Introduction
In recent years, we have observed a dramatic increase in the number of cancer cases. One of the biggest epidemiological problem is breast cancer, which is the second most common malignant cancer in the world. The number of new cases of breast cancer is constantly growing [1]. Thanks to better and better diagnostics and new methods of treatment, the number of deaths caused by this disease is decreasing every year. Nowadays more than 2/3 of patients are cured [2]. Unfortunately, for most women, returning to normal life after the treatment is more difficult than it might seem. The constant fear of remission of the disease is connected with a number of side effects related to the treatment. One of them is skin lesions. Cancers are usually treated with aggressive methods aimed at destroying pathological cells. Unfortunately, normal cells are also destroyed [3, 4]. Various body functions are disturbed, including the protective function of the skin. Considering the presence and distribution of estrogen receptors in the skin and its appendages, it is not difficult to understand that many skin lesions associated with cancer treatment can be eliminated using isoflavonoids, which have also been tested for their anticancer properties for many years.
Methods
This article is an overview describing preclinical and clinical observations on the basis of available literature. It discusses the influence of genistein on skin health in women after breast cancer treatment. The overview focuses on studies conducted with genistein in vitro or in vivo to demonstrate its effect on skin and anticancer properties. As search terms on PubMed and Google Scholar we used: “genistein and skin”, “genistein and fibroblast”, “genistein and cancer” and “genistein and breast cancer”. We selected all articles with the full text available. Only articles from 1998–2020 were chosen.
Results
Estrogen receptors
Estrogens act through two different estrogen receptors (ERs), which are also found in the skin. Both receptors are separate proteins encoded by separate genes, located on different chromosomes. The gene coding for the protein that builds up the estrogen receptor b (ESR2) is located on human chromosome 14, while the gene coding for the protein that builds up the estrogen receptor a (ESR1) is located on chromosome 6. These receptors act as transcriptional factors activated by ligands, and as a result, their biological effects are revealed. The affinity of ERa and ERb is different to different ligands. Estradiol has a higher affinity for ERa and a lower affinity for ERb. Binding of estrogens to ER evokes specific responses i.e. activation of proliferation and apoptosis retention. However, some estrogen actions require the action of other hormones, such as progesterone and androgens [5].
Differences in the distribution of estrogen receptors in the skin suggest that each of them has a different, cell-specific role. ERb is the dominant estrogen receptor in adult human skin. A large amount of b receptors is located in the basal layer and spinosum layer of epidermis and on the surface of fibroblasts [6–8]. The ERa expression is limited to the cutaneous papilla cells of hair follicles [9].
Phytoestrogens and genistein
Phytoestrogens are compounds of plant origin with a non-steroidal structure, which show a number of estrogenic activities. Their chemical structure is similar to that of female estrogen secreted by ovaries [10]. There are three classes of phytoestrogens: lignans, strobens and flavonoids [11]. The best known and most studied are flavonoids (isoflavones) and lignans. Phytoestrogens usually occur in the form of inactive glycosides or as precursors [12]. The richest source of isoflavones is mainly legumes (soybean, its preparations, legumes, lentils, spinach and red clover) [13]. Chemical analyses of compounds contained in soybean showed the presence of two basic isoflavones: genistein and daidzein [11].
Genistein attracted the attention of scientists mainly due to the results of cancer epidemiology research. They showed an inverse relationship between the consumption of significant amounts of genistein-rich soya products and the incidence and mortality of breast and prostate cancer [14, 15].
The genistein activity is weaker than that of endogenous estrogens. It is not stored in tissues as estrogens are [15]. Many phytoestrogens have the properties of both agonists and estrogen antagonists. Their estrogenic activity has been demonstrated by interaction with both ERa and ERb [14]. Genistein acts as a selective estrogen receptor modulator (SERM), mainly binding to ERb [16]. This compound has about thirty times higher affinity to ERb than to ERa [15].
Genistein also exhibits a strong antioxidant effect. It is also an inhibitor of tyrosine kinases, thus it affects a number of signal in pathways [17]. The compound may occur in two different forms: glycosylated (genistine) and aglycone (genistein). Genistein is characterized by higher bioavailability, whereas genistine (which has higher molecular weight and hydrophilicity) significantly reduces its absorption, both in the small intestine and through the skin barrier [18]. Therefore, pre-clinical and clinical studies more often use the form of aglycone [19].
The supplementation and topical use of genistein-based preparations is very common among women with skin problems resulting from low estrogen concentrations. The manufacturers offer consumers many preparations based on different doses of genistein, sometimes in combination with other active ingredients. The majority of studies indicate that genistein has positive effects on the skin only at the appropriately selected dose (usually about 54 mg/day) [20]. Unfortunately, only few products meet this criterion.
In vitro and in vivo studies
The effect of genistein on wound healing
Wound healing and scar formation are dynamic reactions and involve numerous interactions between cells and matrices in a complex environment, affected by both local and systemic factors. In abnormal hyperproliferating fibroblasts from hypertrophic scars, the altered expression of growth factors, dysfunctional receptors and unregulated signalling of tyrosine kinase, plays an important role [21]. Genistein has a high potential to support the wound healing and normal scarring process, which was confirmed by numerous studies [22–29]. Table 1 presents the most important effects of genistein on wound healing.
The effect of genistein on GAG synthesis in the skin
Genistein is also involved in modulating glycosaminoglycans (GAG) synthesis in the skin, by inhibiting or blocking tyrosine kinases (Figure 1). In one study, genistein limited EGFR activity in fibroblasts from patients with type II mucopolysaccharidosis (MPS), associated with deficiencies of enzymes degrading GAG [30]. Although genistein significantly decreased the rate of GAG synthesis, it also ensured the maintenance of their adequate amount, necessary for proper functioning of cells and tissues [30–32].
In another MPS – Sanfilippo disease, genistein was tested and compared with other flavonoids to reduce GAG synthesis and accumulation in patient fibroblasts. The inhibition of GAG synthesis was confirmed in the presence of all the compounds studied. However, the most marked decrease in their production was observed in the presence of kaempferol, daidzein and genistein [32].
Protective effects of genistein against UV radiation
There are also studies that report the protective effect of genisteins against UV radiation [33–35]. The isoflavone prevented UV-dependent COX-2 expression in HaCaT cell cultures, which indicates the anti-inflammatory effects of genistein [33]. Additionally, the compound also increases the expression of the GADD45A gene participating in DNA repair processes [34].
The photoprotective effects of genistein in photo-aging processes were also analysed on fibroblasts after multiple exposure to sub cytotoxic UVB radiation used to induce ageing. Genistein reversed the ageing process in fibroblasts through antioxidant effects related to the reduction of p66Shc protein level [35]. These data confirmed that genistein can be a good candidate for a protective agent against UV radiation-induced damage.
Skin effects of genistein – clinical studies
In addition to preclinical evidence suggesting a beneficial effect of genistein on the skin, a number of clinical studies have been performed. The results demonstrated that the isoflavone might increase epidermal proliferation and collagen content in the skin [36]. In one study, 26 healthy women aged 30–40 years took 40 mg of soy isoflavone aglycons or placebo daily for 3 months. It was observed that genistein affected the shallowing of fine lines and significantly increased skin elasticity [37].
There were also studies, in which 30 women aged 45–55 years (after menopause) were given oral genistein or estrogens for 24 weeks. After the treatment in both groups the level and structure of collagen was examined. In patients from both groups, an increase in the amount of type I and type III collagen and increased hyaluronic acid content in the tissue were noted. However, the results of the estrogen group were slightly better than in the genistein group [38, 39]. Other parameters were also analysed, such as epidermal thickness, number of papillae, fibroblasts and blood vessels. The action of gel with genistein was limited to the increase in skin thickness and number of blood vessels. However, the increases were slightly lower than in the estradiol group. Moreover, no changes in hormonal vaginal cytology were observed after 3 and 6 months compared to the baseline value, which suggests no significant systemic effects [40].
The effect of genistein was also tested in a study in which a group of 19 children (10 males and 9 females, age range: 2.8–19 years) with different MPSIII subtypes, Sanfilippo syndrome and different degrees of disability received genistein supplementation at a dose of 5 mg/kg
per day for a year. After the end of the treatment an improvement of skin texture and hair morphology was observed, but also a decrease in the level of coenzyme Q10 was observed, which did not affect the excretion of GAG in urine or intensify the symptoms of the underlying disease. Treatment was generally well tolerated and no secondary effects were observed. This study was of great importance as it demonstrated that genistein can also be used in children [41].
Genistein was also tested in case of erythema caused by UVB (sunburns) on the back skin of 6 men with phototype II to IV on the Fitzpatrick scale. Genistein (5 µmol/cm2) was applied topically 60 min before and 5 min after exposure to UVB radiation. The skin was photographed and quantified for erythema. The compound was found to effectively block UVB-induced skin burns, which confirmed the potential of its use as a radioprotective agent [42].
Anticancer effects of genistein
Numerous laboratory tests showed that genistein, as a representative of isoflavonoids, inhibited the activity of DNA helicase and topoisomerase I and II, which inhibited DNA replication and consequently led to weakened cell division and growth [43]. Genistein strongly inhibited the process of angiogenesis in the tumour microenvironment by reducing the rate of vascular endothelial cell development. The inhibition of angiogenesis was also associated with stimulation of extracellular matrix protein degradation around the newly formed vessel [44]. Many studies also suggest the inhibitory effect of isoflavonoids on the cell cycle and the induction of neoplastic cell apoptosis. Their action occurs at the transition points of G1 in S and G2 in M [45].
Genistein is also a selective inhibitor of tyrosine kinases, which play an important role in cell proliferation and transformation. By inhibiting the activity of tyrosine kinases, it inhibits the growth of cancer cells. The anti-inflammatory effect of genistein is also of main importance. By activating lymphocytes, it increases their immunostimulating effect, which can be used in cancer chemoprevention [46]. Genistein shows the ability to activate non-specific and humoral immunity processes and increases the immune capacity of cells. Additionally, it activates proliferation of spleen cells and secretion of interleukin-like cytokines such as IL-2 and IL-3 [43, 47].
It was also shown that genistein has the ability to inhibit the activity of cyclins (proteins regulating cell cycle activity) and cyclin-dependent kinases (CDKs). It can also inhibit CDKs by stimulating the transcription of p21 protein, which is an inhibitor of CDK-1 and CDK-4 kinases. This is done with p53 protein, which activates the transcription of the gene responsible for p21 biosynthesis [48, 49]. By increasing its concentration and prolonging its lifetime, genistein reduces the development of cancer cells. Additionally, the isoflavonoid, due to its antioxidant properties, protects protein kinase A (PKA), which is a catalyst of phosphorylation of the transcription factor C/EBP b and has a stimulating effect on the transcription of p21, regardless of the contribution of p53 protein (Figure 2) [43, 47, 49, 50].
Dark sides of genistein
Several studies have also shown the dark side of genistein use in breast cancer [51–53]. In one of them, an in vitro breast cancer model was developed with a positive feedback loop between primary breast adipose fibroblasts and estrogen-dependent MCF-7 tumour cells, thus representing more natural conditions. In this model, genistein could impair the growth inhibitory action of the aromatase inhibitor fadrozole at physiologically important concentrations. These data suggest that soy-based supplements may influence the effectiveness of aromatase inhibitor medication for breast cancer [51].
Another study created a preclinical mouse model simulating low 17b-estradiol blood levels similar to those in postmenopausal women. Using this model, it was observed that genistein ingested with the diet, in combination with low levels of 17b-estradiol circulating acts in an additive manner and stimulates estrogen-dependent tumour growth in vivo [52]. Similar conclusions were reached by other authors who noticed that genistein stimulates the proliferation of MCF-7 and T47D cells a estrogen receptor (ERa-positive), but does not stimulate the proliferation of ERa-negative cell lines. The additional discovering that this isoflavone antagonizes the antiproliferative effect of tamoxifen prompts that genistein can be detrimental in women with breast cancer who are treated with tamoxifen [53].
In another research, based on the association between bioactive sphingolipids and cancer, researchers determined the effect of genistein on ASAH1 transcription in MCF-7 breast cancer cells. ASAH1 encodes the member of the acid ceramidase family of proteins, which is overexpressed in multiple human cancers and may play a role in cancer progression. Authors proved that nanomolar concentrations of genistein induce ASAH1 transcription. Additionally, they demonstrated that this isoflavone stimulates cyclin B2 expression and cell proliferation in an ASAH1 dependent manner. This research indicated the mechanism by which genistein promotes sphingolipid metabolism and confirms the role of ASAH1 in breast cancer cell growth [54].
Conclusions
Skin diseases and defects resulting from the applied oncological treatment are not only an aesthetic problem. Their effects may adversely affect the quality of life of an ill person. Skin defects may cause various reactions, leading to emotional problems and even mental disorders, which may significantly affect the effectiveness of treatment. Numerous studies conducted in vitro, in vivo and clinical trials indicate high potential of genistein to be used in the treatment of skin problems in women during/after oncological treatment of breast cancer. Such treatment could potentially be applied both topically and orally.
It is true that genistein appears to be a safe compound for cancer patients, but undisputedly it is a biologically active substance. Therefore, its introduction to the treatment of oncological patients requires further studies on its mechanisms of action at the molecular level, taking into account genetic and immunological aspects. Also the drug–drug interactions of genistein with other agents need to be extensively studied on both experimental and clinical levels. This will allow to eliminate possible side effects caused by its systemic action.
Conflict of interest
The authors declare no conflict of interest.
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