The present inventions describes a Facile Accelerated Specific Therapeutic (FAST) pipeline to rapidly design, built and test peptide nucleic acid treatments against mammalian or microbial genes of interest. The invention may include a bioinformatics application for facile and accelerated high throughput design of peptide nucleic acids (PNAs) that act as inhibitors of expression of specific targeted genes by binding to their mRNA to block translation, or PNA activators that can activate expression of target genes by binding to the respective promoter regions and recruitment of transcriptional activators. The invention may further involve automated and high throughput parallel synthesis of a PNA inhibitor/activator library for generation of on-site therapeutic molecules, which may reduce storage requirements, and the development of efficient delivery of therapeutic PNAs to host cells to overcome challenges of transport, toxicity, and bioavailability. The invention may further involve the testing of designed and built PNAs in a high throughput manner in a relevant infection, or mammalian cell culture model. The proposed invention may allow identification of important gene targets, and quickly generate translatable therapies that can be tested under host conditions, and most importantly develop a countermeasure platform that can be deployed on-site in the future to generate therapies in short time scales.

The present inventions describes a Facile Accelerated Specific Therapeutic (FAST) pipeline to rapidly design, built and test peptide nucleic acid treatments against mammalian or microbial genes of interest. The invention may include a bioinformatics application for facile and accelerated high throughput design of peptide nucleic acids (PNAs) that act as inhibitors of expression of specific targeted genes by binding to their mRNA to block translation, or PNA activators that can activate expression of target genes by binding to the respective promoter regions and recruitment of transcriptional activators. The invention may further involve automated and high throughput parallel synthesis of a PNA inhibitor/activator library for generation of on-site therapeutic molecules, which may reduce storage requirements, and the development of efficient delivery of therapeutic PNAs to host cells to overcome challenges of transport, toxicity, and bioavailability. The invention may further involve the testing of designed and built PNAs in a high throughput manner in a relevant infection, or mammalian cell culture model. The proposed invention may allow identification of important gene targets, and quickly generate translatable therapies that can be tested under host conditions, and most importantly develop a countermeasure platform that can be deployed on-site in the future to generate therapies in short time scales.

A method and system for calculating the free energy difference between a target state and a reference state. The method includes determining one or more intermediate states using a coupling parameter, performing molecular simulations to obtain ensembles of micro-states for each of the system states, and calculating the free energy difference by an analysis of the ensembles of micro-states of the system states. The method can be particularly suited for calculating physical or non-physical transformation of molecular systems such as ring-opening, ring-closing, and other transformations involving bond breaking and/or formation. A soft bond potential dependent on a bond stretching component of the coupling parameter and different from the conventional harmonic potential is used in the molecular simulations of the system states for the bond being broken or formed during the transformation.

A method and system for calculating the free energy difference between a target state and a reference state. The method includes determining one or more intermediate states using a coupling parameter, performing molecular simulations to obtain ensembles of micro-states for each of the system states, and calculating the free energy difference by an analysis of the ensembles of micro-states of the system states. The method can be particularly suited for calculating physical or non-physical transformation of molecular systems such as ring-opening, ring-closing, and other transformations involving bond breaking and/or formation. A soft bond potential dependent on a bond stretching component of the coupling parameter and different from the conventional harmonic potential is used in the molecular simulations of the system states for the bond being broken or formed during the transformation.

Disclosed is a target-based drug screening method using inverse quantitative structure-(drug)performance relationships (QSPR) analysis and molecular dynamics simulation. The method includes modeling a molecular structure of a test compound group against a target molecule, obtaining a quantitative structure-(drug)performance relationships (QSPR) of the test compound group, acquiring the optimal pharmacophore of a novel target-based drug through a numerical inversion of the QSPR, and selecting drug candidates having a molecular structure similar to the optimum pharmacophore from the test compound group.

Disclosed is a target-based drug screening method using inverse quantitative structure-(drug)performance relationships (QSPR) analysis and molecular dynamics simulation. The method includes modeling a molecular structure of a test compound group against a target molecule, obtaining a quantitative structure-(drug)performance relationships (QSPR) of the test compound group, acquiring the optimal pharmacophore of a novel target-based drug through a numerical inversion of the QSPR, and selecting drug candidates having a molecular structure similar to the optimum pharmacophore from the test compound group.

This invention relates to the identification of peptide binding to ligands, and in particular to identification of epitopes expressed by microorganisms and by mammalian cells. The present invention provides polypeptides comprising the epitopes, and vaccines, antibodies and diagnostic products that utilize or are developed using the epitopes.

This invention relates to the identification of peptide binding to ligands, and in particular to identification of epitopes expressed by microorganisms and by mammalian cells. The present invention provides polypeptides comprising the epitopes, and vaccines, antibodies and diagnostic products that utilize or are developed using the epitopes.

The disclosure provides a process of designing and optimizing supramolecular therapeutics. The disclosure also provides a method for designing and optimizing antibody drug conjugates.

The disclosure provides a process of designing and optimizing supramolecular therapeutics. The disclosure also provides a method for designing and optimizing antibody drug conjugates.