SBIR-STTR Award

Structure Guided Rational Engineering of Novel Dna Reagents.
Award last edited on: 4/12/19

Sponsored Program
STTR
Awarding Agency
NIH : NIGMS
Total Award Amount
$861,373
Award Phase
2
Solicitation Topic Code
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Principal Investigator
Richard D Morgan

Company Information

New England Biolabs Inc (AKA: BIOHELIX~NEB)

240 County Road
Ipswich, MA 01938
   (978) 927-5054
   tinger@neb.com
   www.neb.com

Research Institution

Mount Sinai School of Medicine

Phase I

Contract Number: 1R42GM105097-01
Start Date: 1/1/13    Completed: 6/30/13
Phase I year
2013
Phase I Amount
$99,781
Type II restriction enzymes (REases) are indispensible tools of modern medical research. It has long been a goal of REase manufacturers to be able to offer programmable specificity enzymes, where the sequence recognized and resulting cutting activity can be precisely directed to any desired point in a DNA, as this will offer opportunity for improvement in many applications, from DNA sequencing to gene therapy. We have identified a new family of Type II endonucleases that are amenable for the first time to the rational engineering of new DNA binding and cleavage specificities. To commercialize potentially thousands of new enzymes, we propose a structure-based approach, using crystallographic information to identify specificity determinants, which can then be rationally mutated to generate new nucleases with programmable specificities. In phase I of this application, we will prepare large amounts of several MmeI family enzymes, with the goal of having in hand well-diffracting crystals for two MmeI-family enzymes. In preliminary studies we have obtained well-diffracting cocrystals of MmeI that are highly suitable for structure determination. In Phase II, we will first determine structures for two MmeI family enzymes bound to DNA and then, as part of aim 2, use that information together with structure-based amino acid sequence alignments to generate a code of position-specific amino acids for the engineering of nucleases with programmable specificities. In aim 3, we will generate the potentially thousands of new specificity enzymes using site-directed mutagenesis protocols and, in aim 4, refine our understanding of specificity within this novel family of enzymes through structures of select mutants. An important application of MmeI-like enzymes is in technologies such as Serial Analysis of Gene Expression (SAGE) and paired-end sequence reads in next-generation DNA sequencing methods. Thus, as part of aim 5, we will use the structural information to engineer enzymes with extended reach between the recognition and cleavage sites for improving the quality of SAGE data and for speeding the assembly of genomes in DNA sequencing methods. Engineered Mme-I-like enzymes also offer the potential for targeted therapeutic use with minimal off target cleavage and toxicity. In aim 6, we will use our structural information to generate rare cutting MmeI-like endonucleases for therapeutic use.

Public Health Relevance Statement:


Public Health Relevance:
Type II restriction enzymes (REases) are indispensible tools of modern medical research. We propose to generate and commercialize thousands of new REases with programmable specificities for applications ranging from DNA sequencing to gene therapy.

Project Terms:
Amino Acid Sequence; Amino Acids; base; Binding (Molecular Function); Biotechnology; Code; combinatorial; Complex; Crystallization; Crystallography; Data; DNA; DNA Binding; DNA Restriction Enzymes; DNA Sequence; endonuclease; Engineering; Enzymes; Family; gene therapy; Genes; Genome; Goals; Growth; Hand; improved; Knowledge; Manufacturer Name; Medical Research; Methods; Mutagenesis; mutant; Mutate; New England; next generation; novel; nuclease; Phase; Positioning Attribute; Preparation; Production; Proteins; Protocols documentation; public health relevance; Reading; Reagent; Recombinant DNA; Resolution; Selenomethionine; Sequence Alignment; serial analysis of gene expression; Site; Site-Directed Mutagenesis; Specific qualifier value; Specificity; Speed (motion); Structure; Technology; Testing; Therapeutic Uses; Time; To specify; tool; Toxic effect; Type II site-specific deoxyribonuclease; Work; Zinc Fingers

Phase II

Contract Number: 4R42GM105097-02
Start Date: 1/1/13    Completed: 6/30/15
Phase II year
2013
(last award dollars: 2014)
Phase II Amount
$761,592

Type II restriction enzymes (REases) are indispensible tools of modern medical research. It has long been a goal of REase manufacturers to be able to offer programmable specificity enzymes, where the sequence recognized and resulting cutting activity can be precisely directed to any desired point in a DNA, as this will offer opportunity for improvement in many applications, from DNA sequencing to gene therapy. We have identified a new family of Type II endonucleases that are amenable for the first time to the rational engineering of new DNA binding and cleavage specificities. To commercialize potentially thousands of new enzymes, we propose a structure-based approach, using crystallographic information to identify specificity determinants, which can then be rationally mutated to generate new nucleases with programmable specificities. In phase I of this application, we will prepare large amounts of several MmeI family enzymes, with the goal of having in hand well-diffracting crystals for two MmeI-family enzymes. In preliminary studies we have obtained well-diffracting cocrystals of MmeI that are highly suitable for structure determination. In Phase II, we will first determine structures for two MmeI family enzymes bound to DNA and then, as part of aim 2, use that information together with structure-based amino acid sequence alignments to generate a code of position-specific amino acids for the engineering of nucleases with programmable specificities. In aim 3, we will generate the potentially thousands of new specificity enzymes using site-directed mutagenesis protocols and, in aim 4, refine our understanding of specificity within this novel family of enzymes through structures of select mutants. An important application of MmeI-like enzymes is in technologies such as Serial Analysis of Gene Expression (SAGE) and paired-end sequence reads in next-generation DNA sequencing methods. Thus, as part of aim 5, we will use the structural information to engineer enzymes with extended reach between the recognition and cleavage sites for improving the quality of SAGE data and for speeding the assembly of genomes in DNA sequencing methods. Engineered Mme-I-like enzymes also offer the potential for targeted therapeutic use with minimal off target cleavage and toxicity. In aim 6, we will use our structural information to generate rare cutting MmeI-like endonucleases for therapeutic use.

Public Health Relevance Statement:
Type II restriction enzymes (REases) are indispensible tools of modern medical research. We propose to generate and commercialize thousands of new REases with programmable specificities for applications ranging from DNA sequencing to gene therapy.

Project Terms:
Amino Acid Sequence; Amino Acids; base; Binding (Molecular Function); Biotechnology; Code; combinatorial; Complex; Crystallization; Crystallography; Data; DNA; DNA Binding; DNA Restriction Enzymes; DNA Sequence; endonuclease; Engineering; Enzymes; Family; gene therapy; Genes; Genome; Goals; Growth; Hand; improved; Knowledge; Manufacturer Name; Medical Research; Methods; Mutagenesis; mutant; Mutate; New England; next generation; novel; nuclease; Phase; Positioning Attribute; Preparation; Production; Proteins; Protocols documentation; Reading; Reagent; Recombinant DNA; Resolution; Selenomethionine; Sequence Alignment; serial analysis of gene expression; Site; Site-Directed Mutagenesis; Specific qualifier value; Specificity; Speed (motion); Structure; Technology; Testing; Therapeutic Uses; Time; To specify; tool; Toxic effect; Type II site-specific deoxyribonuclease; Work; Zinc Fingers