A second locus for Marfan syndrome maps to chromosome 3p24.2-p25.

Marfan syndrome (MFS) is an autosomal dominant connective-tissue disorder characterized by skeletal, ocular and cardiovascular defects of highly variable expressivity. The diagnosis relies solely on clinical criteria requiring anomalies in at least two systems. By excluding the chromosome 15 disease locus, fibrillin 1 (FBN1), in a large French family with typical cardiovascular and skeletal anomalies, we raised the issue of genetic heterogeneity in MFS and the implication of a second locus (MFS2). Linkage analyses, performed in this family, have localized MFS2 to a region of 9 centiMorgans between D3S1293 and D3S1283, at 3p24.2-p25. In this region, the highest lod score was found with D3S2336, of 4.89 (theta = 0.05). By LINKMAP analyses, the most probable position for the second locus in MFS was at D3S2335.

Fibulin-2: genetic mapping and exclusion as a candidate gene in Marfan syndrome type 2.

Fibulin-2 (FBLN2) is a new extracellular matrix protein that has been considered a candidate gene for Marfan syndrome type 2 (locus MFS2) based on chromosomal colocation at 3p24.2-p25 and disease phenotype. In the absence of polymorphic markers reported for FBLN2, direct sequencing of the gene was performed and two intragenic polymorphisms were identified. Linkage was excluded between FBLN2 and the MFS2 gene. Furthermore, two-point lod scores were generated between these markers and anonymous markers arrayed on the genetic map of 3p and closely linked to MFS2. These analyses placed FBLN2 at marker D3S1585.

[Contribution of genetics to pathogenicity and diagnosis of Marfan syndrome]. / Apport de la génétique à la pathogénie et au diagnostic de la maladie de Marfan.

The anatomical substrate of Marfan's syndrome is a degeneration of elastic fibres and disorganization of the collagen. It is now known that these lesions are due to mutation of genes localised on chromosome 15. The first of them (FBN1) codes for the main constitutive protein of the elastic tissue: fibrillin 1, present mainly in structures which must resist load and stress (aortic adventitia, the suspending ligament of the lens, skin); the second (FBN2) codes for fibrillin 2: responsible for the orientation of the elastin and mainly present in cartilage, the aortic media, the bronchi, and all tissues rich in elastin. Mutations of FBN1 are very common and are associated not only with Marfan's syndrome but also fibrillinopathies: incomplete forms, neonatal forms, ectopic lens, isolated aneurysms of the thoracic aorta. The widespread distribution of fibrillin explains the pleiotropic nature of Marfan's syndrome and its clinical presentation. The variability of interfamilial expression is due to genetic heterogeneity (at least two genes) and alletic differences (different mutations of FBN1 from one family to another), also explaining mild forms due to quantitative reduction in normal fibrillin and severe forms by "negative dominance" where the fibrillin is structurally abnormal because of alteration of the polymerisation mechanism. The biologic diagnosis of fibrillopathy can be made by a protein test analysing fibrillin on a culture of the patient's fibroblast obtained by skin biopsy. At present, molecular diagnosis of the mutation within the FBN1 gene is not feasible as a routine procedure.

Software and database for the analysis of mutations in the human FBN1 gene.

Fibrillin is the major component of extracellular microfibrils. Mutations in the fibrillin gene on chromosome 15 (FBN1) were described at first in the heritable connective tissue disorder, Marfan syndrome (MFS). More recently, FBN1 has also been shown to harbor mutations related to a spectrum of conditions phenotypically related to MFS and many mutations will have to be accumulated before genotype/phenotype relationships emerge. To facilitate mutational analysis of the FBN1 gene, a software package along with a computerized database (currently listing 63 entries) have been created.

Screening for new mutations in the LDL receptor gene in seven French familial hypercholesterolemia families by the single strand conformation polymorphism method.

To investigate the molecular basis of familial hypercholesterolemia (FH) in France, we applied the single strand conformation polymorphism (SSCP) method to the promoter region and the 18 exons of the low density lipoprotein receptor (LDLR) gene. Seven probands, 4 heterozygotes, 2 compound heterozygotes, and 1 homozygote, belonging to FH families were tested. In all cases, previous genetic analysis and/or LDL receptor fibroblast assay had shown that the disease was due to defects in the LDLR gene. Out of the nine mutations expected, one nonsense mutation in exon 2 and six missense mutations were identified in exons 3, 6, 8, 11, and 15. Two of the latter were found in exon 6. In each family, cosegregation of the base substitution and the disease was observed. Ninety-five control subjects were screened for the presence of the six missense mutations. None was detected, implying that the mutations identified are deleterious. Our results indicate that the SSCP analysis of amplified genomic DNA fragments can be successfully used to rapidly screen mutation containing exons in large genes. Furthermore, all these mutations are newly described and demonstrate heterogeneity of LDLR gene mutations responsible for FH in the French population, as in other reported Caucasian populations.