The activity of the soluble protein kinases, 2′3′ cAMP phosphodiesterase (cyclic phosphodiesterase), total phosphodiesterases, AC and the phosphatases was measured in cells recovering from γ radiation effects (Fig. 3). The AC activity increased rapidly following γ irradiation and reached a maximum in 0.5 h PIR (Fig. 3a), during which the activity of phosphodiesterases and phosphatases was low. Whereas the AP did not change significantly during PIR, the acid phosphatase increased nearly 1.5-fold from 1 h PIR (5.146 μmol min−1 mg−1 protein) to 4 h PIR (8.243 μmol min−1 mg−1
protein) (Fig. 3b). The levels of cyclic phosphodiesterase decreased rapidly in 1 h PIR followed by an increase of nearly threefold in 4 h PIR (Fig. 3c). These Birinapant nmr results might support the argument that the net increase in the cAMP levels was due to differential regulation of AC and cyclic phosphodiesterase activities in response to DNA damage. Although, D. radiodurans R1 genome does not annotate the selleck screening library classical bacterial AC and 2′3′ cAMP phosphodiesterase, it encodes for protein with a phosphodiesterase-type functional domain with nearly 30% genome without annotated functions, leaving the strong possibility
that unknown proteins are responsible for these activities. The amino acid sequence of AC from Escherichia coli was subjected to multiple sequence alignment, which showed different levels of amino acid similarities with some of the deinococcal ORFs. Among them, DR_1433 showed close to 75% match with E. coli protein in psiblast analysis. The presence of AC and cyclic phosphodiesterase activities in cell-free extracts of this bacterium suggested the strong possibility of AC and cyclic phosphodiesterase activities containing uncharacterized proteins in bacterial genome and it will be interesting to investigate these activities separately. Aliquots of γ-irradiated cells were collected during PIR and nucleotide-binding proteins were purified by heparin-sepharose affinity chromatography. Fractions
were tested for nucleolytic activity on dsDNA substrate. Results showed the presence of nucleolytic activity in unirradiated and zero PIR-irradiated samples. This Ketotifen activity was completely absent in 1- and 2-h PIR samples (Fig. 4a) but reappeared in 3- and 4-h PIR samples. This indicated that the bacterium has an as yet unidentified mechanism to regulate the nuclease activity during different stages of PIR. It may be speculated that during early PIR, i.e. before 2 h PIR, the bacterium needs to protect its shattered genome and very low nuclease activity might be required for DSB end-joining, whereas at a later stage, i.e. after 2 h PIR, high recombinase functions are needed, which requires the high nuclease activity observed at 3 and 4 h PIR. Except for the unirradiated control, all the samples, including 1 and 2 h PIR, showed inhibition of nucleolytic function with 2 mM ATP (Fig.