Kinesin-2 differentially regulates the anterograde axonal transports of acetylcholinesterase and choline acetyltransferase in Drosophila

Choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) are involved in acetylcholine synthesis and degradation at pre- and postsynaptic compartments, respectively. Here we show that their anterograde transport in Drosophila larval ganglion is microtubule-dependent and occurs in two different time profiles. AChE transport is constitutive while that of ChAT occurs in a brief pulse during third instar larva stage. Mutations in the kinesin-2 motor subunit Klp64D and separate siRNA-mediated knock-outs of all the three kinesin-2 subunits disrupt the ChAT and AChE transports, and these antigens accumulate in discrete nonoverlapping punctae in neuronal cell bodies and axons. Quantification analysis further showed that mutations in Klp64D could independently affect the anterograde transport of AChE even before that of ChAT. Finally, ChAT and AChE were coimmunoprecipitated with the kinesin-2 subunits but not with each other. Altogether, these suggest that kinesin-2 independently transports AChE and ChAT within the same axon. It also implies that cargo availability could regulate the rate and frequency of transports by kinesin motors.     

mNUDC is required for plus‐end‐directed transport of cytoplasmic dynein and dynactins by kinesin‐1

Lissencephaly is a devastating neurological disorder caused by defective neuronal migration. The LIS1 (or PAFAH1B1) gene was identified as the gene mutated in lissencephaly patients, and was found to regulate cytoplasmic dynein function and localization. In particular, LIS1 is essential for anterograde transport of cytoplasmic dynein as a part of the cytoplasmic dynein–LIS1–microtubule complex in a kinesin‐1‐dependent manner. However, the underlying mechanism by which a cytoplasmic dynein–LIS1–microtubule complex binds kinesin‐1 is unknown. Here, we report that mNUDC (mammalian NUDC) interacts with kinesin‐1 and is required for the anterograde transport of a cytoplasmic dynein complex by kinesin‐1. mNUDC is also required for anterograde transport of a dynactin‐containing complex. Inhibition of mNUDC severely suppressed anterograde transport of distinct cytoplasmic dynein and dynactin complexes, whereas motility of kinesin‐1 remained intact. Reconstruction experiments clearly demonstrated that mNUDC mediates the interaction of the dynein or dynactin complex with kinesin‐1 and supports their transport by kinesin‐1. Our findings have uncovered an essential role of mNUDC for anterograde transport of dynein and dynactin by kinesin‐1.     

Kinesin II is required for cell survival and adherens junction positioning in Drosophila photoreceptors

Photoreceptor morphogenesis requires specific and coordinated localization of junctional markers at different stages of development. Here, we provide evidence that Drosophila Klp64D, a homolog of Kif3A motor subunit of the heterotrimeric Kinesin II complex, is essential for viability of developing photoreceptors and localization of junctional proteins. Genetic analysis of mutant clones shows that absence of Klp64D protein in early larval eye disc does not affect initial differentiation, but results in abnormal nuclear position in differentiating photoreceptors. These cells eventually die in the pupal stage, indicating klp64D's role in cell viability. The function of Klp64D protein is cell type specific because the p35 cell death inhibitor can rescue cell death in cone cells but not photoreceptors. In contrast to early induction of mutant clones, late induction during third instar larval stage just prior to pupation allows survival of single‐ or few‐celled clones of klp64D mutant cells. Analysis of these lately induced clones shows that Klp64D function is essential for Bazooka (Par‐3 homolog) and Armadillo localization to the adherens junction (AJ) in pupal photoreceptors. These findings suggest that Kinesin II complex plays a cell type‐specific function in the localization of AJ and cell polarity proteins in the developing retina, thereby contributing to photoreceptor morphogenesis. genesis 48:522–530, 2010. © 2010 Wiley‐Liss, Inc.     

SKIP,the Host Target of the Salmonella Virulence Factor SifA,Promotes Kinesin‐1‐Dependent Vacuolar Membrane Exchanges

In Salmonella‐infected cells, the bacterial effector SifA forms a functional complex with the eukaryotic protein SKIP (SifA and kinesin‐interacting protein). The lack of either partner has important consequences on the intracellular fate and on the virulence of this pathogen. In addition to SifA, SKIP binds the microtubule‐based motor kinesin‐1. Yet the absence of SifA or SKIP results in an unusual accumulation of kinesin‐1 on the bacterial vacuolar membrane. To understand this apparent contradiction, we investigated the interaction between SKIP and kinesin‐1 and the function of this complex. We show that the C‐terminal RUN (RPIP8, UNC‐14 and NESCA) domain of SKIP interacted specifically with the tetratricopeptide repeat (TPR) domain of the kinesin light chain. Overexpression of SKIP induced a microtubule‐ and kinesin‐1‐dependent anterograde movement of late endosomal/lysosomal compartments. In infected cells, SifA contributed to the fission of vesicles from the bacterial vacuole and the SifA/SKIP complex was required for the formation and/or the anterograde transport of kinesin‐1‐enriched vesicles. These observations reflect the role of SKIP as a linker and/or an activator for kinesin‐1.     

The kinases male germ cell‐associated kinase and cell cycle‐related kinase regulate kinesin‐2 motility in Caenorhabditis elegans neuronal cilia

Kinesin‐2 motors power anterograde intraflagellar transport (IFT), a highly ordered process that assembles and maintains cilia. However, it remains elusive how kinesin‐2 motors are regulated in vivo. Here, we performed forward genetic screens to isolate suppressors that rescue the ciliary defects of OSM‐3‐kinesin (homolog of mammalian homodimeric kinesin‐2 KIF17) mutants in Caenorhabditis elegans. We identified the C. elegans dyf‐5 and dyf‐18, which encode the homologs of mammalian male germ cell‐associated kinase and cell cycle‐related kinase, respectively. Using time‐lapse fluorescence microscopy, we show that DYF‐5 and DYF‐18 are IFT cargo molecules and are enriched at the distal segments of sensory cilia. Mutations of dyf‐5 and dyf‐18 generate elongated cilia and ectopic localization of the heterotrimeric kinesin‐2 (kinesin‐II) at the ciliary distal segments. Genetic analyses reveal that dyf‐5 and dyf‐18 are important for stabilizing the interaction between IFT particles and OSM‐3‐kinesin. Our data suggest that DYF‐5 and DYF‐18 act in the same pathway to promote handover between kinesin‐II and OSM‐3 in sensory cilia.      

KIF1A mediates axonal transport of BACE1 and identification of independently moving cargoes in living SCG neurons

Neurons rely heavily on axonal transport to deliver materials from the sites of synthesis to the axon terminals over distances that can be many centimetres long. KIF1A is the neuron‐specific kinesin with the fastest reported anterograde motor activity. Previous studies have shown that KIF1A transports a subset of synaptic proteins, neurofilaments and dense‐core vesicles. Using two‐colour live imaging, we showed that beta‐secretase 1 (BACE1)‐mCherry moves together with KIF1A‐GFP in both the anterograde and retrograde directions in superior cervical ganglions (SCG) neurons. We confirmed that KIF1A is functionally required for BACE1 transport by using KIF1A siRNA and a KIF1A mutant construct (KIF1A‐T312M) to impair its motor activity. We further identified several cargoes that have little or no co‐migration with KIF1A‐GFP and also move independently from BACE1‐mCherry. Together, these findings support a primary role for KIF1A in the anterograde transport of BACE1 and suggest that axonally transported cargoes are sorted into different classes of carrier vesicles in the cell body and are transported by cargo‐specific motor proteins through the axon.      

Interaction with a kinesin-2 tail propels choline acetyltransferase flow towards synapse

Bulk flow constitutes a substantial part of the slow transport of soluble proteins in axons. Though the underlying mechanism is unclear, evidences indicate that intermittent, kinesin-based movement of large protein-aggregates aids this process. Choline acetyltransferase (ChAT), a soluble enzyme catalyzing acetylcholine synthesis, propagates toward the synapse at an intermediate, slow rate. The presynaptic enrichment of ChAT requires heterotrimeric kinesin-2, comprising KLP64D, KLP68D and DmKAP, in Drosophila. Here, we show that the bulk flow of a recombinant Green Fluorescent Protein-tagged ChAT (GFP::ChAT), in Drosophila axons, lacks particulate features. It occurs for a brief period during the larval stages. In addition, both the endogenous ChAT and GFP::ChAT directly bind to the KLP64D tail, which is essential for the GFP::ChAT entry and anterograde flow in axon. These evidences suggest that a direct interaction with motor proteins could regulate the bulk flow of soluble proteins, and thus establish their asymmetric distribution.     

Kinesin‐2 motors adapt their stepping behavior for processive transport on axonemes and microtubules

Two structurally distinct filamentous tracks, namely singlet microtubules in the cytoplasm and axonemes in the cilium, serve as railroads for long‐range transport processes in vivo. In all organisms studied so far, the kinesin‐2 family is essential for long‐range transport on axonemes. Intriguingly, in higher eukaryotes, kinesin‐2 has been adapted to work on microtubules in the cytoplasm as well. Here, we show that heterodimeric kinesin‐2 motors distinguish between axonemes and microtubules. Unlike canonical kinesin‐1, kinesin‐2 takes directional, off‐axis steps on microtubules, but it resumes a straight path when walking on the axonemes. The inherent ability of kinesin‐2 to side‐track on the microtubule lattice restricts the motor to one side of the doublet microtubule in axonemes. The mechanistic features revealed here provide a molecular explanation for the previously observed partitioning of oppositely moving intraflagellar transport trains to the A‐ and B‐tubules of the same doublet microtubule. Our results offer first mechanistic insights into why nature may have co‐evolved the heterodimeric kinesin‐2 with the ciliary machinery to work on the specialized axonemal surface for two‐way traffic.     

Cytoplasmic dynein, the dynactin complex, and kinesin are interdependent and essential for fast axonal transport

In axons, organelles move away from (anterograde) and toward (retrograde) the cell body along microtubules. Previous studies have provided compelling evidence that conventional kinesin is a major motor for anterograde fast axonal transport. It is reasonable to expect that cytoplasmic dynein is a fast retrograde motor, but relatively few tests of dynein function have been reported with neurons of intact organisms. In extruded axoplasm, antibody disruption of kinesin or the dynactin complex (a dynein activator) inhibits both retrograde and anterograde transport. We have tested the functions of the cytoplasmic dynein heavy chain (cDhc64C) and the p150(Glued) (Glued) component of the dynactin complex with the use of genetic techniques in Drosophila. cDhc64C and Glued mutations disrupt fast organelle transport in both directions. The mutant phenotypes, larval posterior paralysis and axonal swellings filled with retrograde and anterograde cargoes, were similar to those caused by kinesin mutations. Why do specific disruptions of unidirectional motor systems cause bidirectional defects? Direct protein interactions of kinesin with dynein heavy chain and p150(Glued) were not detected. However, strong dominant genetic interactions between kinesin, dynein, and dynactin complex mutations in axonal transport were observed. The genetic interactions between kinesin and either Glued or cDhc64C mutations were stronger than those between Glued and cDhc64C mutations themselves. The shared bidirectional disruption phenotypes and the dominant genetic interactions demonstrate that cytoplasmic dynein, the dynactin complex, and conventional kinesin are interdependent in fast axonal transport.     

Endogenous GSK‐3/Shaggy Regulates Bidirectional Axonal Transport of the Amyloid Precursor Protein

Neurons rely on microtubule (MT) motor proteins such as kinesin‐1 and dynein to transport essential cargos between the cell body and axon terminus. Defective axonal transport causes abnormal axonal cargo accumulations and is connected to neurodegenerative diseases, including Alzheimer's disease (AD). Glycogen synthase kinase 3 (GSK‐3) has been proposed to be a central player in AD and to regulate axonal transport by the MT motor protein kinesin‐1. Using genetic, biochemical and biophysical approaches in Drosophila melanogaster, we find that endogenous GSK‐3 is a required negative regulator of both kinesin‐1‐mediated and dynein‐mediated axonal transport of the amyloid precursor protein (APP), a key contributor to AD pathology. GSK‐3 also regulates transport of an unrelated cargo, embryonic lipid droplets. By measuring the forces motors generate in vivo, we find that GSK‐3 regulates transport by altering the activity of kinesin‐1 motors but not their binding to the cargo. These findings reveal a new relationship between GSK‐3 and APP, and demonstrate that endogenous GSK‐3 is an essential in vivo regulator of bidirectional APP transport in axons and lipid droplets in embryos. Furthermore, they point to a new regulatory mechanism in which GSK‐3 controls the number of active motors that are moving a cargo .     

Load‐dependent detachment kinetics plays a key role in bidirectional cargo transport by kinesin and dynein

Bidirectional cargo transport along microtubules is carried out by opposing teams of kinesin and dynein motors. Despite considerable study, the factors that determine whether these competing teams achieve net anterograde or retrograde transport in cells remain unclear. The goal of this work is to use stochastic simulations of bidirectional transport to determine the motor properties that most strongly determine overall cargo velocity and directionality. Simulations were carried out based on published optical tweezer characterization of kinesin‐1 and kinesin‐2, and for available data for cytoplasmic dynein and the dynein‐dynactin‐BicD2 (DDB) complex. By varying dynein parameters and analyzing cargo trajectories, we find that net cargo transport is predicted to depend minimally on the dynein stall force, but strongly on dynein load‐dependent detachment kinetics. In simulations, dynein is dominated by kinesin‐1, but DDB and kinesin‐1 are evenly matched, recapitulating recent experimental work. Kinesin‐2 competes less well against dynein and DDB, and overall, load‐dependent motor detachment is the property that most determines a motor's ability to compete in bidirectional transport. It follows that the most effective intracellular regulators of bidirectional transport are predicted to be those that alter motor detachment kinetics rather than motor velocity or stall force.      

Dynactin is required for bidirectional organelle transport

Kinesin II is a heterotrimeric plus end-directed microtubule motor responsible for the anterograde movement of organelles in various cell types. Despite substantial literature concerning the types of organelles that kinesin II transports, the question of how this motor associates with cargo organelles remains unanswered. To address this question, we have used Xenopus laevis melanophores as a model system. Through analysis of kinesin II-mediated melanosome motility, we have determined that the dynactin complex, known as an anchor for cytoplasmic dynein, also links kinesin II to organelles. Biochemical data demonstrates that the putative cargo-binding subunit of Xenopus kinesin II, Xenopus kinesin II-associated protein (XKAP), binds directly to the p150Glued subunit of dynactin. This interaction occurs through aa 530-793 of XKAP and aa 600-811 of p150Glued. These results reveal that dynactin is required for transport activity of microtubule motors of opposite polarity, cytoplasmic dynein and kinesin II, and may provide a new mechanism to coordinate their activities.     

Retrograde but not anterograde bead movement in intact axons requires dynein

Dynein and kinesin have been implicated as the molecular motors that are responsible for the fast transport of axonal membranous organelles and vesicles. Experiments performed in vitro with partially reconstituted preparations have led to the hypothesis that kinesin moves organelles in the anterograde direction and dynein moves them in the retrograde direction. However, the molecular basis of transport directionality remains unclear. In the experiments described here, carboxylated fluorescent beads were injected into living Mauthner axons of lamprey and the beads were observed to move in both the anterograde and retrograde directions. The bead movement in both directions required intact microtubules, occurred at velocities approaching organelle fast transport in vivo, and was inhibited by vanadate at concentrations that inhibit organelle fast transport. When living axons were injected with micromolar concentrations of vanadate and irradiated at 365 nm prior to bead injections, a treatment that results in the V1 photolysis of dynein, the retrograde movement of the beads was specifically abolished. Neither the ultraviolet irradiation alone nor the vanadate alone produced the retrograde-specific inhibition. These results support the hypothesis that dynein is required for retrograde, but not anterograde, transport in vivo. © 1995 John Wiley & Sons, Inc.     

An RNA‐binding atypical tropomyosin recruits kinesin‐1 dynamically to oskar mRNPs

Localization and local translation of oskar mRNA at the posterior pole of the Drosophila oocyte directs abdominal patterning and germline formation in the embryo. The process requires recruitment and precise regulation of motor proteins to form transport‐competent mRNPs. We show that the posterior‐targeting kinesin‐1 is loaded upon nuclear export of oskar mRNPs, prior to their dynein‐dependent transport from the nurse cells into the oocyte. We demonstrate that kinesin‐1 recruitment requires the DmTropomyosin1‐I/C isoform, an atypical RNA‐binding tropomyosin that binds directly to dimerizing oskar 3′UTRs. Finally, we show that a small but dynamically changing subset of oskar mRNPs gets loaded with inactive kinesin‐1 and that the motor is activated during mid‐oogenesis by the functionalized spliced oskar RNA localization element. This inefficient, dynamic recruitment of Khc decoupled from cargo‐dependent motor activation constitutes an optimized, coordinated mechanism of mRNP transport, by minimizing interference with other cargo‐transport processes and between the cargo‐associated dynein and kinesin‐1.     

The C‐terminal tails of heterotrimeric kinesin‐2 motor subunits directly bind to α‐tubulin1: Possible implications for cilia‐specific tubulin entry

The assembly of microtubule‐based cytoskeleton propels the cilia and flagella growth. Previous studies have indicated that the kinesin‐2 family motors transport tubulin into the cilia through intraflagellar transport. Here, we report a direct interaction between the C‐terminal tail fragments of heterotrimeric kinesin‐2 and α‐tubulin1 isoforms in vitro. Blot overlay screen, affinity purification from tissue extracts, cosedimentation with subtilisin‐treated microtubule and LC‐ESI‐MS/MS characterization of the tail‐fragment‐associated tubulin identified an association between the tail domains and α‐tubulin1A/D isotype. The interaction was confirmed by Forster's resonance energy transfer assay in tissue‐cultured cells. The overexpression of the recombinant tails in NIH3T3 cells affected the primary cilia growth, which was rescued by coexpression of a α‐tubulin1 transgene. Furthermore, fluorescent recovery after photobleach analysis in the olfactory cilia of Drosophila indicated that tubulin is transported in a non‐particulate form requiring kinesin‐2. These results provide additional new insight into the mechanisms underlying selective tubulin isoform enrichment in the cilia.      

Loss of the m‐AAA protease subunit AFG3L2 causes mitochondrial transport defects and tau hyperphosphorylation

The m‐AAA protease subunit AFG3L2 is involved in degradation and processing of substrates in the inner mitochondrial membrane. Mutations in AFG3L2 are associated with spinocerebellar ataxia SCA28 in humans and impair axonal development and neuronal survival in mice. The loss of AFG3L2 causes fragmentation of the mitochondrial network. However, the pathogenic mechanism of neurodegeneration in the absence of AFG3L2 is still unclear. Here, we show that depletion of AFG3L2 leads to a specific defect of anterograde transport of mitochondria in murine cortical neurons. We observe similar transport deficiencies upon loss of AFG3L2 in OMA1‐deficient neurons, indicating that they are not caused by OMA1‐mediated degradation of the dynamin‐like GTPase OPA1 and inhibition of mitochondrial fusion. Treatment of neurons with antioxidants, such as N‐acetylcysteine or vitamin E, or decreasing tau levels in axons restored mitochondrial transport in AFG3L2‐depleted neurons. Consistently, tau hyperphosphorylation and activation of ERK kinases are detected in mouse neurons postnatally deleted for Afg3l2. We propose that reactive oxygen species signaling leads to cytoskeletal modifications that impair mitochondrial transport in neurons lacking AFG3L2.     

Distribution in brain and retina of four enzymes of acetyl CoA synthesis in relation to choline acetyl transferase and acetylcholine esterase

Eleven regions of mouse brain and twelve layers of monkey retina were assayed for choline acetyl transferase (ChAT), acetylcholine esterase (AChE), and 4 enzymes that synthesize acetyl CoA. The purpose was to seek evidence concerning the source of acetyl CoA for acetylcholine generation. In brain ATP citrate lyase was strongly correlated with ChAT as well as AChE (r=0.914 in both cases). Weak, but statistically significant correlation, was observed between ChAT and both cytoplasmic and mitochondrial thiolase, whereas there was a significant negative correlation between ChAT and acetyl thiokinase. In retina ChAT was essentially limited to the inner plexiform and ganglion cell layers, whereas substantial AChE activity extended as well into inner nuclear, outer plexiform and fiber layers, but no further. ATP citrate lyase activity was also highest in the inner four retinal layers, but was not strongly correlated with either ChAT or AChE (r=0.724 and 0.761, respectively). Correlation between ChAT and acetyl thiokinase was at least as strong (r=0.757), and in the six inner layers of retina, the correlation between ChAT and acetylthiokinase was very strong (r=0.932).Special issue dedicated to Dr. Lawrence Austin     

Phospho-dependent association of neurofilament proteins with kinesin in situ

Recent studies demonstrate co-localization of kinesin with neurofilament (NF) subunits in culture and suggest that kinesin participates in NF subunit distribution. We sought to determine whether kinesin was also associated with NF subunits in situ. Axonal transport of NF subunits in mouse optic nerve was perturbed by the microtubule (MT)-depolymerizing drug vinblastine, indicating that NF transport was dependent upon MT dynamics. Kinesin co-precipitated during immunoprecipitation of NF subunits from optic nerve. The association of NFs and kinesin was regulated by NF phosphorylation, since (1) NF subunits bearing developmentally delayed phospho-epitopes did not co-purify in a microtubule motor preparation from CNS while less phosphorylated forms did; (2) subunits bearing these phospho-epitopes were selectively not co-precipitated with kinesin; and (3) phosphorylation under cell-free conditions diminished the association of NF subunits with kinesin. The nature and extent of this association was further examined by intravitreal injection of (35)S-methionine and monitoring NF subunit transport along optic axons. As previously described by several laboratories, the wave of NF subunits underwent a progressive broadening during continued transport. The front, but not the trail, of this broadening wave of NF subunits was co-precipitated with kinesin, indicating that (1) the fastest-moving NFs were associated with kinesin, and (2) that dissociation from kinesin may foster trailing of NF subunits during continued transport. These data suggest that kinesin participates in NF axonal transport either by directly translocating NFs and/or by linking NFs to transporting MTs. Both Triton-soluble as well as cytoskeleton-associated NF subunits were co-precipitated with kinesin; these data are considered in terms of the form(s) in which NF subunits undergo axonal transport.     

Stirring up development with the heterotrimeric kinesin KIF3

KIF3 is a heterotrimeric member of the kinesin superfamily of microtubule associated motors. This functionally diverse family of motors is involved in anterograde transport of membrane bound organelles in neurons and melanosomes, mediates transport between the endoplasmic reticulum and the Golgi, and transports protein complexes within cilia and flagella required for their morphogenesis. Interestingly, a mutation of KIF3, which impairs ciliogenesis in nodal cells, prevents the unidirectional leftward flow (nodal flow) of putative morphogens during embryogenesis, thereby altering the development of left–right asymmetry in mammals.