The C-Terminal Region of the Stalk Domain of Ubiquitous Human Kinesin Heavy Chain Contains the Binding Site for Kinesin Light Chain†

Biochemistry ◽  
1998 ◽  
Vol 37 (47) ◽  
pp. 16663-16670 ◽  
Author(s):  
Russell J. Diefenbach ◽  
Joel P. Mackay ◽  
Patricia J. Armati ◽  
Anthony L. Cunningham
Keyword(s):  
Binding Site ◽  
Heavy Chain ◽  
Light Chain ◽  
Terminal Region ◽  
Kinesin Light Chain ◽  
Kinesin Heavy Chain ◽  
Stalk Domain

scholarly journals Axonal transport of mitochondria requires milton to recruit kinesin heavy chain and is light chain independent

2006 ◽  
Vol 173 (4) ◽  
pp. 545-557 ◽  
Author(s):  
Elizabeth E. Glater ◽  
Laura J. Megeath ◽  
R. Steven Stowers ◽  
Thomas L. Schwarz
Keyword(s):  
Heavy Chain ◽  
Light Chain ◽  
Adaptor Protein ◽  
Direct Interaction ◽  
Anterograde Transport ◽  
Kinesin Light Chain ◽  
Energy Demands ◽  
Kinesin Heavy Chain ◽  
Conventional Kinesin ◽  
Dependent Transport

Mitochondria are distributed within cells to match local energy demands. We report that the microtubule-dependent transport of mitochondria depends on the ability of milton to act as an adaptor protein that can recruit the heavy chain of conventional kinesin-1 (kinesin heavy chain [KHC]) to mitochondria. Biochemical and genetic evidence demonstrate that kinesin recruitment and mitochondrial transport are independent of kinesin light chain (KLC); KLC antagonizes milton's association with KHC and is absent from milton–KHC complexes, and mitochondria are present in klc −/− photoreceptor axons. The recruitment of KHC to mitochondria is, in part, determined by the NH2 terminus–splicing variant of milton. A direct interaction occurs between milton and miro, which is a mitochondrial Rho-like GTPase, and this interaction can influence the recruitment of milton to mitochondria. Thus, milton and miro are likely to form an essential protein complex that links KHC to mitochondria for light chain–independent, anterograde transport of mitochondria.

scholarly journals Defective Kinesin Heavy Chain Behavior in Mouse Kinesin Light Chain Mutants

1999 ◽  
Vol 146 (6) ◽  
pp. 1277-1288 ◽  
Author(s):  
Amena Rahman ◽  
Adeela Kamal ◽  
Elizabeth A. Roberts ◽  
Lawrence S.B. Goldstein
Keyword(s):  
Heavy Chain ◽  
Light Chain ◽  
Mutant Mice ◽  
Kinesin Light Chain ◽  
Kinesin Heavy Chain ◽  
Neuronal Tissues ◽  
Biochemical Analyses ◽  
Conventional Kinesin

Conventional kinesin, kinesin-I, is a heterotetramer of two kinesin heavy chain (KHC) subunits (KIF5A, KIF5B, or KIF5C) and two kinesin light chain (KLC) subunits. While KHC contains the motor activity, the role of KLC remains unknown. It has been suggested that KLC is involved in either modulation of KHC activity or in cargo binding. Previously, we characterized KLC genes in mouse (Rahman, A., D.S. Friedman, and L.S. Goldstein. 1998. J. Biol. Chem. 273:15395–15403). Of the two characterized gene products, KLC1 was predominant in neuronal tissues, whereas KLC2 showed a more ubiquitous pattern of expression. To define the in vivo role of KLC, we generated KLC1 gene-targeted mice. Removal of functional KLC1 resulted in significantly smaller mutant mice that also exhibited pronounced motor disabilities. Biochemical analyses demonstrated that KLC1 mutant mice have a pool of KIF5A not associated with any known KLC subunit. Immunofluorescence studies of sensory and motor neuron cell bodies in KLC1 mutants revealed that KIF5A colocalized aberrantly with the peripheral cis-Golgi marker giantin in mutant cells. Striking changes and aberrant colocalization were also observed in the intracellular distribution of KIF5B and β′-COP, a component of COP1 coatomer. Taken together, these data best support models that suggest that KLC1 is essential for proper KHC activation or targeting.

Light Chain C-Terminal Region Reinforces the Stability of Clathrin Heavy Chain Trimers

Traffic ◽  
2007 ◽  
Vol 8 (8) ◽  
pp. 1101-1110 ◽  
Author(s):  
Joel A. Ybe ◽  
Samantha Perez-Miller ◽  
Qian Niu ◽  
David A. Coates ◽  
Michael W. Drazer ◽  
...  
Keyword(s):  
Heavy Chain ◽  
Light Chain ◽  
Terminal Region ◽  
Clathrin Heavy Chain ◽  
The Stability

scholarly journals Clathrin assembly involves a light chain-binding region.

1987 ◽  
Vol 105 (5) ◽  
pp. 2011-2019 ◽  
Author(s):  
G S Blank ◽  
F M Brodsky
Keyword(s):  
Monoclonal Antibodies ◽  
Binding Site ◽  
Heavy Chain ◽  
Light Chain ◽  
Intermediate Filament ◽  
Binding Sites ◽  
Light Chains ◽  
Binding Region ◽  
Intermediate Filament Proteins ◽  
Interaction Site

Two regions on the clathrin heavy chain that are involved in triskelion interactions during assembly have been localized on the triskelion structure. These regions were previously identified with anti-heavy chain monoclonal antibodies X19 and X35, which disrupt clathrin assembly (Blank, G. S., and F. M. Brodsky, 1986, EMBO (Eur. Mol. Biol. Organ.) J., 5:2087-2095). Antibody-binding sites were determined based on their reactivity with truncated triskelions, and were mapped to an 8-kD region in the middle of the proximal portion of the triskelion arm (X19) and a 6-kD region at the triskelion elbow (X35). The elbow site implicated in triskelion assembly was also shown to be included within a heavy chain region involved in binding the light chains and to constitute part of the light chain-binding site. We postulate that this region of the heavy chain binds to the interaction site identified on the light chains that has homology to intermediate filament proteins (Brodsky, F. M., C. J. Galloway, G. S. Blank, A. P. Jackson, H.-F. Seow, K. Drickamer, and P. Parham, 1987, Nature (Lond.), 326:203-205). These findings suggest the existence of a heavy chain site, near the triskelion elbow, which is involved in both intramolecular and intermolecular interactions during clathrin assembly.

scholarly journals Identification of an octamer-binding site in the human kappa light-chain enhancer.

1990 ◽  
Vol 10 (7) ◽  
pp. 3843-3846 ◽  
Author(s):  
K Nelms ◽  
B Van Ness
Keyword(s):  
Binding Site ◽  
Heavy Chain ◽  
Light Chain ◽  
Tissue Specificity ◽  
Chain Gene ◽  
Gene Promoters ◽  
Kappa Light Chain ◽  
Light Chain Gene ◽  
Gene Enhancer ◽  
Light Chain Enhancer

Octamer motifs contribute to the function and tissue specificity of immunoglobulin heavy- and light-chain gene promoters and the heavy-chain enhancer. A variant octamer-binding site within a conserved region of the human kappa light-chain gene enhancer which contributes to the function of this enhancer has been identified.

scholarly journals Light Chain– dependent Regulation of Kinesin's Interaction with Microtubules

1998 ◽  
Vol 143 (4) ◽  
pp. 1053-1066 ◽  
Author(s):  
Kristen J. Verhey ◽  
Donna L. Lizotte ◽  
Tatiana Abramson ◽  
Linda Barenboim ◽  
Bruce J. Schnapp ◽  
...  
Keyword(s):  
Light Chain ◽  
Immunofluorescence Microscopy ◽  
Tail Domain ◽  
Kinesin Light Chain ◽  
Cos Cells ◽  
Sedimentation Behavior ◽  
Cargo Transport ◽  
Stalk Domain ◽  
Heptad Repeats ◽  
Conventional Kinesin

We have investigated the mechanism by which conventional kinesin is prevented from binding to microtubules (MTs) when not transporting cargo. Kinesin heavy chain (HC) was expressed in COS cells either alone or with kinesin light chain (LC). Immunofluorescence microscopy and MT cosedimentation experiments demonstrate that the binding of HC to MTs is inhibited by coexpression of LC. Association between the chains involves the LC NH2-terminal domain, including the heptad repeats, and requires a region of HC that includes the conserved region of the stalk domain and the NH2 terminus of the tail domain. Inhibition of MT binding requires in addition the COOH-terminal 64 amino acids of HC. Interaction between the tail and the motor domains of HC is supported by sedimentation experiments that indicate that kinesin is in a folded conformation. A pH shift from 7.2 to 6.8 releases inhibition of kinesin without changing its sedimentation behavior. Endogenous kinesin in COS cells also shows pH-sensitive inhibition of MT binding. Taken together, our results provide evidence that a function of LC is to keep kinesin in an inactive ground state by inducing an interaction between the tail and motor domains of HC; activation for cargo transport may be triggered by a small conformational change that releases the inhibition of the motor domain for MT binding.

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