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Bacterial therapy

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Design of engineered live bacterial therapeutics[1]

Bacterial therapy is the therapeutic use of bacteria to treat diseases. Bacterial therapeutics are living medicines, and may be wild type bacteria (often in the form of probiotics) or bacteria that have been genetically engineered to possess therapeutic properties that is injected into a patient.[2][3] Other examples of living medicines include cellular therapeutics (including immunotherapeutics), activators of anti-tumor immunity, or synergizing with existing tools and approaches. and phage therapeutics, or as delivery vehicles for treatment, diagnosis, or imaging, complementing or synergizing with existing tools and approaches.

Development

Workflow for developing engineered strains.[1]

Development of bacterial therapeutics is an extremely active research area in the fields of synthetic biology and microbiology.[4][5][6][7][8][9][1][10][11] Currently, there is a large focus on: 1) identifying bacteria that naturally produce therapeutic effects (for example, probiotic bacteria), and 2) genetically programming bacteria to produce therapeutic effects.[12][13][14]

Design

Several aspects require consideration during the design of an engineered bacterial therapeutic. The selection of a chassis organism can be guided by the desired site of activity and pharmacokinetic properties of the chassis, as well as manufacturing feasibility. The design of genetic circuits may also be influenced by the circuit's effectors, pragmatic concerns regarding inducer compounds, and the genetic stability of regulatory circuits. Critically, the design of an engineered bacterial drug may also be constrained by considerations for the needs of patients.[citation needed]

Optimal strain design often requires a balance between strain suitability for function in the target microenvironment and concerns for feasibility of manufacturing and clinical development.[1]

The development workflow should incorporate technologies for optimizing strain potency, as well as predictive in vitro and in vivo assays, as well quantitative pharmacology models, to maximize translational potential for patient populations.[1]

Applications

Cancer therapy

Schematic of therapeutic bacteria strategies against hypoxic tumors
Mechanisms by which bacteria target tumors

There is tremendous interest in using bacteria as a therapy to treat tumors. In particular, tumor-homing bacteria that thrive in hypoxic environments are particularly attractive for this purpose, as they will tend to migrate to, invade (through the leaky vasculature in the tumor microenvironment) and colonize tumors. This property tends to increase their residence time in the tumor, giving them longer to exert their therapeutic effects, in contrast to other bacteria that would be quickly cleared by the immune system.[15][16][17] In addition, colonized bacteria can lyze the tumor, activate anti-tumor immune response, can be engineered as a delivery vehicle for anti-cancer therapeutics and may have the potential as contrast agents for cancer imaging. Microbial-based cancer therapy may offer an opportunity to address the issue of global cancer therapy disparity and introduce more suitable cancer immunotherapy approach to low- and middle-income countries.[18]

Mechanism

Genetically engineered probiotics as living medicines to treat intestinal inflammation
Bacteria involved in causing and treating cancers

After systemic administration, bacteria localize to the tumor microenvironment. The interactions between bacteria, cancer cells, and the surrounding microenvironment cause various alterations in tumor-infiltrating immune cells, cytokines, and chemokines, which further facilitate tumor regression. ① Bacterial toxins from S. Typhimurium, Listeria, and Clostridium can kill tumor cells directly by inducing apoptosis or autophagy. Toxins delivered via Salmonella can upregulate Connexin 43 (Cx43), leading to bacteria-induced gap junctions between the tumor and dendritic cells (DCs), which allow cross-presentation of tumor antigens to the DCs. ② Upon exposure to tumor antigens and interaction with bacterial components, DCs secrete robust amounts of the proinflammatory cytokine IL-1β, which subsequently activates CD8+ T cells. ③ The antitumor response of the activated CD8+ T cells is further enhanced by bacterial flagellin (a protein subunit of the bacterial flagellum) via TLR5 activation. The perforin and granzyme proteins secreted by activated CD8+ T cells efficiently kill tumor cells in primary and metastatic tumors. ④ Flagellin and TLR5 signaling also decreases the abundance of CD4+ CD25+ regulatory T (Treg) cells, which subsequently improves the antitumor response of the activated CD8+ T cells. ⑤ S. Typhimurium flagellin stimulates NK cells to produce interferon-γ (IFN-γ), an important cytokine for both innate and adaptive immunity. ⑥ Listeria-infected MDSCs shift into an immune-stimulating phenotype characterized by increased IL-12 production, which further enhances the CD8+ T and NK cell responses. ⑦ Both S. Typhimurium and Clostridium infection can stimulate significant neutrophil accumulation. Elevated secretion of TNF-α and TNF-related apoptosis-inducing ligand (TRAIL) by neutrophils enhances the immune response and kills tumor cells by inducing apoptosis. ⑧ The macrophage inflammasome is activated through contact with bacterial components (LPS and flagellin) and Salmonella-damaged cancer cells, leading to elevated secretion of IL-1β and TNF-α into the tumor microenvironment. NK cell: natural killer cell. Treg cell: regulatory T cell. MDSCs: myeloid-derived suppressor cells. P2X7 receptor: purinoceptor 7-extracellular ATP receptor. LPS: lipopolysaccharide[15]

Microbiome engineering

There is considerable interest in using bacterial therapeutics to alter human gastrointestinal microbiota, which would be helpful in treating diseases like small intestinal bacterial overgrowth, gut dysbiosis associated with the pathogenesis of food allergy,[19] and other forms of dysbiosis.

See also

References

  1. ^ a b c d e Charbonneau MR, Isabella VM, Li N, Kurtz CB (April 2020). "Developing a new class of engineered live bacterial therapeutics to treat human diseases". Nature Communications. 11 (1): 1738. Bibcode:2020NatCo..11.1738C. doi:10.1038/s41467-020-15508-1. PMC 7142098. PMID 32269218.
  2. ^ Sample I (16 January 2019). "'Living medicine' helps make toxic ammonia breakthrough". The Guardian.
  3. ^ Whitaker W, Shepherd E, DeLoache WC, Russ ZN (2019). Engineering Living Medicines for Chronic Diseases. Microbiome Engineering.
  4. ^ Weber W, Fussenegger M (November 2011). "Emerging biomedical applications of synthetic biology". Nature Reviews. Genetics. 13 (1): 21–35. doi:10.1038/nrg3094. PMC 7097403. PMID 22124480.
  5. ^ Fischbach MA, Bluestone JA, Lim WA (April 2013). "Cell-based therapeutics: the next pillar of medicine". Science Translational Medicine. 5 (179): 179ps7. doi:10.1126/scitranslmed.3005568. PMC 3772767. PMID 23552369.
  6. ^ Kitada T, DiAndreth B, Teague B, Weiss R (February 2018). "Programming gene and engineered-cell therapies with synthetic biology". Science. 359 (6376): eaad1067. doi:10.1126/science.aad1067. PMC 7643872. PMID 29439214.
  7. ^ McCarty N (18 December 2018). "Why 2018 Was the Year of 'Living' Medicine". Medium. Retrieved 5 April 2020.
  8. ^ Kelly J (12 June 2019). "The Era of Living Medicines". Ginkgo Bioworks. Retrieved 5 April 2020.
  9. ^ Kurtz CB, Millet YA, Puurunen MK, Perreault M, Charbonneau MR, Isabella VM, et al. (January 2019). "An engineered E. coli Nissle improves hyperammonemia and survival in mice and shows dose-dependent exposure in healthy humans". Science Translational Medicine. 11 (475): eaau7975. doi:10.1126/scitranslmed.aau7975. PMID 30651324. S2CID 58031579.
  10. ^ "Gene Circuits Empower Next-Generation Cell and Gene Therapies". GEN - Genetic Engineering and Biotechnology News. 1 February 2020. Retrieved 5 April 2020.
  11. ^ Gurbatri, Candice R.; Arpaia, Nicholas; Danino, Tal (25 November 2022). "Engineering bacteria as interactive cancer therapies". Science. 378 (6622): 858–864. Bibcode:2022Sci...378..858G. doi:10.1126/science.add9667. PMID 36423303. S2CID 253839557.
  12. ^ Triassi A (2 April 2019). "Why now is the time for programmable living medicines: insights from Jim Collins, Aoife Brennan, and Jason Kelly". SynBioBeta. Archived from the original on 17 April 2019.
  13. ^ Costa K (20 February 2019). "Living medicines: Ginkgo's machine to disrupt the pharma industry". SynBioBeta. Archived from the original on 15 December 2019.
  14. ^ Sieow BF, Wun KS, Yong WP, Hwang IY, Chang MW (May 2021). "Tweak to Treat: Reprograming Bacteria for Cancer Treatment". Trends in Cancer. 7 (5): 447–464. doi:10.1016/j.trecan.2020.11.004. PMID 33303401.
  15. ^ a b Duong MT, Qin Y, You SH, Min JJ (December 2019). "Bacteria-cancer interactions: bacteria-based cancer therapy". Experimental & Molecular Medicine. 51 (12): 1–15. doi:10.1038/s12276-019-0297-0. PMC 6906302. PMID 31827064.
  16. ^ Sedighi M, Zahedi Bialvaei A, Hamblin MR, Ohadi E, Asadi A, Halajzadeh M, et al. (June 2019). "Therapeutic bacteria to combat cancer; current advances, challenges, and opportunities". Cancer Medicine. 8 (6): 3167–3181. doi:10.1002/cam4.2148. PMC 6558487. PMID 30950210.
  17. ^ Song S, Vuai MS, Zhong M (December 2018). "The role of bacteria in cancer therapy - enemies in the past, but allies at present". Infectious Agents and Cancer. 13 (1): 9. doi:10.1186/s13027-018-0180-y. PMC 5856380. PMID 29568324.
  18. ^ Salicrup LA, Ossandon M, Prickril B, Rasooly A (June 2020). "Bugs as Drugs, potential self-regenerated innovative cancer therapeutics approach for global health". Journal of Global Health. 10 (1): 010311. doi:10.7189/jogh.10.010311. PMC 7100862. PMID 32257138.
  19. ^ Rachid R, Stephen-Victor E, Chatila TA (March 2021). "The microbial origins of food allergy". The Journal of Allergy and Clinical Immunology. 147 (3): 808–813. doi:10.1016/j.jaci.2020.12.624. PMC 8096615. PMID 33347905.