EC:3.6.4.4 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.6.4.4 (kinesin)
5,033 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The kinesin superfamily motor protein KIF1B has been shown to transport mitochondria. Here, we describe an isoform of KIF1B, KIF1Bbeta, that is distinct from KIF1B in its cargo binding domain. KIF1B knockout mice die at birth from apnea due to nervous system defects. Death of knockout neurons in culture can be rescued by expression of the beta isoform. The KIF1B heterozygotes have a defect in transporting synaptic vesicle precursors and suffer from progressive muscle weakness similar to human neuropathies. Charcot-Marie-Tooth disease type 2A was previously mapped to an interval containing KIF1B. We show that CMT2A patients contain a loss-of-function mutation in the motor domain of the KIF1B gene. This is clear indication that defects in axonal transport due to a mutated motor protein can underlie human peripheral neuropathy.
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PMID:Charcot-Marie-Tooth disease type 2A caused by mutation in a microtubule motor KIF1Bbeta. 1138 29

Kinesin molecular motor proteins are responsible for many of the major microtubule-dependent transport pathways in neuronal and non-neuronal cells. Elucidating the transport pathways mediated by kinesins, the identity of the cargoes moved, and the nature of the proteins that link kinesin motors to cargoes are areas of intense investigation. Kinesin-II recently was found to be required for transport in motile and nonmotile cilia and flagella where it is essential for proper left-right determination in mammalian development, sensory function in ciliated neurons, and opsin transport and viability in photoreceptors. Thus, these pathways and proteins may be prominent contributors to several human diseases including ciliary dyskinesias, situs inversus, and retinitis pigmentosa. Kinesin-I is needed to move many different types of cargoes in neuronal axons. Two candidates for receptor proteins that attach kinesin-I to vesicular cargoes were recently found. One candidate, sunday driver, is proposed to both link kinesin-I to an unknown vesicular cargo and to bind and organize the mitogen-activated protein kinase components of a c-Jun N-terminal kinase signaling module. A second candidate, amyloid precursor protein, is proposed to link kinesin-I to a different, also unknown, class of axonal vesicles. The finding of a possible functional interaction between kinesin-I and amyloid precursor protein may implicate kinesin-I based transport in the development of Alzheimer's disease.
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PMID:Kinesin molecular motors: transport pathways, receptors, and human disease. 1141 78

Members of the kinesin II family are thought to play essential roles in many types of intracellular transport. One distinguishing feature of kinesin II is that it generally contains two different motor subunits from the Kif3 family. Three Kif3 family members (Kif3A, Kif3B, and Kif3C) have been identified and characterized in mice. Intracellular localization and biochemical studies previously suggested that Kif3C is an anterograde motor involved in anterograde axonal transport. To understand the in vivo function of the Kif3C gene, we used homologous recombination in embryonic stem cells to construct two different knockout mouse strains for the Kif3C gene. Both homozygous Kif3C mutants are viable, reproduce normally, and apparently develop normally. These results suggest that Kif3C is dispensable for normal neural development and behavior in the mouse.
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PMID:Functional analysis of mouse kinesin motor Kif3C. 1146 14

Recent evidence has challenged our ideas about the nature of axonal protein synthesis and transport. Previous metabolic labeling evidence supported the idea that all axonal proteins were synthesized in the cell body and then transported as formed cytoplasmic structures into the axon. Recent evidence suggests that neither the synthesis nor the transport of axonal proteins is that simple. Though most axonal proteins do appear to be synthesized in the neuronal cell body, a small amount of protein appears to be synthesized intra-axonally in some axons. Though small in amount, intra-axonal protein synthesis may be important functionally in some axons. Recent experiments have also begun to identify the presence of a rich array of transport motors in axons, including many members of the kinesin, dynein and myosin families. Progress is being made in identifying which cargoes are being transported by which of these motors. Finally, recent experiments have addressed an old question about whether axoplasmic proteins are transported as filamentous polymers or as soluble components in axons. The answer is that both mechanism can be used in axons. For example, neurofilament protein can move in its particulate or polymeric state, while tubulin can move in its soluble or unpolymerized state.
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PMID:Axonal protein synthesis and transport. 1146 69

A large number of membrane-bounded organelles, protein complexes, and mRNAs are transported along microtubules to different locations within the neuronal axon. Axonal transport in the anterograde direction is carried out by members of a superfamily of specialized motor proteins, the kinesins. All kinesins contain a conserved motor domain that hydrolyses ATP to generate movement along microtubules. Regions outside the motor domain are responsible for cargo binding and regulation of motor activity. Present in a soluble, inactive form in the cytoplasm, kinesins are activated upon cargo binding. Selective targeting of different types of kinesin motors to specific cargoes is directed by amino acid sequences situated in their variable tails. Cargo proteins with specific function at their destination, bind directly to specific kinesins for transport. Whereas most kinesins move to microtubule plus-ends, a small number of them move to microtubule minus-ends, and may participate in retrograde axonal transport. Axonal transport by kinesins has a logic: Fully assembled, multisubunit, functional complexes (e.g., ion channel complexes, signaling complexes, RNA-protein complexes) are transported to their destination by kinesin motors that interact transiently (i.e., during transport only) with one of the complexes' subunits.
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PMID:One axon, many kinesins: What's the logic? 1146 72

The recent demonstration that the axonal transport motors kinesin and dynein participate in axonal transport of neurofilaments (NFs), and that the association of NFs with these motors is regulated by phosphorylation provides new insight into several aspects of axonal transport and NF biology. This review juxtaposes older and more recent findings on NF dynamics, and speculates on the organization of axonal NFs as suggested by real-time analyses of NF transport.
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PMID:Microtubule motors, phosphorylation and axonal transport of neurofilaments. 1146 76

The recent demonstration that the fast axonal transport motors kinesin and dynein participate in axonal transport of neurofilaments--known to undergo slow transport--supports and extends recent studies indicating that some neurofilaments exhibit alternating bursts of fast axonal transport interspersed with periods of non-motility. In addition, these findings unify both certain aspects of axonal transport and neurofilament biology. We discuss these data herein in the context of both older and more recent studies of neurofilament dynamics.
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PMID:Kinesin, dynein and neurofilament transport. 1167 8

We tested the hypothesis that amyloid precursor protein (APP) and its relatives function as vesicular receptor proteins for kinesin-I. Deletion of the Drosophila APP-like gene (Appl) or overexpression of human APP695 or APPL constructs caused axonal transport phenotypes similar to kinesin and dynein mutants. Genetic reduction of kinesin-I expression enhanced while genetic reduction of dynein expression suppressed these phenotypes. Deletion of the C terminus of APP695 or APPL, including the kinesin binding region, disrupted axonal transport of APP695 and APPL and abolished the organelle accumulation phenotype. Neuronal apoptosis was induced only by overexpression of constructs containing both the C-terminal and Abeta regions of APP695. We discuss the possibility that axonal transport disruption may play a role in the neurodegenerative pathology of Alzheimer's disease.
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PMID:Disruption of axonal transport and neuronal viability by amyloid precursor protein mutations in Drosophila. 1170 51

Proteolytic processing of amyloid precursor protein (APP) generates amyloid-beta peptide and has been implicated in the pathogenesis of Alzheimer's disease. However, the normal function of APP, whether this function is related to the proteolytic processing of APP, and where this processing takes place in neurons in vivo remain unknown. We have previously shown that the axonal transport of APP in neurons is mediated by the direct binding of APP to the kinesin light chain subunit of kinesin-I, a microtubule motor protein. Here we identify an axonal membrane compartment that contains APP, beta-secretase and presenilin-1. The fast anterograde axonal transport of this compartment is mediated by APP and kinesin-I. Proteolytic processing of APP can occur in the compartment in vitro and in vivo in axons. This proteolysis generates amyloid-beta and a carboxy-terminal fragment of APP, and liberates kinesin-I from the membrane. These results suggest that APP functions as a kinesin-I membrane receptor, mediating the axonal transport of beta-secretase and presenilin-1, and that processing of APP to amyloid-beta by secretases can occur in an axonal membrane compartment transported by kinesin-I.
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PMID:Kinesin-mediated axonal transport of a membrane compartment containing beta-secretase and presenilin-1 requires APP. 1174 May 61

The bulk of neuronally synthesized proteins destined for the axon is transported in a phase of transport approximately 100 times slower (1mm/day) than the vesicular traffic of fast axonal transport (100mm/day). Of late, a number of studies have shed considerable light on the controversies and mechanisms surrounding this slow phase of axonal transport. Along-standing controversy has centered on the form of the transported proteins. One major transport cargo, neurofilament protein, has now been seen in a number of contexts to be transported primarily in a polymeric form, whereas a second cargo tubulin is transported as a small oligomer. The development of techniques to visualize the slow transport process in live cells has demonstrated that instantaneous motions of transported neurofilaments, and presumably other slow transport cargoes, are fast, bidirectional and interspersed with long pauses. This and additional biochemical efforts indicate that traditional fast motors, such as conventional kinesin and dynein, are responsible for these fast motions.
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PMID:Slow axonal transport: fast motors in the slow lane. 1179 45

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