The invention provides high throughput methods, protein inhibitors, and uses thereof. The invention provides high throughput methods of screening compounds for modulation of protein thermal stability, the method comprising contacting a protein with each of a plurality of test compounds; and (b) measuring the melting transition (T.sub.m) of the protein in the presence of each of the plurality of test compounds, wherein a compound that decreases or increases the apparent Tm by at least 2 standard deviations is identified as a pharmacological protein chaperone.

The invention provides antibodies that specifically bind to transthyretin (TTR). The antibodies can be used for treating or effecting prophylaxis of diseases or disorders associated with TTR accumulation or accumulation of TTR deposits (e.g., TTR amyloidosis). The antibodies can also be used for diagnosing TTR amyloidosis and inhibiting or reducing aggregation of TTR, among other applications.

A humanized antibody which comprises a complementarity determining region of an H chain consisting of the amino acid sequence as shown in SEQ ID NOs: 1 to 3 and a complementarity determining region of an L chain consisting of the amino acid sequence as shown in SEQ ID NOs: 4 to 6. The humanized antibody of the present invention has the activity to specifically bind to transthyretin (TTR) with structural change and the activity to inhibit fibrillization of TTR and is a humanized antibody suitable for application to human body.

A human antibody which comprises a complementarity determining region of an H chain consisting of the amino acid sequence as shown in SEQ ID NOs: 1 to 3 and a complementarity determining region of an L chain consisting of the amino acid sequence as shown in SEQ ID NOs: 4 to 6. The human antibody of the present invention has the activity to specifically bind to transthyretin (TTR) with structural change and the activity to inhibit fibrillization of TTR and is a human antibody suitable for application to human body.

The invention relates to antibodies, antibody fragments and binding agents that specifically recognize oligomeric tau but do not bind to monomelic tau, fibrillar tau or non-disease associated forms of tau.

The invention relates to the identification of a new Tau species starting at residue Met11 (Met11-Tau) which is N-alpha-terminally acetylated form (N-alpha-acetyl-Met11-Tau species: Ac-Met11-Tau). Several monoclonal antibodies specific of this new Tau species have been developed. One of this antibody, 2H2/D11, was used in THY-Tau22 mouse model (that develops with age neurofibrillary degeneration (NFD) and memory deficits), and N-alpha-Ac-Met11-Tau species were clearly detected early in neurons displaying NFD on hippocampal brain sections while it is not reactive in hippocampus from elderly controls. Finally, by using ELISA sandwich specific of Ac-Met11-Tau species, Alzheimer Disease (AD) brain samples are clearly discriminated from human elderly control brains. Thus the invention relates to this new Tau species starting from the methionine residue at position 11 said methionine being N-alpha acetylated. The invention also relates to antibody that specifically binds this new tau species, a method of detection of this new Tau species and a method of diagnosis of Tauopathy disorder.

The invention provides antibodies that specifically bind to medin. The antibodies have the capacity to bind to monomeric, misfolded, aggregated, fibril or deposited forms of medin. The antibodies can be used for treating or effecting prophylaxis of diseases associated with medin, medin accumulation or accumulation of medin deposits (e.g., medin amyloidosis). The antibodies can also be used for diagnosing medin amyloidosis and inhibiting or reducing aggregation of medin, among other applications.

The invention disclosed herein relates to peptide inhibitors for transthyretin (TTR) aggregation and methods of inhibiting TTR aggregation, cytotoxicity, and/or TTR amyloidosis. Illustrative embodiments of the invention include a composition of matter comprising at least one peptide designed to inhibit the aggregation of TTR, with this peptide typically being coupled to a heterologous amino acid tag. A pharmaceutically acceptable carrier selected to be compatible with the inhibitory peptide may also be included. A method for blocking or inhibiting the aggregation of transthyretin TTR is also provided. The method comprises combining TTR with an effective amount of an inhibitory peptide or pharmaceutical composition, so that TTR aggregation and/or cytotoxicity is blocked or inhibited

Methods and systems directed to monitoring for the presence or progression of amyloid diseases via detection of amyloid fibrils in a sample from an individual are disclosed. An individual, or sample from an individual, is treated with a reagent including a fluorescent protein. The fluorescent protein in the reagent binds to amyloid fibrils present in the sample. Detecting a signal from fluorescent protein bound to the treated sample indicates the presence of amyloid fibrils in the sample and possible diagnosis of an amyloid disease. The presence and progression of an amyloid disease is monitored by quantifying signal intensity from samples taken over time. Treatment with a reagent including a fluorescent protein inhibits amyloid fibril formation by providing the reagent to an environment including amyloid monomers. The fluorescent protein binds to amyloid oligomers during the lag phase and/or elongation phase of amyloid fibril formation, preventing formation of mature amyloid fibrils.

A light-inducible intracellular protein aggregation system is described herein, which provides invaluable tools to study the role of protein aggregates in proteinopathies and to screen for novel therapeutic compounds. The system generally comprises a cell expressing an alpha-synuclein polypeptide or another proteopathic polypeptide that self-aggregates under pathogenic conditions, operably linked to a photoactivatable polypeptide. Illumination of the photoactivatable polypeptide with light having a wavelength sufficient for photoactivation triggers irreversible accumulation of intracellular protein aggregates comprising the alpha-synuclein polypeptide or proteopathic polypeptide. The intracellular protein aggregates can be made to accumulate in real-time during the illumination, thereby enabling spatiotemporal control of protein aggregation. In some embodiments, the intracellular protein aggregates may exhibit pathologically-relevant properties of those found in disease-associated proteinopathies, such as irreversibility, auto-perpetuation (seeding) activity, and comprising misfolded proteins rich in beta-sheet conformation.