Abstract
In this paper we expand upon a previously reported observation of the effects of GDP on microtubule assembly. A ratio of GDP to GTP of ten (1 m m-GDP and 0.1 m m-GTP) is generally sufficient to completely block microtubule assembly, but only limited depolymerization is induced if GDP is added after assembly has reached a plateau in the presence of GTP. When added during polymerization, GDP arrests further elongation, and greater steady-state levels of assembly are obtained the later the time of addition of GDP. To explain this behavior we examined the rates of assembly and disassembly and the apparent critical concentration ( C 0) of tubulin in the presence of GDP. GDP-tubulin polymerizes very slowly as compared to GTP-tubulin, while depolymerization rates, as determined by dilution, are nearly identical in GTP and GDP. The C 0 value calculated from the assembly and disassembly rates in GTP is within experimental error of the C 0 value at steady-state determined directly. In the presence of GDP, however, the C 0 value calculated from rate measurements is at least 60 times greater than that determined by equilibrium analysis. Our results indicate that the net assembly rate in GDP is not a valid measure of the reaction occurring at steady-state. A limited amount of depolymerization may occur upon addition of GDP to microtubules, and this appears to be due to a decrease in the fraction of protein able to participate in the polymerization reaction. The amount of tubulin “inactivated” by GDP is increased by the removal of microtubule-associated proteins. GDP-tubulin will stabilize existing microtubules, even when its polymerization cannot be demonstrated. These results are inconsistent with present models of microtubule assembly, and a new model involving co-operative interaction of microtubule-associated protein-tubulin oligomers at microtubule ends is proposed.
Published Version
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