Rheumatoid factors: value of their determination in patients with rheumatoid arthritis

IgM, IgA, IgG rheumatoid factors were investigated by a indirect immunofluorescence method in three groups of patients affected with rheumatoid arthritis of various picture: 30 patients with mild articular disease, 20 with severe joint involvement and 19 with articular and systemic symptoms. Rheumatoid factors occurred more frequently in patients with articular and extraarticular severe rheumatoid arthritis; moreover these patients showed higher titres and higher incidence of different immunoglobulin class rheumatoid factors in comparison with rheumatoid patients having mild joint disease.     

Structure of the replication fork in ultraviolet light-irradiated human cells.

The DNA extracted from xeroderma pigmentosum human fibroblasts previously irradiated with 12.5 J/m2 of UV light and pulse-labeled for 45 min with radioactive and (or) heavy precursors, was used to determine the structural characteristics of the replication fork. Density equilibrium centrifugation experiments showed that a fork moved 6 micrometer in 45 min and bypassed 3 pyrimidine dimers in both strands. The same length was covered in 15-20 min in control cells. The delay in irradiated cells was apparently due to pyrimidine dimers acting as temporary blocks to the fork movement. Evidence for this interpretation comes from kinetics of incorporation of [3H]thymidine into DNA, which show that the time necessary to attain a new stable level of DNA synthesis in irradiated cells is equivalent to that required for the replication fork to cover the interdimer distance in one strand. On the other hand, the action of S1 nuclease on DNA synthesized soon after irradiation gives rise to a bimodal distribution in neutral sucrose gradients, one peak corresponding to 43 X 10(6) daltons and the other to 3 X 10(6) daltons. These two DNA species are generated by the attack of the S1 nuclease on single-stranded regions associated with the replication fork. A possible explanation for these results is given by a model according to which there is a delayed bypass of the dimer in the leading strand and the appearance of gaps opposite pyrimidine dimers in the lagging strand, as a direct consequence of the discontinuous mode of DNA replication. In terms of the model, the DNA of 43 X 10(6) daltons corresponds to the leading strand, linked to the unreplicated branch of the forks, whereas the piece of 3 X 10(6) daltons is the intergap DNA coming from the lagging strand. Pulse and chase experiments reveal that the low molecular weight DNA grows in a pattern that suggests that more than one gap may be formed per replication fork.     

Gaps in DNA synthesized by ultraviolet light-irradiated WI38 human cells.

DNA replication in ultraviolet-irradiated human cells was examined by treatment of the extracted DNA with a single-strand specific endonuclease from Neurospora crassa. WI38 cells were uniformly labeled with 32Pi for two generations before irradiation and then labeled with [3H]thymidine after irradiation. The isolated DNA was sedimented in neutral sucrose gradients after incubation with the endonuclease. The endonuclease treatment had no effect on the sedimentation profiles of either [32P]DNA or [3H]DNA from unirradiated control cultures. The endonuclease treatment also did not significantly alter the profile of [32P]DNA from irradiated cultures but did introduce breaks in the 3H pulse-labeled DNA synthesized after irradiation. These results indicate that DNA synthesis after ultraviolet irradiation proceeds in such fashion that gaps are formed along the newly made strand, leaving regions of single strandness in template DNA. As replication proceeds these gaps disappear and 2 h after irradiation (100-250 ergs/mm2) they are barely detectable by the endonuclease assay.     

T4-endonuclease V-sensitive sites in DNA from ultraviolet-irradiated human cells.

Human diploid cells (WI38) were pre-labeled with 32Pi, exposed to ultraviolet irradiation and then pulse labeled with [3H]thymidine. The extracted DNA from these cells was subsequently treated with the T4-endonuclease V, an enzyme which specifically nicks DNA strands at positions adjacent to pyrimidine dimers. Sedimentation in alkaline sucrose gradients revealed that the DNA synthesized after irradiation, as well as that made before, contained endonuclease-sensitive sites. Our results suggest that pyrimidine dimers are transferred from parental to daughter DNA strands during post-irradiation incubation. Sedimentation in neutral sucrose gradients showed that the molecular weight of native DNA was not affected by the endonuclease treatment, suggesting that the gaps appearing in daughter strands after irradiation are not opposite dimers or that the enzyme cannot recognize dimers in the gap regions.     

Iron and its sensitive balance in the cell

Iron is vital in life because it is an important component of molecules that undergoes redox reactions or transport oxygen. However, the existence of two stable and inter-convertible forms of iron, iron(III) and iron(II), makes possible one electron being transferred to or captured from other species to form radicals. In particular, superoxide and hydroxyl radicals may be formed in these reactions, both with capacity of attacking other molecules. DNA is one important target and a vast literature exists showing that attack of hydroxyl radical to DNA leads to cell death cellular necrosis, apoptosis, mutation and malignant transformation. Therefore, a fine balance must exist at various levels of an organism to maintain iron concentration in a narrow range, above and below which deleterious effects of distinct nature occur. This review will deal with the formation of oxygen reactive species in iron participating reactions, defenses in the organism against these species, the different mechanisms of iron homeostasis and iron deficiency and iron overload related diseases.