NMR Meets Tau: Insights into Its Function and Pathology.

In this review, we focus on what we have learned from Nuclear Magnetic Resonance (NMR) studies on the neuronal microtubule-associated protein Tau. We consider both the mechanistic details of Tau: the tubulin relationship and its aggregation process. Phosphorylation of Tau is intimately linked to both aspects. NMR spectroscopy has depicted accurate phosphorylation patterns by different kinases, and its non-destructive character has allowed functional assays with the same samples. Finally, we will discuss other post-translational modifications of Tau and its interaction with other cellular factors in relationship to its (dys)function.

Proline Conformation in a Functional Tau Fragment.

The conformational state of distinct prolines can determine the folding of a protein but equally other biological processes when coupled to a conformation-sensitive secondary reaction. For the neuronal tau protein, the importance of proline conformation is underscored by its interaction with different prolyl cis/trans isomerases. The proline conformation would gain even further importance after phosphorylation of the preceding residue by various proline-directed kinases. A number of molecular diseases including Alzheimer's disease and traumatic brain injury were thereby recently qualified as "cistauosis", as they would imply a cis conformation for the pThr231-Pro232 prolyl bond. We here investigate by NMR spectroscopy the conformation of all prolines in a functional Tau fragment, Tau[208-324]. Although we can detect and identify some minor conformers in the cis form, we show that all prolines are for over 90% in the trans conformation. Phosphorylation by CDK2/CycA3, which notably leads to complete modification of the Thr231 residue, does not change this conclusion. Our data hence disagree with the notion that specific prolyl bonds in tau would adopt preferentially the cis conformation.

Tau pathology modulates Pin1 post-translational modifications and may be relevant as biomarker.

A prerequisite to dephosphorylation at Ser-Pro or Thr-Pro motifs is the isomerization of the imidic peptide bond preceding the proline. The peptidyl-prolyl cis/trans isomerase named Pin1 catalyzes this mechanism. Through isomerization, Pin1 regulates the function of a growing number of targets including the microtubule-associated tau protein and is supposed to be deregulated Alzheimer's disease (AD). Using proteomics, we showed that Pin1 is posttranslationally modified on more than 5 residues, comprising phosphorylation, N-acetylation, and oxidation. Although Pin1 expression remained constant, Pin1 posttranslational two-dimensional pattern was modified by tau overexpression in a tau-inducible neuroblastoma cell line, in our THY-Tau22 mouse model of tauopathy as well as in AD. Interestingly, in all of these systems, Pin1 modifications were very similar. In AD brain tissue when compared with control, Pin1 is hyperphosphorylated at serine 16 and found in the most insoluble hyperphosphorylated tau fraction of AD brain tissue. Furthermore, in all tau pathology conditions, acetylation of Pin1 may also contribute to the differences observed. In conclusion, Pin1 displays several posttranslational modifications, which are specific in tauopathies and may be useful as biomarker.

Studying the natively unfolded neuronal Tau protein by solution NMR spectroscopy.

The neuronal Tau protein, whose physiological role is to stabilize the microtubules, is found under the form of aggregated filaments and tangles in Alzheimer's diseased neurons. Until recently detailed structural analysis of the natively unfolded Tau protein has been hindered due to its shear size and unfavourable amino acid composition. We review here the recent progress in the assignments of the full-length polypeptide using novel methods of product planes and peptide NMR mapping, and indicate the structural insights that can be obtained from this assignment. Preliminary NMR data on the fibers show that the assignment enables a precise mapping of the rigid core. Future NMR experiments should allow one to gain more insight into the conformational aspects of this intriguing protein.

Control of protein-protein interactions: structure-based discovery of low molecular weight inhibitors of the interactions between Pin1 WW domain and phosphopeptides.

Interactions involving phosphorylated Ser/Thr-Pro motifs in proteins play a key role in numerous regulatory processes in the cell. Here, we investigate potential ligands of the WW binding domain of Pin1 in order to inhibit protein-protein interactions between Pin1 and phosphopeptides. Our structure-based strategy implies the synthesis of analogues of the Ac-Thr(PO(3)H(2))-Pro-NH(2) dipeptide and relies on high resolution NMR spectroscopy to accurately measure the affinity constants even in the high micromolar range.

Regulation of Pin1 peptidyl-prolyl cis/trans isomerase activity by its WW binding module on a multi-phosphorylated peptide of Tau protein.

The WW module of the peptidyl-prolyl cis/trans isomerase Pin1 targets specifically phosphorylated proteins involved in the cell cycle through the recognition of phospho-Thr(Ser)-Pro motifs. When the microtubule-associated Tau protein becomes hyperphosphorylated, it equally becomes a substrate for Pin1, with two recognition sites described around the phosphorylated Thr212 and Thr231. The Pin1 WW domain binds both sites with moderate affinity, but only the Thr212-Pro213 bond is isomerized by the catalytic domain of Pin1. We show here that, in a peptide carrying a single recognition site, the WW module increases significantly the enzymatic isomerase activity of Pin1. However, with addition of a second recognition motif, the affinity of both the WW and catalytic domain for the substrate increases, but the isomerization efficacy decreases. We therefore conclude that the WW domain can act as a negative regulator of enzymatic activity when multiple phosphorylation is present, thereby suggesting a subtle mechanism of its functional regulation.

Accepting its random coil nature allows a partial NMR assignment of the neuronal Tau protein.

A combined strategy to obtain a partial NMR assignment of the neuronal Tau protein is presented. Confronted with the extreme spectral degeneracy that the spectrum of this 441 amino acid long unstructured protein presents, we have introduced a graphical procedure based on residue type-specific product planes. Combining this strategy with the search for pairwise motifs, and combining the spectra of different Tau isoforms and even of peptides derived from the native sequence, we arrive at a partial assignment that is sufficient to map the interactions of Tau with its molecular partners. The obtained assignments equally confirm the absence of regular secondary structure in the isolated protein.

The peptidyl prolyl cis/trans-isomerase Pin1 recognizes the phospho-Thr212-Pro213 site on Tau.

The interaction between the neuronal Tau protein and the Pin1 prolyl cis/trans-isomerase is dependent on the phosphorylation state of the former. The interaction site was mapped to the unique phospho-Thr231-Pro232 motif, despite the presence of many other Thr/Ser-Pro phosphorylation sites in Tau and structural evidence that the interaction site does not significantly extend beyond those very two residues. We demonstrate here by NMR and fluorescence mapping that the Alzheimer's disease specific epitope centered around the phospho-Thr212-Pro213 motif is also an interaction site, and that the sole phospho-Thr-Pro motif is already sufficient for interaction. Because a detectable fraction of the Pro213 amide bond in the peptide centered around the phospho-Thr212-Pro213 motif is in the cis conformation, catalysis of the isomerization by the catalytic domain of Pin1 could be investigated via NMR spectroscopy.

Proline-directed random-coil chemical shift values as a tool for the NMR assignment of the tau phosphorylation sites.

NMR spectroscopy of the full-length neuronal Tau protein has proved to be difficult due to the length of the protein and the unfavorable amino acid composition. We show that the random-coil chemical shift values and their dependence on the presence of a proline residue in the (i+1) position can successfully be exploited to assign all proline-directed phosphorylation sites. This is a first step toward the study of the phosphorylation of Tau by NMR spectroscopy.

Neurofibrillary degeneration of the Alzheimer-type: an alternate pathway to neuronal apoptosis?

Neuronal death is a process which may be either physiological or pathological. Apoptosis and necrosis are two of these processes which are particularly studied. However, in neurodegenerative disorders, some neurons escape to these types of death and "agonize" in a process referred to as neurofibrillary degeneration. Neurofibrillary degeneration is characterized by the intraneuronal aggregation of abnormally phosphorylated microtubule-associated Tau proteins. A number of studies have reported a reactivation of the cell cycle in the neurofibrillary degeneration process. This reactivation of the cell cycle is reminiscent of the initiation of apoptosis in post-mitotic cells where G1/S markers including cyclin D1 and cdk4/6, are commonly found. However, in neurons exhibiting neurofibrillary degeneration, both G1/S and G2/M markers are found suggesting that they do not follow the classical apoptosis and an aberrant cell cycle occurs. This aberrant response leading to neurofibrillary degeneration may be triggered by the sequential combination of three partners: the complex Cdk5/p25 induces both apoptosis and the "abnormal mitotic Tau phosphorylation". These mitotic epitopes may allow for the nuclear depletion of Pin1. This latter may be responsible for escaping classical apoptosis in a subset of neurons. Since neurofibrillary degeneration is likely to be a third way to die, molecular mechanisms leading to changes in Tau phosphorylation including activation of kinases such as cdk5 or other regulators such as Pin1 could be important drug targets as they are possibly involved in early stages of neurodegeneration.

Pin1: a therapeutic target in Alzheimer neurodegeneration.

In Alzheimer's disease, the peptidyl prolyl cis/trans isomerase Pin1 binds to phospho-Thr231 on Tau proteins and, hence, is found within degenerating neurons, where it is associated to the large amounts of abnormally phosphorylated Tau proteins. Conversely, Pin1 may restore the tubulin polymerization function of these hyperphosphorylated Tau. In the present work, we investigated, both at the cellular and molecular levels, the role of Pin1 in Alzheimer's disease through the study of its interactions with phosphorylated Tau proteins. We also showed that in neuronal cells, Pin1 upregulates the expression of cyclin D1. This, in turn, could facilitate the transition from quiescence to the G1 phase (re-entry in cell cycle) in a neuron and, subsequently, neuronal dedifferentiation and apoptosis. The involvement of Pin1 in the G0/G1 transition in neurons points to its function as a good target for the development of new therapeutic strategies in neurodegenerative disorders.