Classic, atypically severe and neonatal Marfan syndrome: twelve mutations and genotype-phenotype correlations in FBN1 exons 24-40.

Mutations in the gene for fibrillin-1 (FBN1) cause Marfan syndrome, an autosomal dominant disorder of connective tissue with prominent manifestations in the skeletal, ocular, and cardiovascular system. There is a remarkable degree of clinical variability both within and between families with Marfan syndrome as well as in individuals with related disorders of connective tissue caused by FBN1 mutations and collectively termed type-1 fibrillinopathies. The so-called neonatal region in FBN1 exons 24-32 comprises one of the few generally accepted genotype-phenotype correlations described to date. In this work, we report 12 FBN1 mutations identified by temperature-gradient gel electrophoresis screening of exons 24-40 in 127 individuals with Marfan syndrome or related disorders. The data reported here, together with other published reports, document a significant clustering of mutations in exons 24-32. Although all reported mutations associated with neonatal Marfan syndrome and the majority of point mutations associated with atypically severe presentations have been found in exons 24-32, mutations associated with classic Marfan syndrome occur in this region as well. It is not possible to predict whether a given mutation in exons 24-32 will be associated with classic, atypically severe, or neonatal Marfan syndrome.

Differential effect of FBN1 mutations on in vitro proteolysis of recombinant fibrillin-1 fragments.

Mutations in the fibrillin-1 gene (FBN1) cause Marfan syndrome (MFS), an autosomal dominant disorder of connective tissue with highly variable clinical manifestations. FBN1 contains 47 epidermal growth factor (EGF)-like modules, 43 of which display a consensus sequence for calcium binding (cbEGF). Calcium binding by cbEGF modules is thought to be essential for the conformation and stability of fibrillin-1. Missense mutations in cbEGF modules are the most common mutations found in MFS and generally affect one of the six highly conserved cysteines or residues of the calcium-binding consensus sequence. We have generated a series of recombinant fibrillin-1 fragments containing six cbEGF modules (cbEGF nos. 15-20) with various mutations at different positions of cbEGF module no. 17, which is known to contain a cryptic cleavage site for trypsin. A mutation affecting a residue of the calcium-binding consensus sequence (K1300E) found in a patient with relatively mild clinical manifestations of classic MFS caused a modest increase in susceptibility to in vitro proteolysis by trypsin, whereas a mutation affecting the sixth cysteine residue of the same cbEGF module (C1320S) reported in a severely affected patient caused a dramatic increase in susceptibility to in vitro proteolysis by trypsin. A mutation at the cryptic cleavage site for trypsin abolished sensitivity of wild-type fragments and fragments containing K1300E to trypsin proteolysis. Whereas the relevance of in vitro proteolysis to the in vivo pathogenesis of MFS remains unclear, our findings demonstrate that individual mutations in cbEGF modules can affect these modules differentially and may suggest an explanation for some genotype-phenotype relationships in MFS.

Clustering of mutations associated with mild Marfan-like phenotypes in the 3' region of FBN1 suggests a potential genotype-phenotype correlation.

Mutations in the gene for fibrillin-1 (FBN1) cause Marfan syndrome, a dominantly inherited disorder of connective tissue that primarily involves the cardiovascular, ocular, and skeletal systems. There is a remarkable degree of variability both within and between families with Marfan syndrome, and FBN1 mutations have also been found in a range of other related connective tissue disorders collectively termed type-1 fibrillinopathies. FBN1 mutations have been found in almost all of the 65 exons of the FBN1 gene and for the most part have been unique to one affected patient or family. Aside from the "hot spots" for the neonatal Marfan syndrome in exons 24-27 and 31-32, genotype-phenotype correlations have been slow to emerge. Here we present the results of temperature-gradient gel electrophoresis analysis of FBN1 exons 59-65. Six mutations were identified, only one of which had been previously reported. Two of the six mutations were found in patients with mild phenotypes. Taken together with other published reports, our results suggest that a sizable subset (ca. 40%) of mutations in this region is associated with mild phenotypes characterized by the lack of significant aortic pathology, compared with about 7% in the rest of the gene. In two cases, mutations affecting analogous positions within one of the 43 cbEGF modules of FBN1 are associated with mild phenotypes when found in one of the 6 C-terminal modules (encoded by exons 59-63), but are associated with classic or severe phenotypes when found in cbEGF modules elsewhere in the gene.

Novel exon skipping mutation in the fibrillin-1 gene: two 'hot spots' for the neonatal Marfan syndrome.

The Marfan syndrome is an autosomal dominant heritable disorder of connective tissue that involves principally the skeletal, ocular, and cardiovascular systems. The most severe end of the phenotypic spectrum, the neonatal Marfan syndrome (nMFS), is characterized by pronounced atrioventricular valve dysfunction, and death often occurs within the first year of life due to congestive heart failure. Mutations in the gene coding for fibrillin-1, FBN1, are known to cause Marfan syndrome, and have been identified in almost all exons of FBN1. Here, we describe a novel mutation affecting the invariant + 1 position of the splice donor site in intron 31, associated with skipping of exon 31, in a patient with nMFS. Published reports of nMFS are reviewed and a strict definition for nMFS is suggested. If this definition is used, all nMFS mutations reported to date lie in one of two hot spots, comprising mainly missense mutations in FBN1 exons 24-27 and mutations causing skipping of exon 31 or 32.

Species-specific detection of Legionella using polymerase chain reaction and reverse dot-blotting.

Legionella pneumophila and some other Legionella species are capable of causing Legionnaire's disease, a potentially fatal pneumonia. The identification of legionellae by standard laboratory techniques such as culture is difficult and time consuming. In the present work, the DNA sequence of the 23S-5S spacer region was determined for 43 Legionella isolates, and the sequence information was used to develop a species-specific detection system using PCR and reverse dot-blotting which employs just one PCR amplicon to perform genus- and species-specific detection. L. pneumophila serogroups 1-16 as well as 21 non-pneumophila isolates could be identified and differentiated at the species level using this system.

Low frequency of p53 gene mutation and protein expression in mucinous colorectal carcinomas.

Immunohistochemical data indicate that the frequency of p53 protein overexpression is consistently lower in the mucinous than in the non-mucinous carcinomas of the breast, ovary, pancreas and colon. This peculiar immunohistochemical behavior of the mucinous phenotype could be due to the effect of large amounts of mucus on the staining or to an actual mutation frequency difference between mucinous and non-mucinous carcinomas. This question was investigated on a group of mucinous colorectal carcinomas. DNA was extracted from paraffin sections of 16 human mucinous colorectal carcinomas and the mutation frequency was determined by sequencing of p53 exons amplified in PCR. The expression of p53 protein was determined with the avidin-biotin complex-peroxidase staining procedure and CM-1 antiserum. Twenty-five percent of the tumors, exhibited p53 protein overexpression and in 31% a mutation was detected. Concordance between the two techniques was found in 69% of tumors. Overexpression without mutation was observed in 12% and mutation without overexpression in 19%. G:C --> A:T transitions represented the most frequent lesion (80%), as previously observed in non-mucinous colorectal carcinomas. These data indicate that the mutation pattern in the p53 gene is similar in mucinous and non-mucinous colorectal carcinomas. The low frequency of p53 overexpression in the mucinous phenotype is not due to a mucus effect on the staining but is related to the low mutation frequency of p53 gene. These results lead to the hypothesis that in contrast to the nonmucinous tumors the development of the majority of colonic carcinomas with the mucinous phenotype may be independent from p53 mutations.