Mechanism of cytotoxicity of 2-chloro and 2-bromodeoxyadenosine for a human lymphoblastic cell line, CCRF-CEM

Comparative effects of cladribine, fludarabine and pentostatin on nucleotide metabolism in T- and B-cell lines

BACKGROUND AND AIMS

the purine nucleoside analogues cladribine (CdA), fludarabine (F-Ara-AMP) and pentostatin (dCf), are effective therapy for a range of T- and B-cell lymphoid malignancies. The effects upon nucleotide metabolism in human CCRF-CEM T-cell leukaemia and Raji B-cell lymphoma cell lines of these drugs have been compared to assess possible mechanisms of cytotoxicity.

METHODS

Leukaemia cells were exposed to a purine nucleoside analogue and perchloric acid extracts were analysed by HPLC for 2'-deoxynucleoside-5'-triphosphates (dNTPs), nucleoside-5'-triphosphates (NTPs) and drug metabolites.

RESULTS

After addition of a purine nucleoside analogue, CdA-TP and F-Ara-ATP accumulate in cells while the levels of dCf-TP formed were not detectable by ultra-violet absorbance. In response to accumulating concentrations of drug triphosphate, the cellular levels of dNTPs initially decrease (0-4 h), then accumulate above their initial levels (4-10 h) before slowly declining beyond 10 h. NTPs also accumulate during the period 4-10 h before declining at later times.

CONCLUSION

The temporal effects on the levels of dNTPs and NTPs of the 3 purine nucleoside analogues are similar against CCRF-CEM and Raji cells. However, CdA induces major depletions of dTTP, dGTP and dATP in CCRF-CEM cells and F-Ara-A induces a major accumulation of dATP in Raji cells.

A human factor that recognizes DNA substituted with 2-chloroadenine, an antileukemic purine analog

2-Chloro-2'-deoxyadenosine (cladribine), an analog of deoxyadenosine, is an important new drug for the treatment of hairy cell leukemia and other forms of adult and pediatric leukemia. By a gel-shift binding assay, we identified an activity in HeLa nuclear extracts that recognizes and binds to oligonucleotides substituted with 2-chloroadenine (ClAde). The activity was specific for ClAde residues because control oligomers did not readily compete out the complex. The binding factor was a monomeric protein that was resistant to inactivation by heating at 45 degrees C but sensitive to heating at 65 degrees C, proteinase K treatment, and 5 mM ZnCl2. This protein, designated ClAde recognition protein (CARP), appeared to be related to a protein that recognized other forms of DNA damage. Gel-shift binding reactions with ultraviolet (UV)-irradiated oligomers revealed a UV-specific protein/DNA complex that had an electrophoretic mobility similar to that of the CARP/DNA complex, and CARP binding to ClAde-containing oligomers was readily competed out by UV-irradiated DNA. Moreover, CARP activity was present in extracts prepared from UV-sensitive xeroderma pigmentosum group A cells but not in a subset of cells from group E, suggesting that CARP was similar to a previously described repair associated factor, xeroderma pigmentosum-E binding factor. Our findings support a possible repair process for ClAde residues incorporated into cellular DNA.