Stability of tubulin polymers formed with dideoxyguanosine nucleotides in the presence and absence of microtubule-associated proteins.

We have examined the effects of dilution, Ca2+, reduced temperature, and triphosphate depletion on microtubules formed from purified tubulin, heat-treated microtubule-associated proteins (MAPs), and either GTP, 2',3'-dideoxyguanosine 5'-diphosphate (ddGDP), or 2',3'-dideoxyguanosine 5'-triphosphate (ddGTP). The stability of the polymer formed with tubulin plus ddGTP without MAPs was also examined. In all cases dilution resulted in rapid depolymerization of polymer until a new turbidity plateau was established. These experiments yielded estimates of the critical concentration of tubulin of 0.09 mg/ml with GTP plus MAPs, 0.04 mg/ml with either ddGDP or ddGTP plus MAPs, and 0.07 mg/ml with ddGTP minus MAPs. Addition of CaCl2 to polymer resulted in depolymerization of microtubules formed with either GTP or ddGDP plus MAPs; but both with and without MAPs the polymer formed with ddGTP was stable to Ca2+. The polymer formed with ddGTP minus MAPs was the most cold-labile, major depolymerization occurring at 25 degrees C. With MAPs, microtubules were progressively less cold-labile when formed with GTP, ddGDP, or ddGTP. Depolymerization with GTP was virtually complete at 15 degrees C, with ddGDP at 5 degrees C, and with ddGTP at 0 degrees C. Rapid triphosphate depletion was achieved with phosphofructokinase. GTP-formed tubules were rapidly and completely depolymerized at all GTP concentrations after the enzyme was added to the reaction mixture. Both with and without MAPs polymer formed with ddGTP was progressively more stable upon enzyme addition the higher the initial ddGTP concentration. At specific ddGTP concentrations, however, less depolymerization was observed following enzyme addition if MAPs were present. Microtubules formed with ddGDP plus MAPs were unaffected by phosphofructokinase addition. This comparison of the properties of microtubules formed with MAPs and either ddGDP or ddGTP demonstrates that their stability is enhanced rather than reduced following nucleotide hydrolysis. The greater stability of microtubules formed with ddGTP plus MAPs than of the polymer formed with ddGTP minus MAPs similarly implies substantial enhancement of microtubule stability by the MAPs.