SBIR-STTR Award

Engineered Bacteriophage as a Platform to Deliver Nucleic Acid Based Therapeutics to Bacteria to Disperse Biofilms in Implant-Associated Infections Such as Prosthetic Joint Infections
Award last edited on: 11/13/2019

Sponsored Program
SBIR
Awarding Agency
NIH : NIAID
Total Award Amount
$263,500
Award Phase
1
Solicitation Topic Code
NIAID
Principal Investigator
Jeffrey A Radding

Company Information

Enbiotix Inc

197 West Springfield Street
Boston, MA 02118
   (508) 400-1856
   info@enbiotix.com
   www.enbiotix.com
Location: Single
Congr. District: 07
County: Suffolk

Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2016
Phase I Amount
$263,500
Bacteriophages are viruses that specifically and solely infect bacteria and are a natural platform delivery system of genetic information, encoded by nucleic acids, to bacteria. Lytic bacteriophages do not integrate their DNA into the bacterial chromosome, but replicate independently and ultimately kill their host bacteria. In the early 1900's bacteriophages were used to fight infections in humans, but largely fell to the wayside after the discovery of antibiotics in the 1920's. Only in Eastern Europe and the former Soviet Republics are bacteriophages still considered as effective therapeutic agents. With the antibiotic armamentarium currently challenged by the combination of increasing antibiotic resistance and a dearth of new investment and discovery in new classes of antibiotics, natural bacteriophage therapy is experiencing a renaissance. Along with this renaissance in bacteriophage therapy, advances in systems and synthetic biology now enable exquisite engineering of bacteriophage genomes to introduce nucleic acid therapeutics to alter the physiology, pathogenicity, virulence and antibiotic sensitivity of targeted bacterial species. Bacteriophage can thus be designed to deliver genetic payloads to achieve specific desired effects, such as enhancing antibiotic killing by genetic repression of DNA repair mechanisms, the self-generation of antimicrobial peptides and proteins and expression of enzymes to degrade bacterial biofilms. Biofilm-associated infections are particularly difficult to treat due to the physical and physiological barriers biofilms pose to antimicrobial agents and host defenses. Biofilms are central to the pathogenesis of many serious clinical infections, and often colonize foreign-body surfaces, such as in prosthetic joint infections (PJI). The annual cost of PJI to US hospitals in 2009 was $566M and is projected to increase to $1.62B by 2020. Much of this cost is for surgical replacement of infected prostheses due to the failure of medical treatment. Failure of medical treatment is most problematic in device infections caused by S. aureus, due to its virulence and rapid biofilm formation. This proposal seeks to improve medical treatment for PJI, caused by S. aureus, by utilizing engineered bacteriophage to deliver nucleic acid therapeutics to the bacteria encoding biofilm-degrading enzymes to disperse the protective biofilm. Removal of the biofilm will reduce the inherent tolerance of bacteria to antimicrobial therapy, improve medical treatment outcomes and thereby reduce surgical intervention, prosthesis replacement and the associated health costs and patient burden.

Public Health Relevance Statement:
Project Narrative Bacteriophages are viruses that infect and kill only bacteria. Using synthetic biology, bacteriophages are a natural platform for delivering engineered genes to bacteria to alter their physiology and function to make bacteria more sensitive to antibiotics. This project will engineer a bacteriophage to deliver gene payloads encoding enzymes to remove the biofilm, a surface-associated aggregate of bacterial cells in a gelatin-like “slime”, that protects bacteria from antibiotics and host defense on prosthetic joints (i.e. knees and hips) infected with Staphylococcus aureus, as an adjuvant to standard antibiotic therapy.

NIH Spending Category:
Assistive Technology; Biodefense; Bioengineering; Emerging Infectious Diseases; Genetics; Infectious Diseases; Rehabilitation

Project Terms:
abstracting; Adjuvant; Animal Model; Antibiotic Resistance; Antibiotic Therapy; Antibiotics; antimicrobial; antimicrobial drug; antimicrobial peptide; Bacteria; Bacterial Artificial Chromosomes; Bacterial Chromosomes; Bacterial Counts; Bacteriophages; base; Biological Assay; Body Surface; Cells; Chloramphenicol; Chloramphenicol Resistance; Clinical; Colony-forming units; cost; design; Devices; DNA; DNA Repair; Eastern Europe; Electroporation; Engineered Gene; Engineering; Enzymes; Epitopes; Escherichia coli; Excision; experience; extracellular; Failure; fighting; Fluorescence; Foreign Bodies; Gelatin; gene product; Generations; Genes; Genetic; genetic information; Genome; Gentian Violet; Goals; Green Fluorescent Proteins; Health Care Costs; Hip region structure; Hospitals; Host Defense; Human; Immunoblotting; Implant; implantable device; improved; In Vitro; Individual; Infection; Investments; joint infection; Joint Prosthesis; killings; Knee; Lytic; Measures; Medical; medical implant; Methodology; Microbial Biofilms; Nucleic Acids; Operative Surgical Procedures; Pathogenesis; Pathogenicity; Patients; Phase; Physiological; Physiology; Predisposition; Production; promoter; Prosthesis; protein expression; prototype; Recovery; Renaissance; Repression; Resistance; Sequence Analysis; Site; Small Business Innovation Research Grant; Stainless Steel; Staphylococcus aureus; Structure; Surface; synthetic biology; System; Teflon; Testing; Therapeutic; Therapeutic Agents; Time; TimeLine; Titania; Titanium; Treatment outcome; Vancomycin; Virulence; Virus

Phase II

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Start Date: ----    Completed: ----
Phase II year
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Phase II Amount
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