Estrogen has been shown to promote breast cancer and many studies have elucidated its mechanisms, including the induction of mitochondrial gene expression changes [18] and the promotion of breast epithelial cell and cancer cell proliferation [19]. Breast cancer risk is directly associated with higher endogenous estrogen levels and differences in estrogen metabolism, which is more significant in postmenopausal women [20] [21]. The association between gut microbes and estrogen has been proposed since the last century [22]. and Plottel CS and Blaser MJ defined all the genes involved in estrogen metabolism in gut bacteria in 2011 [23]. called “estrobolome” genes. Goedert and collaborators demonstrated that intestinal microbial diversity was positively associated with systemic, non-ovarian estrogens in both men and postmenopausal women, but not in premenopausal women [24] [25].

The intestinal microbiota is a key determinant of estrogen metabolism, and the intestinal flora is a major player in estrogen metabolism. Bacteria can uncouple the bound estrogens in the bile excreted into the intestine, and the uncoupling (or unbound) products are more easily reabsorbed into the bloodstream and enter the hepatic circulation, resulting in high levels of estrogenic substances in the body [26] [27]. While high estrogen levels have been mentioned above as a risk factor for breast cancer, the interaction of gut flora with estrogen in humans may be the pathway leading to the development and progression of breast cancer. Bacterial β-glucosidase is responsible for the uncoupling of estrogens, which is encoded by the GUS gene [28] [29] and the BG gene [30]. In recent years, studies have identified gastrointestinal microbial β-glucosidase profiles, which have been established so that we may be able to adjust the body’s estrogen metabolism by altering the intestinal microbiota and further regulate the progression of breast cancer.

Increased risk of breast cancer is associated with the presence of chronic, persistent and dysregulated inflammation [31] [32]. The intestinal mucosa has a huge surface area, colonized with a large number of microorganisms. These microbiotas interact with the host immune system and are involved in the development and functional regulation of the immune system, exerting an influence that cannot be ignored on the immune environment of the whole body, even the immune microenvironment [33] [34] [35] within the tumor. LAKRITZ JR and co-workers found that oral administration of L. reuteri reduced the risk of breast cancer in mice by stimulating the development of host CD4⁺CD 25⁺ T cells [36]. leading to the conclusion that the intestinal flora can induce proliferation and differentiation of regulatory T cells. Peterson DA and collaborators demonstrated that [37] gut microbiota can induce IgA protein expression through further studies. Goedert JJ finds only IgA-coated microbiota influence the risk of breast cancer through immune-mediated pathways, while non-IgA-coated microbiota does not [38]. Sun J and collaborators established a mouse model [39] in which the intestinal microflora was depleted by administration of broad-spectrum antibiotics, and the experimental results pointed out that intestinal microbiota regulates the immune environment by inducing the expression of antimicrobial peptides. In addition, dysbiosis of the intestinal flora will lead to a decrease in lymphocytes and an increase in neutrophils, both of which will be detrimental to the survival of breast cancer patients [40]. In turn, neutrophils, which are involved in the immune response to gut flora, also have a significant impact on breast cancer [41].

At the same time, there have been many studies that have shown that intestinal microbiota has an impact on the efficacy of immunotherapy in breast cancer patients. Therefore, regulating the intestinal flora to reduce the adverse effects of immunotherapy and increase the therapeutic effect will also become a kind of new combination therapy with strong applicability. Such as bactericides sp., especially B.thetaiotomicron and B.fragilis, can enhance the therapeutic effect of immunosuppressive(anti-CTLA-4 antibodies) [42]. On the other hand, some species of intestinal microbiota may upregulate the immune response by enhancing antigen presentation or increasing T-cell recruitment in the local tumor environment [43]. Bifidobacterium and Acinetobacter mucinum have also been found to be associated with enhanced anti-PD-L1 therapeutic response [44] [45]. At present, the effect of gut microbiota on immunotherapy response of breast cancer patients is still unclear, and a foreign clinical trial (NCT02696759) is investigating whether gut microbiota can fight advanced breast cancer through immune modulation. It is also worth further studying to utilize probiotics to overcome the drug resistance and increase the efficacy of immunotherapy in some breast cancer patients.

There is a complex and frequent communication between tumor tissue cells that strongly influences all aspects of tumorigenesis. At the same time, tumor cells interact systemically with the tumor and the entire body, including the intestinal microbiota. It has been found that the intestinal microbiota, through its metabolites, regulates all processes that promote tumor progression, including inflammation, angiogenesis, metabolism, and epithelial mesenchymal transition (EMT), acts on the tumor microenvironment(TME), and influences communication between the tumor microenvironment and the tumor and the entire organism [46]. Intestinal microorganisms produce a large number of metabolites, such as secondary metabolites, lipopolysaccharides, proteins, fermentation products, and breakdown metabolites, which can enter the circulation and interfere with the steady state of the intestine and areas away from the intestine, acting as signaling mediators to influence breast cancer progression [47].

The absorption and bioavailability of most chemotherapeutic drugs require exposure to intestinal enzymes prior to their entry into the circulation, and the intestinal flora is the primary producers of these enzymes, which can alter the mechanism of action and toxicity of chemotherapeutic drugs [68] [69]. The gut microbiota has been shown to metabolize more than 40 drugs and may contribute to the therapeutic efficacy of many more [70]. Lehouritis P et al. tested the direct interaction of E.coli and Listeria welshimeri monocytogenes with 30 commonly used chemotherapeutic drugs in vitro and in vivo and found that one or two of the 10 drugs, whereas the efficacy of the six drugs was enhanced [71].

Radiation therapy is another important treatment modality in the treatment of breast cancer. It has been shown that sterile and microbiota-controlled mice receiving radiotherapy are less susceptible to dsDNA fragmentation in peripheral blood leukocytes than conventional mice [72]. and that sterile mice are less susceptible to the toxic effects of cancer radiotherapy [73]. Thus, control of the microbiota by antibiotics can reduce the side effects of radiotherapy, improve patient compliance and improve patient outcomes.

The role of Lactobacillus in the treatment and prevention of breast cancer growth and metastasis has been confirmed by more and more experiments. Lakritz JR et al. showed that oral supplementation alone with purified L.reuteri was sufficient to inhibit early carcinogenesis and increase the sensitivity of breast cells to apoptosis in two groups of breast cancer mice fed a western diet and manipulated the development of genetic susceptibility [36]. In addition, oral administration of Lactobacillus acidophilus was shown to have anticancer activity in mice with mammary tumors [74]. Hassan Z et al. demonstrated that [75] Enterococcus faecalis and Staphylococcus hominis can significantly inhibit cell proliferation, induce apoptosis, and cell cycle arrest, and that they have no cytotoxic effect on normal cells, making them a good alternative drug for breast cancer treatment.

Changing dietary patterns affects the microbiome and indirectly influences disease development. A case-control study in Japan showed that regular consumption of casein and soy isoflavones from puberty onwards reduced the incidence of breast cancer in Japanese women [76]; Newman TM et al. also indicated that the Mediterranean diet could prevent breast cancer [77]. Xue M et al. confirmed through experiments [78] that fucoidan increases the diversity of intestinal flora and can promote the intestinal barrier function, and he suggested fucoidan as a preventive agent for breast cancer.

These studies of gut flora in the treatment of breast cancer provide further evidence of the impact of gut flora on breast cancer and lay the groundwork for further research.