Honey-processed Astragalus is a dosage form of Radix Astragali processed with honey, which exhibits better efficacy of tonifying Qi than the raw product. Polysaccharides are its main water-soluble active components. This work was designed to study the structural differences of homogeneous honey-processed Astragalus polysaccharides (HAPS3a) and Astragalus polysaccharides (APS3a) and their effects on colitis mice. The results showed that HAPS3a (Mw = 2463.5 kDa) and APS3a (Mw = 3373.2 kDa) differed in molecular weight, monosaccharide compositions, glycosidic bonds and degree of branching (DB). Notably, the molar ratios of galactose and galacturonic acid in HAPS3a were 22.66% and 33.24%, while those in APS3a were 11.87% and 49.55%, respectively. The uronic acid residues 1,4-β-GalpA and 1,6-α-GlcpA of the backbone in APS3a were converted into the corresponding neutral residues in HAPS3a after honey processing. The different DB of HAPS3a (15.35%) and APS3a (25.13%) suggested that the chain conformation became smoother. The anti-inflammatory effects on colitis mice revealed that HAPS3a exhibited better effects than APS3a by protecting intestinal mucosa, regulating the expression of cytokines and influencing microbiota diversity. Taken together, the differences in anti-inflammatory activity might be related to structural differences caused by honey processing. Our findings have laid a foundation for the processing mechanism of Astragalus.

Honey-processed Astragalus is a dosage form of Radix Astragalus mixed with honey by a traditional Chinese medicine processing method which improves immune activity. This pharmacological activity of honey-processed Astragalus polysaccharide (HP-APS) might be due to structural changes during the honey roasting process. Previously, we have prepared and characterized HP-APS and preliminarily found its anti-inflammatory effects. However, whether the pharmacodynamic activity of HP-APS induces tumor cell apoptosis and the mechanisms responsible for the immunogenic death (ICD) have not been elucidated. Here, A549, MC38 and B16 cells were used to evaluate the cells viability, apoptosis and cell cycles, respectively. Cellular immunogenic cell death-related molecules calreticulin (CRT), Heat Shock Proteins (HSP)70, major histocompatibility complex I (MHC-I), and co-stimulator molecules CD80/CD86 were determined by flow cytometry. The extracellular ATP release was also detected. B16-OVA and MC38-OVA cells were treated with HP-APS and co-cultivated with OT1 mouse of CD3+T cells for assessment of proliferation, in mice model, and the establishment of C57BL/B6 mouse model bearing B16 cells for assessment of HP-APS the regulation of immune activity in vivo. Our results showed that HP-APS has an inhibitory effect on tumor cell proliferation, which induces tumor cell apoptosis, preventing cells-transforming from G1 phase to S phase in cell cycles. Furthermore, HP-APS could effectively increase the expression of HSP70, CRT, MHC-I, CD86, CD80 and ATP release. T cell proliferation index is significantly improved. CD3 cell proliferation in OT1 mice was significantly increased from the 4th generation to the 5th generation. Moreover, the results have also shown that HP-APS could inhibit tumor growth by increasing immune cell infiltration in the tumor tissues. In the mouse melanoma model with HP-APS treatment, the tumor weight and volume were significantly reduced, and the growth of melanoma was inhibited. CD8+ T is significantly increased. The ratio of CD4+ T and CD8+ T cells numbers are also significantly increased in mouse spleen, but it is less than PD-1 alone treatment separately. Altogether, these findings suggest that HP-APS exerts anti-tumor effects, and that its underlying mechanisms might be associated with the expression of immunogenicity cell death related molecules and the immunomodulatory effects of immune cells.

Magnolol is a natural extract and the main bioactive component from Chinese medicine-Magnolia. We speculate that it's functional action might be associated with the anti-inflammatory effects of magnolol. Herein, the main purpose was to elucidate the phagocytic immune function and anti-inflammatory activities associated. The toxicity of magnolol on U937 and LO-2 cells was assayed by MTT, flow cytometry and laser scanning confocal microscope was utilized to detect the phagocytosis effect on U937 cells, C57BL/6 mice and the follow-up hematoxylin-eosin staining methods were used to evaluate its bioactivity in vivo. The results showed that magnolol had dose dependent effects on enhancement of phagocytosis ability and significantly inhibited the NO production at the concentration range from10 to 40 μM. Furthermore, Magnolol significantly reduced the gene expression and protein release of IL-1β and TNF-α. However, the p-ERK1/2 in MAPK signaling pathway was not significantly affected by magnolol, whereas p-JNK and p-P38 were down-regulated. Magnolol also inhibited the expression of p-IκBα and p-P65 of NF-κB signaling pathways. The loss of body weight and the shorter length of colon were significantly improved in DSS-treated colitis C57BL/6 mice after the administration of magnolol. The cytokines of pro-inflammatory factors TNF-α, IL-6 and IL-1β attenuated significantly in a concentration dependent manner. The histopathological manifestations of 5-20 mg/kg after the treatment magnolol were markedly improved in the DSS-treated mice. These findings showed that magnolol exerted an anti-inflammatory effect through immunoregulatory phagocytosis, MAPK and NF-κB signaling pathways. Our results provide experimental evidence and theory basis for research on anti-inflammatory effects for magnolol as a potentially anti-inflammatory drug candidate.