The invention relates to an in silico screening method to identify candidate excipients for reducing aggregation of a protein in a formulation. The method combines computational molecular modeling and molecular dynamics simulations to identify sites on a protein where non-specific self-interaction and interaction of different test excipients may occur, determine the relative binding energies of such interactions, and select one or more test excipients that meet specified interaction criteria for use as candidate excipients in empirical screening studies.

Methods of designing a polynucleotide sequence for expressing a polypeptide-of-interest in a cell are provided. Also provided are artificial transcript sequences generated according to the present teachings. Further provided are methods of estimating the adaptiveness of a transcript sequence encoding a polypeptide-of-interest to a gene expression machinery in a cell.

Methods of designing a polynucleotide sequence for expressing a polypeptide-of-interest in a cell are provided. Also provided are artificial transcript sequences generated according to the present teachings. Further provided are methods of estimating the adaptiveness of a transcript sequence encoding a polypeptide-of-interest to a gene expression machinery in a cell.

The disclosure relates to novel selective Grp94 inhibitors, compositions comprising an effective amount of such compounds, and methods to treat or prevent a condition, such as cancer, comprising administering to an animal in need thereof an effective amount of such compounds.

The disclosure relates to novel selective Grp94 inhibitors, compositions comprising an effective amount of such compounds, and methods to treat or prevent a condition, such as cancer, comprising administering to an animal in need thereof an effective amount of such compounds.

Provided herein are methods and systems of molecular profiling of diseases, such as cancer. In some embodiments, the molecular profiling can be used to identify treatments for a disease, such as treatments that were not initially identified as a treatment for the disease or not expected to be a treatment for a particular disease.

Provided herein are methods and systems of molecular profiling of diseases, such as cancer. In some embodiments, the molecular profiling can be used to identify treatments for a disease, such as treatments that were not initially identified as a treatment for the disease or not expected to be a treatment for a particular disease.

A method of screening is provided. In certain embodiments, the method involves a) obtaining the nucleotide sequences of: i. a heavy chain-encoding nucleic acid that encodes the variable domain of a heavy chain of a first antibody of an animal; and ii. a light chain-encoding nucleic acid that encodes the variable domain of a light chain of the first antibody; b) obtaining nucleotide sequences of cDNAs encoding at least a portion of the antibody repertoire of the animal; c) computationally screening the sequences obtained in b) to identify heavy and light chain sequences that are related by lineage to the heavy and light chain sequences of a); and d) testing at least one pair of the heavy and light chain sequences identified in c) to identify a second antibody that binds to the same antigen as the first antibody.

A method of screening is provided. In certain embodiments, the method involves a) obtaining the nucleotide sequences of: i. a heavy chain-encoding nucleic acid that encodes the variable domain of a heavy chain of a first antibody of an animal; and ii. a light chain-encoding nucleic acid that encodes the variable domain of a light chain of the first antibody; b) obtaining nucleotide sequences of cDNAs encoding at least a portion of the antibody repertoire of the animal; c) computationally screening the sequences obtained in b) to identify heavy and light chain sequences that are related by lineage to the heavy and light chain sequences of a); and d) testing at least one pair of the heavy and light chain sequences identified in c) to identify a second antibody that binds to the same antigen as the first antibody.

The present invention is directed to a method for generating a library of antigen binding molecules for screening for binding to an epitope of interest, said method comprising: a. selecting a template antigen-binding molecule from a set of possible template antigen binding molecules wherein said selected template does not specifically bind the epitope of interest but is known to specifically bind another epitope; b. selecting at least one residue position in said template antigen-binding molecule for mutation; and c. selecting at least one variant residue to substitute at the at least one residue position selected in b; such that a library containing a plurality of variants of said template is generated.