Genetic study in patients with factor XII deficiency: a report of three new mutations exon 13 (Q501STOP), exon 14 (P547L) and -13C>T promoter region in three compound heterozygotes.

A group of 29 patients with congenital factor XII (FXII) deficiency belonging to nine distinct families have been investigated. All were cases of true deficiency in the sense that there was no discrepancy between FXII activity and FXII antigen. From a clotting point of view, 11 patients appeared homozygous, as both FXII activity and antigen were very low (< or =1% and traces of antigen). In other words, they were cases with no cross-reactivity material. In the heterozygotes, FXII activity and antigen were about 50% of normal in all cases. The molecular studies revealed that seven patients were real homozygotes for the mutation -8G>C in the promoter region confirming the conclusions reported by coagulation tests. On the contrary, the remaining patients with a homozygote-like phenotype were instead found to be compound heterozygous for two distinct mutations. Three of these mutations were new mutations, namely the combination of -8G to C with 501Q to T (exon 13), 547P to L (exon 14) and -13C to T in the promoter, respectively. The remaining mutations seen were not new. It is interesting that all compound heterozygotes showed a clotting and immunological pattern similar to that shown by homozygotes, namely very low FXII activity and antigen. The new mutations were not present in the group of 98 normal persons of both sexes with the same geographical background. The wide diffusion of the -8G>C mutation in this group of patients coming from a limited geographical area suggests a founder effect. The significance and importance of genetic analysis in addition to clotting and immunological studies in FXII deficiency is emphasized.

Transcriptional deregulation and a missense mutation define ANKRD1 as a candidate gene for total anomalous pulmonary venous return.

Total anomalous pulmonary venous return (TAPVR) is a congenital heart defect in which the pulmonary veins fail to enter the left atrium and drain instead into the right atrium or one of its venous tributaries. Although a genetic basis for TAPVR has long been recognized, no single gene involved in the pathogenesis of this disease has been identified to date. We previously reported a TAPVR patient bearing a de novo 10;21 balanced translocation. In this work, we cloned both translocation breakpoints from this patient and mapped the ANKRD1 gene, encoding a cardiac transcriptional regulator, 130 kb proximally to the breakpoint on chromosome 10. In situ hybridization analysis performed on murine embryos showed ANKRD1 expression in the developing pulmonary veins, suggesting a possible role for this gene in TAPVR pathogenesis. Moreover, ANKRD1 expression levels were found to be highly increased in lymphoblastoid cell lines derived from both the translocation-bearing proband and a second independent sporadic TAPVR patient, suggesting that disruption of the normal ANKRD1 expression pattern is associated with TAPVR. Finally, a nonconservative missense mutation in the ANKRD1 gene was found in a third sporadic TAPVR patient. In vitro calpain-mediated degradation assays, coupled to reporter gene analysis in transfected HeLa cells, strongly suggested that this mutation enhances both the stability of the ANKRD1/CARP protein and its transcriptional repression activity upon the cardiac-specific atrial natriuretic factor (ANF) promoter. Taken together, these results define ANKRD1 as a possible candidate gene for TAPVR pathogenesis.

Tumor and metastasis suppression by the human RNASET2 gene.

The region 6q27 from human chromosome 6 has been reported to contain one or more tumor suppressor genes on the basis of cytogenetic, molecular and functional studies. We have recently carried out a detailed analysis of a candidate gene from 6q27 to evaluate its putative role as a tumor suppressor gene involved in ovarian cancer pathogenesis. The RNASET2 gene was shown to behave as a class II tumor suppressor and abolish the tumorigenic potential of an ovarian cancer-derived cell line. In this study, we have started the cellular and biochemical characterization of RNASET2 and showed that it is a secreted glycoprotein. Moreover, we have extended our previous studies by evaluating the effect of RNASET2 on the metastatic behavior of the highly-invasive ovarian cancer cell line HEY3MET2. From such analysis, RNASET2 was found to significantly decrease the metastatic potential of this cell line in vivo. Moreover, RNASET2-mediated suppression of tumorigenesis and metastasis was not affected by a double point mutation targeted to the putative ribonuclease catalytic sites, suggesting that tumor suppression by RNASET2 is not mediated by its ribonuclease activity. The potential biological implications of this unexpected finding are discussed in relation to the current evolutionary models.

Genetic damage induced by in vitro irradiation of human G0 lymphocytes with low-energy protons (28 keV/microm): HPRT mutations and chromosome aberrations.

Cell survival, mutations and chromosomal effects were studied in primary human lymphocytes exposed in G0 phase to a proton beam with an incident energy of 0.88 MeV (incident LET of 28 keV/microm) in the dose range 0.125-2 Gy. The curves for survival and mutations at the hypoxanthine-guanine phosphoribosyl transferase locus were obtained by fitting the experimental data to linear and linear-quadratic equations, respectively. In the dose interval 0-1.5 Gy, the alpha parameters of the curves were 0.42/Gy and 3.6 x 10(-6) mutants/Gy, respectively. The mutation types at the HPRT locus were analyzed by multiplex-PCR in 94 irradiated and 41 nonirradiated clones derived from T lymphocytes from five healthy donors. All clones showed a normal multiplex-PCR pattern and were classified as point mutations. Chromosome aberration data were fitted as a linear function of dose (alpha = 0.62 aberrations per cell Gy(-1)). By irradiating G0 lymphocytes from a single subject with 28 keV/microm protons and gamma rays, an RBE of 6.07 was obtained for chromosome aberrations. An overinvolvement of chromosome 9 relative to chromosome 7 was found in chromosome breaks after chromosome painting analysis.