Information

What phosphorylates tau protein & and what causes tau to be phosphorylated?

What phosphorylates tau protein & and what causes tau to be phosphorylated?


We are searching data for your request:

Forums and discussions:
Manuals and reference books:
Data from registers:
Wait the end of the search in all databases.
Upon completion, a link will appear to access the found materials.

I want to know what phosphorylates tau protein and its 6 isoforms. I know kinases cause phosphorylation events, and in tau it can be phosphorylated in a healthy neuron in the trans conformation, but when it is hyperphosphorylated it becomes the cis conformation of tau.

Do the same or different kinases cause the normal phosphorylation / abnormal hyperphosphorylation of tau? Is it completed by a single kinase or multiple kinases?

----Edit---

So I've done a lot of reading of many different papers and have uncovered that there two types of broad spectrum kinases classified as: Proline-directed kinases, such as CDK5 and GSK-3beta Non-proline directed kinases

Source: https://www.hindawi.com/journals/omcl/2015/151979/

But I read in this paper: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3601591/

that Cdc2 can also phosphorylate tau

My new question is a follow up to my existing previous question, I guess why is tau phosphorylated at all? What causes tau to be phosphorylated at in the first place? Thanks.


Xu Han and Keping Chen*

Institute of Life Sciences, Jiangsu University, PR China

Received: February 12, 2020 | Published: March 19, 2020

Corresponding author: Keping Chen, Institute of Life Sciences, Jiangsu University, 301 Xuefu Road, Zhenjiang 212013, PR China

Abstract

Protein phosphorylation is a reversible post-translational modification that involves a series of sequence-specific kinases and occurs on specific residues such as serine, threonine, and tyrosine. The reversible phosphorylation of proteins regulates almost all aspects of the cell’s life cycle and abnormal phosphorylation is the cause or consequence of many diseases. Protein phosphorylation states can mediate protein complex formation and regulate protein function, which is important for cell physiology but can also promote neuropathic events. The tau protein is a very important microtubule-associated protein in the brain, occurring most commonly in neurons and glial cells. Its level of phosphorylation is associated with a variety of diseases of the central nervous system such as Alzheimer’s disease. Under normal circumstances, post-transcriptional tau phosphorylation is conducive to the stability of microtubules. However, hyperphosphorylation can lead to the deformation and aggregation of various types of cytoskeletal components of nerve tissue, causing them to lose normal function.

Keywords: Protein Tau Phosphorylation Alzheimer’s Disease Tubulin Structure Drug Effects

Abbreviations: MAPS: Microtubule-Associated Proteins AD: Alzheimer’s Disease MTRS: Mercuric Transport SER: Serine THR: Threonine MT: Microtubule GSK3β: Glycogen Synthase Kinase 3β ALA: Alanine PD: Projection Domain MBD: Microtubule- Binding Domain PSP: Progressive Supranuclear Palsy MAP1B: Microtubule Associated Protein 1B GSK3: Glycogen Synthase Kinase 3 CDK5: Cyclin-Dependent Kinases 5 NFTs: Neurofibrillary Tangles PHFs: Paired Helical Filaments SFs: Straight Filaments FTLD: Frontotemporal lobar degeneration CJD: Creutzfeldt-Jakob Disease PDPK: Proline- Dependent Protein Kinase UPS: Ubiquitin-Proteasome System PHF: Pair of Helical Filaments PTPs: Protein Tyrosine Phosphatases PSPs: Protein Serine/Threonine Phosphatases PP1: Phosphatase Types 1 PsP2A: phosphatase types2A PP2B: Phosphatase Types2B PP2C: Phosphatase Types2C PP: Protein Phosphatase CCH: Chronic Cerebral Hypoperfusion BRET: Bioluminescent Resonance Energy Transfer PKA: Protein Kinases A

Introduction

Cellular proteins that bind to microtubules are collectively referred to as microtubule-associated proteins (MAPs). Under normal circumstances, MAPs are essential components for Maintaining the Structure and function of microtubules. They can increase the stability of microtubules, promote microtubule assembly, and regulate the relationship between microtubules and other cellular components [1]. MAPs con tain two functional regions: an alkaline binding domain that binds to the side of the microtubule and an acidic salient binding domain that is an outwardly protruding filamentous structure in the form of a horizontal bridge connecting the MAP to other cell components, cytoskeleton components, membranes, and other structures. MAPs have microtubule binding activity, and their function can be performed by regulating the phosphorylation and dephosphorylation of specific amino acids.A variety of functions of MAPs involving the regulation of microtubule cytoskeletal dynamics have been discovered. MAPs are present in nerve tissue during neuronal development and play an indispensable role in microtubule remodeling during neuronal activity and in the stability of microtubules during neuronal maintenance. As a result, mutations in MAPs lead to neurodevelopmental disorders, psychiatric disorders, and neurodegenerative diseases.

MAPs are post-translationally regulated by phosphorylation, which can affect microtubule affinity, cell localization, or the overall function of specific MAPs with a profound effect on neuronal health. The microtubule-binding activity of a MAP is regulated by the phosphorylation and dephosphorylation of specific amino acids. The MAP family mainly includes MAP1, MAP2, tau, and MAP4. The first three are found mainly in neurons, while MAP4 exists in all kinds of cells. Of these four MAPs, the role of tau protein phosphorylation and dephosphorylation in Alzheimer’s Disease (AD) is the most extensively studied and significant progress has been made. The function of the microtubule-associated protein tau is to promote microtubule assembly and stabilization in neurons, which is required for axonal transport and neurite outgrowth [2]. Tau is a microtubule-associated phosphoprotein that is abundant in neurons and is regulated by protein kinases and protein phosphatases. Appropriately phosphorylated Tau binds to microtubules, thereby stimulating the assembly of tubulin into microtubules and maintaining microtubule stability [3]. In the brain of Alzheimer’s disease, tau is abnormally hyperphosphorylated it contains three to four times more phosphate than normal tau [4]. In vitro and in vivo, hyperphosphorylation of tau has been shown to reduce the affinity of tau for microtubules, leading to disruption of neuronal cytoskeleton and axonal transport [5]. Abnormal aggregation of hyperphosphorylated tau protein is a common pathological feature of neurodevelopmental disorders commonly referred to as tauopathy, including AD, progressive supranuclear palsy and frontotemporal dementia [6]. Several neurodegenerative diseases, collectively referred to as tauopathy, are characterized by insoluble, highly phosphorylated tau that is a neuronal inclusion of straight or paired helical filaments [7].

Microtubules and the Effects of Tau Phosphorylation on Microtubule Structure

Neuronal development and function are influenced by the cytoskeletal infrastructure of cells, namely microtubules, actin, and intermediate filament networks. Microtubule cytoskeletal networks are organized into stable and dynamic arrays that provide structural support as molecular motion trajectories and serve as signal platforms during neuronal development and plasticity [8-10]. Microtubules are composed of alpha- and beta-tubulin heterodimers that assemble into protofilaments and then laterally contact each other to form tubules [11]. β-Tubulin must be in a GTP-bound state to allow the assembly of heterodimers onto the protofilament. Alpha- tubulin binds to β-tubulin but only β-tubulin can hydrolyze GTP. Once the protofilament is assembled, β-tubulin is exposed at the “plus end” and alpha-tubulin is exposed at the “minus end.” This structural polarity leads to a difference in the growth rate at each end and it has been observed that end-capping occurs more often [12] and is much faster on the plus end than on the minus end. Microtubules can be modified within cells by switching between assembled and disassembled states in a process called dynamic instability [13]. MAPs have the ability to bind to microtubule lattices, tubulin heterodimers, or both. They can thereby regulate the assembly/ disassembly kinetics of microtubules to properly organize and remodel microtubule cytoskeletal structure during neuronal development and activity [14,15].

The α- and β-tubulin heterodimers that assemble into microtubules exist in a state of dynamic equilibrium with non-polymeric tubulin. The filamentous structure of microtubules forms intracellular cytoskeletons in a variety of cells but are particularly enriched in neurons [16-18]. The dynamics of microtubule assembly can be regulated by temperature, microtubule protein modifications, small molecules such as paclitaxel, and some mercuric transport (MerT) interacting proteins [19-21]. Since microtubules play an important role in a wide range of biological functions, including the structural formation of neurons and the transport of intracellular substances, it is speculated that microtubule disruption (if any) can profoundly influence neuronal structure and function [22-24]. Tau protein has been identified as a factor that promotes microtubule assembly and stability. Microtubule assembly is thought to be negatively regulated by tau protein phosphorylation. More than 40 serine (Ser) and Threonine (Thr) residues have been identified as possible phosphorylation sites on the tau protein. Although the biological significance of every single phosphorylation site is not clear, it is known that phosphorylation of tau at Ser-262 of tau (in the 441-residue tau protein) has a profound influence on its interaction with microtubules [25].

Effect of Tau Phosphorylation on the Structure of Threonine 231

The amino acid sequence that interacts with MT in Tau is localized to a proline-rich region and a repeat domain. Tau contains 85 potential phosphorylation sites, of which three sites S214, T231 and S262 are critical for Tau-MT interaction. In tau, both unprimed and primed sites are phosphorylated by GSK3β, with Thr231 being the most notable primer epitope [26]. Although phosphorylation of S262 strongly reduced affinity for MT [27], phosphorylation of S214 [28] and T231 [29] primarily reduced Tau polymerization MTs. Ability [30] Phosphorylation of T231 not only regulates MT binding, but is also important for the role of Tau in disease [31] because it separates tau from MTS, which may Interaction with another cell partner [32]. Several kinases can phosphorylate Tau at T231, including glycogen synthase kinase 3β (GSK3β), one of the most important kinases involved in disease processes [33]. After initiation of phosphorylation at S235, GSK3β phosphorylates T231 more efficiently [34], even though this initiation of phosphorylation is not required [33]. Tau deposits isolated from Alzheimer’s disease patients typically contain phosphorylated T231 and S235, as well as phosphorylated S237 and S238 [35]. Furthermore, the unprimed site on GSK3β-R96A phosphorylated tau was more potent than wild-type GSK3β, clearly indicating the importance of priming site phosphorylation in regulating tau-microtubule interactions [36]. Following this preliminary study, it was demonstrated that GSK3β-induced tau phosphorylation of Thr231 plays a key role in reducing tau binding and stabilizing microtubules [37]. In transfected cells, tau with Thr231 mutated to Ala was still able to efficiently bind to microtubules after phosphorylation with GSK3β [37]. These studies clearly show that although GSK3β phosphorylates many sites on tau, not all sites have an effect on tau function.

Structure and Phosphorylation of Tau Protein

Figure 1: Different isomers of tau formed by alternative splicing of mRNA in the normal adult brain. The tau protein consists of two large regions: the projection domain (PD) and the microtubule-binding domain (MBD). The six unique isomers are mainly differentiated by the number of N-terminal insertion sequences (0N, 1N, or 2N) and the number of microtubule binding repeats (3R or 4R) that they contain. In the normal adult brain, the ratio of the 3R to 4R isomers is about 1:1.

The tau protein was identified in 1975 as a protein with the ability to induce microtubule formation [38,39]. It is the most widely occurring MAP in the normal brain and its primary function is to bind tubulin and promote its polymerization into microtubules [39]. It also combines with fully formed microtubules to maintain their stability [40], reduce the dissociation of tubulin molecules, and induce the formation of microtubule bundles. The tau gene is located on the long arm of chromosome 17 and has 79 phosphorylation sites that can be modified by serine/threonine protein kinases [38]. In fact, the polymerization and stabilization of microtubules are mainly determined by the state of tau phosphorylation. The phosphorylation of tau can be divided into two types depending on whether the modified residue is phosphorylated by a proline-directed kinase or a non-proline-directed kinase. Along the pathological course of many neurodegenerative diseases, tau protein is mainly (but not solely) phosphorylated by proline-directed protein kinases. In the central nervous system of a healthy human, alternate splicing of tau mRNA results in six different isoforms of the tau protein between 352–441 amino acids long with molecular weights of 48-67 kDa (Figure 1) [41-43]. The tau protein is subdivided into four regions: the acidic region at the N-terminal portion, the proline-rich region, the microtubule-binding domain, and the C-terminal region. Of the 85 putative phosphorylation sites in the tau protein, 45 sites are serines, 35 are threonines, and 5 are tyrosines [44-46].

Serine phosphorylation on the KXGS motif of the microtubule- binding domain reduces tau’s affinity for microtubules and thus prevents their binding [47-49]. The amount of tau protein phosphorylated at proline-rich sites like Thr-181, Ser-199, and Thr-231is higher in the brains of AD patients and these three phosphorylated forms of tau can therefore be used as biomarkers for AD [50-52]. Kinetic analysis showed that pseudophosphorylation increased the tau aggregation rate by increasing the filament nucleation rate. In addition, it increases the tendency to aggregate by stabilizing mature filaments to prevent depolymerization. The covalently bound phosphate is distributed within the tau microtubule- binding domain and adjacent to approximately 40 sites [45,53,54]. The occupancy of these sites may affect the tau aggregation in two ways. First, the occupancy of certain loci regulates the affinity of tau-tubulin [55], promoting an increase in the level of free cytoplasmic tau available for nucleation and supporting aggregation reactions [56-59]. Second, hyperphosphorylation directly increases the tendency of tau aggregation [60,61]. In addition, tau phosphorylation has been reported to reduce proteasome-mediated tau conversion in neuronal cell models [62]. Thus, the occupancy of certain tau phosphorylation sites can increase the free cytoplasmic tau concentration by a variety of mechanisms.

Tau phosphorylation and Neurological Diseases

Neurodegenerative diseases with abundant filamentous tau protein inclusion bodies are called tauopathies. Some neurodegenerative diseases differ from AD in that they lack the pathology of beta-amyloid plaques [63]. However, the tauopathies other than AD include chromosome 17-linked Parkinson’s disease with frontotemporal dementia, chronic traumatic encephalopathy, argicophilia granulosus, Progressive Supranuclear Palsy (PSP), corticobasal degeneration, globular glia tauopathy, and Pick’s disease. Due to the abnormal accumulation of phosphorylated tau protein in neuronal and glial cells in these neurodegenerative diseases, synaptic plasticity of hippocampal neurons can be affected, and memory function seriously disrupted [64]. It has been reported that changes in protein phosphorylation affect axonal transport in neurodegenerative disease models. For example, one study showed that as phosphorylation of neurofilament proteins and the microtubule-associated protein MAP1B increased, their respective axonal transport rates decreased [65].

In contrast, another study revealed that the enhanced phosphorylation level of tau increased the overall slow rate of tau protein transport in neurons and that the inhibition of tau phosphorylation by GSK-3 decreased its motility (Figure 2). Due to these and other similar findings, axonal transport defects have been regarded one of the contributing factors to neurodegenerative disease [66]. (Figure 2) Tau and other microtubule-associated proteins are phosphorylated by glycogen synthase kinase 3 (GSK-3), as well as cyclin- dependent kinases (like CDK5) and activator subunit p25, to form highly phosphorylated tau proteins. This highly phosphorylated form of the protein then dissociates into helical filaments that eventually form neurofibrillary tangles (NFTs) AD is acknowledged as the leading cause of dementia and is estimated to affect 47 million people worldwide [67]. The disease is primarily characterized by progressive cognitive and memory impairments. The neuropathological features of AD are (1) extensive cell death, (2) extracellular deposits of β-amyloid plaques (causing nephritis), and (3) synaptic aggregation of hyperphosphorylated tau protein also known as neurofibrillary tangles (NFTs) [68]. The analysis of the crystal structure of tau filaments in AD brains by Fitzpatrick et al. in 2017 showed that these pathological tau inclusions consist of paired helical filaments (PHFs) and straight filaments (SFs) [69- 71].

Figure 2: Tau and other microtubule-associated proteins are phosphorylated by glycogen synthase kinase 3 (GSK- 3), as well as cyclin-dependent kinases (like CDK5) and activator subunit p25, to form highly phosphorylated tau proteins. This highly phosphorylated form of the protein then dissociates into helical filaments that eventually form neurofibrillary tangles (NFTs).

Phosphorylation of tau enhances PHF formation. Phosphorylation can also be a physiologically feasible way to bring tau into a PHF-prone state. Phosphorylation can alter the conformation of tau, making it long and stiff [72]. Negative-stained electron microscopy showed that the core of the PHFs and SFs is composed of a double helix stack of C-shaped subunits [73] and successive steps along the β-strand of the protofilament are linked by helical symmetry. Moreover, the C-terminal region of tau is disordered, and it projects away from the core to form a fuzzy shell [74]. The protofilament cores of the PHFs and SFs are similar, indicating that they are ultrastructural polymorphs. The ultrastructural polymorphism between the PHF and SF is due to the difference in lateral contact between the two protofilaments. In the PHF, the two strands form exactly the same spiral symmetric structure, whereas in the SF, the protofilaments are asymmetric. In AD, tau is highly phosphorylated and many of the major kinases that phosphorylate the tau protein target glycogen synthase kinase-3 (GSK-3)-targeted tau phosphorylation sites [75]. Another of the major kinases responsible for tau hyperphosphorylation is cyclin-dependent kinase 5 (CDK5), a member of the serine/threonine kinase family of cyclin-dependent kinases.

Most AD neurons do not have normal microtubule structure but instead have pathological NFTs that are paired helical filaments of abnormal, hyperphosphorylated tau. Since tau pathology has been shown to be associated with neuronal loss, one of the treatment strategies targeting the molecular basis of AD includes inhibition of tau hyperphosphorylation [76]. To examine whether microtubule destruction induces tau phosphorylation, et al. co-expressed tau protein with stathmin, a 19 kDa phosphoprotein that depolymerizes microtubules, in COS-7 cells. Stathmin expression induced microtubule mutations and hyperphosphorylation of tau at Thr- 181, Ser-202, and Thr-205, indicating that microtubule disruption induces subsequent tau phosphorylation [77]. Frontotemporal lobar degeneration (FTLD) encompasses two clinical syndromes and three clinicopathological subtypes: the clinical syndromes are behavioral variant frontotemporal dementia and primary progressive aphasia, and the neuropathological subtypes are characterized by abnormal protein aggregation [64]. PSP is a rare, late-onset neurodegenerative disease whose clinical symptoms include early postural instability, vertical gaze palsy, and a later onset of dementia.

From the ultrastructural perspective, the NFT filaments present in PSP are straight and contain only the 4R isoform of the tau protein [78]. Animal models have revealed that mutations in the tau gene led to sprouting in dentate gyrus granule cells of hippocampal mossy fibers, and primary epilepsy is partially caused by mutations in the Tau protein gene. The S169L mutation of the presenilin 1 gene has also been found in patients with epileptic seizures and familial Alzheimer’s disease [79]. AD is the most common cause of dementia. It is a degenerative disease of the central nervous system and is mainly characterized by progressive cognitive impairment and memory impairment. The main pathological features of AD are senile plaques and neurofibrillary tangles. The core component of neurofibrillary tangles is the double-helical fibril formed by abnormally modified Tau protein [80]. Creutzfeldt-Jakob disease (CJD) is a rare and fatal human neurodegenerative disease that belongs to family of diseases known as transferable spongiform encephalopathies or prion diseases. The cerebrospinal fluid level in patients with CJD is significantly higher than that of AD patients and other dementia patients [81] (Table 1). As detailed above, it is clear that tau protein is closely associated with many diseases of the central nervous system and clarifying its mechanism of action can lead to new targets of treatment for tau protein-related diseases.

Table 1: Classification and characteristics of diseases caused by tau phosphorylation.

Phosphorylation Affects Axonal Transport and Degradation of the Tau protein

The phosphorylated form of the MAP tau accumulates in neurofibrillary tangles in Alzheimer’s disease. To investigate the effect of specific phosphorylated tau residues on protein function, expressed wild-type or phosphorylated tau protein in cultured cells. Their results showed that enhanced phosphorylation of tau decreased its microtubule binding and increased the number of moving tau particles without affecting axon transport kinetics. Conversely, decreasing tau protein phosphorylation increased the amount of tau protein bound to microtubules and inhibited axonal transport of tau. To determine whether the removal of tau protein resulted in an increase in phosphorylated tau, autophagy in neurons was inhibited. This resulted in a 3-fold increase in phosphorylated tau compared to wild-type tau and endogenous tau was not affected. In autophagy-deficient mouse embryonic fibroblasts, the proteasomal degradation of phosphorylated tau was also reduced compared with wild-type tau. These findings indicate that while both autophagy and proteasome pathways are involved in tau degradation, autophagy appears to be the main pathway for the removal of phosphorylated tau in neurons. Therefore, defective autophagy may contribute to the pathological accumulation of phosphorylated tau in neurodegenerative diseases [82].

Tauopathies are characterized by the presence of insoluble tau protein. The interaction of tau with microtubules is mainly achieved by the microtubule-binding domain located at the C-terminal of tau. This domain contains either three or four binding repeats (depending on alternative splicing of tenth exons), resulting in a 3R or 4R tau protein isomer, respectively. However, tau also interacts with components of the plasma membrane through its N-terminal projection domain [83]. While we know that phosphorylation of tau reduces its ability to bind and stabilize microtubules, we have recently found that the binding of tau to the plasma membrane is also regulated by phosphorylation [84]. It is well known that increased phosphorylation of tau reduces its affinity for microtubules, leading to instability of the neuronal cytoskeleton [85]. Phosphorylation specifically at Ser-262, Ser-293, Ser-324, and Ser-356, which are serines found in the KXGS sequences of R1, R2, R3, and R4 domains, respectively, have been shown to reduce the binding of tau to microtubules. Phosphorylation of tau in proline-rich regions surrounding Ser-202, Ser-235, Thr-231, and Ser-235 also contributes to the dissociation of tau from microtubules. However, phosphorylation in proline-rich regions alone is not enough to completely dissociate tau from microtubules [29]. GSK3β is a key protein in the insulin signaling pathway that phosphorylates several residues on tau [77,86]. The most favorable tau phosphorylation sites for GSK- 3β are Ser-396, Ser-400, and Ser-404 [87].

Phosphorylation of Ser-262 has been reported to result in reduced microtubule binding of tau [48,88]. However, phosphorylation of Ser-262 induced only about 40% of the microtubule binding activity [89], indicating that phosphorylation at other sites is necessary to completely inhibit its biological activity. The 21 phosphorylation sites in PHF-tau have been identified by reactivity with antibody and protein sequencing technologies at various phosphorylation sites. Among them, 10 sites are on the Ser / Thr- Pro motif and 11 are on the non-Ser / Thr-Pro motif [90,91]. Ser / Thr-Pro and non-Ser / Thr-Pro sites may be phosphorylated by proline- dependent protein kinase (PDPK) and non-PDPK, respectively. In the non-proline-directed phosphorylation site of PHF-tau, both Ser-208 and Ser-210 are in the SR-motif range.

In addition, in addition to the known GSK-3βphosphorylation site on tau, studies have identified a new phosphorylation site Thr- 175 and a non-prolineated phosphorylation site Ser-400. TTK is a non-proline-directed Ser / Thr kinase that has been purified from bovine brain [92]. It is the first tau kinase to phosphorylate Ser- 208 and Ser-210, both of which are PHE phosphate. Site. Thr-212 is a neighboring residue close to Ser-208 in tau and is known to be the phosphorylation site of GSK-3β [93]. Absorption tests by peptides pS208 and pS210 demonstrated the specificity of anti-pS208. Therefore, we can confirm that the phosphorylation site Ser-208 is a site separate from Thr-212. In addition to affecting its transport, tau phosphorylation also affects its ability to be degraded [94]. We studied the degradation of tau by the ubiquitin-proteasome system (UPS) and macroautophagy (autophagy) in the context of tau transport. While the UPS eliminates transient proteins by tagging them with chains of ubiquitin, autophagy removes long-lived structural proteins, as well as damaged or misfolded proteins [95]. Autophagy has also been shown to reduce both wild-type and modified tau proteins, including caspase-cleaved and C-terminally truncated species [96].

Tau protein hyperphosphorylation

Aberrant protein phosphorylation can lead to disease-related processes [97]. Accordingly, the abnormal phosphorylation of tau is observed in many neurodegenerative diseases. For example, histopathological investigations of AD showed extra-neuronal accumulation of β-amyloid peptide in plaques, neuronal aggregates of NFTs, and astrogliosis surrounding neurons [98]. Abnormal hyperphosphorylation of tau leads to aggregation, formation of NFTs, microtubule rupture, neuronal dysfunction, and death [99]. NFT consists of a pair of helical filaments (PHF), which in turn consists of a microtubule-associated protein tau in a hyperphosphorylated state [100]. In AD, the phosphorylation/dephosphorylation system appears to be greatly affected [101]. It has been shown that brain glucose uptake/metabolism in AD is impaired [102] and this damage has been suggested to be associated with abnormal hyperphosphorylation of tau. This finding implicates astrocytes as a key factor, especially because changes in glucose uptake and/or glutamate uptake (mediated by astrocytes) affect neuronal function and survival.

Through complex signal cascades, protein phosphorylation and dephosphorylation can regulate neuronal plasticity and neurotransmission, consequently impairing learning and memory. The signal cascade is precisely controlled by the dynamic reversible process of phosphorylation that is dependent on a precise balance between protein kinase and protein phosphatase activity. Human genome sequencing predicts the existence of more than 500 kinases and approximately 150 phosphatase genes. Protein kinases are subdivided into two families: serine/threonine kinases with 428 members and tyrosine kinases with 90 members [103,104]. Protein phosphatases are categorized into three different families: protein tyrosine phosphatases (PTPs) [105], protein serine/threonine phosphatases (PSPs) [106], and dual-specificity protein phosphatases (tyrosine and serine/threonine). Of the known phosphatases, about 107 are PTPs and about 40 are PSPs [107].

Recent data show that the enzyme phosphatase family plays an indispensable role in controlling neuronal function [108]. The protein serine threonine phosphatase represents a highly conserved multigene family in evolution [109]. Based on sequence homology and biochemical properties, known phosphatases can be divided into four interrelated families. The three families of the protein serine threonine phosphatase types 1, 2A and 2B (PP1, PP2A and PP2B) have significant primary amino acid sequence homology, respectively. In contrast, phosphatase type 2C (PP2C) is more diverse. Among them, PP2A is a protein phosphatase that regulates the most phosphorylation of tau protein. Among the tau phosphatases identified in the human brain, PP2A accounts for more than 70% of tau dephosphorylation [110]. In the AD brain, PP2A activity was significantly reduced [111]. PP2A is a multimeric enzyme consisting of a catalytic subunit (C) and two regulatory subunits (A subunit or B subunit). The physiological form of PP2A is considered to be a heterogeneous composition composed of A and C subunits. Trimer. The major natural form of PP2A is a heterotrimer in which the core enzyme binds to one of several regulatory subunits expressed in a cell- and tissue-specific manner [112]. Another potential function of PP2A in the brain is to regulate phosphorylation of microtubule- associated protein (MAPS).

The activity of protein phosphatase (PP) 2A is downregulated and promotes hyperphosphorylation of tau in the brain of Alzheimer’s disease (AD). Studies have shown that calyculin A, a potent specific protein phosphatase (PP) 2A and PP1 inhibitor, is injected into both sides of the rat hippocampus, thereby replicating Alzheimer’s- like defects in the dephosphorylation system. It was found that rats injected with calyculin A found spatial memory retention damage in the Morris water maze test. At the same time, tau was hyperphosphorylated at the Ser396 / Ser404 (PHF-1) and Ser-262 / Ser-356 (12E8) sites, as determined by immunohistochemistry and Western blotting. This suggests that PP2A is involved in the in vivo regulation of tau phosphorylation and that down-regulation of this phosphatase will result in hyperphosphorylation of tau protein [113]. The hyperphosphorylation of the tau protein and the subsequent formation of NFTs are associated with abnormal activation of protein kinases [114].

In fact, studies have shown that the imbalance of kinase and phosphatase activity may play a causative role in the hyperphosphorylation of tau [102]. The proline-directed protein kinases that catalyze the phosphorylation of tau (such as GSK-3 and CDK5) predominantly do so at Ser-Pro and Thr-Pro sites on the tau protein, whereas the non-proline-directed protein kinases (such as protein kinase A, protein kinase C, calmodulin-dependent kinases, plasmin- dependent kinases, and glucocorticoid-dependent kinases) primarily phosphorylate serine or threonine residues and do not require proline guidance. It has been demonstrated at the cellular, brain, and animal levels that phosphatases play an important role in protein degradation in neurons in diseases such as AD. Studies have reported that inhibiting protein phosphatase activity induced tau hyperphosphorylation and aggregation [115].

Drugs that Affect Tau Phosphorylation Patterns

Nimodipine Attenuates Phosphorylation of Tau at Ser-396: Nimodipine is an L-type calcium channel antagonist that reduces excessive calcium influx in pathological conditions [116] and shows neuroprotective effects. Nimodipine treatment was initially used due to its ability to produce vasodilation in smooth muscle cells lined with blood vessels [117]. Chronic cerebral hypofusion (CCH) has been reported to promote hyperphosphorylation of the tau protein. It showed that nimodipine attenuated CCH-induced tau phosphorylation by up-regulating the expression of miR-132. In addition, nimodipine inhibited CCH-induced activation of GSK-3β and neuronal apoptosis. These findings support the role of nimodipine in inhibiting tau phosphorylation at Ser-396 via miR-132/GSK-3β and points to new potential drug target for the treatment of tauopathy in CCH by regulating the miR-132/GSK3β pathway [116].

Tamoxifen Inhibits CDK5 Kinase Activity and Regulates Tau Phosphorylation: CDK5 is a multifunctional enzyme that plays an important role in brain development. The catalytic subunit of this kinase does not have enzymatic activity as a monomer but is activated by binding to activation subunits p35 or p39. These activation subunits are structurally related to cyclins, activators of cell cycle CDKs, but do not show homology with cyclins at the amino acid level. In contrast to other CDKs, activation of CDK5 does not require phosphorylation of the activation loop. Studies have shown that neurotoxicity induces proteolytic cleavage of the p35 subunit by calcium-regulated calpains [68]. In vitro experiments have shown that this proteolytic conversion of p35 to p25 does not significantly alter the steady-state kinetics of tau phosphorylation by CDK5 [118]. The binding of CDK5 to p25, the N-terminally truncated proteolytic product, stabilizes CDK5 in the active dimer form and alters its substrate specificity.et al.identified tamoxifen from a large-scale bioluminescent resonance energy transfer (BRET)-based screen of small molecules that inhibit the interaction between CDK5 and p25. They showed that tamoxifen reduced tau phosphorylation by blocking the activation of CDK5 by p25 [118]. This finding paves the way for new therapies for tauopathies by harnessing the drug tamoxifen [118].

Rapamycin Reduces Tau Phosphorylation at Ser-214 by Modulating cAMP-Dependent kinases: Mammalian target of rapamycin (mTOR) is a highly evolutionarily conserved serine/threonine kinase. mTOR is involved in regulating many cellular processes such as autophagy, protein translation, ribosome biosynthesis, actin organization, mitochondrial oxygen consumption, proliferation, and differentiation [119]. It is worth noting that mTOR acts as a linker to protein kinase signals, receiving inputs from many upstream signaling pathways and delivering various downstream kinases such as cAMP-dependent protein kinases (e.g. PKA), GSK-3β, and mitogen-activated protein kinases [120]. Since all these kinases are tau-associated kinases, whether rapamycin can modulate tau phosphorylation by regulating these kinases remains to be determined. In human neuroblastoma SH-SY5Y cells, a cell model widely used for tau pathology studies, research indicated that rapamycin reduced the PKA-mediated phosphorylation of tau at Ser-214. Similar results were obtained in wild-type human embryonic kidney 293 (HEK293) cells that were stably transfected with the longest isoform of recombinant human tau (tau441 HEK293/tau441). Since Ser-214 is a site that blocks tau hyperphosphorylation [121], the inhibition of mTOR by rapamycin could indirectly prevent or reduce tau hyperphosphorylation.

Research has focused on rapamycin-induced enhancement of autophagy, as autophagy mediates massive degradation of cytoplasmic content and thus enhances the clearance of hyperphosphorylated tau [122]. It is also thought that rapamycin may inhibit the synthesis of the tau protein. However, since autophagyinduced by rapamycin gives priority to the reduction of excessive phosphorylated and insoluble tau and soluble tau is dispersed throughout the cell, it may not be easy to reduce tau levels by autophagic degradation, and showed that rapamycin improved memory deficits in 6-month-old 3xTg AD mice before accumulation of hyperphosphorylated and insoluble tau was observed [123]. Similarly, another study using an AD mouse model showed that the protective effect of rapamycin was apparent only before insoluble tau accumulated in these animals [124]. These studies suggest that the protective effects of rapamycin may not be limited to autophagic clearance of hyperphosphorylated and insoluble tau.

Conclusion

As a major MAP, tau protein plays an important role in neurodegenerative diseases. AD is pathologically identified by the presence of NFTs containing hyperphosphorylated tau protein. Glycosylation and ubiquitination also play a role in aberrant tau phosphorylation. Investigating the phosphorylation mechanisms of tau protein provides considerable insight into the progress of neurodegenerative diseases and can provide a reasonable basis for early disease treatment. Tubulin is a very unstable protein that easily loses GTP/ GDP exchange efficiency at 37°C without the presence of GTP and protein-stabilizing compounds with multiple hydroxyl groups. Thus, decreased tubulin turnover and/or the reduced expression of factors required for tubulin maintenance may decrease the number of microtubules or tubulin level in normal aging neurons. In addition, in autophagy-deficient mouse embryonic fibroblasts, but not in neurons, proteasomal degradation of phosphorylated tau is reduced compared to wild-type tau.

While autophagy and proteasome pathways are involved in tau degradation, autophagy appears to be the main pathway for the clearance of phosphorylated tau in neurons. The enhancement of autophagy pathways may have potential as a novel therapeutic strategy in AD and other neurodegenerative diseases, along with inhibiting in vivo signaling pathways that form hyperphosphorylated tau and proteins aggregates. Phosphorylation of the tau protein is regulated by inhibiting GSK-3β, CDK5, and activating PP2A acid esterase. In vitro cell culture studies have revealed that aniline, rhodanine, benzylhydrazide, amino pyridine, and other such compounds can inhibit the aggregation of tau. In recent years, a defect in kinase inactivation in old age has been suggested as a potential mechanism linking body temperature regulation and tau protein phosphorylation. This finding could provide a strategy to help the elderly improve their thermoregulatory mechanisms. It may also serve as a potential new AD treatment strategy.

Table Abbreviations

Frontotemporal dementia and tremor paralysis: FTDP-17, Microtubule Associated Protein Tau: MAPT, progressive supranuclear palsy: PSP, Marfan syndrome: MFS, Alzheimer’s disease: AD, Creutzfeldt-Jakob disease: CJD, Colony Stimulating Factor: CSF

Author Contributions

Conceptualization, Xu Han. and Keping Chen. Validation, Keping Chen. Formal Analysis, Xu Han Investigation, Xu Han. Writing – Original Draft Preparation, Xu Han Writing – Review & Editing, Xu Han. Visualization, Xu Han. Supervision, Keping Chen Project Administration, Keping Chen. Funding Acquisition, Keping Chen.

Funding

This work was supported by the ational Natural Science Foundation of China [No. 31572467].

Acknowledgment

We would like to thank LetPub (www.LetPub.com) for providing linguistic assistance during the preparation of this manuscript.

Conflicts of Interest

The authors declare that they have no competing interests.

-->


Introduction

Alzheimer’s disease (AD) is the most common neurodegenerative dementia and affects more than 35 million people worldwide. Thus, the development of therapeutic methods is urgently needed to determine the underlying molecular mechanism of AD. Major pathological hallmarks of AD include senile plaques and neurofibrillary tangles (NFT), which consist mainly of amyloid β peptide (Aβ) and hyperphosphorylated tau, respectively (Mattson, 1997 Bettens et al., 2010). Mutations of the amyloid precursor protein (APP) and presenilin, a component of γ-secretase, are found in familial AD, and previous studies have established the hypothesis of the amyloid cascade (Huse and Doms, 2000 Gotz et al., 2004 Hardy, 2006 Bertram et al., 2010). On the basis of this hypothesis, great effort has been paid to develop drugs to reduce Aβ production or to clear Aβ, but successful results have not yet been obtained. In contrast, it has been shown that tau pathology is more closely related to neuronal loss (Gómez-Isla et al., 1997 Ingelsson et al., 2004). Tau is a genetic factor of a neurodegenerative disease known as frontotemporal dementia parkinsonism linked with chromosome 17 (FTDP-17 Hutton et al., 1998 Poorkaj et al., 1998 Spillantini et al., 1998). FTDP-17 tau mutants are highly phosphorylated in patient brains. Regardless of whether phosphorylation is a cause of FTDP-17, it is still critical to determine the neuronal milieu in which tau hyperphosphorylation occurs. Cyclin-dependent kinase 5 (Cdk5) is a major tau kinase that is involved in abnormal phosphorylation in AD brains (Imahori and Uchida, 1997 Cruz and Tsai, 2004 Engmann and Giese, 2009). Here, we summarize the phosphorylation of tau by Cdk5. To the best of our knowledge, this is the first review article focused specifically on Cdk5 phosphorylation of tau.


Abstract

One of the hallmarks of Alzheimer's disease is the abnormal state of the microtubule-associated protein tau in neurons. It is both highly phosphorylated and aggregated into paired helical filaments, and it is commonly assumed that the hyperphosphorylation of tau causes its detachment from microtubules and promotes its assembly into PHFs. We have studied the relationship between the phosphorylation of tau by several kinases (MARK, PKA, MAPK, GSK3) and its assembly into PHFs. The proline-directed kinases MAPK and GSK3 are known to phosphorylate most Ser-Pro or Thr-Pro motifs in the regions flanking the repeat domain of tau: they induce the reaction with several antibodies diagnostic of Alzheimer PHFs, but this type of phosphorylation has only a weak effect on tau−microtubule interactions and on PHF assembly. By contrast, MARK and PKA phosphorylate several sites within the repeats (notably the KXGS motifs including Ser262, Ser324, and Ser356, plus Ser320) in addition PKA phosphorylates some sites in the flanking domains, notably Ser214. This type of phosphorylation strongly reduces tau's affinity for microtubules, and at the same time inhibits tau's assembly into PHFs. Thus, contrary to expectations, the phosphorylation that detaches tau from microtubules does not prime it for PHF assembly, but rather inhibits it. Likewise, although the phosphorylation sites on Ser-Pro or Thr-Pro motifs are the most prominent ones on Alzheimer PHFs (by antibody labeling), they are only weakly inhibitory to PHF assembly. This implies that the hyperphosphorylation of tau in Alzheimer's disease is not directly responsible for the pathological aggregation into PHFs on the contrary, phosphorylation protects tau against aggregation.

The project was supported by the Deutsche Forschungsgemeinschaft.

Corresponding author. Tel: +49-40-89982810. Fax: +49-40-89716822. E-mail: [email protected]


Discussion

Due to the controversial role of neurofibrillary tangle (NFT) formation in the neurodegenerative process [2–4, 6–9, 43–47], a better understanding of the mechanisms leading to the formation of NFT would be beneficial to our understanding of AD.

In this report, we have demonstrated that GSK-3β phosphorylation of tau is sufficient to induce the clustering of ARA-induced filaments into structures similar to the NFT-like aggregates of tau filaments purified from AD brain [33, 34]. These results suggest that GSK-3β phosphorylation not only produces a small but significant increase in tau filament formation, but also shows that phosphorylation alters the nature of interactions between those filaments resulting in their clustering into NFT-like structures. Although in this report we address only the effects of tau phosphorylation by GSK-3β, ARA inducer concentration (the inducer:tau ratio in polymerization), and ThS on the clustering of tau filaments into NFT-like structures, we feel that this is an important first step in unraveling the molecular mechanisms of NFT formation through cell-free in vitro modeling.

The clusters of tau filaments formed by polymerization of GSK-3β phosphorylated tau are stable and their formation is readily reproducible, although various factors influence the size, mass and density of the clusters. Here we demonstrate the effects of inducer and the ratio of inducer:tau concentration on these properties. In general, we have found that phosphorylation by GSK-3β is sufficient for cluster formation. In addition, conditions that alter filament length modify both the density of the filaments in the cluster, and the size of the cluster. Increases in inducer concentration which result in a change from the suboptimal to optimal ratio of inducer:tau concentration in the polymerization reaction increase the filament length within clusters and the area covered by the clusters. This results in clustered filaments that are less densely packed. Conversely, conditions that decrease filament length produce smaller clusters that contain a higher density of filaments.

With this newly developed in vitro model, we can begin to dissect the molecular mechanisms that are involved in filament aggregations that form NFT-like structures. Further studies will be aimed at understanding whether GSK-3β phosphorylation unmasks regions of tau molecules that interact with one another in forming clusters or whether the GSK-3β phosphorylation sites are interacting directly. It is tempting to speculate a role for the former since GSK-3β phosphorylation results in an SDS-resistant conformational change as observed by an upward shift in mobility on SDS page analysis. The apparent increase in initial polymerization velocity as monitored by ThS fluorescence also suggests that the GSK-3β phosphorylated tau may be in a conformation that more readily interacts with the ARA inducer or with the ThS as used to detect amyloid-type interactions in tau kinetic analyses. Although the co-localization of GSK-3β with tau pathology in AD suggests that NFTs may form from the direct interaction of GSK-3β with tau filaments [15], our mock-phosphorylation results strongly suggest that phosphorylation is the primary role of GSK-3β in promoting cluster formation.

This in vitro model for NFT formation requires the induction of tau polymerization via the addition of ARA, which may lead to the questioning of its physiological relevance. An inducer of tau polymerization in AD and other neurodegenerative disorders has not been identified, but that does not dampen our enthusiasm for the use of ARA as an inducer in our cell-free in vitro model system. This is due to ample evidence that ARA induced tau filaments are structurally similar to filaments from AD [42, 48–51]. Additionally, there is growing evidence that ARA or its metabolites could be involved in the neurodegenerative process in AD (reviewed in [52]). While a direct connection between tau polymerization and ARA remains to be made in AD, the structural similarity between ARA induced filaments and AD filaments, plus the similarity between GSK-3β induced NFT-like clusters of tau filaments and those found in AD provide a strong argument for the physiological relevance of this model. In addition to the characterization of the GSK-3β induced clustering of filaments, this in vitro model provides a tool for investigating whether other kinases such as cyclin dependent kinase 5 or microtubule affinity regulating kinase have similar properties to induce the formation of NFT-like filament bundles. Likewise, other modifications found in association with AD NFTs, such as truncation, ubiquitination, nitration and glycation (reviewed in [1, 10]) could also be tested. Our hope is that these ongoing studies will isolate factors contributing not only to the formation of NFT-like clusters, but also to identify the conditions that could lead to potentially toxic tau aggregates in cell and animal culture models.


Comments

This is an interesting study that suggests the field may have to change the way they think about tau phosphorylation in Alzheimer's disease. Tau phosphorylation has historically been thought of as a contributor to neurofibrillary tangle formation and disease-associated tau toxicity, but in this study Ittner et al. identify that phosphorylation of tau on threonine 205 may actually serve a protective role. This is of note as phosphorylation of tau at this site has often been used as a measure of disease pathology and is the recognition site of the commonly used &ldquoAT8&rdquo tau antibody as well many commonly used reagents.

The authors identify p38γ, a previously underappreciated isoform of p38, as a tau kinase that preferentially phosphorylates T205. Surprisingly, loss of p38γ enhanced rather than suppressed tau-based toxicity. This could be explained through the observation that phosphorylation of T205 resulted in dissociation of tau/fyn/PSD-95 complexes, which was identified as a mechanism of tau-based neurotoxicity by the authors in a previous study. From a therapeutic perspective, a wealth of data is presented supporting p38γ as the key kinase regulating tau T205 phosphorylation, though unfortunately the development of compounds that act as kinase activators has proven far less tractable than kinase inhibitors. Therefore, more work is likely needed in order to translate these discoveries into development of new treatments for Alzheimer's disease.

Overall the study is comprehensive, well-designed, and contains a number of loss-of-function and gain-of-function experiments with both tau and p38γ that solidify their conclusions. It is a nice addition to our understanding of tau function and will surely provide a starting point for a range of future work.

This is a well-done study. Although the authors have not pointed it out, one very intriguing possible conclusion that can be drawn is that the Aβ drug trials, especially immunotherapies, continue to be negative because tau in AD brain is hyperphosphorylated at Thr 205, along with several other sites, which protects AD brain from Aβ-induced neurotoxicity and hence removal of Aβ will not have any beneficial therapeutic effect.

I believe a serious problem with this present study, and for that matter for many other such studies on the etiopathogenic relationship between Aβ and tau pathologies, is the use of highly artificial overexpression/knockout transgenic mice, which can grossly alter the quantitative effects and hence the outcome.

The hyperphosphorylation of tau has long been proposed to contribute to the tau pathology in Alzheimer&rsquos disease and other tauopathies. However, owing to the number and heterogeneity of phosphorylation sites on tau, investigating the exact role of phosphorylation of tau in neurodegeneration proves to be a challenge. Although hyperphosphorylation of tau is generally regarded as a culprit of neurodegeneration, hyperphosphorylation of tau occurs in other transient situations (e.g., hibernation, stress) without causing lasting side effects. In their recent paper, the Ittner brothers provide evidence that the phosphorylation of tau at Thr205 by P38γ can even be protective because it can suppress excitotoxicity induced by Aβ or PTZ. This is because the phosphorylation at Thr205 of tau disrupts the formation of NMDA-Receptor/PSD-95/tau/Fyn complexes, which mediate Aβ or PTZ induced excitotoxicity. This interesting result expands on the earlier studies of the Ittner and Götz team (Ittner et al., 2010), which assigned a physiological role to the small fraction of tau found in dendrites (which is otherwise mainly axonal). The Thr205 residue is one of several Ser-Pro or Thr-Pro motifs in tau that are targeted by several proline-directed kinases involved in cellular signaling pathways, including those of the JNK family. This type of phosphorylation has been under intense scrutiny, and therefore the current study can be compared to others, leaving several issues to be clarified in the future:

(1) Mondragon-Rodriguez and colleagues reported that phosphorylation of tau can suppress excitotoxicity and thus can serve as a regulatory mechanism to prevent NMDA receptor overexcitation (Mondragon-Rodriguez et al., 2012). These authors focused on phosphorylation of tau at the phospho-epitopes AT180, AT8, or AT100, also representing Ser-Pro or Thr-Pro sites, which reduces tau's interaction with PSD-95. This is at variance with the current study demonstrating that only phosphorylation at Thr205 reduces the association of tau with PSD-95 and Fyn.

(2) The current study showed that the kinase P38γ phosphorylates tau at Thr205 and to a lesser extent at Ser199 (included in the phospho-epitope AT8, a widely used antibody to characterize phosphorylated tau), but not at Ser 202 (included in the phospho-epitope AT8) and hardly any at Ser396 and Ser404 (epitopes of PHF1, another commonly used antibody against phospho-tau). On the other hand, several earlier studies (for instance, Buee-Scherrer and Goedert, 2002 Goedert et al., 1997) revealed that P38γ phosphorylates tau not only at AT8 sites, but also strongly at the PHF1-epitope pSer396/pSer404. It is not clear whether this discrepancy is due to the difference of antibodies used in these studies, since the current Ittner paper used antibodies with epitopes of a single phosphorylation site (pT205, pS202 etc.), while the other studies used antibodies against a combination of multiple phosphorylation sites (e.g. AT8, PHF1).

The present study also shows that the P38γ level is reduced in old APP23 mice but not in young APP23 mice (Fig.S10), compared to wild-type mice. On the other hand, the APP23 mice display enhanced epileptiform activity at four months, when there is no P38γ reduction. Therefore, there must be mechanisms independent of P38γ underlying the Aβ-induced hyperexcitotoxicity in the young APP mice whose nature deserves attention in future experiments.


References

Lu, P.-J., Wulf, G., Zhou, X. Z., Davies, P. & Lu, K. P. Nature 399, 784–788 (1999).

Lu, K. P., Hanes, S. D. & Hunter, T. Nature 380, 544–547 (1996).

Yaffe, M. B. et al. Science 278, 1957–1960 (1997).

Vincent, I., Rosado, P. & Davies, P. J. Cell Biol. 132, 413–425 (1996).

Kondratick, C. M. & Vandré, D. D. J. Neurochem. 67, 2405–2416 (1996).

Pope, W. B. et al. Exp. Neurol. 126, 185–194 (1994).

Illenberger, S. et al. Mol. Biol. Cell 9, 1495–1512 (1998).

Hasegawa, M. et al. J. Biol. Chem. 267, 17047–17054 (1992).

Watanabe, A. et al. J. Biol. Chem. 268, 25712–25717 (1993).

Ishiguro, K. et al. FEBS Lett. 325, 167–172 (1993).

Goedert, M. et al. Biochem. J. 301, 871–877 (1994).

Matsuo, E. S. et al. Neuron 13, 989–1002 (1994).

Morishima-Kawashima, M. et al. J. Biol. Chem. 270, 823–829 (1995).

Goedert, M., Crowther, R. A. & Spillantini, M. G. Neuron 21, 955–958 (1998).

Vincent, I., Jicha, G., Rosado, M. & Dickson, D. W. J. Neurosci. 17, 3588–3598 (1997).

Nagy, Zs., Esiri, M. M., Cato, A.-M. & Smith, A. D. Acta Neuropathol. 94, 6–15 (1997).

Busser, J., Geldmacher, D. S. & Herrup, K. J. Neurosci. 18, 2801–2807 (1998).


ABSTRACT

Neurofibrillary tangles (NFTs), consisting of abnormally hyperphosphorylated tau, are implicated in the pathogenesis of several neurodegenerative diseases including Alzheimer's disease (AD). The molecular mechanisms underlying the regulation of tau phosphorylation are largely unknown. While the PI3K/Akt pathway has been shown to regulate multiple cellular events pertinent to AD pathogenesis, potential functions of tumor suppressor phosphatase and tensin homologue deleted on chromosome 10 (PTEN) in AD pathogenesis have not been explored. Here, we examine the effects of PTEN on tau phosphorylation, its microtubule association and formation of aggregates, and consequentially neuronal morphology. In cultured cells, overexpression of wild-type (WT) PTEN alters tau phosphorylation at several sites, increases tau-microtubule association and decreases formation of tau aggregates. In addition, the phosphatase-null PTEN increases tau aggregation and impairs tau binding to microtubule and neurite outgrowth of neurons expressing the mutant PTEN. We also found a significant loss of PTEN in AD patient brains correlated with a dramatically increased concentration of phospho-tau at Ser-214 in NFTs. Together, our results demonstrate that PTEN regulates tau phosphorylation, binding to microtubules and formation of aggregates and neurite outgrowth. These findings suggest a link between malfunction of PTEN and tauopathy, and imply PTEN as a therapeutic target for tauopathy.—Zhang, X., Li, F., Bulloj, A., Zhang, Y.-w., Tong, G., Zhang, Z., Liao, F.-F., Xu, H. Tumor-suppressor PTEN affects tau phosphorylation, aggregation, and binding to microtubules. FASEB J. 20, E605–E613 (2006)

A key pathological hallmark for Alzheimer's disease (AD) is intracellular neurofibrillary tangles (NFTs), whose major component is bundles of paired helical filaments (PHF) of hyperphosphorylated tau proteins (1). The biochemical study of neuropathological lesions has revealed that such intracellular tau filamentous deposits occur numerous other neurodegenerative diseases as well, including Pick's disease (PiD), corticobasal degeneration (CBD), progressive supranuclear palsy (PSP), argyrophilic grain disease and frontotemporal dementia and parkinsonism linked to chromosome 17 (FTDP-17) (2). The evidence for a causal role of tau aggregation in neurodegenerative diseases was provided by the genetic analyses of the inherited FTDP-17, which led to identification of tau mutations that cause the disease (3–5).

Tau is a class of microtubule-associated protein (MAP) in neuronal and glial cells, which exist in six tau splicing variants in human brain. The tau protein is normally expressed in cytoplasm including cell bodies, neurites, and axons, where it binds to and stabilizes microtubules (6–8). Tau can be phosphorylated at several serine or threonine sites before proline. Numerous kinases, including CDK5 (cyclin-dependent kinase 5), GSK-3 (glycogen synthase kinase-3), MAPK (mitogen-activated protein kinase), protein kinase A (PKA), protein kinase (PKC), and Akt have been identified to phosphorylate tau in vitro (9). Tau is phosphorylated under normal physiological conditions, carrying 2–3 phosphates per molecule. However, hyperphosphorylation of tau, which renders tau 3–4 times more phosphates (10, 11), will cause dysfunction of tau (12), tau aggregation, and likely NFTs formation (13).

The tumor suppressor gene Pten (phosphatase and tensin homologue deleted on chromosome 10), also known as MMAC1 and TEP1, is the second most frequently mutated gene after p53 in many human sporadic and hereditary cancers (14–17). PTEN contains a tyrosine phosphatase functional domain, exhibiting both protein and lipid phosphatase activity in vitro (18). The phosphatidylinositol (3–5)-triphosphate (PIP3) has been identified as a major lipid substrate for PTEN (15, 16), but the putative substrates of PTEN with proteinaceous nature are unknown. PTEN antagonizes the phosphoinositide 3-kinase (PI3K) signaling to govern a variety of crucial cellular functions, including cell proliferation, migration, and apoptosis (19, 20). Therefore, the lipid phosphatase activity of PTEN is critical for its tumor-suppressor function (21). Pten-null mice die at early embryonic stages, and heterozygous knockout mice develop a number of tumors (22–25). Mouse brains with conditionally inactivated Pten showed an increased soma size of neurons without altering proliferation (26, 27). A recent study showed decreased levels and altered distribution of PTEN along with elevated PI3K signaling in AD patient brains, suggesting that a loss of PTEN contributes to neurodegeneration in AD (28).

Akt and GSK-3 are two major downstream effectors of the PIP3 pathway. PTEN down-regulates Akt, which in turn activates GSK-3. GSK-3 has been shown to phosphorylate tau at multiple sites in vitro and in vivo (29–33). The observation that Akt/GSK-3 can affect tau phosphorylation raises a possibility that PTEN may also modulate tau phosphorylation. In the present study, we have analyzed tau phosphorylation and investigated whether the altered phosphorylation of tau by PTEN leads to changes in tau aggregation and microtubulebinding ability in cultured cells and primary neurons. We demonstrate that WT PTEN modulates tau phosphorylation at certain residues reducing tau aggregation and promoting its microtubule binding, while lipid phosphatase-null PTEN has opposite effects. In addition, we observe a decreased concentration of PTEN accompanied by increased phospho-tau at Ser-214 (a major Akt site) in AD brains.


Results

The relative levels of phosphorylation of tau by JNK1, JNK2, JNK3, SAPK4, ERK2, GSK3β, DYRK1A and PKA were determined using the incorporation of 32 P and autoradiography (Fig. 2). SAPK4 was the best at phosphorylating tau, followed by JNK2, JNK3 and JNK1. The latter enzymes incorporated 79, 40 and 37% of label, when the amount of radioactivity in tau following phosphorylation by SAPK4 was taken as 100%. This value was 20% for ERK2 and GSK3β, 9% for DYRK1A and 4% for PKA. The extent of phosphorylation of tau protein was reflected in its reduced gel mobility (Fig. 2). Thus, phosphorylation by SAPK4 and JNK2 resulted in the highest apparent molecular mass of tau. Phosphorylation by JNK3 and JNK1 gave rise to broader bands of slower migrating tau. Lesser mobility shifts were seen upon phosphorylation by ERK2 and GSK3β, whereas tau phosphorylated by DYRK1A and PKA showed no change in mobility.

Relative levels of phosphorylation of human tau protein by JNK1, JNK2, JNK3, SAPK4, ERK2, GSK3β, DYRK1A and PKA. (a) Relative levels of 32 P-radioactivity incorporated into tau following phosphorylation, with the value for SAPK4 taken as 100%. Phosphorylated tau was resolved on SDS-PAGE and quantitated by PhosphorImager (Molecular Dynamics, Inc.) analysis (arbitrary units). The results are shown as the means ± SEM (n = 5). (b) Autoradiogram (AR) of a typical experiment showing tau before and after phosphorylation.

Phosphorylation-dependent anti-tau antibodies were used to identify phosphorylated amino acid residues (Fig. 3, Table 1). Tau phosphorylated by SAPK4 and JNK2 gave similar patterns on immunoblots. It was strongly labelled by antibodies AT270, pS199, AT8, pS202, pT205, pT212, pT217, AD2, pS396, pS404 and AP422, and weakly by AT180 and pT231. Tau phosphorylated by JNK3 was strongly labelled by AT270, pS202, pT205, pS396 and AP422, and weakly by pS199, AT8, pT212, pT217, AD2 and pS404. Tau phosphorylated by JNK1 was strongly labelled by pS199, pS202, pT212, pS404 and AP422, and weakly by AT8, pT205, pT217, pS396 and AD2. Tau phosphorylated by ERK2 was strongly labelled by AT270, pS202 and AP422, and weakly by pS199, pT205, pT217, pT231, AD2, pS396 and pS404. Tau phosphorylated by GSK3β was strongly labelled by pS199, AD2, pS396 and pS404, and weakly by AT270, AT8, pS202 and pT205. Tau was phosphorylated at T212 by DYRK1A and at S214 by PKA. The epitope of antibody AT100 was not generated by any of the protein kinases used. When phosphorylated by the combination of GSK3β and JNK2, GSK3β and JNK3 or GSK3β and SAPK4, tau became strongly immunoreactive with antibody AT180, but not with antibody AT100 (Fig. 4). The combination of DYRK1A and PKA or GSK3β and PKA failed similarly to generate the AT100 epitope, even in the presence of 50 µg/mL heparin (data not shown).

Immunoblot analysis of phosphorylation of human tau protein by JNK1, JNK2, JNK3, SAPK4, ERK2, GSK3β, DYRK1A and PKA. Blots were incubated with anti-tau serum BR134 and the phosphorylation-dependent anti-tau antibodies AT270, pS199, AT8, pS202, pT205, pT212, pS214, pT217, pT231, AT180, AD2, pS396, pS404 and AP422. cont, No kinase.

Antibody Epitope [phosphorylation site(s)] Kinase
JNK1 JNK2 JNK3 SAPK4 ERK2 GSK3β DYRK1A PKA
AT270 Thr181 + + + + + + + + + + + +
pS199 Ser199 + + + + + + + + + + + + +
AT8 Ser202 + Thr205 + + + + + + + + + + + +
pS202 Ser202 + + + + + + + + + + + +
pT205 Thr205 + + + + + + + + + + + +
AT100 Thr212 + Ser214
pT212 Thr212 + + + + + + + + + + + +
pS214 Ser214
pT217 Thr217 + + + + + + + + + + + + + +
AT180 Thr231 + + + +
pT231 Thr231 + +
AD2 Ser396 + Ser404 + + + + + + + + + + +
pS396 Ser396 + + + + + + + + + + + +
pS404 Ser404 + + + + + + + + + + + + + + +
AP422 Ser422 + + + + + + + + + + + + +
  • –, no immunoreactivity +, weak immunoreactivity + +, strong immunoreactivity + + +, very strong immunoreactivity.

Immunoblot analysis of phosphorylation of human tau by JNK2, JNK3 and SAPK4, alone or in combination with GSK3β. GSK3β was added either at the same time as JNK2 (JNK2/GSK3β), JNK3 (JNK3/GSK3β) and SAPK4 (SAPK4/GSK3β), or 9 h after JNK2 (JNK2 + GSK3β), JNK3 (JNK3 + GSK3β) and SAPK4 (SAPK4 + GSK3β), or 9 h before JNK2 (GSK3β + JNK2), JNK3 (GSK3β + JNK3) and SAPK4 (GSK3β + SAPK4). Blots were incubated with the phosphorylation-independent anti-tau serum BR134 and the phosphorylation-dependent anti-tau antibodies AT180 and AT100. A68fr denotes sarkosyl-insoluble tau extracted from the brains of 5-month-old mice transgenic for human P301S tau protein ( Allen et al. 2002 ).

We examined whether phosphorylation by JNK1, JNK2, JNK3 and SAPK4 influences the ability of tau to promote microtubule assembly (Fig. 5). Phosphorylation of tau by SAPK4 strongly reduced microtubule assembly, followed by JNK2, JNK3 and JNK1. The rates of polymerization calculated at 2 min after starting polymerization were 0.1%, 0.6%, 1.5% and 19.4%, respectively, with the value for non-phosphorylated tau taken as 100%.

Effects of phosphorylation by JNK1, JNK2, JNK3 and SAPK4 on the ability of tau to promote microtubule assembly. Polymerization of tubulin was monitored by turbidity over time following the addition of either non-phosphorylated tau (no kinase), or tau phosphorylated by JNK1, JNK2, JNK3 or SAPK4. No change in turbidity was observed in the absence of tau (dotted line). A typical experiment is shown. Similar results were obtained in three separate experiments.


Acknowledgements

This work was supported by the UK Medical Research Council and the Alzheimer’s Research Trust. The authors thank Dr P. Seubert (Elan Pharmaceutials) for the 12E8 antibody, and Drs A. Dérevier and CJ. Zhao for help with the preparation of primary neuronal cultures.

Figure S1. Substrate specificity of AMPK-related kinases. AMPK-related kinases (1 U/mL) were assayed using 0.1 mM of either AMARA peptide (AMARAASAAALARRR) or CHKtide (KKKVSRSGLYRSPSMPENLNRPR), as described in MATERIALS AND METHODS. The activities (relative 32P-labeling) are presented as the average ± SD of three separate experiments, with each determination performed in triplicate.

As a service to our authors and readers, this journal provides supporting information supplied by the authors. Such materials are peer-reviewed and may be re-organized for online delivery, but are not copy-edited or typeset. Technical support issues arising from supporting information (other than missing files) should be addressed to the authors.

Filename Description
JNC_7523_sm_FigS1.pdf89.4 KB Supporting info item

Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.