EC:3.6.4.4 - FACTA Search

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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)

A model for intracellular transport of pigment granules in the red ovarian chromatophores of the freshwater shrimp Macrobrachium olfersi is proposed on the basis of shifts in the equilibrium of resting forces acting on an elastic pigment matrix. The model describes a pigment-transport mechanism in which mechanochemical protein motors like kinesin and myosin alternately stretch and compress a structurally unified, elastic pigment matrix. Quantifiable properties of the spring-matrix obey Hooke's Law during the rapid phases of pigment aggregation and dispersion. The spring-like response of the pigment mass is estimated from previous kinetic experiments on pigment translocation induced by red pigment concentrating hormone, or by the calcium ionophore A23187. Both translocation effectors trigger an initial phase of rapid pigment aggregation, and their removal or washout after complete aggregation produces a phase of rapid pigment dispersion, followed by slow pigment translocation. The rapid-phase kinetics of pigment transport are in reasonable agreement with Hooke's Law, suggesting that such phases represent the release of kinetic energy, probably produced by the mechanochemical protein motors and stored in the form of matrix deformation during the slow phases of translocation. This semiquantitative model should aid in analyzing intracellular transport systems that incorporate an elastic component.
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PMID:A spring-matrix model for pigment translocation in the red ovarian chromatophores of the freshwater shrimp Macrobrachium olfersi (Crustacea, Decapoda). 1840 Sep 93

Nonmotile primary cilia are sensory organelles composed of a microtubular axoneme and a surrounding membrane sheath that houses signaling molecules. Optimal cellular function requires the precise regulation of axoneme assembly, membrane biogenesis, and signaling protein targeting and localization via as yet poorly understood mechanisms. Here, we show that sensory signaling is required to maintain the architecture of the specialized AWB olfactory neuron cilia in C. elegans. Decreased sensory signaling results in alteration of axoneme length and expansion of a membraneous structure, thereby altering the topological distribution of a subset of ciliary transmembrane signaling molecules. Signaling-regulated alteration of ciliary structures can be bypassed by modulation of intracellular cGMP or calcium levels and requires kinesin-II-driven intraflagellar transport (IFT), as well as BBS- and RAB8-related proteins. Our results suggest that compensatory mechanisms in response to altered levels of sensory activity modulate AWB cilia architecture, revealing remarkable plasticity in the regulation of cilia structure.
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PMID:Sensory signaling-dependent remodeling of olfactory cilia architecture in C. elegans. 1847 43

Inositol 1,4,5-trisphosphate (IP3) is a second messenger that induces the release of calcium from the endoplasmic reticulum (ER). The IP3 receptor was discovered as a developmentally regulated glycophosphoprotein, P400, that is absent in strains of mutant mice. The crystal structures of the IP3-binding core and N-terminal suppressor sequence of the IP3 receptor have been identified. The IP3-binding core's affinity to IP3 is similar among the three isoforms of IP3 receptors; however, the N-terminal IP3-binding suppressor region is responsible for isoform-specific IP3-binding affinity tuning. Various pathways for the trafficking of IP3 receptors have been identified; for example, the ER forms a meshwork on which IP3 receptors move by lateral diffusion, and vesicular ER subcompartments containing IP3 receptors move rapidly along microtubules using a kinesin motor. Furthermore, IP3 receptor messenger RNA within messenger RNA granules also moves along microtubules. Recently, we discovered that IP3 receptors play a crucial role in exocrine secretion. ERp44 works as a redox sensor in the ER and regulates IP3 type 1 receptor activity. IP3 receptor also releases IP3 receptor-binding protein released with IP3 (IRBIT). IRBIT is a pseudoligand for IP3 that regulates the frequency and amplitude of calcium oscillations through the IP3 receptor. IRBIT binds to pancreas-type sodium bicarbonate cotransporter 1, which is important for acid-base balance. Type 2 and 3 double-deficient mice show a deficit in saliva and lacrimal and pancreatic juice secretion. Type 1 IP3 receptor influences brain-derived neurotrophic factor production.
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PMID:The role of Ca2+ signaling in cell function with special reference to exocrine secretion. 1881 72

TGases (transglutaminases) are a class of calcium-dependent enzymes that catalyse the interactions between acyl acceptor glutamyl residues and amine donors, potentially making cross-links between proteins. To assess the activity of apple (Malus domestica) pollen TGase on the functional properties of actin and tubulin, TGase was prepared from apple pollen by hydrophobic- interaction chromatography and assayed on actin and tubulin purified from the same cell type. The enzyme catalysed the incorporation of putrescine into the cytoskeleton monomers. When tested on actin filaments, pollen TGase induced the formation of high-molecular-mass aggregates of actin. Use of fluorescein-cadaverine showed that the labelled polyamine was incorporated into actin by pollen TGase, similar to with guinea pig liver TGase. The pollen TGase also reduced the enzyme activity and the binding of myosin to TGase-treated actin filaments. Polymerization of tubulin in the presence of pollen TGase also yielded the formation of high-molecular-mass aggregates. Furthermore, the pollen TGase also affected the binding of kinesin to microtubules and reduced the motility of microtubules along kinesin-coated slides. These results indicate that the pollen TGase can control different properties of the pollen tube cytoskeleton (including the ability of actin and tubulin to assemble and their interaction with motor proteins) and consequently regulate the development of pollen tubes.
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PMID:Effects of post-translational modifications catalysed by pollen transglutaminase on the functional properties of microtubules and actin filaments. 1901 51

The transport of mitochondria to specific neuronal locations is critical to meet local cellular energy demands and for buffering intracellular calcium. A critical role for kinesin motor proteins in mitochondrial transport in neurons has been demonstrated. Currently however the molecular mechanisms that underlie the recruitment of motor proteins to mitochondria, and how this recruitment is regulated remain unclear. Here we show that a protein trafficking complex comprising the adaptor protein Grif-1 and the atypical GTPase Miro1 can be detected in mammalian brain where it is localised to neuronal mitochondria. Increasing Miro1 expression levels recruits Grif-1 to mitochondria. This results in an enhanced transport of mitochondria towards the distal ends of neuronal processes. Uncoupling Grif-1 recruitment to mitochondria by expressing a Grif-1/Miro1 binding fragment dramatically reduces mitochondrial transport into neuronal processes. Altering Miro1 function by mutating its first GTPase domain affects Miro's ability to recruit Grif-1 to mitochondria and in addition alters mitochondrial distribution and shape along neuronal processes. These data suggest that Miro1 and the kinesin adaptor Grif-1 play an important role in regulating mitochondrial transport in neurons.
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PMID:GTPase dependent recruitment of Grif-1 by Miro1 regulates mitochondrial trafficking in hippocampal neurons. 1910 91

The mammalian acrosome reaction is a specialised exocytotic event. Although molecular motors are known to be involved in exocytosis in many cell types, their potential involvement in the acrosome reaction has remained unknown. Here, it has been shown that actin is localised within the equatorial segment and in the marginal acrosomal ridge of the heads of unreacted bull spermatozoa. Myosins IIA and IIB are found within the anterior acrosomal margins of virtually all sperm cells and, less prominently, within the equatorial segment. Tubulin was detected in the equatorial segment and around the periphery of the acrosome while kinesin was prominent in the equatorial segment. After induction of the acrosome reaction by means of the calcium ionophore A23187, the number of cells exhibiting actin fluorescence intensity in the anterior acrosomal margin decreased four-fold and those displaying equatorial segment fluorescence decreased 3.5-fold; myosin IIA immunofluorescence decreased in intensity with most spermatozoa losing equatorial staining, whereas there was little change in the distribution or intensity of myosin IIB immunofluorescence, except for approximately 20% decrease in the number of cells exhibiting acrosomal staining. Tubulin became largely undetectable within the head and kinesin staining spread rostrally over the main acrosome region. A possible sequence of events that ties in these observations of molecular motor involvement with the known participation of SNARE proteins is provided.
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PMID:Relocation of myosin and actin, kinesin and tubulin in the acrosome reaction of bovine spermatozoa. 1921 Sep 28

The expression of hippocalcin, a calcium-sensor protein of the recoverin family, and mixed lineage kinase 2 (MLK2) in Lewy bodies (LBs) was immunohistochemically examined in patients with Parkinson's disease (PD). Hippocalcin and MLK2 were colocalized in the halo of LBs, and neither protein was detected in normal pigmented neurons. Since hippocalcin binds to the C-terminal region of MLK2 [Nagata K., Puls A, Futter C, Aspenstrom P, Schaefer E, Nakata T et al., The MAP kinase kinase kinase MLK2 co-localizes with activated JNK along microtubules and associates with kinesin superfamily motor KIF3. EMBO J 1998;17:149-1588.], it may constitutively activate MLK2. Both hippocalcin and MLK2 may be associated with the pathogenesis of PD.
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PMID:Mixed lineage kinase 2 and hippocalcin are localized in Lewy bodies of Parkinson's disease. 1933 48

Calcium oscillations control mitochondrial motility along the microtubules and in turn, support on-demand distribution of mitochondria. However, the mechanism mediating the Ca(2+) effect remained a mystery. Recently, several papers reported on the Ca(2+)-dependent regulation of mitochondrial dynamics by a Miro-Milton complex linking mitochondria to kinesin motors. Both mitochondrial motility and fusion-fission dynamics seem to be sensitive to a Ca(2+)-dependent switch by this complex. Evidence is emerging that calcium signaling through Miro-Milton is central to coordination of the local oxidative metabolism with the energy demands and protection against Ca(2+)-induced cell injury.
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PMID:Ca2+-dependent regulation of mitochondrial dynamics by the Miro-Milton complex. 1948 Nov 72

Calcium (Ca(2+)) is a key second messenger in eukaryotes where it regulates a diverse array of cellular processes in response to external stimuli. An important Ca(2+) sensor in both animals and plants is calmodulin (CaM). In addition to evolutionarily conserved CaM, plants possess a unique family of CaM-like (CML) proteins. The majority of these CMLs have not yet been studied, and investigation into their physical properties and cellular functions will provide insight into Ca(2+) signal transduction in plants. Here we describe the characterization of CML42, a 191-amino acid Ca(2+)-binding protein from Arabidopsis. Ca(2+) binding to recombinant CML42 was assessed by fluorescence spectroscopy, NMR spectroscopy, microcalorimetry, and CD spectroscopy. CML42 displays significant alpha-helical secondary structure, binds three molecules of Ca(2+) with affinities ranging from 30 to 430 nm, and undergoes a Ca(2+)-induced conformational change that results in the exposure of one or more hydrophobic regions. Gene expression analysis revealed CML42 transcripts at various stages of development and in many cell types, including the support cells, which surround trichomes (leaf hairs) on the leaf surface. Using yeast two-hybrid screening we identified a putative CML42 interactor; kinesin-interacting Ca(2+)-binding protein (KIC). Because KIC is a protein known to function in trichome development, we examined transgenic CML42 knockout plants and found that they possess aberrant trichomes with increased branching. Collectively, our data support a role for CML42 as a Ca(2+) sensor that functions during cell branching in trichomes.
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PMID:The calmodulin-related calcium sensor CML42 plays a role in trichome branching. 1972 Aug 24

Mitochondrial distribution is integrally related to cellular function. Highly polarized cells, such as neurons, likely depend on mitochondrial transport to maintain proper synaptic function and neurite plasticity. In some cases, mitochondrial transport is also required for cellular migration and proper calcium signaling in non-neuronal cells. Over the past few years, much progress has been made in identifying proteins that control mitochondrial transport and distribution. Miro and Milton, which are two outer mitochondrial membrane proteins, tether mitochondria to kinesin motor proteins. Our recent work identified a novel protein, HUMMR, which interacts with Miro. While present in normoxia, HUMMR protein abundance is markedly induced by hypoxia through a HIF-1 dependent mechanism. Knock down of HUMMR function diminishes the number of mitochondria in the axon, an effect that was more prominent in neurons exposed to hypoxia. Interestingly, in hypoxic neurons, knock down of HUMMR also diminished the number of anterograde moving mitochondria, but increased the number of retrograde moving mitochondria. Thus, HUMMR is a protein which biases mitochondrial movement in the anterograde direction in response to hypoxia. The implication for this biased transport of mitochondria during hypoxia on neuronal function and viability is yet to be discerned. Regardless, since hypoxia is prominent during ischemia and in solid tumors, HUMMR likely contributes to mitochondrial distribution under these conditions. As such, HUMMR may influence cellular function that is dependent upon the correct mitochondrial localization.
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PMID:During hypoxia, HUMMR joins the mitochondrial dance. 2001 76

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