Clostridium Bacteria: Harnessing Tumour Necrosis for Targeted Gene Delivery

Necrosis is a common feature of solid tumours that offers a unique opportunity for targeted cancer therapy as it is absent from normal healthy tissues. Tumour necrosis provides an ideal environment for germination of the anaerobic bacterium Clostridium from endospores, resulting in tumour-specific c...

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Veröffentlicht in:	Molecular diagnosis & therapy 2024-03, Vol.28 (2), p.141-151
Hauptverfasser:	Theys, Jan, Patterson, Adam V., Mowday, Alexandra M.
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Sprache:	eng
Schlagworte:	Antibiotics Anticancer properties Bacteria Base Composition Biomedical and Life Sciences Biomedicine Cancer Cancer immunotherapy Cancer Research Cancer therapies Clostridium Clostridium - genetics Clostridium - metabolism CRISPR Enzymes Gene transfer Gene Transfer Techniques Genes Genetic modification Genomes Germination Human Genetics Humans Immune checkpoint inhibitors Immunomodulation Immunotherapy Infections Laboratory Medicine Leading Leading Article Molecular Medicine Necrosis Neoplasms - genetics Neoplasms - therapy Pharmacotherapy Phylogeny Plasmids Prodrugs Prodrugs - metabolism RNA, Ribosomal, 16S Sequence Analysis, DNA Solid tumors Strains (organisms) Therapy Toxicity Transgenes Tumor Microenvironment Tumor necrosis factor-α Tumors
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description	Necrosis is a common feature of solid tumours that offers a unique opportunity for targeted cancer therapy as it is absent from normal healthy tissues. Tumour necrosis provides an ideal environment for germination of the anaerobic bacterium Clostridium from endospores, resulting in tumour-specific colonisation. Two main species, Clostridium novyi -NT and Clostridium sporogenes , are at the forefront of this therapy, showing promise in preclinical models. However, anti-tumour activity is modest when used as a single agent, encouraging development of Clostridium as a tumour-selective gene delivery system. Various methods, such as allele-coupled exchange and CRISPR–cas9 technology, can facilitate the genetic modification of Clostridium , allowing chromosomal integration of transgenes to ensure long-term stability of expression. Strains of Clostridium can be engineered to express prodrug-activating enzymes, resulting in the generation of active drug selectively in the tumour microenvironment (a concept termed Clostridium -directed enzyme prodrug therapy). More recently, Clostridium strains have been investigated in the context of cancer immunotherapy, either in combination with immune checkpoint inhibitors or with engineered strains expressing immunomodulatory molecules such as IL-2 and TNF-α. Localised expression of these molecules using tumour-targeting Clostridium strains has the potential to improve delivery and reduce systemic toxicity. In summary, Clostridium species represent a promising platform for cancer therapy, with potential for localised gene delivery and immunomodulation selectively within the tumour microenvironment. The ongoing clinical progress being made with C. novyi -NT, in addition to developments in genetic modification techniques and non-invasive imaging capabilities, are expected to further progress Clostridium as an option for cancer treatment.
doi_str_mv	10.1007/s40291-024-00695-0
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More recently, Clostridium strains have been investigated in the context of cancer immunotherapy, either in combination with immune checkpoint inhibitors or with engineered strains expressing immunomodulatory molecules such as IL-2 and TNF-α. Localised expression of these molecules using tumour-targeting Clostridium strains has the potential to improve delivery and reduce systemic toxicity. In summary, Clostridium species represent a promising platform for cancer therapy, with potential for localised gene delivery and immunomodulation selectively within the tumour microenvironment. 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Tumour necrosis provides an ideal environment for germination of the anaerobic bacterium Clostridium from endospores, resulting in tumour-specific colonisation. Two main species, Clostridium novyi -NT and Clostridium sporogenes , are at the forefront of this therapy, showing promise in preclinical models. However, anti-tumour activity is modest when used as a single agent, encouraging development of Clostridium as a tumour-selective gene delivery system. Various methods, such as allele-coupled exchange and CRISPR–cas9 technology, can facilitate the genetic modification of Clostridium , allowing chromosomal integration of transgenes to ensure long-term stability of expression. Strains of Clostridium can be engineered to express prodrug-activating enzymes, resulting in the generation of active drug selectively in the tumour microenvironment (a concept termed Clostridium -directed enzyme prodrug therapy). More recently, Clostridium strains have been investigated in the context of cancer immunotherapy, either in combination with immune checkpoint inhibitors or with engineered strains expressing immunomodulatory molecules such as IL-2 and TNF-α. Localised expression of these molecules using tumour-targeting Clostridium strains has the potential to improve delivery and reduce systemic toxicity. In summary, Clostridium species represent a promising platform for cancer therapy, with potential for localised gene delivery and immunomodulation selectively within the tumour microenvironment. 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More recently, Clostridium strains have been investigated in the context of cancer immunotherapy, either in combination with immune checkpoint inhibitors or with engineered strains expressing immunomodulatory molecules such as IL-2 and TNF-α. Localised expression of these molecules using tumour-targeting Clostridium strains has the potential to improve delivery and reduce systemic toxicity. In summary, Clostridium species represent a promising platform for cancer therapy, with potential for localised gene delivery and immunomodulation selectively within the tumour microenvironment. 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subjects	Antibiotics Anticancer properties Bacteria Base Composition Biomedical and Life Sciences Biomedicine Cancer Cancer immunotherapy Cancer Research Cancer therapies Clostridium Clostridium - genetics Clostridium - metabolism CRISPR Enzymes Gene transfer Gene Transfer Techniques Genes Genetic modification Genomes Germination Human Genetics Humans Immune checkpoint inhibitors Immunomodulation Immunotherapy Infections Laboratory Medicine Leading Leading Article Molecular Medicine Necrosis Neoplasms - genetics Neoplasms - therapy Pharmacotherapy Phylogeny Plasmids Prodrugs Prodrugs - metabolism RNA, Ribosomal, 16S Sequence Analysis, DNA Solid tumors Strains (organisms) Therapy Toxicity Transgenes Tumor Microenvironment Tumor necrosis factor-α Tumors
title	Clostridium Bacteria: Harnessing Tumour Necrosis for Targeted Gene Delivery
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