A synthetic ancestral kinesin-13 depolymerizes microtubules faster than any natural depolymerizing kinesin.

The activity of a kinesin is largely determined by the approximately 350 residue motor domain, and this region alone is sufficient to classify a kinesin as a member of a particular family. The kinesin-13 family are a group of microtubule depolymerizing kinesins and are vital regulators of microtubule length. Kinesin-13s are critical to spindle assembly and chromosome segregation in both mitotic and meiotic cell division and play crucial roles in cilium length control and neuronal development. To better understand the evolution of microtubule depolymerization activity, we created a synthetic ancestral kinesin-13 motor domain. This phylogenetically inferred ancestral motor domain is the sequence predicted to have existed in the common ancestor of the kinesin-13 family. Here we show that the ancestral kinesin-13 motor depolymerizes stabilized microtubules faster than any previously tested depolymerase. This potent activity is more than an order of magnitude faster than the most highly studied kinesin-13, MCAK and allows the ancestral kinesin-13 to depolymerize doubly stabilized microtubules and cause internal breaks within microtubules. These data suggest that the ancestor of the kinesin-13 family was a 'super depolymerizer' and that members of the kinesin-13 family have evolved away from this extreme depolymerizing activity to provide more controlled microtubule depolymerization activity in extant cells.

The family-specific α4-helix of the kinesin-13, MCAK, is critical to microtubule end recognition.

Kinesins that influence the dynamics of microtubule growth and shrinkage require the ability to distinguish between the microtubule end and the microtubule lattice. The microtubule depolymerizing kinesin MCAK has been shown to specifically recognize the microtubule end. This ability is key to the action of MCAK in regulating microtubule dynamics. We show that the α4-helix of the motor domain is crucial to microtubule end recognition. Mutation of the residues K524, E525 and R528, which are located in the C-terminal half of the α4-helix, specifically disrupts the ability of MCAK to recognize the microtubule end. Mutation of these residues, which are conserved in the kinesin-13 family and discriminate members of this family from translocating kinesins, impairs the ability of MCAK to discriminate between the microtubule lattice and the microtubule end.

Use of stopped-flow fluorescence and labeled nucleotides to analyze the ATP turnover cycle of kinesins.

The kinesin superfamily of microtubule associated motor proteins share a characteristic motor domain which both hydrolyses ATP and binds microtubules. Kinesins display differences across the superfamily both in ATP turnover and in microtubule interaction. These differences tailor specific kinesins to various functions such as cargo transport, microtubule sliding, microtubule depolymerization and microtubule stabilization. To understand the mechanism of action of a kinesin it is important to understand how the chemical cycle of ATP turnover is coupled to the mechanical cycle of microtubule interaction. To dissect the ATP turnover cycle, one approach is to utilize fluorescently labeled nucleotides to visualize individual steps in the cycle. Determining the kinetics of each nucleotide transition in the ATP turnover cycle allows the rate-limiting step or steps for the complete cycle to be identified. For a kinesin, it is important to know the rate-limiting step, in the absence of microtubules, as this step is generally accelerated several thousand fold when the kinesin interacts with microtubules. The cycle in the absence of microtubules is then compared to that in the presence of microtubules to fully understand a kinesin's ATP turnover cycle. The kinetics of individual nucleotide transitions are generally too fast to observe by manually mixing reactants, particularly in the presence of microtubules. A rapid mixing device, such as a stopped-flow fluorimeter, which allows kinetics to be observed on timescales of as little as a few milliseconds, can be used to monitor such transitions. Here, we describe protocols in which rapid mixing of reagents by stopped-flow is used in conjunction with fluorescently labeled nucleotides to dissect the ATP turnover cycle of a kinesin.

Differential protein adduction by seven organophosphorus pesticides in both brain and thymus.

There is a need for mechanistic understanding of the lasting ill health reported in several studies of workers exposed to organophosphorus (OP) pesticide. Although the acute toxicity is largely explicable by acetylcholinesterase inhibition and the lasting effects of frank poisoning by direct excitotoxicity or indirect consequences of the cholinergic syndrome, effects at lower levels of exposure would not be predicted from these mechanisms. Similarly, reversible interactions with nicotinic and muscarinic receptors in adults would not predict continuing ill health. Many OP pesticides produce protein adduction, and the lasting nature of this makes it a candidate mechanism for the production of continuing ill health. We found significant adduction of partially characterized protein targets in both rat brain and thymus by azamethiphos, chlorfenvinphos, chlorpyrifos-oxon, diazinon-oxon, dichlorvos and malaoxon, in vitro and pirimiphos-methyl in vivo. The diversity in the adduction pattern seen across these agents at low dose levels means that any longer term effects of adduction would be specific to specific organophosphates, rather than generic. This presents a challenge to epidemiology, as most exposures are to different agents over time. However, some adducted proteins are also expressed in blood, notably albumin, and so may provide exposure measures to increase the power of future epidemiological studies.

Novel protein targets for organophosphorus pesticides in rat brain.

We report preliminary results from a proteomic search for rat brain protein targets adducted by organophosphorous pesticides. Azamethaphos, chlorfenvinphos, diazinon, malathion and chlorpyrifos oxons (in rat brain homogenates) or pirimiphos-methyl (after systemic treatment) were tested at levels producing no more than 30% inhibition of brain acetylcholinesterase. Loss of reactivity with tritiated diisopropylflurophosphate was taken as proof of adduction by the test organophosphate. In addition to acetylcholinesterase other, previously unrecognised, adducted proteins were detected in total brain protein extracts at 30, 32, 41, 71 and 83kDa. Azamethiphos adducted all but the 30 and 32kDa bands, but chlorpyrifos only acetylcholinesterase.