, 7q21, 9p21-23, and 16q12. We further analyzed the three most convincing regions--4p15, 5q31, and 7q21--by evaluation of dense marker arrays across each region and by analysis of an additional 38 families. Although multipoint analysis with dense markers provided supportive evidence (multipoint LOD scores 3.25 at 4p15, 1.49 at 5q31, and 1.04 at 7q21) for the initial findings, the additional 38 families did not strengthen evidence for linkage. The role that HLA-DQ plays was studied in more detail by analysis of DQB1 alleles in all 98 families. All but one patient carried one or two HLA-DQ risk alleles, and 65% of HLA-DQ2 carriers were affected. Our study indicates that the HLA region harbors a predominant CD-susceptibility locus in these Finnish families.

Unusual deep intronic mutations in the COL4A5 gene cause X linked Alport syndrome

Abstract. The X-linked form of Alport syndrome is caused by mutations in the COL4A5 gene in Xq22. This large multiexonic gene has, in the past, been difficult to screen, with several studies detecting only about 50% of mutations. We report three novel intronic mutations that may, in part, explain this poor success rate and demonstrate that single base changes deep within introns can, and do, cause disease: one mutation creates a new donor splice site within an intron resulting in the inclusion of a novel in-frame cryptic exon; a second mutation results in a new exon splice enhancer sequence (ESE) that promotes splicing of a cryptic exon containing a stop codon; a third patient exhibits exon skipping as a result of a base substitution within the polypyrimidine tract that precedes the acceptor splice site. All three cases would have been missed using an exon-by-exon DNA screening approach.

Factor VIII gene explains all cases of haemophilia A

Using an mRNA-based method to examine haemophilia A mutations we provide an explanation for the puzzling report that half of the mutations causing severe disease are not detected by analysis of the putative promoter, exons, and most exon/intron boundaries of the factor VIII gene. An unusual cluster of mutations involving regions of intron 22 not examined earlier leads to defective joining of exons 22 and 23 in the mRNA and caused haemophilia A in 10/24 severely affected UK patients.

Int22h‐related inversions causing hemophilia A: a novel insight into their origin and a new more discriminant PCR test for their detection

Summary.  Background: Intrachromosomal, homologous recombination of the duplicon int22h‐1 with int22h‐2 or int22h‐3 causes inversions accounting for 45% of severe hemophilia A, hence the belief that int22h‐2 and int22h‐3 are in opposite orientation to int22h‐1. However, inversions involving int22h‐2 are five times rarer than those involving its virtually identical copy: int22h‐3. Recent sequencing has indicated that int22h‐2 and int22h‐3 form the internal part of the arms of an imperfect palindrome so that int22h‐2, in the centromeric arm, has the same orientation as int22h‐1 and, upon recombination with int22h‐1, should produce deletions and duplications but not inversions. Aim: This work aims to provide rapid tests for all the mutations that can result from recombinations between the int22h sequences and to investigate whether int22h‐2‐related inversions causing hemophilia A arise in chromosomes, where the arms of the palindrome have recombined so that int22h‐2 and int22h‐3 swap places and orientation. Patients/methods: Twenty patients with int22h‐related inversions were examined together with a control and inversion carriers using reverse transcription‐polymerase chain reaction (RT‐PCR), long‐range PCR and sequencing. Results and conclusions: Analysis of mRNA in patients and a control provided evidence confirming the palindromic arrangement of int22h‐2 and int22h‐3 and the proposed inversion polymorphism that allows int22h‐2 to be in the telomeric arm of the palindrome and in opposite orientation to int22h‐1. New long‐range PCR reactions were used to develop a single tube test that detects and discriminates inversions involving int22h‐2 or int22h‐3 and a two‐tube test that can distinguish inversions, deletions, and duplications due to recombination between int22h sequences.

Mutation rates in humans. II. Sporadic mutation-specific rates and rate of detrimental human mutations inferred from hemophilia B

We estimated the rates per base per generation of specific types of mutations, using our direct estimate of the overall mutation rate for hemophilia B and information on the mutations present in the United Kingdoms population as well as those reported year by year in the hemophilia B world database. These rates are as follows: transitions at CpG sites 9.7x10-8, other transitions 7.3x10-9, transversions at CpG sites 5.4x10-9, other transversions 6.9x10-9, and small deletions/insertions causing frameshifts 3.2x10-10. By taking into account the ratio of male to female mutation rates, the above figures were converted into rates appropriate for autosomal DNA-namely, 1.3x10-7, 9.9x10-9, 7.3x10-9, 9.4x10-9, 6.5x10-10, where the latter is the rate for all small deletion/insertion events. Mutation rates were also independently estimated from the sequence divergence observed in randomly chosen sequences from the human and chimpanzee X and Y chromosomes. These estimates were highly compatible with those obtained from hemophilia B and showed higher mutation rates in the male, but they showed no evidence for a significant excess of transitions at CpG sites in the spectrum of Y-sequence divergence relative to that of X-chromosome divergence. Our data suggest an overall mutation rate of 2.14x10-8 per base per generation, or 128 mutations per human zygote. Since the effective target for hemophilia B mutations is only 1.05% of the factor IX gene, the rate of detrimental mutations, per human zygote, suggested by the hemophilia data is approximately 1.3.

Detection of mutations in COL4A5 in patients with Alport Syndrome

Alport syndrome (AS) can be caused by mutations in COL4A5, one of the six type IV collagen genes. For the purposes of confirming diagnoses, carrier screening and correlating genotype to phenotype, we have screened all 51 exons of this gene by SSCP analysis in 153 families with suspected AS. Mutations were identified in 77 families (of which 20 have previously been reported) and are reported with all available clinical information. All types of mutation were found (missense, nonsense, splicing, small and large deletions and insertions), with the commonest type being those affecting glycine residues in the collagen triple helix. Our 50% detection rate is similar to that of other groups and may imply the presence of mutations outside of the COL4A5 coding region or the existence of a second X‐linked AS gene. Hum Mutat 13:124–132, 1999.