The therapeutic effects of medicinal mushrooms are due to the presence of lectin, β-glucan, ergosterol, arginine, and other bioactive substances in mushrooms.5–9 The benefits and possible mechanisms of action of these substances are described in Table 1.

Table 1.

Mechanisms of action of various modulating substances present in mushrooms.

Lectins have been shown to be therapeutic agents with anticancer properties in animals and in clinical studies. They cause cytotoxicity and apoptosis and inhibition of tumor growth by preferentially binding to cancer cell membranes. Lectins function by sequestering the body's polyamines, thereby inhibiting cancer cell growth. Lectins also alter the production of many interleukins, activate protein kinases, bind to ribosomes, and inhibit protein synthesis. In addition, lectins modify the cell cycle by inducing cell cycle arrest at the G2/M phase, promoting apoptosis, and stimulating non-apoptotic G1-phase accumulation mechanisms. Finally, lectins can also down-regulate telomerase activity and inhibit angiogenesis.16–20

β-glucan is a glucose polymer present in medicinal mushrooms. It exhibits immunomodulatory effects as well as tumoricidal and antiproliferative activities in cancer patients through the stimulation of natural killer cells, neutrophils, monocytes, macrophages, and T-cells.21–28

Ergosterol (or provitamin D2) is a precursor of ergocalciferol, an important substrate in vitamin D biosynthesis and is found in the lipid fraction of Agaricales extracts. This substance has antitumor, antiproliferation, and antimigratory effects on human cancer cells.25–27 It has also been shown to inhibit angiogenesis. In a study on sarcoma 180 cells, patients treated with ergosterol demonstrated delayed tumor growth with minimal side effects. For example, the decrease in lymphocyte count that is commonly caused by chemotherapy was not observed in these patients. Ergosterol appears to have no direct in vitro cytotoxic effects on tumor cells, although it inhibits tumor-induced neovascularization.28

Arginine is a semi-essential amino acid used as a dietary supplement in cancer patients. It has been associated with a reduction of tumor growth and metastasis progression, and it is reported to have beneficial effects on the immune system, weight gain, and the time of survival of cancer patients.29,30

A complete understanding of the actions of these fungi and their bioactive molecules in the prevention and treatment of cancer will require further investigation. However, research shows that many of these substances exert anticarcinogenic, antiviral, antithrombotic, antibiotic, and anti-inflammatory effects in addition to many other activities that provide health benefits.5,6,9,31–32

Promising results have been reported in animals and in vitro using medicinal mushrooms in the treatment of breast cancer and several other cancers.33–49Table 2 provides a summary of the studies mentioned below.

Table 2.

The effects of Agaricales mushrooms and other medicinal fungi on breast cancer: experimental studies in animals, in vivo and in vitro.

Takimoto et al.33 demonstrated that rats administered Agaricus blazei extract orally exhibited increased cytotoxic T lymphocyte growth, increased levels of interferon-gamma and an increase in NK cells when compared to water-treated controls. This study indicates that mushroom extracts estimulate cytotoxic activity on both, innate and adaptive immunological systems.

Immunomodulatory, antitumor, and antiproliferative effects of lectin isolated from various types of Agaricaceae mushrooms have been demonstrated by Zhao et al.34 The lectin contained in Agaricus bisporus has been shown to exhibit an antiproliferative effect on breast cancer cells, and the lectin contained in Tricholoma mongolicum has been shown to have an inhibitory effect on mastocytoma cells (P815) in vitro.

In an in vivo study, extracts of Coriolus versicolor promoted significant tumor reductions in mice inoculated with mastocytoma tumor cells and mammary tumors.35

Chen et al.36 examined the ability of an Agaricus bisporus extract to inhibit aromatase at the estrogen receptor in vitro in MCF-7 cells and rat ovarian cells and in vivo in rats. The extract inhibited cell proliferation. The linoleic and linolenic acid present in the extract inhibited aromatase activity by altering or mutating the active sites. The in vivo study showed that the extract decreased proliferation and tumor growth without affecting apoptosis in rats.

In studies of breast cancer cells (MFC-7), Grube et al.37 showed that Agaricus bisporus extract suppresses the activity of aromatase, resulting in a reduction of estrogen production, which is a major contributor to postmenopausal breast cancer in women.

In experiments with breast cancer cells (MDA-MB-231), Thyagarajan et al.38 showed that Ganoderma lucidum extract inhibits cell proliferation and the formation of new cell colonies through the negative regulation of the expression of c-myc, an oncogene. The combination of G. lucidum extract with green tea extract demonstrated a synergistic effect by suppressing secretion of urokinase plasminogen, which is a breast cancer cell activator, and thereby suppressed the growth and invasion of metastatic breast cancers.

In a study of breast cancer cells (MCF7), Petrova et al.39 noted that extracts of fungi significantly inhibited the reporter activity of nuclear factor-kappa β (NF-κβ) by interfering negatively in its activation pathway. The study was conducted with 28 fungi extracts, 40% of which were found to inhibit NF-κβ activity.

Gu & Leonard40 reported the activities of 38 species of edible mushrooms in estrogen receptor-positive (MCF-7) and negative (MDA-MB-231, BT-20) human breast cancer cells. In aqueous extracts from Coprinellus sp., Flammulina velutipes, and Coprinus comatus, anticancer agents were identified that actively inhibited tumor growth.

Fang et al.41 conducted an in vitro investigation of fractions of ethyl acetate extracts from Shiitake mushrooms (Lentinus edodes) via biological assays of apoptosis and cell cycle analysis in two human breast carcinoma cell lines (MDA-MB-453 and MCF-7). The authors observed antiproliferative activity in all strains. Apoptosis was induced in 50% of the tumor cell lines via the positive regulation of bax, a pro-apoptotic protein. Cell cycle analysis revealed a decrease in the percentage of cells in S phase, an induction of cdk inhibitors and p21 and a suppression of CDK4 and cyclin D1 activities, thus indicating cell cycle arrest.

Studies using MCF-7 and MDA-MB-231 cells evaluated the effectiveness of various types of edible mushroom extracts. Jedinak & Sliva,42 using flow cytometry, revealed that Pleorotus ostreatus inhibited the proliferation of these cells in breast and colon cancers via p53-dependent and p53-independent mechanisms. This fungus exerted its effect by inducing the expression of the tumor suppressor p53 and the cyclin-dependent kinase inhibitor p21 (CIP1/WAF1), but at the same time inhibited the phosphorylation of retinoblastoma protein (Rb) in MCF-7 and HT-29 cells, breast and colon cells respectively.42

A study by Jiang et al.43 revealed that Ganoderma lucidum inhibits proliferation of MDA-MB-231 breast cancer cells. By inhibiting Akt and NF-kappaβ activity in MDA-MB-231 cells, Ganoderma lucidum reduced their growth.

Talorete et al.44 isolated breast cancer cells (MCF-7) and exposed them to an aqueous extract of Agaricus blazei. The results indicated that this extract was able to reduce cell proliferation in 26% compared to the control group, by significantly enhancing the expression of an API gene regulatory complex in the human breast cancer cell line MCF7. This, again, highlights the anticarcinogenic potential of mushrooms.

In a study of rats inoculated with breast cancer cells, Vetvicka et al.45 observed a reduction in cell proliferation after oral supplementation of β-Glucan extracted from medicinal mushrooms. Likewise, a decrease in the proliferation of cancer cells has been reported in studies carried out by Israilides et al.46 with breast cancer cells (MCF-7) and by Sliva et al.47 using the MDA-MB-231 cell line.

Although there are some inconsistencies in the results of clinical studies regarding the use of medicinal mushrooms as an adjuvant therapy in breast cancer treatment, the majority of studies suggest a beneficial effect (Table 3).

Table 3.

The results of clinical studies using Agaricales and other medicinal fungi for dietary supplementation and adjuvant treatment in patients with breast cancer.

A study in patients with breast cancer who received four daily doses (1.6 g each) of Agaricus sylvaticus revealed that Agaricus sylvaticus supplementation resulted in an increased number of natural killer (NK) cells in 75.7% of the patients. More than half of the patients were receiving chemotherapy or radiotherapy, which typically reduces the numbers of NK cells in the body.45,11

In a clinical study of various cancers, including breast cancer (stage IV), Sliva et al.47 provided patients with a complex of immunomodulatory components, including Agaricus blazei tea (10 mg/day). After six months of treatment, some patients had increased NK cell activity, as well as increased levels of TNF-α (tumor necrosis factor), erythrocytes, hemoglobin, and glutathione. In contrast, the number of TNF-α receptors was reduced. Diarrhea and occasional nausea were reported, but the quality of life had improved. The combination of immune-active components was effective in increasing NK cell function and other immunological parameters in patients with advanced stages of cancer, thus providing an effective nutritional combination for the treatment of the late stages of cancer.47

Gennari et al.48 reported a case study of a patient with breast cancer and showed that dietary supplementation with Agaricus sylvaticus increased the number of CD56+ NK cells in the blood and caused a total regression of lung metastasis.

Dolby12 reported that the D-fraction oβ-D-Glucan (extracted from Maitake) and mushroom tablets of Grifola frondosa had a positive effect on the health status of the 15 breast cancer patients included in the study. This study reported an improvement in the clinical parameters and laboratory test results of patients as well as improvements in their hematological parameters, reductions in the amount of vomiting caused by chemotherapy, increased appetite and reduced anorexia, which can be a side effect of conventional treatments.

Hong et al.7 conducted a study with 362 breast cancer patients between 30 and 65 years of age. The frequency of ingestion of mushrooms was measured through a specific questionnaire. It was found that both the daily intake and the frequency of consumption were inversely related to the risk of breast cancer, especially in postmenopausal women. Similar results were reported by Shin et al.14; however, in the Shin study, the consumption of medicinal mushrooms showed a strong protective effect against breast cancer in premenopausal women as well.

Several published experimental clinical studies have reported that medicinal mushrooms exhibit beneficial effects on the health and quality of life in breast cancer patients. The use of supplements as adjunctive therapies for the treatment of breast cancer has shown promising results, such as antiproliferative effects on tumor cells and immunomodulatory activities in the body. However, few articles have examined the effects of supplementation with medicinal mushrooms for the treatment of breast cancer. Therefore, new protocols for the purpose of conducting clinical trials are required to elucidate the possible mechanisms of action and clinical benefits of these fungi with respect to the survival time, clinical progression and quality of life of breast cancer patients.