Insights into Kinesin-1 Activation from the Crystal Structure of KLC2 Bound to JIP3

Cockburn, J.J.B.; Hesketh, Sophie J.; Mulhair, Peter O.; Thomsen, Maren; O’Connell, Mary J.; Way, Michael

doi:10.1016/j.str.2018.07.011

Cited by 51 publications

(65 citation statements)

References 79 publications

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“…Binding of GST-JIP3 LZ2 to His 6 -KLC1 extTPR is an enthalpy-driven process with a dissociation constant K D of ~3.5 μM in which two TPR domains bind to a JIP3 LZ2 coiled-coil dimer ( Figure 5D ). This stoichiometry is consistent with the recently published crystallographic analysis of the KLC2 TPR -JIP3 LZ2 complex that shows two TPR domains symmetrically bound to the JIP3 LZ2 coiled-coil ( Cockburn et al, 2018 ) and also native mass spectrometry (MS) analysis ( Figure 5—figure supplement 1 ). No significant changes in K D are observed when His 6 -KLC1 extTPR is replaced by either His 6 -KLC1 extTPR -JIP1 C-term ( Figure 5E ) or His 6 -KLC1 TPR -JIP1 C-term ( Figure 5F ) thus indicating that the binding of JIP3 LZ2 to KLC1 TPR is independent of either JIP1 C-term and of the conformational change it elicits or the LFP-acidic region.…”

Section: Resultssupporting

confidence: 91%

“…Alternatively, the LFP-acidic linker remains bound and there is an as yet uncharacterized activation pathway triggered by JIP1/JIP3 binding that is more reliant on the additional direct adaptor interactions with KHC. Our ITC and mass spectrometry data suggest the possibility that could be driven by steric effects resulting from the JIP3 LZ2 -mediated dimerization of KLC1 TPR within the kinesin-1 tetramer, a notion further substantiated by the recent publication of a KLC2 TPR -JIP3 LZ2 structure that shows two TPR domains (in their ‘open’ conformation) symmetrically bound to the JIP3 LZ2 coiled-coil ( Cockburn et al, 2018 ). However, our data strongly argue that a functional JIP1-JIP3 transport complex would have its TPR domains in their closed conformation induced by Y-acidic binding.…”

Section: Discussionmentioning

confidence: 59%

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Structural basis for isoform-specific kinesin-1 recognition of Y-acidic cargo adaptors

Pernigo

Chegkazi

Yip

et al. 2018

eLife

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The light chains (KLCs) of the heterotetrameric microtubule motor kinesin-1, that bind to cargo adaptor proteins and regulate its activity, have a capacity to recognize short peptides via their tetratricopeptide repeat domains (KLCTPR). Here, using X-ray crystallography, we show how kinesin-1 recognizes a novel class of adaptor motifs that we call ‘Y-acidic’ (tyrosine flanked by acidic residues), in a KLC-isoform specific manner. Binding specificities of Y-acidic motifs (present in JIP1 and in TorsinA) to KLC1TPR are distinct from those utilized for the recognition of W-acidic motifs found in adaptors that are KLC- isoform non-selective. However, a partial overlap on their receptor binding sites implies that adaptors relying on Y-acidic and W-acidic motifs must act independently. We propose a model to explain why these two classes of motifs that bind to the concave surface of KLCTPR with similar low micromolar affinity can exhibit different capacities to promote kinesin-1 activity.

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Section: Resultssupporting

confidence: 91%

Section: Discussionmentioning

confidence: 59%

Structural basis for isoform-specific kinesin-1 recognition of Y-acidic cargo adaptors

Pernigo

Chegkazi

Yip

et al. 2018

eLife

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“…The kinesin-1 light chain TPR domain can interact directly with a leucine zipper domain (a subclass of coiled-coil) within the JIP3 adaptor protein. This cooperates with peptide motif recognition by JIP1 [30][31][32] (Figure 2a). Both proteins also directly engage the KHCs [33,34].…”

Section: A Common Role For Coiled-coil Adaptors and The Recruitment/cmentioning

confidence: 64%

“…Both proteins also directly engage the KHCs [33,34]. JIP3 may promote dimerization of the kinesin light chain TPR domains within the tetramer to promote activation [30]. Alternatively, this could provide a mechanism to cross-link multiple motors into a larger assembly, analogous to the recruitment of multiple dyneins discussed below (Figure 2b).…”

Section: A Common Role For Coiled-coil Adaptors and The Recruitment/cmentioning

confidence: 99%

Motor–cargo adaptors at the organelle–cytoskeleton interface

Cross

Dodding

2019

Current Opinion in Cell Biology

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Cytoskeletal motors of the dynein, kinesin and myosin superfamilies maintain and adapt subcellular organelle organization to meet functional demands and support the vesicular transport of material between organelles. These motors require the capacity to specifically recognize the vesicle/organelle to be transported and are capable of selective recognition of multiple cargo. Recent studies have begun to uncover the molecular basis for motor recruitment and have highlighted the role of organelle-associated 'cargo-adaptor' proteins in cellular transport. These adaptors possess sequences and/or structural features that enable both motor recruitment and activation from regulated, inactive, states to enable motility on the cytoskeleton. Motor-cargo adaptor interactions define a key organelle-cytoskeleton interface, acting as crucial regulatory hubs to enable the cell to finely control membrane trafficking and organelle dynamics. Understanding the molecular basis of these interactions may offer new opportunities to control and manipulate cytoskeletal and organelle dynamics for the development of new research tools and potentially therapeutics.

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“…34 In cells, kinesin-1 is inactive and only gets activated upon cargo binding. 35,36 Kinesore interacts with kinesin-1 at the kinesin light chain-cargo interface (Ki = 49 µM for aiKLC2 TPR : SKIP WD complex), mimicking the effect of cargo binding and resulting in kinesin-1 activation. The enhanced motion causes profound rearrangement of the MT network.…”

Section: Qpd Crystals Track Mts Originating From the Golgi Apparatusmentioning

confidence: 99%

Kinesin-1 motility traced by an activity-based precipitating dye

Angerani

Lindberg

Klena

et al. 2020

Preprint

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Kinesin-1 is a processive motor protein that uses ATP-derived energy to transport a variety of intracellular cargoes toward the cell periphery. As tracks for cargo delivery, kinesin-1 uses a subset of microtubules within the dense microtubule network. It is still debated what defines the specific binding of kinesin-1 to a subset of microtubules. Therefore, the ability to visualize and monitor kinesin transport in live cells is critical to study the myriad of functions associated with cargo trafficking. Herein we report the discovery of a fluorogenic small molecule substrate for kinesin-1 that yields a precipitating dye. The activity of kinesin-1 thus leaves a fluorescent trail along its walking path and can be visualized without loss of signal due to diffusion. Kinesin-1 specific transport of cargo from the Golgi appears as trails of fluorescence over time.

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Insights into Kinesin-1 Activation from the Crystal Structure of KLC2 Bound to JIP3

Cited by 51 publications

References 79 publications

Structural basis for isoform-specific kinesin-1 recognition of Y-acidic cargo adaptors

Structural basis for isoform-specific kinesin-1 recognition of Y-acidic cargo adaptors

Motor–cargo adaptors at the organelle–cytoskeleton interface

Kinesin-1 motility traced by an activity-based precipitating dye

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