PMID- 25371568
OWN - NLM
STAT- MEDLINE
DCOM- 20150707
LR  - 20220408
IS  - 2505-0044 (Electronic)
IS  - 2505-0044 (Linking)
VI  - 11
IP  - 3
DP  - 2014
TI  - Astragalus mongholicus regulate the Toll-like-receptor 4 meditated signal 
      transduction of dendritic cells to restrain stomach cancer cells.
PG  - 92-6
AB  - BACKGROUND: According to the traditional view, we depend on three methods to 
      treat tumors; surgery, chemotherapy and radiotherapy. However, these methods have 
      its own limitations in application. Traditional Chinese Medicine (TCM) is one of 
      the oldest healing systems. Astragalus mongholicus (AMs) that is the common 
      herbal medicine, the biggest part of TCM, have been proved to be effective in 
      treating cancers from lots of clinical cases. However, we have not fully 
      understood the anti-tumor mechanism of AMs, and this has lead to some doubt for 
      some Western-Medicine scholars and restricts its wide use. The main objective of 
      this research is to discuss the effect and mechanism of AMs to human stomach 
      cancer. MATERIALS AND METHODS: To observe the effect and mechanism of tumor 
      treatment by AMs, we have done the research from three major aspects, the 
      influence of DCs, the inhibition of tumor in vitro as well as the animal studies 
      in vivo after treatment. First, we culture the mouse dendritic cells (DCs) from 
      bone marrow of mouse hind legs according to the method using Interleukin-4(IL-4) 
      and Granulocyte-macrophage colony stimulating factor (GM-CSF), which refer to the 
      way established by Inaba (Inaba K, 1992). And then we investigate the growth-rate 
      of the DCs co-cultured with AMs injection. We analyze the expression of the 
      Toll-like-receptor 4 (TLR4), with SYBR-Green I Real-time PCR and the 
      I-kappa-B-alpha (IkappaB-alpha) with Western-Blot, the main regulatory protein to control 
      nuclear factor NFkappaB-p65 nuclear translocation. Second, we choose the human 
      gastric cancer cell lines MKN 45 as the target cell, which was co-cultured with 
      DCs, T cells from spleen of mouse and AMs injection, and use MTT assay to judge 
      the amount of cell lines and Immnunoflurescene to analyze the expression of 
      anti-active caspase 3 pAb anti-PARP P85 fragment pAb, the mark of apoptosis of 
      cells. Third, we have conducted the animal studies beside the basic experiment in 
      vitro. The nude mouse developed stomach cancer, due to intra-preritoneal 
      injection with MKN45 have been divided into two groups: the treatment group 
      challenged with AMs injection and the control group with saline injection. We 
      took the average of the diameter of each group as the y axis and the days after 
      administered with AMs as x axis. After 40 days, all animals were killed by 
      detruncation, and the tumor were removed and measured. We compare the diameter 
      (<40 days) and weight (>40 days) of the tumor as well as the survival days 
      between different groups to investigate the effect of inhibition of cancer. 
      RESULTS: All results show that AMs is effective in treating human stomach cancer 
      and the mechanism might be regulated by TLR4 mediated signal transduction of DCs. 
      The results are briefly introduced as follows: First, we succeed in culturing the 
      DCs induced by IL-4 and GM-CSF and find the positive rate of CD11c expression, 
      the mark of DCs, is beyond 90% (Fig-1). We detect AMs can precipitate DCs 
      maturation by upregulating TLR4 in SYBR-Green I Real-time PCR (Fig-2) and 
      suppressing I.B-aby Western-Blot (Fig-3). Second, after the MKN45 co-cultured 
      with DCs, T cells and AMs injection, the result show that AMs can great reduce 
      the amount of cell lines by MTT assay (Fig-4) and induce apoptosis with 
      Immunofluorescence (Fig-5). Finally, we have conducted animal studies beside the 
      experiment in vitro, and the result in vivo show that AMs can delay tumor 
      development from the diameter and weight of the tumor (Fig-6, Fig-7), prolong 
      life-span and improve life-quality. Figure 1the morphology and phenotypic 
      identification of DCs.The form of DCs observed by microscope with field 20*.The 
      isotype antibody control using FCM.The positive rate of CD11c expression.Figure 
      2the melting curve and the chart of TLR4 expressiona) the melting curve of 
      beta-actin; b)the melting curve of TLR4;c)the TLR4 expression of DCs stimulated 
      with AM at different dose. There is significant statistic difference between the 
      60ng/mL and 80ng/mL group and other group (P<0.05 by rank test)Figure 3the IkappaB-alpha 
      expression of DCs with different dose of AMsL0: 0ng/mL; L1:20ng/mL; L2:40ng/mL; 
      L3:60ng/mL; L4:80ng/mLFigure 4MTT assay to analyse the viability and 
      proliferation of the two cell lines (P<0.05 between the group with the dose of 
      60ng/mL and 80ng/mL and other group). the horizontal axis is the group treated 
      with AM and saline at different dose, the vertical axis is the cell number.Figure 
      5the anti-active caspase-3 pAb (a) and anti-PARP P85 fragment pAb (b) actived by 
      immunofluorescence.The cell mix were treated with 100uL anti-active caspase-3 pAb 
      at a 1:250 dilution and anti-PARP P85 fragment pAb at a 1:100 dilution, and the 
      secondary Ab was donkey anti-rabbit Cy(R)3 conjugate diluted 1:500 in PBS (Jackson 
      Cat#711-165-152). From the photo, we find that anti-active caspase-3 pAb and 
      anti-PARP P86 fragment pAb can express which is very important to indicate 
      cell-apoptosis.Figure 6The difference of tumor between treatment group and 
      control group. CONCLUSION: Ams Can play a great role in treating human stomach 
      cancers as a good Chinese herbal medicine by precipitating DCs maturation, which 
      is probably due to its effects by regulating the TLR4 mediated signal 
      transduction.
FAU - Tian, Ye
AU  - Tian Y
AD  - Affiliate Jiangsu People's Hospital, Nanjing Medical University, Nanjing, Jiangsu 
      Province.
FAU - Li, Xueliang
AU  - Li X
AD  - The First People's hospital, Hefei, Jiangsu Province.
FAU - Li, Hongxia
AU  - Li H
AD  - Affilliated Zhongda Hospital of Southeast University, Nanjing, Jiangsu Province.
FAU - Lu, Qing
AU  - Lu Q
AD  - Jiangsu Civil Administration Rehabilitation Hospital, Nanjing, Jiangsu Province.
FAU - Sun, Guoping
AU  - Sun G
AD  - Affiliate Jiangsu People's Hospital, Nanjing Medical University, Nanjing, Jiangsu 
      Province.
FAU - Chen, Hongjing
AU  - Chen H
AD  - The First Affiliated hospital of Anhui Medical University, Hefei, Anhui Province.
LA  - eng
PT  - Journal Article
DEP - 20140403
PL  - Nigeria
TA  - Afr J Tradit Complement Altern Med
JT  - African journal of traditional, complementary, and alternative medicines : AJTCAM
JID - 101232990
RN  - 0 (Drugs, Chinese Herbal)
RN  - 0 (Tlr4 protein, mouse)
RN  - 0 (Toll-Like Receptor 4)
RN  - 207137-56-2 (Interleukin-4)
SB  - IM
MH  - Animals
MH  - Apoptosis/drug effects
MH  - Astragalus Plant/*chemistry
MH  - Dendritic Cells/*drug effects/metabolism
MH  - Drugs, Chinese Herbal/*administration & dosage
MH  - Female
MH  - Humans
MH  - Interleukin-4/genetics/metabolism
MH  - Mice
MH  - Mice, Inbred C57BL
MH  - Mice, Nude
MH  - Signal Transduction/*drug effects
MH  - Stomach Neoplasms/*drug therapy/genetics/metabolism
MH  - Toll-Like Receptor 4/genetics/*metabolism
PMC - PMC4202424
OTO - NOTNLM
OT  - Astragalus mongholicus
OT  - Chinese herbal medicine
OT  - IkappaB-alpha
OT  - NFkappaB-p65
OT  - Toll-like-receptors 4
OT  - Traditional Chinese Medicine (TCM)
OT  - huaman stomach cancer
EDAT- 2014/11/06 06:00
MHDA- 2015/07/08 06:00
PMCR- 2015/04/03
CRDT- 2014/11/06 06:00
PHST- 2014/11/06 06:00 [entrez]
PHST- 2014/11/06 06:00 [pubmed]
PHST- 2015/07/08 06:00 [medline]
PHST- 2015/04/03 00:00 [pmc-release]
AID - jAJT.v11.i3.pg92 [pii]
AID - 10.4314/ajtcam.v11i3.13 [doi]
PST - epublish
SO  - Afr J Tradit Complement Altern Med. 2014 Apr 3;11(3):92-6. doi: 
      10.4314/ajtcam.v11i3.13. eCollection 2014.