CAN THE MESENCHYMAL STEM CELLS ATTENUATE APOPTOSIS IN ADULT MALE ALBINO RATS WITH ACETAMINOPHEN-INCUCED HEPATIC FAILURE

Document Type : Original Article

Authors

1 Departments of Medical Physiology, Al-Azhar, Faculties of Medicine

2 Departments of Biochemistry, Cairo, Faculties of Medicine

Abstract

Background: Liver failure is a worldwide health problem. Stem cells provide a great promise in regeneration of liver tissue. Objective:  Assessment of the role of apoptosis in the pathophysiology of liver failure and bone marrow derived mesenchymal stem cells (BM MSCs) effect on it. Materials and Methods: Twenty four adult male albino rats of local strain were chosen as an animal model for this study. They were divided into control, liver failure (LF) rats, LF rats received culture media and LF rats received BM MSCs.  Mesenchymal stem cells were separated from rat bone marrow, being identified by their morphology and immunophenotype (CD29, CD45 and CD90) by flow cytometry. BM MSCs were labeled with PKH26 dye before injection. LF was induced by oral administration of acetaminophen. At the end of the experiment (24 days), blood samples were obtained for estimation of serum alanine transferase (ALT) and aspartate transferase (AST). Animals were sacrificed and livers were obtained for measurement of BCL2 associated X protein (Bax), B-cell CLL/lymphoma 2 (BCL2) and transformation growth factor beta (TGFβ) gene expression in addition to histopathological examination of liver tissue. Results: BM MSCs were successfully separated from bone marrow, being identified as mesenchymal stem cells showing plastic adherence properties and fibroblastoid shape. The cells showed +ve expression of CD29 and CD90, -ve expression of CD45 proving that they were mesenchyml cells not hematopoitic cells. Acetaminophen showed significant increase in serum ALT and AST. There were significant increases of TGFβ and BAX gene expression in the liver tissue. There was significant decrease of BCL2 gene expression. BM MSCs showed significant decrease in serum ALT and AST, also there were significant decrease in TGFβ and BAX gene expression in the liver tissue in addition to significant increase in BCL2 gene expression. Histopathological examination revealed regeneration of the damaged liver tissue and restoration of normal architecture of liver tissue in BM MSCs-treated group in comparison with LF group.
Conclusion: Apoptosis has important role in the pathophysiology of hepatic failure, and BM MSCs have significant role in its attenuation.

Keywords


CAN THE MESENCHYMAL STEM CELLS ATTENUATE APOPTOSIS IN ADULT MALE ALBINO RATS WITH ACETAMINOPHEN-INCUCED HEPATIC FAILURE

 

By

 

Yousri El – Amir Ahmad Ganaym, Fawzy Ahmad Ashour,

Laila Ahmad Rashed*, Mohammad Abulhassan Zoair

and Osama Mohammad Abd El – Hai

 

Departments of Medical Physiology and Biochemistry*, Al-Azhar and Cairo* Faculties of Medicine

 

ABSTRACT

Background: Liver failure is a worldwide health problem. Stem cells provide a great promise in regeneration of liver tissue. Objective:  Assessment of the role of apoptosis in the pathophysiology of liver failure and bone marrow derived mesenchymal stem cells (BM MSCs) effect on it. Materials and Methods: Twenty four adult male albino rats of local strain were chosen as an animal model for this study. They were divided into control, liver failure (LF) rats, LF rats received culture media and LF rats received BM MSCs.  Mesenchymal stem cells were separated from rat bone marrow, being identified by their morphology and immunophenotype (CD29, CD45 and CD90) by flow cytometry. BM MSCs were labeled with PKH26 dye before injection. LF was induced by oral administration of acetaminophen. At the end of the experiment (24 days), blood samples were obtained for estimation of serum alanine transferase (ALT) and aspartate transferase (AST). Animals were sacrificed and livers were obtained for measurement of BCL2 associated X protein (Bax), B-cell CLL/lymphoma 2 (BCL2) and transformation growth factor beta (TGFβ) gene expression in addition to histopathological examination of liver tissue. Results: BM MSCs were successfully separated from bone marrow, being identified as mesenchymal stem cells showing plastic adherence properties and fibroblastoid shape. The cells showed +ve expression of CD29 and CD90, -ve expression of CD45 proving that they were mesenchyml cells not hematopoitic cells. Acetaminophen showed significant increase in serum ALT and AST. There were significant increases of TGFβ and BAX gene expression in the liver tissue. There was significant decrease of BCL2 gene expression. BM MSCs showed significant decrease in serum ALT and AST, also there were significant decrease in TGFβ and BAX gene expression in the liver tissue in addition to significant increase in BCL2 gene expression. Histopathological examination revealed regeneration of the damaged liver tissue and restoration of normal architecture of liver tissue in BM MSCs-treated group in comparison with LF group.

Conclusion: Apoptosis has important role in the pathophysiology of hepatic failure, and BM MSCs have significant role in its attenuation.

Key word: BM MSCs, acetaminophen, apoptosis, liver failure.

  

 

INTRODUCTION

Prompt removal of unwanted cells, such as damaged, genetically mutated, or virus infected cells, is crucial for the maintenance of liver health. This process is naturally achieved through a highly regulated programmed form of cell death, i.e. apoptosis. In healthy organisms, the number of cells eliminated by apoptosis equals the number of cells generated by mitosis, ensuring the proper organ homeostasis. In addition, physiological apoptosis allows the removal of cells with virtually no release of proinflammatory cytokines and minimal immune response. However, in pathophysiological situa-tions, the balance between cell prolifera-tion and cell death is often altered, with the consequent loss of tissue homeostasis and the onset of several liver diseases (Que et al., 1999). Excessive and/or sustained apoptosis can lead to acute injuries, such as fulminant hepatitis (Kohli et al., 1999), or even chronic sustained injuries, such as alcoholic liver disease, cholestatic liver disease, and viral hepatitis (Canbay et al., 2002). Therefore, therapeutic strategies to inhibit apoptosis in liver injury have the potential to provide a powerful tool for the treatment of liver disease (Guicciardi and  Gores, 2005).

      End-stage liver disease is a devastat-ing condition with multiple etiologies, However, epidemiological data indicate an increasing worldwide prevalence of liver cirrhosis, related to chronic infection by hepatitis C or B viruses, alcohol consumption and non-alcoholic fatty liver disease (Poynard et al., 1997 and Parola et al., 2008). Currently, the only curative treatment is liver transplantation (Bernal & Wendon, 2004; Chen et al., 2005; Reding, 2005 and Fried- man, 2008). This method is limited by the critical shortage of donor organs, high cost, and the need for immunosuppression (Williams & Wendon, 1994 and Reding, 2005). Cell transplantation with hepatic stem cells could potentially replace liver transplantation in patients with end-stage liver diseases (Sanmartin et al., 2006 and Yang et al., 2007).

      Cell-based therapies are quickly taking hold as a revolutionary new approach to treat many human diseases. MSCs are widely used because they are considered clinically safe, unique in their immune-capabilities, easily obtained from adult tissues, and quickly expanded as well as stored (Betancourt, 2013). 

      The pathophysiology of liver failure and the regenerative mechanism of MSCs are not fully understood. So, the aim of this research was to investigate the role of apoptosis in the pathophysiology of liver failure and, possible mechanism of MSCs on this model.

MATERIALSAND METHODS

Animals:   Twenty four adult male albino rats of local strain were chosen as an animal model for this study.  They were kept in suitable cages (20x32x20 cm for every three rats) at room temperature, with the natural light-dark cycle. They weighed 120 -140 g (average weight was 130 g). They were fed on a standard food in addition to green vegetables with free water supply.   They were kept for 10 days for the adaptation to the new environments before the start of the experiment. The animals were divided into four equal groups as follows:

Group I (control group): received distilled water (0.5 ml/rat) by oral gavage for three days. Group II (LF group): LF was induced by oral administration of acetaminophen (500mg/kg) for three days Gopi et al., 2010).  Group III (LF + vehicle): Received culture media (Dulbecco’s modified Eagle’s medium DMEM), by single intravenous injection (1ml/rat) in the caudal vein in the fourth day after induction of LF. Group IV (LF + BM MSCs): received BM MSCs by intravenous injection in the caudal vein, (one million cells per rat) in the fourth day after induction of LF (Abdel Aziz et al., 2007). After twenty days from BM MSCs injection, blood samples were taken from the retro-orbital vein for measurement of serum ALT and AST. The animals were sacrificed to obtain liver tissue for histopathological examination and detection of TGFβ, BAX and BCL2 gene expression.

     BM MSCs were prepared according to Abdel Aziz et al. (2007). Cells were identified as being MSCs by their morphology, plastic adherence (Dexter et al., 1981) and immunophenotyping using flowcytometry for CD29,CD45 and CD90 (Bieback et al., 2004). BM MSCs were labeled with PKH26 (Sigma, USA). Cells were centrifuged and washed twice in serum free medium. Cells were pelleted and suspended in dye solution. Cells were injected intravenously into rat tail vein. After twenty days, liver tissues were examined with a fluorescence microscope (Leica Microsystem, USA) to detect and trace the cells (Shao-Fang et al., 2011). Measurements were done for serum ALT (Reitman and Frankel, 1957), serum AST (Reitman and Frankel, 1957). Gene expression of BAX, BCL2 and TGFβ were done by real time polymerase chain reaction syber green I dye method (Aggarwal and Gupta, 1998).

       Liver was excised for histopatho-logical studies and detection of BM MSCs homing in the liver tissue. Different sections were obtained, stained with hematoxyline and eosin (Hx and E) and examined using a light microscope. Other slides were kept without staining to be examined by fluorescent microscope for detection of BM MSCs homing.

Statistical analysis: All the statistical analyses were processed using Statistical Program of Social Sciences (SPSS) for windows (version 17, SPSS Inc., Chicago, IL, USA), Values of the measured parameters were expressed as mean value ± standard deviation (SD), and the differences and significance were verified by one-way ANOVA followed by the Fisher’s least significant difference (LSD) post hoc test. Pvalues less than 0.05 were considered statistically significant.

RESULTS

     Twenty four hours from the primary culture (passage 0 = P0) of bone marrow derived mesenchymal stem cells, the cultured cells appeared crowded and suspended. They were variable in size and shape. Most of the cells appeared rounded (Figs.1a).Twelve days from the primary culture, the adherent cells reached 80-90% confluency (Fig.1b) and appeared triangular, star shaped and spindle shaped (Fig.1c).The cells were examined under fluorescent microscope after labeling with PKH26 dye (Fig.1d). The liver tissue was examined under fluorescent microscope for detection of homing of BM MSCs (Fig.1e) Immunophenotyping of BM MSCs using flowcytometry showed positive expression of CD29 & CD90, and negative expression of CD45 (Fig.1f,g & h).

Effects of BM MSCs on some liver functions Fig. (2):

     In group I, the mean ± standard deviation of serum ALT and AST were 21.03±0.74 IU / L and 13.5±1.52 IU / L respectively. In group II, the mean ± standard deviation of serum ALT and AST were 106.53±4.8IU / L and  86.01±1.41 IU / L respectively. There were significant increases in serum ALT and AST in group II when compared with group I. In group III, the mean ± standard deviation of serum ALT and AST were 104.38±3.13 IU/L and 87.16±2.04 IU/L respectively. There were no significant differences in group III when compared with group II. In group IV, the mean ± standard deviation of serum ALT and AST were 40.28±1.34 IU/L and 31.17±2.32 IU/L respectively. There were significant decreases in serum ALT and AST in group IV when compared with group II.

 

 

 

 
   
 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 


Figure (1): phase contrast micrograph of BM MSCs under inverted microscope, the cell appeard rounded after 24hrs of separation (a), turned to fibroblastoid, star and triangular shape reaching 80 to 90% confluency (b,c). The cells have taken the colour of PKH26 dye under fluorescent microscope (d). Labeled cells were detected in liver tissue in the central canal and blood sinusoids taking (e). Histograms of flowcytometry showing +ve expression of CD29 and CD90 (f,g),and –ve expression of CD45 (h).

 

Figure (2): Effects of BM MSCs on serum ALT and AST (Mean±SD).

 


Effect of BM MSCs on TGFβ, Bax and Bcl2 gene expression in the liver tissue Fig. (3):

      In group I, the mean ± standard deviation of liver tissue levels of TGFβ, Bax and Bcl2 were 1.074±0.043, 1.091±0.062 and 1.087±0.079 respectively. In group II, the mean ± standard deviation of liver tissue levels of TGFβ, Bax and Bcl2 were 9.28±1.2, 7.93±0.33 and 0.39±0.028 respectively. There were significant increases in TGFβ and Bax in group II when compared with group I. Also, there was significant decrease in Bcl2 in group II when compared with group I. In group III, the mean ± standard deviation of liver tissue levels of TGFβ, Bax and Bcl2 were 10.13±0.88, 7.81±0.38 and 0.43±0.025 respectively. There was no significant difference in group III when compared with group II. In group IV, the mean ± standard deviation of liver tissue levels of TGFβ, Bax and Bcl2 were 3.45±0.28, 3.02±0.32 and 0.88±0.029 respectively. There were significant decreases in TGFβ and Bax in group IV when compared with group II. Also, there was significant increase in Bcl2 in group IV when compared with group II.

Histopathological examination:

    In group I there was normal architecture of hepatic tissue, normal cords of hepatocytes radiating from normal central vein and normal blood sinusoids. Group II and III showed dilation, congestion of central vein, widening of blood sinusoid, congestion and dilation of portal tract with lymphocytic infiltration. Group IV showed more or less normal central vein, radiating regenerated cords of hepatocytes with normal blood sinusoids.

 


 

 

Figure (3): Effect of BM MSCs on TGFβ, Bax and Bcl2 gene expression in the liver tissue (Mean±SD).

 

 
   
 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 


Figure (4): Photomicrograph of the liver tissue by light microscope showed normal cords of hepatocytes radiating from normal central vein (a). Fig. b and c showed congestion and dilatation of the central vein (cv) and portal tract (pt) with lymphocytic infiltration of portal tract (li). There was showed restoration of normal cords of hepatocytes and central vein by regenerating cells (4d) (HX and E, X100).


DISCUSSION

      MSCs can be separated from many tissues like adipose tissue, dental bulb, skeletal muscles, umbilical cord and even the brain tissue (Orbay et al., 2012). In the current work MSCs were separated from bone marrow showing characteristics which agreed with (Abd el Aziz et al., 2014). Only bone marrow-derived MSCs have documented evidence of stemness including the ability to form bone and bone marrow organ upon serial transplantation in vivo. In addition, they are multipotent cells (Sacchetti et al., 2007). Separation of MSCs from bone marrow can be done by several methods including plastic adherence (Bara et al., 2014),gradient density centrifugation (Insausti et al., 2012)and immuno-magnetic selection (Tillotson et al., 2016). In the current work MSCs were separated by plastic adherence method which depended on MSCs adherence to any plastic surface. In the current work mesenchymal stem cells were separated from bone marrow and labeled with PKH26 dye. Shao-Fang et al. (2011) found that labeling with PKH26 did not yield any differences in morphology, proliferation ability, apoptosis, and cell cycle of human umbilical mesenchymal stem cells which indicate that PKH26 did not change the physiological activity of cells.

     The non-treated liver failure group showed significant increase in liver enzymes (ALT and AST) compared to control group. These results agreed with Zaher et al.(2008) and Gopi et al.(2010) who concluded abnormally higher activities of serum ALT and AST after paracetamol administration. When liver plasma membrane gets damaged, a variety of enzymes normally located in the cytosol are released into the circulation (Afroz et al., 2014).

      Acetaminophen-treated group showed significant increase of TGFβ and BAX gene expression. Also, there was significant decrease in BCL2 gene expression which indicated occurrence of apoptosis in the liver tissue. This result agreed with Li et al. (2013). Accumulating evidence suggests that hepatocyte apoptosis plays a critical role in acetaminophen-induced hepatic injury (Hu & Colletti, 2010 and Havasi & Borkan, 2011). Acetaminophen-induced apoptosis is observed not only in primary hepatocytes (Sharma et al., 2011), but also in livers of mice treated with toxic doses of acetaminophen. Moreover, inhibiting apoptosis prevents the development of acute liver failure (Hu et al., 2010).

    The transforming growth factor-β1 (TGF-β1) gene is located on chromo­some 19. The TGF-β1 polypeptide is a member of the TGF-β superfamily of cytokines. It is a secreted protein that performs many cellu­lar functions, including the control of cell growth, inflammation, extracellular matrix deposition, cell proliferation, cell differentiation, and apoptosis(Dobaczewski et al., 2011 and Wan et al., 2015). Increased transforming growth factor-b1 (TGF-b1) signaling is a highly potent inducer of collagen synthesis, and TGF-b1 pathway plays a vital role in the progression of hepatic fibrosis(Xiao et al., 2010).

    BAX is a member of the Bcl-2 gene family. BCL2 family members act as anti- or pro-apoptotic regulators that are involved in a wide variety of cellular activities. The encoded protein from BAX forms a heterodimer with BCL2, and functions as an apoptotic activator. This protein is reported to interact with, and increase the opening of the mitochondrial voltage-dependent anion channel, which leads to the loss in membrane potential and the release of cytochrome c (Kazi et al., 2011). Deng et al. (2015) reported that hepatitis C virus increases BAX gene expression which mediates apoptosis in the mitochondria. It was reported that TGFβ induces expression of BAX and this expression is a key factor of TGFβ induced apoptosis (Westphal et al., 2014).

     BM MSCs-treated group showed significant decrease in TGFβ and BAX in addition to significant increase in BCL2 gene expression which indicates that BM MSCs significantly decreased occurrence of apoptosis in the liver tissue in this group. This agreed with Jin et al. (2013). BM-MSCs inhibit hepatocyte apoptosis by secreting cytokines, thus regulating cellular signal transduction pathways. In rats, BM-MSCs secrete vascular endothelial growth factor, which attenuates myocardial IR injury by activating the PI3K signaling pathway (Angoulvant et al., 2010), and the PI3K pathway can regulate the expression of BCl-2, an anti-apoptotic protein (Westphal et al., 2014). In rat neurons, MSCs secrete cytokines that reduce chronic ethanol-induced injury by modulating the extracellular-signal-regulated kinase (ERK)1/2 pathway (Liu et al., 2010). The ERK1/2 pathway regulates apoptosis by increasing the Bax/Bcl-2 ratio, Casp3 levels and TNF levels (Mohan et al., 2012).

REFERENCES

1. Abdel Aziz, M.T., Atta, H., Mahfouz, S., Fouad, H.H., Roshdy, N.K., Ahmed, H.H., Rashed, L.A., Sabry, D., Hassouna, A.A. and Hasan, N.M. (2007): Therapeutic potential of bone marrow-derived mesenchymal stem cells on experimental liver cirrhosis. Clin. Biochem., 40:893–899.

2. Abdel Aziz. M.T.,Wassef, M.A., Ahmed, H.H., Rashed, L., Mahfouz, S., Aly, M.I., Hussein, R.E. and Abdelaziz, M. (2014): The role of bone marrow derived-mesenchymal stem cells in attenuation of kidney function in rats with diabetic nephropathy. Diabetology & Metabolic Syndrome, 6: 34-46.

3. Afroz, R., Tanvir, E.M., Hossain, M.F., Gan, S.H., Parvez, M. and Islam, M.A. (2014): Protective Effect of Sundarban Honey against Acetaminophen-Induced Acute Hepatonephro-toxicity in Rats. Evidence-Based Complemen-tary and Alternative Medicine, 2014: 12-20.

4. Aggarwal, S. and Gupta, S., (1998): Increased apoptosis of T cell subsets in aging humans: altered expression of Fas (CD95), Fas ligand, Bcl-2, and Bax. J. Immunol., 160: 1627-1636.

5. Angoulvant, D., Ivanes, F., Ferrera, R., Matthews, P.G., Nataf, S. and Ovize, M. (2010): Mesenchymal stem cell conditioned media attenuates in vitro and ex vivo myocardial reperfusion injury. J. Heart Lung Transplant., 30:95–102.

6. Bara, J.J., Richards, R.G., Alini, M. and Stoddart, M.J.(2014): Concise review: Bone marrow-derived mesenchymal stem cells change phenotype following in vitro culture: implications for basic research and the clinic. Stem Cells, 32: 1713-1723.

7. Bernal, W. and Wendon, J. (2004): Liver transplantation in adults with acute liver failure. J. Hepatol., 40: 192–197.

8. Betancourt, A.M. (2013): New Cell-Based Therapy Paradigm: Induction of Bone Marrow-Derived Multipotent Mesenchymal Stromal Cells into Pro-Inflammatory MSC1 and Anti-inflammatory MSC2 Phenotypes. Adv. Biochem. Eng. Biotechnol., 130:163-197.

9. Bieback, K., Kern, S., Klüter, H. and Eichler, H. (2004): Critical parameters for the isolation of mesenchymal stem cells from umbilical cord blood. Stem Cells, 22: 625-634.

10. Canbay, A., Higuchi, H., Bronk, S.F., Taniai, M., Sebo, T.J. and Gores, G.J. (2002): Fas enhances fibrogenesis in the bile duct ligated mouse: a link between apoptosis and fibrosis. Gastroenterology, 123:1323–30.

11. Chen, Y., Kobayashi, N., Suzuki, S., Soto-Gutierrez, A., Rivas-Carrillo, J.D., Tanaka, K., Navarro-Alvarez N., Fukazawa T., Narushima M., Miki A., Okitsu T., Amemiya H. and Tanaka, N. (2005): Trans-plantation of human hepatocytes cultured with deleted variant of hepatocyte growth factor prolongs the survival of mice with acute liver failure. Transplantation, 79: 1378–1385.

12. Deng, L., Chen, M., Tanaka, M., Ku, Y., Itoh, T., Shoji, I. and Hotta, H. (2015): HCV upregulates Bim through the ROS/JNK signalling pathway, leading to Bax-mediated apoptosis. J. Gen. Virol., 96(9):2670-83.

13. Dexter, T.M., Testa, N.G., Allen, T.D., Rutherford, T. and Scolnick, E. (1981): Molecular and cell biological aspects of erythropoiesis in long term bone marrow. Blood, 58:699-709.  

14. Dobaczewski, M., Chen, W. and Frangogiannis, N.G. (2011): Transforming growth factor (TGF)-beta signaling in cardiac remodeling. J. Mol. Cell Cardiol., 51:600–606.

15. Friedman, S.L. (2008): Hepaticfibrosis- overview. Toxicology, 254:120–129.

16. Gopi, K.S.,  Gopala, A., Reddy, K., Jyothi, D. and Kumar, B. A. (2010): Acetaminophen-induced Hepato- and Nephrotoxicity and Amelioration by Silymarin and Terminalia chebula in Rats. Toxicol. Int., 17(2): 64–66.

17. Guicciardi, M.E. and  Gores, G.J. (2005): Apoptosis: a mechanism of acute and chronic liver injury. Gut, 54: 1024–1033.

18. Havasi, A. and Borkan, S.C. (2011): Apoptosis and acute kidney injury. Kidney Int., 80: 29–40.

19. Hu, B. and Colletti, L.M. (2010): CXC receptor-2 knockout genotype increases X-linked inhibitor of apoptosis protein and protects mice from acetaminophen hepatotoxicity. Hepatology, 52:691–702.

20. Hu, J., Yan, D., Gao, J., Xu, C., Yuan, Y., Zhu, R., Xiang, D., Weng, S., Han, W., Zang, G. and Yu, Y. (2010): rhIL-1Ra reduces hepatocellular apoptosis in mice with acetaminophen-induced acute liver failure. Lab Invest., 90:1737–1746.

21. Insausti, C.L., Blanquer, M.B., Olmo, L.M., López-Martínez, M.C., Ruiz, X.F. and Lozano, F.J. (2012): Isolation and characterization of mesenchymal stem cells from the fat layer on the density gradient separated bone marrow. Stem Cells Dev., 21: 260-272.

22. Jin, G., Qiu, G.,Wu, D.,Hu, Y., Qiao, P., Fan, C. and Gao, F. (2013): Allogeneic bone marrow-derived mesenchymal stem cells attenuate hepatic ischemia-reperfusion injury by suppressing oxidative stress and inhibiting apoptosis in rats. International journal of molecular medicine, 1340: 1395-1401.

23. Kazi, A., Sun, J., Doi, K., Sung, S.S., Takahashi, Y., Yin, H., Rodriguez, J.M., Becerril, J., Berndt, N., Hamilton, A.D., Wang, H.G. and Sebti, S.M. (2011): The BH3 alpha-helical mimic BH3-M6 disrupts Bcl-X(L), Bcl-2, and MCL-1 protein-protein interactions with Bax, Bak, Bad, or Bim and induces apoptosis in a Bax- and Bim-dependent manner. J. Biol. Chem., 286:9382-92.

24. Kohli, V., Selzner, M., Madden, J.F., Bentley, R.C. and Clavien, P.A. (1999): Endothelial cell and hepatocyte deaths occur by apoptosis after ischemia-reperfusion injury in the rat liver. Transplantation, 67: 1099–105.

25. Li, G., Chen, J.,Wang, C.,Xu, Z.,Nie, H.,Qin, X., Chen, X. and Gong, Q. (2013): Curcumin protects against acetaminophen-induced apoptosis in hepatic injury. World J. Gastroenterol., 42: 7440–7446.

26. Liu, L., Cao, J.X., Sun, B., Li, H.L., Xia, Y., Wu, Z., Tang, C.L. and Hu, J. (2010): Mesenchymal stem cells inhibition of chronic ethanol-induced oxidative damage via upregu-lation of phosphatidylinositol-3-kinase/Akt and modulation of extracellular signal-regulated kinase 1/2 activation in PC12 cells and neurons. Neuroscience, 167:1115–1124.

27. Mohan, S., Abdelwahab, S.I., Kamalidehghan, B., Syam, S., May, K.S. and Harmal, N.S. (2012): Involvement of NF-κB and Bcl2/Bax signaling pathways in the apoptosis of MCF7 cells induced by a xanthone compound Pyranocycloartobiloxan-thone A. Phytomedicine, 19:1007-1015.

28. Orbay, H., Tobita, M. and Mizuno, H. (2012): Mesenchymal StemCells Isolated from Adipose and Other Tissues: Basic Biological Properties and Clinical Applications. Stem Cells International, 12: 54 - 63.

29. Parola, M., Marra, F. and Pinzani, M. (2008): Myofibroblast – like cells and liver fibrogenesis: emerging concepts in a rapidly moving scenario. Mol. Aspect Med., 29:58–66.

30. Poynard, T., Bedossa, P. and Opolon, P. (1997): Natural history of liver fibrosis progression in patients with chronic hepatitis C. The obsvirc, metavir, clinivir and dosvirc groups. Lancet, 349:825–832.

31. Que, F.G., Phan, V.A., Phan, V.H., Celli, A., Batts, K., LaRusso, N.F. and Gores, G.J. (1999): Cholangiocarcinomas express Fas ligand and disable the Fas receptor. Hepatology, 30:1398–404.

32. Reding, R. (2005): Is it right to promote living donor liver transplantation for fulminant hepatic failure in pediatric recipients? Am. J. Transplant., 5: 1587–1591.

33. Reitman, S. and Frankel, S. (1957): A colorimetric method for the determination of serum glutamic oxalacetic and glutamic pyruvic transaminases.Amer. J. Clin. Path., 28: 56-63.

34. Sacchetti, B., Funari, A., Michienzi, S., Di Cesare, S., Piersanti, S., Saggio, I., Tagliafico, E., Ferrari, S., Robey, P., Riminucci, M. and Bianco, P. (2007): Self-Renewing Osteoprogenitors in Bone Marrow Sinusoids Can Organize a Hematopoietic Microenvironment. Cell, 131: 324–336.

35. Sanmartin, A., English, D. and Sanberg, P.R., (2006): Stem cells in cell transplantation. Stem Cells Dev., 15: 963–966.

36. Shao-Fang, Z., Hong-Tian, Z., Zhi-Nian, Z. and Yuan-Li, H. (2011): PKH26 as a fluorescent label for live human umbilical mesenchymal stem cells. In Vitro Cell.Dev.Biol.Animal, 47:516–520.

37. Sharma, S., Singh, R.L. and Kakkar, P. (2011): Modulation of Bax/Bcl-2 and caspases by probiotics during acetaminophen induced apoptosis in primary hepatocytes. Food Chem. Toxicol., 49:770–779.

38. Tillotson, M., Logan, N. and Brett, P. (2016): Osteogenic stem cell selection for repair and regeneration. Bone Reports, 5: 22–32.

39. Wan, P.Q., Wu, J.Z., Huang, L.Y., Wu, J.L., Wei, Y.H. and Ning, Q.Y. (2015): TGF-β1polymorphisms and familial aggregation of liver cancer in Guangxi, China. Genetics and Molecular Research, 14: 8147-8160.

40. Westphal, D., Kluck, R.M. and Dewson, G. (2014): Building blocks of the apoptotic pore: how Bax and Bak are activated and oligomerize during apoptosis.Cell Death and Differentiation, 21: 196–205.

41. Williams, R. and Wendon, J., (1994): Indications for orthotopic liver transplantation in fulminant liver failure. Hepatology, 20: S5–10S.

42. Xiao, H., Lei, H., Qin, S., Ma, K. and Wang, X. (2010): TGF-beta1 expression and atrial myocardium fibrosis increase in atrial fibrillation secondary to rheumatic heart disease. Clin. Cardiol., 33:149–156.

43. Yang, Y., Zheng, J., Zhou, X., Yang, Z., Tan, Y., Liu, A., Gao, X., Chang, Z. and Sheng, H.Z., (2007): Potential treatment of liver-related disorders with in vitro expanded human liver precursors. Differentiation, 75: 928–938.

44. Zaher, A., Hady, H., Mahmoud, M. and Farrag, M. (2008): The potential protective role of alpha-lipoic acid against acetaminophen-induced hepatic and renal damage. Toxicol., 243:261–270.


هل بامکان الخلایا الجذعیة تقلیص موت الخلایا المبرمج فی الفشل الکبدی المحدث بالأسیتامینوفین فی ذکور الجرذان البیضاء البالغة

 

یسری الامیر أحمد – فوزی أحمد عاشور – لیلی أحمد راشد* – محمد أبو الحسن زعیر

أسامه محمد عبد الحی

قسمی الفسیولوجیا الطبیة والکیمیاء الحیویة* – کلیة طب الازهر والقاهرة*

خلفیة البحث: یمثل الفشل الکبدی مشکلة صحیة عالمیة ومن الممکن للخلایا الجذعیة ان تعطی أملا کبیرا فی إصلاح هذا التلف.

الهدف من البحث: تقییم دور موت الخلایا المبرمج فی تطور الفشل الکبدی ومدی تأثیر الخلایا الجذعیة المفصولة من نخاع العظم علیه.

مواد وطرق البحث: استخدم فی هذا البحث أربعة وعشرون فأرا أبیضا بالغا من فصیلة محلیة وتم تقسیمهم إلی أربع مجموعات وهی مجموعة ضابطة ومجموعة الفشل الکبدی ومجموعة فشل کبدی أعطیت وسط الزراعة المستخدم فی زراعة الخلایا بعد فصلها ومجموعة فشل کبدی تم إعطائها الخلایا الجذعیة المفصولة من نخاع العظم. وقد تم التعرف علی الخلایا الجذعیة عن طریق الفحص المجهری والتصنیف المناعی, وتم ترقیم الخلایا بالصبغة ب ک هـ 26 قبل الحقن و قد تم إحداث الفشل الکبدی بإستخدام مادة الأسیتامینوفین. وفی نهایة التجربة (أربعة وعشرین یوما) تم أخذ عینات من الدم لقیاس بعض وظائف الکبد, وکذلک تم أخذ عینات من نسیج الکبد لفحص النسیج مجهریا ولعمل بعض القیاسات الخاصة بظهور بعض الجینات.

النتائج: تمفصل الخلایا الجذعیة من نخاع العظم والتعرف علیها حیث أنها التصقت بالسطح البلاستیکی لأنبوبة الإختبار وتحولها تحت المجهر من الشکل الکروی لشکل یشبه الخلیة اللیفیة بالإضافة إلی أنه تم التعرف علیها مناعیا من خلال ظهور بعض الأجسام المناعیة علی السطح الخارجی لغشاء الخلایا وهی (س د 29 وس د 90) مع عدم ظهور ل س د 45 الذی أثبت ان الخلایا المفصولة هی بالفعل خلایا جذعیة. وقد أحدث الأسیتامینوفین فشلا فی وظائف الکبد وزیادة فی موت الخلایا المبرمج , بینما أحدثت الخلایا الجذعیة رجوعا فی المقاییس التی تم دراستها إلی المستوایات الطبیعیة وتقلیص موت الخلایا المبرمج.

الإستنتاج: موت الخلایا المبرمج له دور فی تطور الفشل الکبدی فی حین أن للخلایا الجذعیة دور فی تقلیصه.

REFERENCES
1. Abdel Aziz, M.T., Atta, H., Mahfouz, S., Fouad, H.H., Roshdy, N.K., Ahmed, H.H., Rashed, L.A., Sabry, D., Hassouna, A.A. and Hasan, N.M. (2007): Therapeutic potential of bone marrow-derived mesenchymal stem cells on experimental liver cirrhosis. Clin. Biochem., 40:893–899.
2. Abdel Aziz. M.T.,Wassef, M.A., Ahmed, H.H., Rashed, L., Mahfouz, S., Aly, M.I., Hussein, R.E. and Abdelaziz, M. (2014): The role of bone marrow derived-mesenchymal stem cells in attenuation of kidney function in rats with diabetic nephropathy. Diabetology & Metabolic Syndrome, 6: 34-46.
3. Afroz, R., Tanvir, E.M., Hossain, M.F., Gan, S.H., Parvez, M. and Islam, M.A. (2014): Protective Effect of Sundarban Honey against Acetaminophen-Induced Acute Hepatonephro-toxicity in Rats. Evidence-Based Complemen-tary and Alternative Medicine, 2014: 12-20.
4. Aggarwal, S. and Gupta, S., (1998): Increased apoptosis of T cell subsets in aging humans: altered expression of Fas (CD95), Fas ligand, Bcl-2, and Bax. J. Immunol., 160: 1627-1636.
5. Angoulvant, D., Ivanes, F., Ferrera, R., Matthews, P.G., Nataf, S. and Ovize, M. (2010): Mesenchymal stem cell conditioned media attenuates in vitro and ex vivo myocardial reperfusion injury. J. Heart Lung Transplant., 30:95–102.
6. Bara, J.J., Richards, R.G., Alini, M. and Stoddart, M.J.(2014): Concise review: Bone marrow-derived mesenchymal stem cells change phenotype following in vitro culture: implications for basic research and the clinic. Stem Cells, 32: 1713-1723.
7. Bernal, W. and Wendon, J. (2004): Liver transplantation in adults with acute liver failure. J. Hepatol., 40: 192–197.
8. Betancourt, A.M. (2013): New Cell-Based Therapy Paradigm: Induction of Bone Marrow-Derived Multipotent Mesenchymal Stromal Cells into Pro-Inflammatory MSC1 and Anti-inflammatory MSC2 Phenotypes. Adv. Biochem. Eng. Biotechnol., 130:163-197.
9. Bieback, K., Kern, S., Klüter, H. and Eichler, H. (2004): Critical parameters for the isolation of mesenchymal stem cells from umbilical cord blood. Stem Cells, 22: 625-634.
10. Canbay, A., Higuchi, H., Bronk, S.F., Taniai, M., Sebo, T.J. and Gores, G.J. (2002): Fas enhances fibrogenesis in the bile duct ligated mouse: a link between apoptosis and fibrosis. Gastroenterology, 123:1323–30.
11. Chen, Y., Kobayashi, N., Suzuki, S., Soto-Gutierrez, A., Rivas-Carrillo, J.D., Tanaka, K., Navarro-Alvarez N., Fukazawa T., Narushima M., Miki A., Okitsu T., Amemiya H. and Tanaka, N. (2005): Trans-plantation of human hepatocytes cultured with deleted variant of hepatocyte growth factor prolongs the survival of mice with acute liver failure. Transplantation, 79: 1378–1385.
12. Deng, L., Chen, M., Tanaka, M., Ku, Y., Itoh, T., Shoji, I. and Hotta, H. (2015): HCV upregulates Bim through the ROS/JNK signalling pathway, leading to Bax-mediated apoptosis. J. Gen. Virol., 96(9):2670-83.
13. Dexter, T.M., Testa, N.G., Allen, T.D., Rutherford, T. and Scolnick, E. (1981): Molecular and cell biological aspects of erythropoiesis in long term bone marrow. Blood, 58:699-709.  
14. Dobaczewski, M., Chen, W. and Frangogiannis, N.G. (2011): Transforming growth factor (TGF)-beta signaling in cardiac remodeling. J. Mol. Cell Cardiol., 51:600–606.
15. Friedman, S.L. (2008): Hepaticfibrosis- overview. Toxicology, 254:120–129.
16. Gopi, K.S.,  Gopala, A., Reddy, K., Jyothi, D. and Kumar, B. A. (2010): Acetaminophen-induced Hepato- and Nephrotoxicity and Amelioration by Silymarin and Terminalia chebula in Rats. Toxicol. Int., 17(2): 64–66.
17. Guicciardi, M.E. and  Gores, G.J. (2005): Apoptosis: a mechanism of acute and chronic liver injury. Gut, 54: 1024–1033.
18. Havasi, A. and Borkan, S.C. (2011): Apoptosis and acute kidney injury. Kidney Int., 80: 29–40.
19. Hu, B. and Colletti, L.M. (2010): CXC receptor-2 knockout genotype increases X-linked inhibitor of apoptosis protein and protects mice from acetaminophen hepatotoxicity. Hepatology, 52:691–702.
20. Hu, J., Yan, D., Gao, J., Xu, C., Yuan, Y., Zhu, R., Xiang, D., Weng, S., Han, W., Zang, G. and Yu, Y. (2010): rhIL-1Ra reduces hepatocellular apoptosis in mice with acetaminophen-induced acute liver failure. Lab Invest., 90:1737–1746.
21. Insausti, C.L., Blanquer, M.B., Olmo, L.M., López-Martínez, M.C., Ruiz, X.F. and Lozano, F.J. (2012): Isolation and characterization of mesenchymal stem cells from the fat layer on the density gradient separated bone marrow. Stem Cells Dev., 21: 260-272.
22. Jin, G., Qiu, G.,Wu, D.,Hu, Y., Qiao, P., Fan, C. and Gao, F. (2013): Allogeneic bone marrow-derived mesenchymal stem cells attenuate hepatic ischemia-reperfusion injury by suppressing oxidative stress and inhibiting apoptosis in rats. International journal of molecular medicine, 1340: 1395-1401.
23. Kazi, A., Sun, J., Doi, K., Sung, S.S., Takahashi, Y., Yin, H., Rodriguez, J.M., Becerril, J., Berndt, N., Hamilton, A.D., Wang, H.G. and Sebti, S.M. (2011): The BH3 alpha-helical mimic BH3-M6 disrupts Bcl-X(L), Bcl-2, and MCL-1 protein-protein interactions with Bax, Bak, Bad, or Bim and induces apoptosis in a Bax- and Bim-dependent manner. J. Biol. Chem., 286:9382-92.
24. Kohli, V., Selzner, M., Madden, J.F., Bentley, R.C. and Clavien, P.A. (1999): Endothelial cell and hepatocyte deaths occur by apoptosis after ischemia-reperfusion injury in the rat liver. Transplantation, 67: 1099–105.
25. Li, G., Chen, J.,Wang, C.,Xu, Z.,Nie, H.,Qin, X., Chen, X. and Gong, Q. (2013): Curcumin protects against acetaminophen-induced apoptosis in hepatic injury. World J. Gastroenterol., 42: 7440–7446.
26. Liu, L., Cao, J.X., Sun, B., Li, H.L., Xia, Y., Wu, Z., Tang, C.L. and Hu, J. (2010): Mesenchymal stem cells inhibition of chronic ethanol-induced oxidative damage via upregu-lation of phosphatidylinositol-3-kinase/Akt and modulation of extracellular signal-regulated kinase 1/2 activation in PC12 cells and neurons. Neuroscience, 167:1115–1124.
27. Mohan, S., Abdelwahab, S.I., Kamalidehghan, B., Syam, S., May, K.S. and Harmal, N.S. (2012): Involvement of NF-κB and Bcl2/Bax signaling pathways in the apoptosis of MCF7 cells induced by a xanthone compound Pyranocycloartobiloxan-thone A. Phytomedicine, 19:1007-1015.
28. Orbay, H., Tobita, M. and Mizuno, H. (2012): Mesenchymal StemCells Isolated from Adipose and Other Tissues: Basic Biological Properties and Clinical Applications. Stem Cells International, 12: 54 - 63.
29. Parola, M., Marra, F. and Pinzani, M. (2008): Myofibroblast – like cells and liver fibrogenesis: emerging concepts in a rapidly moving scenario. Mol. Aspect Med., 29:58–66.
30. Poynard, T., Bedossa, P. and Opolon, P. (1997): Natural history of liver fibrosis progression in patients with chronic hepatitis C. The obsvirc, metavir, clinivir and dosvirc groups. Lancet, 349:825–832.
31. Que, F.G., Phan, V.A., Phan, V.H., Celli, A., Batts, K., LaRusso, N.F. and Gores, G.J. (1999): Cholangiocarcinomas express Fas ligand and disable the Fas receptor. Hepatology, 30:1398–404.
32. Reding, R. (2005): Is it right to promote living donor liver transplantation for fulminant hepatic failure in pediatric recipients? Am. J. Transplant., 5: 1587–1591.
33. Reitman, S. and Frankel, S. (1957): A colorimetric method for the determination of serum glutamic oxalacetic and glutamic pyruvic transaminases.Amer. J. Clin. Path., 28: 56-63.
34. Sacchetti, B., Funari, A., Michienzi, S., Di Cesare, S., Piersanti, S., Saggio, I., Tagliafico, E., Ferrari, S., Robey, P., Riminucci, M. and Bianco, P. (2007): Self-Renewing Osteoprogenitors in Bone Marrow Sinusoids Can Organize a Hematopoietic Microenvironment. Cell, 131: 324–336.
35. Sanmartin, A., English, D. and Sanberg, P.R., (2006): Stem cells in cell transplantation. Stem Cells Dev., 15: 963–966.
36. Shao-Fang, Z., Hong-Tian, Z., Zhi-Nian, Z. and Yuan-Li, H. (2011): PKH26 as a fluorescent label for live human umbilical mesenchymal stem cells. In Vitro Cell.Dev.Biol.Animal, 47:516–520.
37. Sharma, S., Singh, R.L. and Kakkar, P. (2011): Modulation of Bax/Bcl-2 and caspases by probiotics during acetaminophen induced apoptosis in primary hepatocytes. Food Chem. Toxicol., 49:770–779.
38. Tillotson, M., Logan, N. and Brett, P. (2016): Osteogenic stem cell selection for repair and regeneration. Bone Reports, 5: 22–32.
39. Wan, P.Q., Wu, J.Z., Huang, L.Y., Wu, J.L., Wei, Y.H. and Ning, Q.Y. (2015): TGF-β1polymorphisms and familial aggregation of liver cancer in Guangxi, China. Genetics and Molecular Research, 14: 8147-8160.
40. Westphal, D., Kluck, R.M. and Dewson, G. (2014): Building blocks of the apoptotic pore: how Bax and Bak are activated and oligomerize during apoptosis.Cell Death and Differentiation, 21: 196–205.
41. Williams, R. and Wendon, J., (1994): Indications for orthotopic liver transplantation in fulminant liver failure. Hepatology, 20: S5–10S.
42. Xiao, H., Lei, H., Qin, S., Ma, K. and Wang, X. (2010): TGF-beta1 expression and atrial myocardium fibrosis increase in atrial fibrillation secondary to rheumatic heart disease. Clin. Cardiol., 33:149–156.
43. Yang, Y., Zheng, J., Zhou, X., Yang, Z., Tan, Y., Liu, A., Gao, X., Chang, Z. and Sheng, H.Z., (2007): Potential treatment of liver-related disorders with in vitro expanded human liver precursors. Differentiation, 75: 928–938.
44. Zaher, A., Hady, H., Mahmoud, M. and Farrag, M. (2008): The potential protective role of alpha-lipoic acid against acetaminophen-induced hepatic and renal damage. Toxicol., 243:261–270.