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1. Local direction change of surface gliding microtubules

   https://doi.org/10.1002/bit.26933  

   Li, Feiran; Pan, Jing; Choi, Jong_Hyun (February 2019, Biotechnology and Bioengineering)

   Abstract In vitro gliding assay, microtubule translocation by kinesin motor proteins on a surface, has been used as an engineering tool in analyte detection, molecular cargo transport, and other applications. Although controlling the moving direction is often necessary to realize these applications, current direction control methods focus largely on lithographic microfabrication of tracks or external fields on the microtubules. These methods are effective, but are relatively complicated. In addition, they cannot target particular microtubules without affecting others. In this study, we propose a facile approach that can make local direction changes for selected microtubules using a polystyrene particle as a circular motion center and a DNA double helix with streptavidin as a capture arm. The DNA arm captures a microtubule in the close proximity of the immobilized particle via biotin–streptavidin interaction and changes the moving direction ~10° on average. In contrast, no significant direction changes are observed other than random variations with streptavidin‐less DNA arms (normal distribution centered at 0°), similar to regular motility assay. The particle‐assisted local direction change scheme is compared with a flow field‐based ensemble method. The combination of flow and kinesin interactions with each microtubule exerts a force to change the direction, ultimately aligning it to the flow field, regardless of its initial direction. A simple model based on the force balance predicts the time needed for such an alignment. Overall, the particle‐based local scheme is distinct and different from ensemble methods such as crossflow that changes directions of all microtubules in the field, thus offering unique utility in engineering applications. 

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2. Computational analysis of hereditary spastic paraplegia mutations in the kinesin motor domains of KIF1A and KIF5A

   https://doi.org/10.1142/S0219633620410035  

   Mahase, Vidhyanand; Sobitan, Adebiyi; Johnson, Christina; Cooper, Farion; Xie, Yixin; Li, Lin; Teng, Shaolei (September 2020, Journal of Theoretical and Computational Chemistry)

   • The structure-based energy calculations were applied to determine the effects of disease-causing kinesin missense mutations on protein stability and protein-protein interaction. • The mutations associated with Intellectual Disability can decrease the protein stability of KIF1A motor domain. • Hereditary Spastic Paraplegia mutations located in kinesin-tubulin complex interface can destabilize the binding infinity of KIF5A-tubulin complex. 

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3. TRAK adaptors regulate the recruitment and activation of dynein and kinesin in mitochondrial transport

   https://doi.org/10.1038/s41467-023-36945-8  

   Canty, John T.; Hensley, Andrew; Aslan, Merve; Jack, Amanda; Yildiz, Ahmet (March 2023, Nature Communications)

   Abstract Mitochondrial transport along microtubules is mediated by Miro1 and TRAK adaptors that recruit kinesin-1 and dynein-dynactin. To understand how these opposing motors are regulated during mitochondrial transport, we reconstitute the bidirectional transport of Miro1/TRAK along microtubules in vitro. We show that the coiled-coil domain of TRAK activates dynein-dynactin and enhances the motility of kinesin-1 activated by its cofactor MAP7. We find that TRAK adaptors that recruit both motors move towards kinesin-1’s direction, whereas kinesin-1 is excluded from binding TRAK transported by dynein-dynactin, avoiding motor tug-of-war. We also test the predictions of the models that explain how mitochondrial transport stalls in regions with elevated Ca²⁺. Transport of Miro1/TRAK by kinesin-1 is not affected by Ca²⁺. Instead, we demonstrate that the microtubule docking protein syntaphilin induces resistive forces that stall kinesin-1 and dynein-driven motility. Our results suggest that mitochondrial transport stalls by Ca²⁺-mediated recruitment of syntaphilin to the mitochondrial membrane, not by disruption of the transport machinery. 

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4. Mechanistic basis of propofol-induced disruption of kinesin processivity

   https://doi.org/10.1073/pnas.2023659118  

   Dutta, Mandira; Gilbert, Susan P.; Onuchic, José N.; Jana, Biman (January 2021, Proceedings of the National Academy of Sciences)

   Propofol is a widely used general anesthetic to induce and maintain anesthesia, and its effects are thought to occur through impact on the ligand-gated channels including the GABA_Areceptor. Propofol also interacts with a large number of proteins including molecular motors and inhibits kinesin processivity, resulting in significant decrease in the run length for conventional kinesin-1 and kinesin-2. However, the molecular mechanism by which propofol achieves this outcome is not known. The structural transition in the kinesin neck-linker region is crucial for its processivity. In this study, we analyzed the effect of propofol and its fluorine derivative (fropofol) on the transition in the neck-linker region of kinesin. Propofol binds at two crucial surfaces in the leading head: one at the microtubule-binding interface and the other in the neck-linker region. We observed in both the cases the order–disorder transition of the neck-linker was disrupted and kinesin lost its signal for forward movement. In contrast, there was not an effect on the neck-linker transition with propofol binding at the trailing head. Free-energy calculations show that propofol at the microtubule-binding surface significantly reduces the microtubule-binding affinity of the kinesin head. While propofol makes pi–pi stacking and H-bond interactions with the propofol binding cavity, fropofol is unable to make a suitable interaction at this binding surface. Therefore, the binding affinity of fropofol is much lower compared to propofol. Hence, this study provides a mechanism by which propofol disrupts kinesin processivity and identifies transitions in the ATPase stepping cycle likely affected. 

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5. An Arabidopsis Kinesin-14D motor is associated with midzone microtubules for spindle morphogenesis

   https://doi.org/10.1016/j.cub.2024.07.020  

   Guo, Xiaojiang; Huang, Calvin H; Akagi, Takashi; Niwa, Shinsuke; McKenney, Richard J; Wang, Ji-Rui; Lee, Yuh-Ru Julie; Liu, Bo (August 2024, Current Biology)

   The acentrosomal spindle apparatus has kinetochore fibers organized and converged toward opposite poles; however, mechanisms underlying the organization of these microtubule fibers into an orchestrated bipolar array were largely unknown. Kinesin-14D is one of the four classes of Kinesin-14 motors that are conserved from green algae to flowering plants. In Arabidopsis thaliana, three Kinesin-14D members displayed distinct cell cycle-dependent localization patterns on spindle microtubules in mitosis. Notably, Kinesin-14D1 was enriched on the midzone microtubules of prophase and mitotic spindles and later persisted in the spindle and phragmoplast midzones. The kinesin-14d1 mutant had kinetochore fibers disengaged from each other during mitosis and exhibited hypersensitivity to the microtubule-depolymerizing herbicide oryzalin. Oryzalin-treated kinesin-14d1 mutant cells had kinetochore fibers tangled together in collapsed spindle microtubule arrays. Kinesin-14D1, unlike other Kinesin-14 motors, showed slow microtubule plus end-directed motility, and its localization and function were dependent on its motor activity and the novel malectin-like domain. Our findings revealed a Kinesin-14D1-dependent mechanism that employs interpolar microtubules to regulate the organization of kinetochore fibers for acentrosomal spindle morphogenesis. 

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