Lack of Fas (APO-1/CD95) gene structural alterations or transcript variant ratio changes in breast cancer.

Fas (APO-1/CD95) is a transmembrane receptor protein involved in cell death signaling. Fas receptor and ligand are both expressed in breast cancer cells, however these cells are resistant to apoptosis. Fas gene mutations were detected in hematological and solid tumors, while overexpression of a soluble Fas isoform in serum was related to cancer stage and prognosis. In this work, direct sequencing of exons 6 and 9 of the Fas gene from 90 patients did not reveal any structural alterations. Moreover, no decrease was found in the ratio of the corresponding mRNA species of transmembrane versus soluble Fas isoforms in 31 breast cancer samples compared to 14 controls. Therefore, inhibition of Fas-mediated apoptosis may not be due to structural alterations in the critical exons 6 and 9 of the Fas gene or a shift of expression towards the soluble Fas isoform, but to other mechanisms operating in breast cancer cells.

Thalassaemia mutations within the 5'UTR of the human beta-globin gene disrupt transcription.

The mechanisms by which mutations within the 5' untranslated region (UTR) of the human beta-globin gene (HBB) cause thalassaemia are currently not well understood. We present here the first comprehensive comparative functional analysis of four 'silent' mutations in the human beta-globin 5'UTR, namely: +10(-T), +22(G --> A), +33(C --> G) and +(40-43)(-AAAC), which are present in patients with beta-thalassaemia intermedia. Expression of these genes under the control of the beta-globin locus control region in stable transfected murine erythroleukaemia cells showed that all four mutations decreased steady state levels of mRNA to 61.6%, 68%, 85.2% and 70.6%, respectively, compared with the wildtype gene. These mutations did not interfere with either mRNA transport from the nucleus to the cytoplasm, 3' end processing or mRNA stability. Nuclear run-on experiments demonstrated that mutations +10(-T) and +33(C --> G) reduced the rate of transcription to a degree that fully accounted for the observed lower level of mRNA accumulation, suggesting a disruption of downstream promoter sequences. Interestingly, mutation +22(G --> A) decreased the rate of transcription to a low degree, indicating the existence of a mechanism that acts post-transcriptionally. Generally, our data demonstrated the significance of functionally analysing mutants of this type in the presence of a full complement of transcriptional regulatory elements within a stably integrated chromatin context in an erythroid cell environment.

The beta-globin C-->G mutation at 6 bp 3' to the termination codon causes beta-thalassaemia by decreasing the mRNA level.

We have studied the expression of the silent beta-thalassaemia term+6 (C-->G) mutation, at nucleotide 6 after the stop codon within the human beta-globin 3' untranslated regions (3'UTR), by stable transfection in murine erythroleukaemia (MEL) cells. Steady state mRNA levels from transfected MEL cells containing the term+6 mutant allele were reduced by 52-60%, compared with those obtained from the normal beta-globin gene, in both total and cytoplasmic RNA fractions, showing that the mutation itself is responsible for the similar data obtained from patients. Upon analysis of nuclear RNA, the term+6 mutation was found to also lower the ratio of cleaved/uncleaved transcripts by 22-30%, thus revealing that it interferes with correct 3'-end formation of beta-globin mRNA. The term+6 mutation lies within a polypyrimidine track, similar to that in the beta-intervening sequence II (beta-IVSII), which is known to be an important contributor to the promotion of premRNA 3'-end formation. We propose that the two polypyrimidine tracks flanking the translated region of exon III of the human beta-globin gene may co-operate during beta-globin mRNA biogenesis.