Cerebrotendinous xanthomatosis caused by two new mutations of the sterol-27-hydroxylase gene that disrupt mRNA splicing.

Cerebrotendinous xanthomatosis (CTX) is an inherited sterol storage disease associated with the accumulation of cholestanol and cholesterol in various tissues. CTX is caused by a deficiency of sterol-27-hydroxylase, a mitochondrial enzyme that oxidizes the side chain of cholesterol in the pathway leading to the formation of bile acids. In the present study we report two mutations of sterol-27-hydroxylase gene (CYP27 gene) found in Italian CTX patients. Proband T.C. is homozygous for a G-->A transition at the first nucleotide of intron 7. This mutation causes the formation of minute amounts of an abnormal mRNA, in which exon 6 joins directly to exon 8 with the skipping of exon 7. The exon 6-exon 8 junction results in a frame shift, downstream from the codon for Arg362, which generates a string of 28 novel amino acids preceding a premature termination codon. Proband C.U. is homozygous for a G-->C transversion at the last nucleotide of exon 3. This mutation, which changes the consensus sequence of the 5' donor splice site, is associated with barely detectable levels of sterol-27-hydroxylase mRNA, of normal size, in proband fibroblasts. As both mutations change the sites for two restriction enzymes, rapid methods were devised for the identification of the healthy carriers among the probands' family members and for the screening of these mutations in other CTX patients.

Partial deletion of the gene encoding sterol 27-hydroxylase in a subject with cerebrotendinous xanthomatosis.

An Italian subject with cerebrotendinous xanthomatosis (CTX) was found to have a partial deletion of the gene encoding the enzyme sterol 27-hydroxylase (CYP27 gene). Southern blot analysis revealed that this deletion (approximately 2 kb) spans from intron 6 to the 3' flanking (3'FLK) region, eliminating exons 7-9, the last three exons of CYP27 gene. No sterol 27-hydroxylase mRNA was detected in proband cells, either by Northern blot analysis or by reverse transcription polymerase chain reaction (PCR). This suggests that the mutant mRNA devoid of the exon encoding the whole untranslated sequence (exon 9) might be rapidly degraded in the cytoplasm. We used inverse PCR to obtain a partial sequence of the 3'FLK region of the normal CYP27 gene; this allowed us to define the mechanism underlying the deletion. The established sequence was used to design suitable primers to perform step-wise sequences of a 1.7 kb segment of the 3'FLK region of the normal gene and of the deletion joint in the CTX patient. The analysis of the sequence data indicate that the deletion might result from a complex mechanism involving two intragenic recombinations between a) two 14 nucleotide complementary sequences, one in intron 6 and the other in the 3'FLK region: and b) AT-rich complementary sequences of the 3'FLK region, and a slipped mispairing between two 6 nucleotide direct repeats, one in intron 6 and the other in the 3'FLK region. Such repeats are brought close to each other by the formation of the stem-loops induced by the two intragenic recombinations. This is the first example of CTX caused by a rearrangement of CYP27 gene.

Two novel partial deletions of LDL-receptor gene in Italian patients with familial hypercholesterolemia (FH Siracusa and FH Reggio Emilia).

In the present study we report two novel partial deletions of the LDL-R gene. The first (FH Siracusa), found in an FH-heterozygote, consists of a 20 kb deletion spanning from the 5' flanking region to the intron 2 of the LDL-receptor gene. The elimination of the promoter and the first two exons prevents the transcription of the deleted allele, as shown by Northern blot analysis of LDL-R mRNA isolated from the proband's fibroblasts. The second deletion (FH Reggio Emilia), which eliminates 11 nucleotides of exon 10, was also found in an FH heterozygote. The characterization of this deletion was made possible by a combination of techniques such as single strand conformation polymorphism (SSCP) analysis, direct sequence of exon 10 and cloning of the normal and deleted exon 10 from the proband's DNA. The 11 nt deletion occurs in a region of exon 10 which contains three triplets (CTG) and two four-nucleotides (CTGG) direct repeats. This structural feature might render this region more susceptible to a slipped mispairing during DNA duplication. Since this deletion causes a shift of the BamHI site at the 5' end of exon 10, a method has been devised for its rapid screening which is based on the PCR amplification of exon 10 followed by BamHI digestion. FH Reggio Emilia deletion produces a shift in the reading frame downstream from Lys458, leading to a sequence of 51 novel amino acids before the occurrence of a premature stop codon (truncated receptor). However, since RT-PCR failed to demonstrate the presence of the mutant LDL-R mRNA in proband fibroblasts, it is likely that the amount of truncated receptor produced in these cells is negligible.