Introduction
In Traditional Chinese Medicine (TCM) it is believed that blood deficiency can be defined as suffering from Qi and blood loss, deficiency in the stomach and spleen, and insufficient hematogenesis. Common symptoms are pale or pale-yellow complexion, pale lips, dizziness, blurred vision, hand and foot numbness, and low menstrual volume in women (1). These symptoms are in line with the symptoms of anemia in modern medicine (2). Patients with malignant tumors are treated with chemotherapy drugs, which usually cause myelosuppression and immunosuppression. The reduction of erythrocytopenia and thrombocytopenia in chemotherapy patients may impede the chemotherapy process, which can affect both the therapeutic outcome and quality of life of patients (3). Therefore, compounds that can treat and/or prevent the side effects of anemia in patients with malignant tumors are of great interest.
Panax notoginseng (Burk.) F.H. Chen (PN) is a well-known traditional herb in China and has been used in TCM for >2,000 years. PN can promote blood circulation, hemostasis, detumescence and relieve pain. Saponins are a general term for a type of glycoside composed of triterpenes or spirostanes. The saponins first found in ginseng that were named as ginsenosides Rb1, Rg1, Rd, etc. and in PN were named as notoginsenosides R1, Ft1, and etc. The main active components of PN are saponins, including notoginsenoside R1 (nR1), and ginsenosides Rb1, Rg1 and Rd (4). These saponins are used as anti-inflammatory and antitumor treatments and are also considered to support the immune system, provide cardiovascular protection and promote blood circulation (5,6). Traditionally, PN has two different forms, raw and processed. The processed PN, known as steamed PN, is the key component in generating blood (7), which increases the production of blood cells and is involved in the activation of immune cells through the JAK-STAT signaling pathway, finally promoting hematopoiesis in anemia (8). The process of steaming PN increases the amount and activities of certain ginsenosides. For example, the ginsenoside Rb1 is converted into the more bioactive ginsenoside compound K (CK) and protopanaxadiol (PPD) (9). Although PN is typically processed by steaming, it can also be processed by fermentation. The enzymes produced by microorganisms in the fermentation process hydrolyze the carbohydrate side chains at C-3, C-6 and C-20, which changes the composition and contents of saponins (10). Previous studies (9,10) have reported that the processed PN generates a large number of effective ginsenosides, which differ from the ones found in raw PN. Ginsenosides Rk3, Rh4, Rk1, Rg5, F4, 20(S/R)-Rg3, CK and 20(S/R)-Rh1 are unique saponins that only exist in processed PN but not in raw PN (11). The microbial transformation method is stable in the production of PN or NS (12,13) and can also improve drug efficacy and reduce toxicity. Several studies have reported that the β-glucosidase enzyme produced by Lactobacillus plantarum, Lactobacillus delbrueckii, Lactobacillus fermentum, Bifidobacterium longum or Leuconostoc mesenteroides could transform the ginsenosides into rare ginsenosides, which are the deglycosylated secondary metabolic derivatives of major ginsenosides and function as active substances (14,15). In the present study, the chemical composition and content of the total saponins from PN before and after fermentation with Lactobacillus plantarum were compared.
In anemia, functional recovery of hematopoietic organs is a key process. Hematopoiesis is the differentiation of a small pool of self-renewing pluripotent hematopoietic stem cells (HSCs) to produce blood cells, including white blood cells (WBCs), red blood cells (RBCs), platelets (PLTs) and reticulocytes (Rets) (16). HSCs can produce a new blood cell count to resist the reduction caused by blood deficiency. Hematopoietic cytokines, such as thrombopoietin (TPO), erythropoietin (EPO) and granulocyte-macrophage colony-stimulating factor (GM-CSF), perform vital roles in the progress of hemopoiesis (17). Cytokines are crucial in the inflammatory response to anemia and are necessary for re-establishing flow to the afflicted organs (18). Decreased levels of cytokines suggest organ pathology, which inhibits the development of T cells and other immune cells (19). The effect of saponins on hematopoiesis and immunity should be evaluated for use in treating anemia. However, to the best of our knowledge, no studies have previously reported the therapeutic effect of notoginseng saponins (NS) and fermented NS (FNS) on blood deficiency.
In the present study, the total saponins from PN were fermented with Lactobacillus plantarum, and the changes in saponin content were evaluated. Blood deficiency was induced in rats using acetylphenylhydrazine (APH) and cyclophosphamide (CP), and the effects of FNS and NS on blood deficiency parameters were assessed. The present study aimed to provide a useful theoretical basis for the future clinical treatment of blood deficiency.
Discussion
According to the theory of TCM, deficiency of viscera and insufficiency of Qi and blood are attributed to blood deficiency. The effect of PN in promoting hemostasis is known as ‘the raw materials eliminate and the steamed ones tonify’ and steamed PN is considered to possess the function of warming and toning viscera, benefiting Qi and nourishing blood in TCM (39). In TCM it is believed that there are marked differences in composition, activities and efficacy between raw PN and the steamed PN (8). For example, in TCM raw PN is considered to primarily stop bleeding, promote apokatastasis, strengthen the heart and provide pain relief. Whereas steamed PN is used in TCM to nourish blood, regulate circulation and improve immune function (40).
Previous research has shown that fermentation of PN extracts produces a similar ginsenoside profile to steamed PN (41). L. plantarum metabolizes ginsenosides mainly through deglycosylation and dehydration (42). NS contains Rb1, Rg1, Re and nR1 as the major active compounds, which are metabolized by β-glycosidases produced by the gut microbiota (43). The C-20 glucosides of Rb1/Rb2/Rc are deglycosylated to form Rd, which further be converted to Rg3. The C-20 of Rg3 is dehydrated to form Rk1 or Rg5(44). The C-3 glucoside of Rg3 is deglycosylated to form Rh2 which is then transformed into PPD (45). In addition, the C-3 glucoside of Rb1 is deglycosylated to convert X VII to LXXV/F2, CK and PPD (46,47).
Previous studies have reported on the metabolic pathway for the elimination of the C-20 sugar moieties in Re and Rg1 produce 20(S)-Rg2 and 20(S)-Rh1, respectively (48,49). It has been suggested that the C-6 rhamnose of Rg2 is eliminated to generate Rh1 (50,51). The elimination of the C-6 glucoside of Re produces Rg1. Rg1 is transformed into Rh1, which further changed into PPT by L. plantarum fermentation. Furthermore, the C-20 glucoside of Re is deglycosylated to produce Rg2, which is further dehydrated to Rh4, F4 or Rg6. The C-6 glucoside of Rg6 and nR1 can also be deglycosylated to produce Rk3 and Rg1, respectively (51). In the present study, according to HPLC analysis, L. plantarum fermentation transformed nR1, Rg1, Rb1 and Re into their corresponding metabolites, and increased the PPD, Rd, PPT, CK and Rh2 content in FNS compared with unfermented NS.
Hypodermic injection of APH and intraperitoneal injection of CP were used to establish a blood deficiency rat model (52). Hua et al (53) and Li et al (54) reported that Sprague Dawley rats were hypodermically injected with 2% APH saline solution on days 1 and 4 at a dose of 20 and 40 mg/kg, respectively; 2 h after the hypodermic injection with 2% APH saline solution on day 4, the rats were intraperitoneally injected with CP saline solution on days 4, 5, 6 and 7 at a dose of 20 mg/kg. A similar modeling method has been previously reported in mice; however, the dose of CP was 40 mg/kg on days 4, 5, 6 and 7(55). Then, the blood deficiency model was created. APH and CP decreased WBCs, RBCs, HGB, PLTs and Rets, and model rats exhibited mental sluggishness, movement retardation, peripheral blood cell count reduction and weight loss (25,53). Liu et al (56) reported that PN extract treated with a microwave processing method increased the WBCs and HGB of blood deficiency model mice induced by APH and CP compared with raw PN. In an additional study, steamed PN was demonstrated to elevate the levels of WBCs, RBCs, HGB and PLTs in mice with blood deficiency induced by APH and CP. The PN contents were examined and the main saponins included the notoginsenoside R1, Rg1, Re, Rh1, Rb1, Rd, Rk3, Rh4 and Rg3(7). The results of the present study demonstrated that FNS and NS significantly improved the blood cell parameters. Notably, the levels of WBCs and LYMPHs of rats treated with FNS were increased compared with those of rats treated with NS.
BM is a key site of hematopoiesis and is responsible for producing new blood cells (57). A series of hematopoiesis-related cytokines, including GM-CSF, EPO and TPO are required for blood cell formation (58). TPO has been reported to improve thrombocytopenia and markedly augment megakaryopoiesis (59). EPO and GM-CSF have been suggested to promote erythropoiesis and the generation of myeloid cell subsets, respectively (60). CP damage the BM and cause cell apoptosis by increasing the expression of the pro-apoptotic protein Bax and decreasing the expression of anti-apoptotic proteins in the model mice, such as Bcl-2(61). CP induce G0/G1 phase arrest of BM (62) and inhibit the protein expressions of Cyclin D1(63). NS has previously been reported to decrease the apoptosis rate, Bax expression and caspase-3 activity of BM stromal cells induced by hydrogen peroxide (64,65). Ginsenoside CK could control apoptosis and promote cells to enter the normal cell cycle via the Bcl-2/Bax and MEK/ERK signaling pathways in myelosuppression mice induced by CP (66). Ginsenoside Rg1 increased the number of hematopoietic stem and progenitor cells and restored the function of BM in CP-treated myelosuppressed mice.
The results of the present study demonstrated that both FNS and NS reduced the cell apoptosis rate, recovered the normal pattern of the cell cycle of BM cells and increased the levels of GM-CSF, EPO and TPO. Furthermore, treatment with FNS further increased the levels of WBCs, LYMPHs, GM-CSF, EPO and TPO, and the protein expression levels of cyclin A and D1 compared with NS treatment. FNS treatment further decreased the total apoptosis rate of BM cells compared with NS treatment.
The liver stores blood and regulates the quantity of blood in circulation. CP is converted to phosphoramide mustard and acrolein by the liver cytochrome P450, which can result in liver damage (24). ALT and AST indicate the degree of liver damage. A high level of ALT suggests liver damage (67). DBIL represents the liver metabolic capacity, acting as an indicator of liver damage, and the level of DBIL is increased in patients with hepatitis and cirrhosis (68). ALP is released from the liver and bones, and its levels are increased in certain liver diseases and bone disorders (69). TRF is responsible for transporting iron from the digestive tract and degrading RBCs that enter the BM as a complex of TRF-Fe3+ (70). Due to the barrier of iron utilization by RBCs, the TRF is reduced during anemia (71). NS can improve hepatic function in non-alcoholic fatty liver disease and acute ethanol-induced liver injury (72,73). Zhong et al (74) reported that NS promoted liver regeneration through activation of the PI3K/AKT/mTOR cell proliferation pathway and upregulation of the AKT/Bad cell survival pathway in mice. The results of the present study indicated that FNS and NS protected the liver and maintained normal biochemical parameters in blood deficiency rats by reducing the ALP, ALT and DBIL levels and increasing the AST, LDH and TRF levels. The effect on ALT and AST levels in FNS rats was greater than that in NS treated rats.
APH and CP can damage the spleen and thymus, immune cells, such as T cells, B-LYMPHs and granulocytes, and cause a reduction in levels of inflammatory cytokines, such as IL-2, IL-4 and IL-6 (27,75). Lcs are produced in the BM and mature in the thymus gland or BM (76), and are the key cells involved in the regulation of immune function throughout the body (77). CD4+ T cells are activated by antigen-presenting cells and regulate immune responses via the production of cytokines and helper T (Th) cells, such as Th1, Th2, Th17 and regulatory T cells (78). T-bet can induce Th1 cells to produce IL-2, IFN-γ and TNF-α, which are pro-inflammatory cytokines. These cytokines enhance antigen presentation and facilitate phagocytic function by macrophages (79). GATA-3 can induce Th2 cells to secrete IL-4, IL-10 and IL-13, which are anti-inflammatory cytokines involved in humoral immunity (80). Th1 and Th2 serve essential roles in the coordination and intercellular communication of lymphoid, inflammatory and hematopoietic cells in the immune system (81). CP inhibits the expression of TNF-α, IFN-γ, IL-4 and IL-10, and decreases the Th1/Th2 cytokine secretion ratio (17,82). Both APH and CP decrease the levels of TNF-α and IL-6(38). In radiation-induced aplastic anemia mice, NS regulates Th1 and Th2 immune responses by downregulating the production of Th1 cytokines and T-bet protein expression, and upregulating the production of Th2 cytokines and expression of GATA-3(83). Furthermore, Rd can promote the Th1 and Th2 immune responses by increasing IL-2, IFN-γ, IL-4 and IL-10 mRNA expression in mice splenocytes (84).
The results of the present study demonstrated that FNS and NS increased the protein expression levels of IL-4, IL-10, IL-12, IL-13, TGF-β, IL-6, IFN-γ and TNF-α, and regulated Th1 and Th2 immune responses by increasing the protein expression levels of GATA-3 and T-bet. Furthermore, FNS treatment significantly increased the levels of immune cytokines (IL-10, IL-12, IL-13 and TNF-α) and transcription factor T-bet compared with NS treatment. This difference may be due to the increase of certain ginsenosides during fermentation.
Most ginsenosides in NS have low oral bioavailability (85). In L. plantarum fermentation, the hydrophilic ginsenosides (nR1, Rb1, Rg1, Rc, Re and R1) are deglycosylated and converted into hydrophobic ginsenosides (Rd, Rh2, CK, PPT and PPD). This increased hydrophobicity allows passage through cell membranes and increases bioavailability (86-88). In the present study, the total contents of nR1, Rg1, Rb1 and Re, as the main bioactive components in NS (89,90), were reduced from 53.91 g/100 g to 36.67 g/100 g, and the total content of Rd, Rh2, CK, PPT and PPD was increased from 20.16 g/100 g to 34.11 g/100 g, during the NS Lactobacillus fermentation process. Zhu et al (91) reported that the levels of Rb1, Rd, Rk1, Rg5, Rk3, Rh4 and 20(S)-PPD increased in steamed PN and could be used as pharmacokinetic markers of the steamed PN based on their elevated levels in the plasma. The ginsenosides in PN are classified as oleanane type, protopanaxadiol (PPD) and protopanaxatriol (PPT) types, according to the chemical structure. The PPD-type ginsenosides showed improved absorption compared with PPT-types in rat gastrointestinal systems. The peak concentration (Cmax) and area under the concentration-time curve (AUC) of PPD-type ginsenosides Fa, Rb1, Rd, Rk1 Rg5 and PPD were higher than PPT-type ginsenosides R1, Re, Rg1, Rg2, F4, Rh1 and PPT; the peak time (Tmax) of the PPT-types ginsenosides Rg1 (0.83 h), R1 (1.17 h), Re (1.33 h), Rg2 (1.00 h), Rh1 (0.63 h) and 20(R)-Rh1 (0.79 h) was shorter than that of the PPD-types ginsenosides Fa (8.00 h), Rb1 (8.00 h), Rb2 (8.00 h), Rd (9.33 h), CK (12.00 h), Rk1 (3.67 h), Rg5 (3.67 h) and PPD (12.00 h) (91).
The present study demonstrated that the content of PPD-type ginsenosides Rd, CK and PPD in FNS was increased during the fermentation process, with results suggesting increased blood concentration, prolonged the drug duration and increased activity, and so served an important role in the treatment of blood deficiency rats.
CK is a secondary ginsenoside, which is more bioavailable and soluble than its parent ginsenoside (92). The Cmax of CK is double that of ginsenoside Rb1, and the Tmax of CK is higher than that of Rb1(93). Fukami et al (94) reported that the Tmax, Cmax and AUC were different between Lactobacillus paracasei A221 fermented ginseng (FG) and non-FG (NFG). The Tmax of CK was 2.2 and 16 h and the Cmax was 41.5 and 1.16 ng/ml in the FG and NFG group, respectively. The AUC0-12 h and AUC0-24 h of healthy adults treated with FG were 58.3 and 17.5-fold higher than those in the NFG group (94). Choi et al (95) reported that the AUC0-24 h and Cmax of CK from FG were 6.3-fold and 6.0-fold higher than those from NFG in rats. The Tmax of CK in humans and rats was 2.54 and 3.33 h for FG and 9.11 and 6.75 h for NFG, respectively. The results of the present study demonstrated that the content of CK in FNS was higher than that in NS. These results suggested that administration of FNS resulted in a higher and faster absorption of CK in blood deficiency rats compared with NS.
In conclusion, both FNS and NS treatment appeared to reduce the changes in the blood deficiency parameters induced by APH and CP. For certain parameters, FNS exhibited a greater impact compared with NS, improving the function of the BM, spleen, thymus and liver.