Tumor-targeting engineered probiotic Escherichia coli Nissle 1917 inhibits colorectal tumorigenesis and modulates gut microbiota homeostasis in mice

Exploring preventive and treatment strategies for oral cancer: Modulation of signaling pathways and microbiota by probiotics

The evidence suggests that the microbiome plays a crucial role in cancer development. The oral cavity has many microorganisms that can influence oral cancer progression. Understanding the mechanisms and signaling pathways of the oral, gum, and teeth microbiome in tumor progression can lead to new treatment strategies. Probiotics, which are friendly microorganisms, have shown potential as anti-cancer agents. These positive characteristics of probiotic strains make them suitable for cancer prevention or treatment. The oral-gut microbiome axis supports health and homeostasis, and imbalances in the oral microbiome can disrupt immune signaling pathways, epithelial barriers, cell cycles, apoptosis, genomic stability, angiogenesis, and metabolic processes. Changes in the oral microbiome in oral cancer may suggest using probiotics-based treatments for their direct or indirect positive roles in cancer development, progression, and metastasis, specifically oral squamous cell carcinoma (OSCC). Here, reported relationships between probiotics, oral microbiota, and oral cancer are summarized.

Enhancing the persistence of engineered biotherapeutics in the gut: Adhesion, glycan metabolism, and environmental resistance

Engineered live biotherapeutic products (eLBPs) are receiving increasing attention as next-generation therapeutics to treat a variety of diseases with high specificity and effectiveness. Despite their potential, eLBPs face challenges, such as limited colonization, competition with native microbiota, nutrient depletion, and susceptibility to gastrointestinal stresses, which ultimately reduce their persistence in the gut and hinder their therapeutic efficacy. This review examines the key strategies to enhance the persistence and activity of eLBPs in the gut environment. First, methods to strengthen the adhesion capacity of eLBPs are discussed, including genetic engineering to express adhesins and chemical surface modifications to improve their binding to mucus and epithelial cells. Second, strategies to improve the ability of eLBPs to efficiently use mucin-derived sugars, which are continuously secreted by intestinal epithelial cells, were highlighted. These strategies involve the introduction and optimization of glycan-degrading enzymes and metabolic pathways for key mucin sugars, such as N-acetylglucosamine, galactose, and sialic acid, to support sustained energy production and enhance gut colonization. Third, strategies to improve the resistance of eLBPs against environmental stress are discussed, including genetic modifications to stabilize cell membranes, enhancement of ion pump activity, overexpression of stress-response proteins, and encapsulation techniques to provide protection. The implementation of these strategies can address challenges related to gut colonization by eLBPs, thereby enhancing their metabolic activity and enabling sustained and efficient secretion of therapeutic molecules. This review offers a comprehensive framework for developing and optimizing eLBPs, paving the way for their successful clinical application with enhanced effectiveness in treating gastrointestinal and systemic diseases.

Advances in understanding therapeutic mechanisms of probiotics in cancer management, with special emphasis on breast cancer: A comprehensive review

The increasing global prevalence of cancer, particularly breast cancer, necessitates the development of innovative therapeutic strategies. Probiotics, proficient in promoting gut health, have emerged as promising candidates for cancer treatment due to their immunomodulatory and potential anticancer properties. This review focuses on the therapeutic mechanisms of probiotics in breast cancer, examining their anticancer efficacy through metabolic, immune, and molecular mechanisms. Probiotics enhance cancer therapies, minimize side effects, and offer new adjuvant approaches in oncology. Recent advancements discussed in the review include the utilization of probiotics as oncolytic gene expression systems and drug delivery vectors, as well as personalized probiotic interventions aimed at optimizing cancer therapy. Clinical studies are critically evaluated, highlighting both the outcomes and limitations of probiotic use in cancer patients, particularly those suffering from breast cancer. Additionally, the review explores factors influencing anticancer effects of probiotics, focusing on their role in modulating the tumor microenvironment. Challenges in translating preclinical findings to clinical practice are discussed, along with future research directions, focusing on the relationship between probiotics, the microbiome, and cancer treatment. Ultimately, this review advocates for further investigation into the therapeutic potential of probiotics in breast cancer, aiming to harness their benefits in oncology.

The Encapsulation Strategies for Targeted Delivery of Probiotics in Preventing and Treating Colorectal Cancer: A Review

Colorectal cancer (CRC) ranks as the third most prevalent cancer worldwide. It is associated with imbalanced gut microbiota. Probiotics can help restore this balance, potentially reducing the risk of CRC. However, the hostile environment and constant changes in the gastrointestinal tract pose significant challenges to the efficient delivery of probiotics to the colon. Traditional delivery methods are often insufficient due to their low viability and lack of targeting. To address these challenges, researchers are increasingly focusing on innovative encapsulation technologies. One such approach is single-cell encapsulation, which involves applying nanocoatings to individual probiotic cells. This technique can improve their resistance to the harsh gastrointestinal environment, enhance mucosal adhesion, and facilitate targeted release, thereby increasing the effectiveness of probiotic delivery. This article reviews the latest developments in probiotic encapsulation methods for targeted CRC treatment, emphasizing the potential benefits of emerging single-cell encapsulation techniques. It also analyzes and compares the advantages and disadvantages of current encapsulation technologies. Furthermore, it elucidates the underlying mechanisms through which probiotics can prevent and treat CRC, evaluates the efficacy and safety of probiotics in CRC treatment and adjuvant therapy, and discusses future directions and potential challenges in the targeted delivery of probiotics for CRC treatment and prevention.

Anti-tumor activity of an αPD-L1-PE38 immunotoxin delivered by engineered Nissle 1917

Although immune checkpoint inhibitors specifically targeting the PD-1/PD-L1 axis have exhibited remarkable clinical success, they are not uniformly effective across all patient cohorts. Immunotoxins, a novel class of cancer therapeutics, offering a promising alternative. PD-L1, which is also present in certain normal tissues, limits its suitability as an ideal target for immunotoxins. The probiotic strain of E. coli Nissle 1917 (EcN) could target and colonize to solid tumors, which positions it as a promising candidate for tumor tissue-specific delivery of anti-tumor proteins. In this study, we constructed a PD-L1-targeted immunotoxin, designated as αPD-L1-PE38, by fusing an anti-PD-L1 nanobody and a clinically validated PE38 toxin. This immunotoxin exhibited potent cytotoxic activity against tumor cells while showed slightly cytotoxic activity against normal cells. To effectively deliver the αPD-L1-PE38 to tumor tissues, we engineered the EcN strain to release the immunotoxin induced by L-arabinose. Upon induction, the immunotoxin was efficiently secreted, and exhibited robust anti-tumor activity mainly by inducing cell apoptosis both in vitro and in vivo. Furthermore, we enhanced the immunotoxin's affinity for PD-L1 by optimizing the linker between the nanobody and PE38 toxin. The engineered EcN expressing the optimized immunotoxin, achieved superior anti-tumor activity. Collectively, our study suggests that the delivery of immunotoxins through live bacteria to improve safety and efficacy is a promising option in cancer therapeutics.

Engineered probiotic E.coli Nissle 1917 for release PTEN to improve the tumor microenvironment and suppress tumor growth

The cancer is one of the diseases of serious threat to people's health and life nowadays. But heterogeneity, drug resistance and treatment side effects of cancer, traditional treatments still have limitations. Tumor-targeting probiotics with a well-established Biosafety and efficient targeting as a delivery vectors to deliver anticancer genes or antitumor drugs to tumor microenvironment has attracted much attention in cancer therapies. In this study, E.coil Nissle 1917 (EcN) was utilized to deliver eukaryotic anti-tumor protein PTEN to tumor microenvironment and suppress tumor growth. Therefore, the EcN (PTEN) was developed. Our results demonstrated that EcN (PTEN) could colonize the tumor site accurately and inhibit the growth of colorectal cancer cells in tumor-bearing mice. It is worth noting that the tumor microenvironment of the treated mice showed significant recruitment of and M1 macrophages, neutrophils and T lymphocytes. No toxicity was observed in the normal tissues during the experiments. This research show the probiotic EcN(PTEN) holds the promise of becoming a powerful weapon against cancer and expected to provide more effective treatments for cancer patients.

Targeting the gut microbiota: a new strategy for colorectal cancer treatment

BACKGROUND

How to reduce the high incidence rate and mortality of colorectal cancer (CRC) effectively is the focus of current research. Endoscopic treatment of early-stage CRC and colorectal adenomas (CAC) has a high success rate, but although several treatments are available for advanced CRC, such as surgery, radiotherapy, chemotherapy, and immunotherapy, the 5-year survival rate remains low. In view of the high incidence rate and mortality of CRC, early rational drug prevention for high-risk groups and exploration of alternative treatment modalities are particularly warranted. Gut microbiota is the target of and interacts with probiotics, prebiotics, aspirin, metformin, and various Chinese herbal medicines (CHMs) for the prevention of CRC. In addition, the anti-cancer mechanisms of probiotics differ widely among bacterial strains, and both bacterial strains and their derivatives and metabolites have been found to have anti-cancer effects. Gut microbiota plays a significant role in early drug prevention of CRC and treatment of CRC in its middle and late stages, targeting gut microbiota may be a new strategy for colorectal cancer treatment.

Escherichia coli on colorectal cancer: A two-edged sword

Escherichia coli (E. coli) is a ubiquitous symbiotic bacterium in the gut, and the diversity of E. coli genes determines the diversity of its functions. In this review, the two-edged sword theory was innovatively proposed. For the question 'how can we harness the ambivalent nature of E. coli to screen and treat CRC?', in terms of CRC screening, the variations in the abundance and subtypes of E. coli across different populations present an opportunity to utilise it as a biomarker, while in terms of CRC treatment, the natural beneficial effect of E. coli on CRC may be limited, and engineered E. coli, particularly certain subtypes with probiotic potential, can indeed play a significant role in CRC treatment. It seems that the favourable role of E. coli as a genetic tool lies not in its direct impact on CRC but its potential as a research platform that can be integrated with various technologies such as nanoparticles, imaging methods, and synthetic biology modification. The relationship between gut microflora and CRC remains unclear due to the complex diversity and interaction of gut microflora. Therefore, the application of E. coli should be based on the 'One Health' view and take the interactions between E. coli and other microorganisms, host, and environmental factors, as well as its own changes into account. In this paper, the two-edged sword role of E. coli in CRC is emphasised to realise the great potential of E. coli in CRC screening and treatment.

A probiotic Limosilactobacillus fermentum GR-3 mitigates colitis-associated tumorigenesis in mice via modulating gut microbiome

Bacterial therapy for colorectal cancer (CRC) represents a burgeoning frontier. The probiotic Limosilactobacillus fermentum GR-3, derived from traditional food "Jiangshui", exhibited superior antioxidant capacity by producing indole derivatives ICA and IPA. In an AOM/DSS-induced CRC mouse model, GR-3 treatment alleviated weight loss, colon shortening, rectal bleeding and intestinal barrier disruption by reducing oxidative stress and inflammation. GR-3 colonization in distant colon induced apoptosis and reduced tumor incidence by 51.2%, outperforming the control strain and vitamin C. The beneficial effect of GR-3 on CRC was associated with gut microbiome modulation, increasing SCFA producer Lachnospiraceae NK4A136 group and suppressing pro-inflammatory strain Bacteroides. Metagenomic and metabolic analyses revealed that GR-3 intervention upregulated antioxidant genes (xseA, ALDH) and butyrate synthesis gene (bcd), while increasing beneficial metabolites (SCFAs, ICA, IPA, VB12 and VD3) and reducing harmful secondary bile acids. Overall, GR-3 emerges as a promising candidate in CRC therapy, offering effective gut microbiome remediation.

The role of the gut microbiota in tumor, immunity, and immunotherapy

In recent years, with the deepening understanding of the gut microbiota, it has been recognized to play a significant role in the development and progression of diseases. Particularly in gastrointestinal tumors, the gut microbiota influences tumor growth by dysbiosis, release of bacterial toxins, and modulation of host signaling pathways and immune status. Immune checkpoint inhibitors (ICIs) have greatly improved cancer treatment efficacy by enhancing immune cell responses. Current clinical and preclinical studies have demonstrated that the gut microbiota and its metabolites can enhance the effectiveness of immunotherapy. Furthermore, certain gut microbiota can serve as biomarkers for predicting immunotherapy responses. Interventions targeting the gut microbiota for the treatment of gastrointestinal diseases, especially colorectal cancer (CRC), include fecal microbiota transplantation, probiotics, prebiotics, engineered bacteria, and dietary interventions. These approaches not only improve the efficacy of ICIs but also hold promise for enhancing immunotherapy outcomes. In this review, we primarily discuss the role of the gut microbiota and its metabolites in tumors, host immunity, and immunotherapy.

Priestia megaterium ASC-1 Isolated from Pickled Cabbage Ameliorates Hyperuricemia by Degrading Uric Acid in Rats

Pickled cabbage, a traditional fermented food rich in functional microorganisms, can effectively control hyperuricemia and gout. In this study, a Priestia megaterium ASC-1 strain with strong uric acid (UA) degradation ability was isolated from pickled cabbage. After oral administration for 15 days, ASC-1 was stably colonized in the rats in this study. ASC-1 significantly reduced UA levels (67.24%) in hyperuricemic rats. Additionally, ASC-1 alleviated hyperuricemia-related inflammatory response, oxidative stress, and blood urea nitrogen. Intestinal microbial diversity results showed that ASC-1 restored intestinal injury and gut flora dysbiosis caused by hyperuricemia. These findings suggest that P. megaterium ASC-1 may be used as a therapeutic adjuvant for the treatment of hyperuricemia.

A Probiotic Targets Bile Acids Metabolism to Alleviate Ulcerative Colitis by Reducing Conjugated Bile Acids

SCOPE

Gut microbiota (GM) dysbiosis and dysregulated bile acids (BAs) metabolism have been linked to ulcerative colitis (UC) pathogenesis. The possibility of utilizing live probiotics with a defined BAs-metabolizing capability to modify the composition BAs for UC treatment remains unexplored.

METHODS AND RESULTS

In this study, Strain GR-4 is sourced from traditional Chinese fermented food, "Jiangshui," and demonstrated the ability to deconjugate two common conjugated BAs by over 69% and 98.47%, respectively. It administers strain GR-4 to dextran sulfate sodium (DSS)-induced UC mice, and observes an overall alleviation of UC symptoms, as evidence by improved colon morphology, reduces inflammation and oxidative stress, and restores intestinal barrier function. Importantly, these effects are reliant on an intact commensal microbiota, as depletion of GM mitigated GR-4s efficacy. Metabolomics analysis unveils a decline in conjugated BAs and an increase in secondary BAs following GR-4 administration. GM analysis indicates that GR-4 selectively enriches bacterial taxa linked to BAs metabolism, enhancing GM's capacity to modify BAs.

CONCLUSION

This research demonstrates the potential for natural fermented foods and probiotics to effectively manipulate BAs composition, including conjugated and secondary BAs, to alleviate UC symptoms, underscoring the benefits of these approaches for gut health.

A Review of the Use of Native and Engineered Probiotics for Colorectal Cancer Therapy

Colorectal cancer (CRC) is a serious global health concern, and researchers have been investigating different strategies to prevent, treat, or support conventional therapies for CRC. This review article comprehensively covers CRC therapy involving wild-type bacteria, including probiotics and oncolytic bacteria as well as genetically modified bacteria. Given the close relationship between CRC and the gut microbiota, it is crucial to compile and present a comprehensive overview of bacterial therapies used in the context of colorectal cancer. It is evident that the use of native and engineered probiotics for colorectal cancer therapy necessitates research focused on enhancing the therapeutic properties of probiotic strains.. Genetically engineered probiotics might be designed to produce particular molecules or to target cancer cells more effectively and cure CRC patients.

Microbiota Transplant and Gynecological Disorders: The Bridge between Present and Future Treatments

Fecal microbiota transplantation (FMT) is a procedure that involves transferring fecal bacteria from a healthy donor to a patients' intestines to restore gut-immunity homeostasis. While FMT was primarily supposed to treat gastrointestinal disorders such as inflammatory bowel disease and irritable bowel syndrome-and especially Clostridium difficile infection (currently the only used as clinical treatment)-recent research has suggested that it may also become a potential treatment for gynecological disorders, including endometriosis and polycystic ovary syndrome (PCOS). On the contrary, vaginal microbiota transplantation (VMT) is a newer and less commonly used procedure than the FMT approach, and its potential applications are still being explored. It involves direct grafting of the entire vaginal microbiota of healthy women into the vaginal tract of patients to easily rebuild the local microbiota environment, restoring vaginal eubiosis and relieving symptoms. Like FMT, VMT is thought to have potential in treating different microbiota-related conditions. In fact, many gynecological disorders, such as bacterial vaginosis and vulvovaginal candidiasis, are thought to be caused by an imbalance in the vaginal microbiota. In this review, we will summarize the development, current challenges, and future perspectives of microbiota transplant, with the aim of exploring new strategies for its employment as a promising avenue for treating a broad range of gynecological diseases.