By using monoclonal antibodies raised against isolated clam centrosomes, we have identified a novel 135-kD centrosomal protein (Cep135), present in a wide range of organisms. Cep135 is located at the centrosome throughout the cell cycle, and localization is independent of the microtubule network. It distributes throughout the centrosomal area in association with the electron-dense material surrounding centrioles. Sequence analysis of cDNA isolated from CHO cells predicted a protein of 1,145–amino acid residues with extensive α-helical domains. Expression of a series of deletion constructs revealed the presence of three independent centrosome-targeting domains. Overexpression of Cep135 resulted in the accumulation of unique whorl-like particles in both the centrosome and the cytoplasm. Although their size, shape, and number varied according to the level of protein expression, these whorls were composed of parallel dense lines arranged in a 6-nm space. Altered levels of Cep135 by protein overexpression and/or suppression of endogenous Cep135 by RNA interference caused disorganization of interphase and mitotic spindle microtubules. Thus, Cep135 may play an important role in the centrosomal function of organizing microtubules in mammalian cells.
Abstract. Using the CHO2 monoclonal antibody raised against CHO spindles (Sellitto, C., M. Kimble, and R. Kuriyama. 1992. Cell Motil. Cytoskeleton.22:7-24) we identified a 66-kD protein located at the interphase centrosome and mitotic spindle. Isolated cDNAs for the antigen encode a 622-amino acid polypeptide. Sequence analysis revealed the presence of 340-amino acid residues in the COOH terminus, which is homologous to the motor domain conserved among other members of the kinesin superfamily. The protein is composed of a central u-helical portion with globular domains at both NH2 and COOH termini, and the epitope to the monoclonal antibody resides in the central a-helical stalk. A series of deletion constructs were created for in vitro analysis of microtubule interactions. While the microtubule binding and bundling activities require both the presence of the COOH terminus and the o~-helical domain, the NH2-
Neurons extend two types of processes with distinct morphologies and patterns of microtubule polarity orientation. Axons are thin cylindrical processes containing microtubules that are uniformly oriented with their plus-ends-distal to the cell body while dendrites are stout tapering processes that contain nonuniformly oriented microtubules. We have proposed that these distinct microtubule patterns are established by molecular motors that transport microtubules into each type of process with the appropriate orientation. To test the feasibility of this proposal, we have embarked on a series of studies involving the expression of vertebrate motors in insect Sf9 cells. We previously focused on a kinesin-related protein termed CHO1/MKLP1, which localizes to the midzone of the mitotic spindle, and which has been shown to have the appropriate properties to transport microtubules of opposite orientation relative to one another. Expression of a fragment of CHO1/MKLP1 containing its motor domain induces Sf9 cells to extend processes with a stout tapering morphology and a nonuniform microtubule polarity pattern similar to dendrites. Here we focus on a minus-end-directed kinesin-related motor protein termed CHO2, which localizes to the non-overlapping regions of the mitotic spindle, and which has been shown to have the appropriate properties to transport microtubules with plus-ends-leading. Sf9 cells induced to express a fragment of CHO2 containing its motor domain extend processes with a long cylindrical morphology and a uniformly plus-end-distal microtubule polarity pattern similar to axons. These results show that motor proteins have the capacity to organize distinct patterns of microtubule polarity orientation during process outgrowth, and that these patterns are intimately related to the unique morphological characteristics of the processes. Moreover, mutation of three amino acids corresponding to the ATP binding site necessary for motor function suppresses the capacity of the CHO2 fragment to induce process formation and microtubule reorganization, indicating that at least in the case of CHO2, the transport properties of the motor are essential for it to elicit these effects.
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