The N-terminal domain of dynein intermediate chain, IC(1-289), is highly disordered, but upon binding to dynein light-chain LC8, it undergoes a significant conformational change to a more ordered structure. Using circular dichroism and fluorescence spectroscopy, we demonstrate that the change in conformation is due to an increase in the helical structure and to enhanced compactness in the environment of tryptophan 161. An increase in helical structure and compactness is also observed with trimethylamine-N-oxide (TMAO), a naturally occurring osmolyte used here as a probe to identify regions with a propensity for induced folding. Global protection of IC(1-289) from protease digestion upon LC8 binding was localized to a segment that includes residues downstream of the LC8-binding site. Several smaller constructs of IC(1-289) containing the LC8-binding site and one of the predicted helix or coiled-coil segments were made. IC(1-143) shows no increase in helical structure upon binding, while IC(114-260) shows an increase in helical structure similar to what is observed with IC(1-289). Binding of IC(114-260) to LC8 was monitored by fluorescence and native gel electrophoresis and shows saturation of binding, a stoichiometry of 1:1, and moderate binding affinity. The induced folding of IC(1-289) upon LC8 binding suggests that LC8 could act through the intermediate chain to facilitate dynein assembly or regulate cargo-binding interactions.
The assembly factor heterodimer Rsa4–Nsa2 binds to the preribosome and transmits remodeling energy from the force-generating ATPase Rea1 to facilitate relocation of ribosomal RNA elements during ribosome maturation.
The homodimeric light chains LC8 and Tctex-1 are integral parts of the microtubule motor cytoplasmic dynein, as they directly associate with dynein intermediate chain IC and various cellular cargoes. These light chains appear to regulate assembly of the dynein complex by binding to and promoting dimerization of IC. In addition, both LC8 and Tctex-1 play roles in signaling, apoptosis, and neuronal development that are independent of their function in dynein, but it is unclear how these various activities are modulated. Both light chains undergo specific phosphorylation, and here we present biochemical and NMR analyses of phosphomimetic mutants that indicate how phosphorylation may regulate light chain function. For both LC8 and Tctex-1, phosphorylation promotes dissociation from IC while retaining their binding activity with other non-dynein proteins. Although LC8 and Tctex-1 are homologs having a common fold, their reduced affinity for IC upon phosphorylation arises by different mechanisms. In the case of Tctex-1, phosphorylation directly masks the IC binding site at the dimer interface, whereas for LC8, phosphorylation dissociates the dimer and indirectly eliminates the binding site. This modulation of the monomer-dimer equilibrium by phosphorylation provides a novel mechanism for discrimination among LC8 binding partners.Cytoplasmic dynein is a principal cellular motor responsible for minus end directed traffic along microtubules. It is a large multisubunit protein complex involved in a variety of processes, including mitotic spindle assembly and orientation, chromosome segregation, intracellular trafficking of vesicles and mRNA, and the establishment of cell polarity (reviewed in Ref. (1)). The heavy chain subunits of dynein provide ATPase and microtubule binding functions, whereas the intermediate and light chain subunits are thought to mediate binding and transport of a wide array of cargo. LC8 2 and Tctex-1, two of the three light chain subunits of cytoplasmic dynein, tightly associate with, and increase the structure of, disordered dynein intermediate chain (IC) (2, 3). The association with either dimeric light chain is postulated to be essential for dimerization of the intermediate chain (4), although recent work has challenged this hypothesis (5). In the cell, significant amounts of LC8 and Tctex-1 are not incorporated into the dynein complex, raising the possibility that these proteins have additional roles independent of dynein (6, 7). Consistent with this hypothesis, several proteins unrelated to dynein bind LC8 and Tctex-1 (8 -20). Many of these interactions are interpreted to indicate that these molecules are cargoes transported by dynein, and except for the Swallow protein which is required for the proper localization of bicoid mRNA (14), there is little evidence for their active transport along microtubules by dynein. The question remains as to how these ubiquitously expressed highly conserved light chains are regulated for multiple functional roles both as part of dynein and as part of other com...
Background: Nucleoporin Nup159 has multiple recognition motifs for Dyn2, the yeast ortholog of LC8. Results: Nup159 is intrinsically disordered and binds Dyn2 cooperatively at five of the six recognition motifs. Conclusion: Initial binding aligns two Nup chains in a bivalent scaffold; motifs 5 and 6 underlie rigidity. Significance: Multiple recognition sites provide entropy/enthalpy balance to a stable yet entropically unfavorable rigid complex.
Dynein light chains are bivalent dimers that bind two copies of dynein intermediate chain IC to form a cargo attachment subcomplex. The interaction of light chain LC8 with the natively disordered N-terminal domain of IC induces helix formation at distant IC sites in or near a region predicted to form a coiled-coil. This fostered the hypothesis that LC8 binding promotes IC self-association to form a coiled-coil or other interchain helical structure. However, recent studies show that the predicted coiled-coil sequence partially overlaps the light chain LC7 recognition sequence on IC, raising questions about the apparently contradictory effects of LC8 and LC7. Here, we use NMR and fluorescence quenching to localize IC self-association to residues within the predicted coiled-coil that also correspond to helix 1 of the LC7 recognition sequence. LC8 binding promotes IC self-association of helix 1 from each of two IC chains, whereas LC7 binding reverses self-association by incorporating the same residues into two symmetrical, but distant, helices of the LC7-IC complex. Isothermal titration experiments confirm the distinction of LC8 enhancement of IC self-association and LC7 binding effects. When all three light chains are bound, IC self-association is shifted to another region. Such flexibility in association modes may function in maintaining a stable and versatile light chain-intermediate chain assembly under changing cellular conditions.
The tetratricopeptide repeat (TPR) domain mediates inter-protein associations in a number of systems. The domain is also thought to mediate oligomerization of some proteins, but this has remained controversial, with conflicting data appearing in the literature. By way of investigating such TPR-mediated self-associations we used a variety of biophysical techniques to characterize purified recombinant Sgt1, a TPR-containing protein found in all eukaryotes that is involved in a broad range of biological processes, including kinetochore assembly in humans and yeast and disease resistance in plants. We show that recombinant Sgt1 from Arabidopsis, barley, and yeast self-associates in vitro while recombinant human Sgt1 does not. Further experiments on barley Sgt1 demonstrate unambiguously a TPR-mediated dimerization, which is concentration- and ionic-strength-dependent and results in a global increase in helical structure and stability of the protein. Dimerization is also redox sensitive, being completely abolished by the formation of an intramolecular disulfide bond where the contributing cysteines are conserved in plant Sgt1s. The dimer interface was mapped through cross-linking and mass spectrometry to the C-terminal region of the TPR domain. Our study, which provides the first biophysical characterization of plant Sgt1, highlights how TPR domains can mediate self-association in solution and that sequence variation in the regions involved in oligomerization affects the propensity of TPR-containing proteins to dimerize.
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