Overexpression of tau leads to the stimulation of neurite outgrowth, the activation of caspase 3 activity, and accumulation and phosphorylation of tau in neuroblastoma cells on cAMP treatment

Dermatan sulphate promotes neuronal differentiation in mouse and human stem cells

Dermatan sulphate (DS), a glycosaminoglycan, is present in the extracellular matrix and on the cell surface. Previously, we showed that heparan sulphate plays a key role in the maintenance of the undifferentiated state in mouse embryonic stem cells (mESCs) and in the regulation of their differentiation. Chondroitin sulphate has also been to be important for pluripotency and differentiation of mESCs. Keratan sulphate is a marker of human pluripotent stem cells. To date, however, the function of DS in mESCs has not been clarified. Dermatan 4 sulfotransferase 1, which transfers sulphate to the C-4 hydroxyl group of N-acetylgalactosamine of DS, contributes to neuronal differentiation of mouse neural progenitor cells. Therefore, we anticipated that neuronal differentiation would be induced in mESCs in culture by the addition of DS. To test this expectation, we investigated neuronal differentiation in mESCs and human neural stem cells (hNSCs) cultures containing DS. In mESCs, DS promoted neuronal differentiation by activation of extracellular signal-regulated kinase 1/2 and also accelerated neurite outgrowth. In hNSCs, DS promoted neuronal differentiation and neuronal migration, but not neurite outgrowth. Thus, DS promotes neuronal differentiation in both mouse and human stem cells, suggesting that it offers a novel method for efficiently inducing neuronal differentiation.

Cycloheximide Treatment Causes a ZVAD-Sensitive Protease-Dependent Cleavage of Human Tau in Drosophila Cells

Neurofibrillary tangles are the main pathological feature of Alzheimer’s disease. Insoluble tau protein is the major component of neurofibrillary tangles. Defects in the tau protein degradation pathway in neurons can lead to the accumulation of tau and its subsequent aggregation. Currently, contradictory results on the tau degradation pathway have been reported by different groups. This discrepancy is most likely due to different cell lines and methods used in those studies. In this study, we found that cycloheximide treatment induced mild activation of a ZVAD-sensitive protease in Drosophila Kc cells, resulting in cleavage of tau at its C-terminus; this cleavage could generate misleading tau protein degradation pattern results depending on the antibodies used in the assay. Because cycloheximide is a broadly used chemical reagent for the study of protein degradation, the unexpected artificial effect we observed here indicates that cycloheximide is not suitable for the study of tau degradation. Other methods, such as inducible expression systems and pulse-chase assays, may be more appropriate for studying tau degradation under physiological conditions.

PKA-CREB Signaling Suppresses Tau Transcription

Accumulated and abnormally hyperphosphorylated tau aggregates into neurofibrillary tangles in the brains of patients with Alzheimer's disease (AD). cAMP response binding protein (CREB), a constitutively expressed nuclear transcription factor, is a critical component of the neuroprotective transcriptional network. Numerous studies have shown that cAMP-dependent protein kinase (PKA)-CREB signaling is down-regulated in AD brain. In the present study, we studied the regulation of tau expression by PKA-CREB signaling. We found that the promoter of human tau gene contains three potential cAMP response element (CRE)-like elements, CRE1, CRE2, and CRE3. Overexpression of CREB or activation of PKA significantly suppressed the expression of tau at mRNA and protein levels. ChIP (Chromatin immunoprecipitation) and EMSA (electrophoretic mobility shift assay) revealed that CREB interacted with these three CRE cis-element and that CRE1, among the three elements, plays the most important role in the suppression of tau expression. Furthermore, upregulation of PKA-CREB signaling suppressed expression of endogenous tau. Collectively, these results suggest that PKA-CREB signaling down-regulates tau expression by reducing tau transcription, which may provide a novel insight into the regulation of tau expression and a molecular mechanism involved in tau pathogenesis in AD.

Microtubule-associated protein tau promotes neuronal class II β-tubulin microtubule formation and axon elongation in embryonic Xenopus laevis

Compared with its roles in neurodegeneration, much less is known about microtubule-associated protein tau's normal functions in vivo, especially during development. The external development and ease of manipulating gene expression of Xenopus laevis embryos make them especially useful for studying gene function during early development. To study tau's functions in axon outgrowth, we characterized the most prominent tau isoforms of Xenopus embryos and manipulated their expression. None of these four isoforms were strictly analogous to those commonly studied in mammals, as all constitutively contained exon 10, which is preferentially removed from mammalian fetal tau isoforms, as well as exon 8, which in mammals is rare. Nonetheless, like mammalian tau, Xenopus tau exhibited alternative splicing of exon 4a, which in mammals distinguishes 'big' tau of peripheral neurons, and exon 6. Strongly suppressing tau expression with antisense morpholino oligonucleotides only modestly compromised peripheral nerve outgrowth of intact tadpoles, but severely disrupted neuronal microtubules containing class II β-tubulins while leaving other microtubules largely unperturbed. Thus, the relatively mild dependence of axon development on tau likely resulted from having only a single class of microtubules disrupted by its loss. Also, consistent with its greater expression in long peripheral axons, boosting expression of 'big' tau increased neurite outgrowth significantly and enhanced tubulin acetylation more so than did the smaller isoform. These data demonstrate the utility of Xenopus as a tool to gain new insights into tau's functions in vivo.

Derailed intraneuronal signalling drives pathogenesis in sporadic and familial Alzheimer's disease

Although a wide variety of genetic and nongenetic Alzheimer's disease (AD) risk factors have been identified, their role in onset and/or progression of neuronal degeneration remains elusive. Systematic analysis of AD risk factors revealed that perturbations of intraneuronal signalling pathways comprise a common mechanistic denominator in both familial and sporadic AD and that such alterations lead to increases in Aβ oligomers (Aβo) formation and phosphorylation of TAU. Conversely, Aβo and TAU impact intracellular signalling directly. This feature entails binding of Aβo to membrane receptors, whereas TAU functionally interacts with downstream transducers. Accordingly, we postulate a positive feedback mechanism in which AD risk factors or genes trigger perturbations of intraneuronal signalling leading to enhanced Aβo formation and TAU phosphorylation which in turn further derange signalling. Ultimately intraneuronal signalling becomes deregulated to the extent that neuronal function and survival cannot be sustained, whereas the resulting elevated levels of amyloidogenic Aβo and phosphorylated TAU species self-polymerizes into the AD plaques and tangles, respectively.

The cellular distribution and Ser262 phosphorylation of tau protein are regulated by BDNF in vitro

The brain-enriched microtubule-associated protein tau, a critical regulator of cytoskeletal dynamics, forms insoluble aggregates in a number of neurodegenerative diseases termed tauopathies, including Alzheimer's disease (AD). Hyperphosphorylation of tau protein is an important mechanism for aggregation, so many studies on the pathogenesis of AD and other tauopathies have focused on regulation of tau phosphorylation by kinases and phosphatases. Less studied are mechanisms of tau transcriptional and post-transcriptional regulation by extracellular signals such as BDNF and how such changes alter neuronal function. Previously, we reported that tau is required for morphological plasticity induced by BDNF. Here, we further explore tau modification during BDNF-induced changes in neuronal cell morphology. In undifferentiated SH-SY5Y cells lacking neurites, tau formed a sphere within the soma as revealed by immunocytochemistry. In contrast, tau was enriched in the neurites and sparse in the soma of SH-SY5Y cells induced to differentiate by retinoic acid (RA). Treatment with RA also increased total tau protein levels but decreased expression of tau phosphorylated at Ser262 as determined by Western blot. Both effects were further enhanced by subsequent BDNF treatment. Upregulation of tau protein and downregulation of p-Ser262 tau were correlated with total neurite length (R = .94 and R = −.98, respectively). When primary E18 hippocampal neurons were treated with nocodazole, a blocker of microtubule polymerization, nascent neurites were lost and tau shifted to the soma. This process of retrograde tau movement away from neurites was reversed by BDNF. These results indicate that tau is redistributed to neurites and dephosphorylated during RA- and BDNF-mediated differentiation.

Insulin-induced neurite-like process outgrowth: acceleration of tau protein synthesis via a phosphoinositide 3-kinase~mammalian target of rapamycin pathway

Both insulin and tau, promoting neuronal differentiation (neurite outgrowth, neuronal polarity, and myelination) and cell survival, are associated with neurodegenerative disease (e.g., Alzheimer's disease). The aim of this study was to explore relation between insulin-induced activation of insulin signal and expression of tau protein on neurite-like process outgrowth in adrenal chromaffin cells. Primary cultured bovine adrenal chromaffin cells were incubated with insulin to determine whether stimulant of insulin signal could affect tau expression and neurite-like process outgrowth. Chronic treatment with insulin (⩾6h) led neurite-like process outgrowth as well as increased tau protein level by ∼99% in a concentration (EC(50) 5.5nM)- and time-dependent manner, without changing Ser(396)-phosphorylated tau level. The insulin-induced increase of tau protein level was abolished by LY294002 [an inhibitor of phosphoinositide 3-kinase (PI3K)] and rapamycin [an inhibitor of mammalian target of rapamycin (mTOR)], but not by PD98059 and U0126 [two inhibitors of mitogen-activated protein kinase/extracellular signal-regulated kinase (MEK)]. Additionally, insulin-induced increase of tau was blocked by cyclohexamide (an inhibitor of protein synthesis), but not by actinomycin D (an inhibitor of gene transcription). Pulse-label followed by polyacrylamide gel electrophoresis revealed that insulin accelerated tau protein synthesis rate (t(1/2)) from 2.6 to 1.9h. Insulin did not change tau mRNA level. Taken together, these results suggest that insulin-induced activation of PI3K∼mTOR pathway up-regulated tau protein via acceleration of protein synthesis, on which insulin promoted neurite-like process outgrowth.

Tau binding to microtubules does not directly affect microtubule-based vesicle motility

Tau protein is a major microtubule (MT)-associated brain protein enriched in axons. Multiple functional roles are proposed for tau protein, including MT stabilization, generation of cell processes, and targeting of phosphotransferases to MTs. Recently, experiments involving exogenous tau expression in cultured cells suggested a role for tau as a regulator of kinesin-1-based motility. Tau was proposed to inhibit attachment of kinesin-1 to MTs by competing for the kinesin-1 binding site. In this work, we evaluated effects of tau on fast axonal transport (FAT) by using vesicle motility assays in isolated squid axoplasm. Effects of recombinant tau constructs on both kinesin-1 and cytoplasmic dynein-dependent FAT rates were evaluated by video microscopy. Exogenous tau binding to endogenous squid MTs was evidenced by a dramatic change in individual MT morphologies. However, perfusion of tau at concentrations approximately 20-fold higher than physiological levels showed no effect on FAT. In contrast, perfusion of a cytoplasmic dynein-derived peptide that competes with kinesin-1 and cytoplasmic dynein binding to MTs in vitro rapidly inhibited FAT in both directions. Taken together, our results indicate that binding of tau to MTs does not directly affect kinesin-1- or cytoplasmic dynein-based motilities. In contrast, our results provide further evidence indicating that the functional binding sites for kinesin-1 and cytoplasmic dynein on MTs overlap.

Induction of heat shock proteins in differentiated human and rodent neurons by celastrol

Neurodegenerative disorders such as Alzheimer's disease, Parkinson's disease, and amyotrophic lateral sclerosis have been termed protein misfolding disorders that are characterized by the neuronal accumulation of protein aggregates. Manipulation of the cellular stress-response involving induction of heat shock proteins (Hsps) in differentiated neurons offers a therapeutic strategy to counter conformational changes in neuronal proteins that trigger pathogenic cascades resulting in neurodegenerative diseases. Hsps are protein repair agents that provide a line of defense against misfolded, aggregation-prone proteins. These proteins are not induced in differentiated neurons by conventional heat shock. We have found that celastrol, a quinine methide triterpene, induced expression of a wider set of Hsps, including Hsp70B', in differentiated human neurons grown in tissue culture compared to cultured rodent neuronal cells. Hence the beneficial effect of celastrol against human neurodegenerative diseases may exceed its potential in rodent models of these diseases.

Molecular Mechanism of Learning and Memory Based on the Research for Ca2+/Calmodulin-dependent Protein Kinase II

In the central nervous system (CNS), the synapse is a specialized junctional complex by which axons and dendrites emerging from different neuron intercommunicates. Changes in the efficiency of synaptic transmission are important for a number of aspects of neural function. Much has been learned about the activity-dependent synaptic modifications that are thought to underlie memory storage, but the mechanism by which these modifications are stored remains unclear. Thus, it is important to find and characterize "memory molecules," and "memory apparatus or memory forming apparatus." A good candidate for the storage mechanism is Ca(2+)/calmodulin-dependent protein kinase II (CaM kinase II). CaM kinase II is one of the most prominent protein kinases, present in essentially every tissue but most concentrated in the brain. Neuronal CaM kinase II regulates important neuronal functions, including neurotransmitter synthesis, neurotransmitter release, modulation of ion channel activity, cellular transport, cell morphology and neurite extension, synaptic plasticity, learning and memory, and gene expression. Studies concerning this kinase open a door of the molecular basis of nerve function, especially learning and memory, and indicate one direction for the studies in the field of neuroscience. This review presents molecular structure, properties and functions of CaM kinase II, as a major component of neuron, which are mainly developed in our laboratory.

Development and specific induction of apoptosis of cultured cell models overexpressing human tau during neural differentiation: Implication in Alzheimer's disease

Apoptosis or programmed cell death is considered to be involved in neurodegenerative disorders, including Alzheimer's disease (AD). AD is characterized by intracellular aggregates of hyperphosphorylated tau, a microtubule-associated protein. To investigate the induction of apoptosis by abnormal tau resembling AD, cultured cells may be useful tools. We developed a cell culture model and established NG108-15 and P19 cells stably transfected with human tau, naming them tau/NG and tau/P19 cells, respectively. Increased accumulation and phosphorylation of tau were observed during neural differentiation in tau/NG cells. Tau/P19 cells underwent drastic apoptosis during neural differentiation induced by retinoic acid (RA). Tau protein was distributed throughout the cytoplasm and in specific zones of the nucleus. The cytoplasmic tau was associated with microtubules, but the nucleic tau was observed to form clusters and was associated with RA receptor (RAR). The apoptosis induced by RA was inhibited by the treatment of glycogen synthase kinase 3 (GSK3) inhibitor in tau/P19 cells. We propose that translocation of tau into nucleus affects RA signaling in apoptosis via GSK3 in the cells. These cells are useful for monitoring the apoptosis by abundant tau and may be applied to investigate the molecular mechanism of apoptosis resembling AD.

Increase in apoptosis with neural differentiation and shortening of the lifespan of P19 cells overexpressing tau

Apoptosis or programmed cell death is considered to be involved in neurodegenerative disorders including Alzheimer's disease (AD). AD is characterized by intracellular aggregates of hyperphosphorylated tau, a microtubule-associated protein. To investigate the effect of the overexpression of tau in P19 cells, we engineered P19 wild-type cells (P19wt) stably expressing human tau441 (P19tau). When P19tau cells were induced to undergo neural differentiation by treatment with retinoic acid (RA), a remarkable increase in apoptosis was observed. However, in the undifferentiated state, there was no notable difference of phenotype between P19wt and P19tau cells. Additionally, we found that tau dissociated from microtubules, and co-localized with the RA receptor (RAR) at nucleoli. Further, the lifespan of the differentiated P19tau cells was shorter than that of P19wt cells, and the re-treatment of differentiated P19wt cells with RA resulted in a reduction of lifespan. These observations suggested that tau affects RA signaling in apoptosis and lifespan during the neural differentiation induced by RA treatment.

Neuronal Ca2+/calmodulin-dependent protein kinase II--discovery, progress in a quarter of a century, and perspective: implication for learning and memory

Much has been learned about the activity-dependent synaptic modifications that are thought to underlie memory storage, but the mechanism by which these modifications are stored remains unclear. A good candidate for the storage mechanism is Ca2+/calmodulin-dependent protein kinase II (CaM kinase II). CaM kinase II is one of the most prominent protein kinases, present in essentially every tissue but most concentrated in brain. Although it has been about a quarter of a century since the finding, CaM kinase II has been of the major interest in the region of brain science. It plays a multifunctional role in many intracellular events, and the expression of the enzyme is carefully regulated in brain regions and during brain development. Neuronal CaM kinase II regulates important neuronal functions, including neurotransmitter synthesis, neurotransmitter release, modulation of ion channel activity, cellular transport, cell morphology and neurite extension, synaptic plasticity, learning and memory, and gene expression. Studies concerning this kinase have provided insight into the molecular basis of nerve functions, especially learning and memory, and indicate one direction for studies in the field of neuroscience. This review presents the molecular structure, properties and functions of CaM kinase II, as a major component of neurons, based mainly developed on findings made in our laboratory.