The light intermediate chains (LICs) of cytoplasmic dynein consist of multiple isoforms, which undergo post-translational modification to produce a large number of species separable by two-dimensional electrophoresis and which we have proposed to represent at least two gene products. Recently, we demonstrated the first known function for the LICs: binding to the centrosomal protein, pericentrin, which represents a novel, non-dynactin-based cargo-binding mechanism. Here we report the cloning of rat LIC1, which is approximately 75% homologous to rat LIC2 and also contains a P-loop consensus sequence. We compared LIC1 and LIC2 for the ability to interact with pericentrin, and found that only LIC1 will bind. A functional P-loop sequence is not required for this interaction. We have mapped the interaction to the central region of both LIC1 and pericentrin. Using recombinant LICs, we found that they form homooligomers, but not heterooligomers, and exhibit mutually exclusive binding to the heavy chain. Additionally, overexpressed pericentrin is seen to interact with endogenous LIC1 exclusively. Together these results demonstrate the existence of two subclasses of cytoplasmic dynein: LIC1-containing dynein, and LIC2-containing dynein, only the former of which is involved in pericentrin association with dynein.

Cytoplasmic dynein is a molecular motor complex consisting of four major classes of polypeptide: the catalytic heavy chains (HC), intermediate chains (IC), light intermediate chains (LIC), and light chains (LC). Previous studies have reported that the ICs bind near the N terminus of the HCs, which is thought to correspond to the base of the dynein complex. In this study, we co-overexpressed cytoplasmic dynein subunits in COS-7 cells to map HC binding sites for the ICs and LICs, as well as HC dimerization. We have found that the LICs bind directly to the N terminus of the HC, adjacent to and overlapping with the IC binding site, consistent with a role for the LICs in cargo binding. Mutation of the LIC P-loop had no detectable effect on HC binding. We detected no direct interaction between the ICs and LICs. Using triple overexpression of HC, IC and LIC, we found that both IC and LIC are present in the same complexes, a result verified by anti-IC immunoprecipitation of endogenous complexes and immunoblotting. Our results indicate that the LICs and ICs must be located on independent surfaces of cytoplasmic dynein to allow each to interact with other proteins without steric interference.

Cytoplasmic dynein is a multisubunit complex involved in retrograde transport of cellular components along microtubules. The heavy chains (HC) are very large catalytic subunits which possess microtubule binding ability. The intermediate chains (IC) are responsible for targeting dynein to its appropriate cargo by interacting with the dynactin complex. The light intermediate chains (LIC) are previously unexplored subunits that have been proposed to modulate dynein activity by regulating the motor or the IC-dynactin interaction. The light chains (LC) are a newly identified class of subunit which are also thought to have regulatory functions. In the first part of this work, I analyzed the relationship between the four SDS-PAGE gel bands that comprise the light intermediate chains. 1- and 2-D electrophoresis before and after alkaline phosphatase treatment revealed that the four bands are derived from two different polypeptides, each of which is phosphorylated. Peptide microsequencing of these subunits yielded sequences that indicated similarity between them. cDNA cloning of the rat LICs revealed the presence of a conserved P-loop sequence and a very high degree of homology between the two different rat LICs and among LICs from different species. The second series of experiments was designed to analyze the association of pericentrin with cytoplasmic dynein. First, various dynein and dynactin subunits were co-associate with pericentrin in these experiments. Co-precipitation from 35S labeled cell extracts revealed a direct interaction between LIC and pericentrin. Comparison of pericentrin binding by LICl and LIC2 showed that only LICl was able to bind. Further investigation of the relationship between LICl and LIC2 demonstrated that each LIC will self-associate, but they will not form heterooligomers. Additionally, using co-overexpression and immunoprecipitation of LICl, LIC2, and HC, I have shown that binding of the two LICs to HC is mutually exclusive. Finally, I investigated the relationships between dynein HC, IC, and LIC by examining the interactions among the subunits. IC and LIC were both found to bind to the HC, but not to each other. Despite the lack of interaction between IC and LIC, they are, in fact, present in the same dynein complexes and they have partially overlapping binding sites within the N-terminal sequence of the HC. The HC dimerization site was determined to extend through a large portion of the N-terminus, and it includes both the IC and LIC binding sites, although these subunits are not required for dimerization. Together these studies implicate the light intermediate chains in dynein targeting. Targeting of dynein to its cargo has been thought to be performed by the dynactin complex, and for one particular cargo, the kinetochore, there is considerable evidence to support this model. The results presented here suggest that the light intermediate chains appear to function in a separate, non-dynactin-based targeting mechanism.

Pericentrin is a conserved protein of the centrosome involved in microtubule organization. To better understand pericentrin function, we overexpressed the protein in somatic cells and assayed for changes in the composition and function of mitotic spindles and spindle poles. Spindles in pericentrin-overexpressing cells were disorganized and mispositioned, and chromosomes were misaligned and missegregated during cell division, giving rise to aneuploid cells. We unexpectedly found that levels of the molecular motor cytoplasmic dynein were dramatically reduced at spindle poles. Cytoplasmic dynein was diminished at kinetochores also, and the dynein-mediated organization of the Golgi complex was disrupted. Dynein coimmunoprecipitated with overexpressed pericentrin, suggesting that the motor was sequestered in the cytoplasm and was prevented from associating with its cellular targets. Immunoprecipitation of endogenous pericentrin also pulled down cytoplasmic dynein in untransfected cells. To define the basis for this interaction, pericentrin was coexpressed with cytoplasmic dynein heavy (DHCs), intermediate (DICs), and light intermediate (LICs) chains, and the dynamitin and p150(Glued) subunits of dynactin. Only the LICs coimmunoprecipitated with pericentrin. These results provide the first physiological role for LIC, and they suggest that a pericentrin-dynein interaction in vivo contributes to the assembly, organization, and function of centrosomes and mitotic spindles.

Cytoplasmic dynein is a minus end-directed microtubule motor responsible for centripetal organelle movement and several aspects of chromosome segregation. Our search for cytoplasmic dynein-interacting proteins has implicated the dynactin complex as the cytoplasmic dynein 'receptor' on organelles and kinetochores. Immunofluorescence microscopy using a total of six antibodies generated against the p150Glued, Arp1 and dynamitin subunits of dynactin revealed a novel fraction of dynactin-positive structures aligned in linear arrays along the distal segments of interphase microtubules. Dynactin staining revealed that these structures colocalized extensively with CLIP-170. Cytoplasmic dynein staining was undetectable, but extensive colocalization with dynactin became evident upon transfer to a lower temperature. Overexpression of the dynamitin subunit of dynactin removed Arp1 from microtubules but did not affect microtubule-associated p150Glued or CLIP-170 staining. Brief acetate treatment, which has been shown to affect lysosomal and endosomal traffic, also dispersed the Golgi apparatus and eliminated the microtubule-associated staining pattern. The effect on dynactin was rapidly reversible and, following acetate washout, punctate dynactin was detected at microtubule ends within 3 minutes. Together, these findings identify a region along the distal segments of microtubules where dynactin and CLIP-170 colocalize. Because CLIP-170 has been reported to mark growing microtubule ends, our results indicate a similar relationship for dynactin. The functional interaction between dynactin and cytoplasmic dynein further suggests that this these regions represent accumulations of cytoplasmic dynein cargo-loading sites involved in the early stages of minus end-directed organelle transport.