Colorectal carcinoma and folate.

More than a million people a year worldwide develops colorectal cancer (CRC), with a mortality rate close to 33%. Most of the CRC cases are sporadic, only 25% of the patients have a family history of the disease, and major genes causing syndromes predisposing to CRC only account for 5-6% of the total cases. The following subtypes can be recognized: MIN (microsatellite instability), CIN (chromosomal instability), and CIMP (CpG island methylator phenotype). CRC arises from an accumulation of genetic and epigenetic alterations such as DNA methylation, which is able to modulate gene expression. Several studies in the literature show a possible correlation between an altered methylation in the promoter of tumor suppressor genes, proto-oncogenes, genes involved in DNA repair and the CRC risk; it has also been observed a global DNA hypomethylation, especially in the presence of a low folate uptake. Epigenetic changes are reversible, then could be interesting to evaluate on their relationship with dietary factors (as well as folates) and the genetic background of the individuals, for the development of novel strategies for cancer prevention.

Serum gamma-glutamyltransferase fractions in myotonic dystrophy type I: differences with healthy subjects and patients with liver disease.

OBJECTIVES: Elevation of serum gamma-glutamyltransferase (GGT), in absence of a clinically significant liver damage, is often found in Myotonic Dystrophy type-1 (DM1). In this study we investigated if a specific GGT fraction pattern is present in DM1. DESIGNS AND METHODS: We compared total and fractional GGT values (b-, m-, s-, f-GGT) among patients with DM1 or liver disease (LD) and healthy subjects (HS). RESULTS: The increase of GGT in DM1 and LD, vs HS, was mainly due to s-GGT (median: 32.7; 66.7; and 7.9 U/L, respectively), and b-GGT (8.5; 18.9; and 2.1 U/L). The subset of DM1 patients matched with HS with corresponding serum GGT showed higher b-GGT (6.0 vs 4.2 U/L). CONCLUSIONS: DM1 patients with normal total GGT values showed an alteration of the production and release in the blood of GGT fractions. Since increased s-GGT is also found in LD, a sub-clinical liver damage likely occurs in DM1 subjects apparently free of liver disease.

Selection of a WEHI-3B leukemia cell subclone resistant to inhibition by cholera toxin.

The studies on the inhibitory effect exerted by Cholera Toxin (CT) on cell growth and proliferation indicate a remarkable heterogeneity of cell response suggesting that the inhibition represents the final event of many different ways or mechanisms. After CT binding, cAMP accumulation may not occur (as in L1210 leukemia cells) or, when occurring (as in SR-4987 stromal cells), may not be coupled with the antiproliferative effect of CT. In WEHI-3B cells CT binds a Gal-GalNac-GM1b receptor and the anticlonogenic effect of CT seems correlated with cAMP accumulation. To demonstrate the central role of cAMP in WEHI-3B cells, starting from the sensitive cell strain we selected and established a clone of WEHI-3B resistant to CT. This revertant clone (WEHI-3B/CT/REV) is currently cultured in the absence of CT and in the proliferation assay shows a dramatic resistance (>46,000 than the parental cells). Stimulation ofWEHI-3B/CT/REV cells by cholera toxin failed to enhance cAMP and the ganglioside-CT binding studied on Thin Layer Chromatography (TLC) blots showed that the resistant cells lost the spot correspondent to the migration of Gal-GalNac-GM1b ganglioside. Both the lines respond at the same level to the adenylate cyclase stimulation by forskolin and the incorporation of GM1a did not decrease the resistance of WEHl-3B/CT/REV. These data confirm that Gal-GalNac-GM1b is the most important functional receptor for CT in WEHI-3B cells able to transduce the signal by enhancing cAMP which in turn inhibits cell proliferation (probably by cAMP dependent protein kinase activation). Our study describes the first cell line resistant to CT originated from a susceptible parental strain and provides a new interesting cell model for studying the cAMP dependent mechanisms involved in cell growth regulation.

Secretion of basic fibroblast growth factor (FGF-2) by WEHI-3B myelomonocytic leukemia cells.

In order to investigate the role of Fibroblast Growth Factors in hematopoietic cells, we studied the expression of FGF-1, FGF-2, FGF-3, FGF-4, FGF-5 and FGF-6 mRNAs both in murine myelomonocytic leukemia WEHI-3B and in a murine stromal cell line SR-4987. Secretion of FGF-2 in the cell culture supernatant was also studied. Expression of mRNA encoding for the above-mentioned FGFs was analyzed by RT-PCR. The production of FGF-2 in the conditioned media of WEHI-3B and SR-4987 cell cultures was evaluated by techniques of affinity chromatography, chromatofocusing and immunoblotting. The biological activity of FGF-2 was checked on SR-4987 cells by a agar clonogenic assay. In both cell lines mRNA was found encoding for FGF-1, FGF-2 and FGF-6 and WEHI-3B cells express also mRNA for FGF-3 (int-2) and FGF-4 (K-FGF/hst). Furthermore, supernatant from WEHI-3B cells was found to stimulate dramatically the agar clonogenicity of SR-4987 cells which have a very poor basal capacity for growth in agar. The clonogenic activity of WEHI-3B conditioned medium is due to FGF-2 secreted into cell culture supernatant whereas SR-4987 cells, although express FGF-2 mRNA, do not seem able to secrete this factor. The expression in myeloid leukemia cells of oncogene-related factors such as FGF-3, FGF-4 and FGF-6 together with the secretion of FGF-2 able to support a positive regulation of bone marrow stromal cells function suggest that FGFs may have an important role in sustaining the leukemogenic process and related disorders.