GSK3ß Impairs KIF1A Transport in a Cellular Model of Alzheimer's Disease but Does Not Regulate Motor Motility at S402.

Impairment of axonal transport is an early pathologic event that precedes neurotoxicity in Alzheimer's disease (AD). Soluble amyloid-ß oligomers (AßOs), a causative agent of AD, activate intracellular signaling cascades that trigger phosphorylation of many target proteins, including tau, resulting in microtubule destabilization and transport impairment. Here, we investigated how KIF1A, a kinesin-3 family motor protein required for the transport of neurotrophic factors, is impaired in mouse hippocampal neurons treated with AßOs. By live cell imaging, we observed that AßOs inhibit transport of KIF1A-GFP similarly in wild-type and tau knock-out neurons, indicating that tau is not required for this effect. Pharmacological inhibition of glycogen synthase kinase 3ß (GSK3ß), a kinase overactivated in AD, prevented the transport defects. By mass spectrometry on KIF1A immunoprecipitated from transgenic AD mouse brain, we detected phosphorylation at S402, which conforms to a highly conserved GSK3ß consensus site. We confirmed that this site is phosphorylated by GSK3ß in vitro Finally, we tested whether a phosphomimic of S402 could modulate KIF1A motility in control and AßO-treated mouse neurons and in a Golgi dispersion assay devoid of endogenous KIF1A. In both systems, transport driven by mutant motors was similar to that of WT motors. In conclusion, GSK3ß impairs KIF1A transport but does not regulate motor motility at S402. Further studies are required to determine the specific phosphorylation sites on KIF1A that regulate its cargo binding and/or motility in physiological and disease states.

Identification of the carboxy terminus as important for the isoform-specific subcellular targeting of glucose transporter proteins.

Differential trafficking of glucose transporters contributes significantly to the establishment of a cell's capacity for hormone-regulatable hexose uptake. In the true insulin-sensitive peripheral target tissues, muscle and adipose, the transporter isoform GLUT1 residues on the cell surface and interior of the cell whereas the highly homologous isoform GLUT4 displays virtually exclusive intracellular sequestration, allowing the latter to redistribute to the cell surface in response to hormone. These patterns are equally pronounced in cells into which the transporters have been introduced by DNA-mediated gene transfer, suggesting that signals for isoform-specific sorting are recognized in diverse cell types. To determine the primary sequences responsible for the characteristic distributions, chimeric transporters were constructed in which reciprocal domains were exchanged between GLUT1 and GLUT4. In addition, a non-disruptive, species-specific epitope "tag" was introduced into a neutral region of the transporter to allow analysis of reciprocal chimeras using a single antibody. These recombinant transporters were stably expressed in HIH 3T3 and PC12 cells by retrovirus-mediated gene transfer, and were localized by indirect immunofluorescence and laser scanning confocal microscopy, as well as by staining of plasma membrane sheets prepared from these cells. The results indicate that the carboxy-terminal 30 amino acids are primarily responsible for the differential targeting of the glucose transporter isoforms GLUT1 and GLUT4, though there is a lesser additional contribution by the amino-terminal 183 amino acids.

Distinct signals in the GLUT4 glucose transporter for internalization and for targeting to an insulin-responsive compartment.

In adipose and muscle cells, insulin stimulates a rapid and dramatic increase in glucose uptake, primarily by promoting the redistribution of the GLUT4 glucose transporter from its intracellular storage site to the plasma membrane. In contrast, the more ubiquitously expressed isoform GLUT1 is localized at the cell surface in the basal state, and shows a less dramatic translocation in response to insulin. To identify sequences involved in the differential subcellular localization and hormone-responsiveness of these isoforms, chimeric GLUT1/GLUT4 transporters were stably expressed in mouse 3T3-L1 adipocytes. The NH2 terminus of GLUT4 contains sequences capable of sequestering the transporter inside the cell, although not in an insulin-sensitive pool. In contrast, the COOH-terminal 30 amino acids of GLUT4 are sufficient for its correct localization to an intracellular storage pool which translocates to the cell surface in response to insulin. The dileucine motif within this domain, which is required for intracellular sequestration of chimeric transporters in fibroblasts, is not critical for targeting to the hormone-responsive compartment in adipocytes. Analysis of rates of internalization of chimeric transporter after the removal of insulin from cells, as well as the subcellular distribution of transporters in cells unexposed to or treated with insulin, leads to a three-pool model which can account for the data.

Cargo of kinesin identified as JIP scaffolding proteins and associated signaling molecules.

The cargo that the molecular motor kinesin moves along microtubules has been elusive. We searched for binding partners of the COOH terminus of kinesin light chain, which contains tetratricopeptide repeat (TPR) motifs. Three proteins were found, the c-jun NH(2)-terminal kinase (JNK)-interacting proteins (JIPs) JIP-1, JIP-2, and JIP-3, which are scaffolding proteins for the JNK signaling pathway. Concentration of JIPs in nerve terminals requires kinesin, as evident from the analysis of JIP COOH-terminal mutants and dominant negative kinesin constructs. Coprecipitation experiments suggest that kinesin carries the JIP scaffolds preloaded with cytoplasmic (dual leucine zipper-bearing kinase) and transmembrane signaling molecules (the Reelin receptor, ApoER2). These results demonstrate a direct interaction between conventional kinesin and a cargo, indicate that motor proteins are linked to their membranous cargo via scaffolding proteins, and support a role for motor proteins in spatial regulation of signal transduction pathways.

Light chain-dependent regulation of Kinesin's interaction with microtubules.

We have investigated the mechanism by which conventional kinesin is prevented from binding to microtubules (MTs) when not transporting cargo. Kinesin heavy chain (HC) was expressed in COS cells either alone or with kinesin light chain (LC). Immunofluorescence microscopy and MT cosedimentation experiments demonstrate that the binding of HC to MTs is inhibited by coexpression of LC. Association between the chains involves the LC NH2-terminal domain, including the heptad repeats, and requires a region of HC that includes the conserved region of the stalk domain and the NH2 terminus of the tail domain. Inhibition of MT binding requires in addition the COOH-terminal 64 amino acids of HC. Interaction between the tail and the motor domains of HC is supported by sedimentation experiments that indicate that kinesin is in a folded conformation. A pH shift from 7.2 to 6.8 releases inhibition of kinesin without changing its sedimentation behavior. Endogenous kinesin in COS cells also shows pH-sensitive inhibition of MT binding. Taken together, our results provide evidence that a function of LC is to keep kinesin in an inactive ground state by inducing an interaction between the tail and motor domains of HC; activation for cargo transport may be triggered by a small conformational change that releases the inhibition of the motor domain for MT binding.

Kinesin carries the signal.

Conventional kinesin has long been known to be a molecular motor that transports vesicular cargo, but only recently have we begun to understand how it functions in cells. Regulation of kinesin involves self-inhibition in which a head-to-tail interaction prevents microtubule binding. Although the mechanism of motor activation remains to be clarified, recent progress with respect to cargo binding might provide a clue. Kinesin binds directly to the JIPs (JNK-interacting proteins), identified previously as scaffolding proteins in the JNK (c-Jun NH(2)-terminal kinase) signaling pathway. The JIPs can allow kinesin to transport many different cargoes and to concentrate and respond to signaling pathways at certain sites within the cell. The use of scaffolding proteins could be a general mechanism by which molecular motors link to their cargoes.

A Leu-Leu sequence is essential for COOH-terminal targeting signal of GLUT4 glucose transporter in fibroblasts.

In the insulin-responsive tissues, muscle and adipose, the GLUT4 glucose transporter isoform accounts for most of the increase in hexose flux in response to hormone. In these cell types, as well as in fibroblasts transfected with cDNAs encoding the transporters, GLUT1 and GLUT4 are sorted to different subcellular locations. In the latter, GLUT1 is found primarily at the cell surface whereas GLUT4 localizes to the interior of the cell in a perinuclear distribution. The construction and analysis of chimeras of these two transporter isoforms have allowed identification of the COOH-terminal 30 amino acids as a critical sorting signal for differential localization of the transporters. In this study, we show that 2 residues present in the GLUT4 COOH terminus, Leu-489 and Leu-490, are critical for the intracellular sequestration of this isoform in NIH3T3 cells.

Kinetic analysis of glucose transporter trafficking in fibroblasts and adipocytes.

Insulin regulates hexose uptake by the redistribution of glucose transport proteins from intracellular compartments to the cell surface. We have submitted the trafficking of GLUT1, GLUT4, and GLUT1/GLUT4 chimeras to a mathematical analysis in the context of different models. Our data suggest that a model with one intracellular and one cell surface compartment can describe the glucose transporter-trafficking kinetics in fibroblasts. Moreover, the difference in cellular distribution between GLUT1 and GLUT4 overexpressed in fibroblasts is best explained by a slower rate of movement of GLUT4 to the plasma membrane. In 3T3-L1 adipocytes, glucose transporter-trafficking kinetics is adequately described by a three-pool model which includes flow of transporters from the endosomal compartment to cell surface. The kinetic roles of previously identified motifs in GLUT4 trafficking were defined in proposed fibroblast and adipocyte glucose transporter-trafficking models. The C-terminus is important in reducing the exocytosis rate from the endosomal compartment to the cell surface in both fibroblasts and adipocytes, and the N-terminus behaves similarly in adipocytes. The C-terminus has an additional signal(s) that allows GLUT4 to be sequestered more efficiently into the insulin responsive vesicle compartment. Mutation of the dileucine motif in the C-terminus significantly reduces the endocytosis of GLUT4 in both fibroblasts and adipocytes, but these amino acids appear not to be primarily responsible for the different kinetics of wild-type GLUT1 and GLUT4.