Relapse is the main cause of mortality in patients with glioblastoma multiforme (GBM). Treatment options involve surgical resection followed by a combination of radiotheraphy and chemotherapy with ...temozolomide. Several genes and genetic pathways have been identified to contribute to therapeutic resistance, giving rise to recurrence of the malignancy. In the last decades, glioma stem cells (GSCs) with the capacity of self-renewal have been demonstrated to maintain tumor propagation and treatment resistance. Here, we isolated CD133-positive (CD133+) and CD133-negative (CD133−) cells from glioblastoma U98G and U87MG cell lines. The role of phosphoribosylpyrophosphate synthetase 1 (PRPS1), which catalyzes the first step of the synthesis of nucleotide, in proliferation and apoptosis was investigated. We found that PRPS1 had a remarkable effect on cell proliferation and sphere formation in both CD133+ and CD133− cells. Compared to CD133− cells, CD133+ cells exhibited more significant results in cell apoptosis assay. CD133+ T98G and U87MG cells were used in xenograft mouse model of tumor formation. Interestingly, the mice implanted with PRPS1 knockdown T98G or U87MG stem cells exhibited prolonged survival time and reduced tumor volume. By immunostaining caspase-3 in tumor tissues of these mice, we demonstrated that the apoptotic activities in tumor cells were positively correlated to the survival time but negatively correlated to PRPS1 expression. Our results indicate that PRPS1 plays an important role in proliferation and apoptosis in GSCs and provide new clues for potential PRPS1-targeted therapy in GBM treatment.
This study examined recombinant wild-type human phosphoribosylpyrophosphate synthetase 1 (wt-PRS1, EC 2.7.6.1) and the point mutant Asn114Ser PRS1 (N114S-Mutant) in cells of a patient with primary ...gout. Dynamic light-scattering and sedimentation velocity experiments indicated that the monomeric wt-PRS1 in solution was assembled into hexamers after adding the substrate ATP. However, this ATP-induced aggregation effect was not observed with N114S-Mutant, which has a 50% higher enzymatic activity than that of wt-PRS1. Synchrotron radiation circular dichroism spectroscopy revealed that the point mutation causes an increase of α-helix content and a decrease of turn content. Examination of the crystal structure of wt-PRS1 indicated that 12 hydrogen bonds formed by 6 pairs of N114 and D139 have an important role in stabilizing the hexamer. We suggest that the substitution of S114 for N114 in N114S-Mutant leads to the rupture of 12 hydrogen bonds and breakage of the
PO
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allosteric site where
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functions as a fixer of the ATP-binding loop. Therefore, we consider that formation of the hexamer as the structural basis of the ADP allosteric inhibition is greatly weakened by the N114S mutation, and that alteration of the ATP-binding loop conformation is the key factor in the increased activity of N114S-Mutant. These two factors could be responsible for the high level of activity of N114S-Mutant in this patient.
