Changes in Serum Cytokine Concentration : A Morphological Study of Liver Cirrhosis Induced by Common Bile Duct Ligation in Rats

Article information

Korean J Intern Med. 2003;18(1):6-12

doi : https://doi.org/10.3904/kjim.2003.18.1.6

Byung Seok Lee, M.D., Nam Jae Kim, M.D., Hyun Yong Jeong, M.D., Heon Young Lee, M.D., Dae Young Kang, M.D.^*, Seung Moo Noh, M.D.^†

^*Departments of Internal Medicine, Pathology, Chungnam National University College of Medicine, Daejeon, Korea

^†Departments of General Surgery, Chungnam National University College of Medicine, Daejeon, Korea

Correspondence to : Byung Seok Lee, M.D., Chung Nam National University Hospital, Daesa-dong, Jung-gu, Daejeon 301-721, Korea. E-mail : gie001@cnuh.co.kr

Received 2002 September 24; Accepted 2002 November 04.

Abstract

Background

Liver cirrhosis is a diffuse hepatic fibrosis and nodule formation. The transforming growth factor-β1 (TGF-β1) and interleukin-10 (IL-10) are very important cytokines in hepatic fibrogenesis. The aim of this study was to examine the relationship between the changes of the serum cytokines and morphological changes following common bile duct ligation in experimental rats.

Methods

Common bile ducts of fifty male Sprague-Dawley rats were ligated and seven male rats were set aside as controls. Five rats each were sacrificed in 1, 2, 4, 6, 8, and 10 experimental weeks. Light microscopic studies and liver function tests were performed during the above experimental weeks. The levels of serum TGF-β1 and IL-10 were analyzed by ELISA. Also, alpha smooth muscle actin (α-SMA) immunohistochemical stains were performed.

Results

On the eighth week after common bile duct ligation, most hepatic lobular areas had been replaced by proliferated bile ducts and fibrous tissue (typical biliary cirrhosis). Serum TGF-β1 levels between the control group and the common bile duct ligation group showed statistically significant changes. The α-SMA was stained at proliferated bile ducts. These findings were correlated with each other.

Conclusion

Thus, this experiment may clarify our understanding of the mechanism in liver fibrogenesis. Also, indicated is a need to explore the therapeutic potential of these cytokines as anti-fibrotic agents.

Keywords: TGF-β1; Interleukin-10; Alpha-SMA; Cytokine; Liver cirrhosis

INTRODUCTION

Liver cirrhosis is a chronic liver disease caused by viruses, alcohol, various drugs and congenital disease. Complications of this disease include gastrointestinal bleeding, ascites, hepatic failure and hepatocellular carcinoma. However, there is no definite treatment of this disease. Until 1980, in Korea, hepatitis B was a prominent cause of liver cirrhosis, but frequency was decreased due to life-style changes and vaccination, especially for the young¹⁾. However, alcoholic cirrhosis has increased²⁾. Hepatocellular carcinoma associated with liver cirrhosis is an important cause of death in Korea³⁾. Therefore, an understanding of the pathogenesis of liver cirrhosis and fibrosis is an important task in the fight against hepatocellular carcinoma.

Liver fibrosis causes scar formation regardless of the various causes and this process is similar in the other organs. Fibrosis of the liver is increased in the extracellular matrix and results in loss of liver parenchymal cells. Various factors, such as cell and extracellular matrix and cytokines, are known in the process of hepatic fibrosis. Hepatic stellate cells (Ito cell or lipocyte) are important cells that secrete the extracellular matrix. These cells are in a resting state normally, but are activated when the cytokines or oxidative stress are given. Activated hepatic stellate cells increase the secretion and accumulation of extracellalar matrix surrounding the space of Disse⁴, ⁵⁾.

Cytokines which activate hepatic stellate cells are a transforming growth factor -beta 1 (TGF-β1), platelet-derived growth factor (PDGF), fibroblast growth factor (FGF) and endothelin-1 (ET-1). TGF-β1 is a key cytokine that initiates and terminates tissue repair and development of hepatic fibrosis⁶⁾. In fact, TGF-β1 is the most potent mediator in fibrogenic mechanism. TGF-β1 plays an important role in the production of extracellular matrix deposition and prevention of the degradation of extracellular proteins by enhancing production of fibronectin and collagen in the liver. Excessive or sustained production of TGF-β1 is an important mediator of liver fibrosis⁷, ⁸⁾.

Interleukin-10 is a potent anti-inflammatory and anti-fibrotic cytokine. This cytokine increases in the early stage of hepatic stellate cell activation and the abscence of this leads to enhanced fibrogenesis⁹, ¹⁰⁾.

In this report, we demonstrate the relationship between the morphological changes and serum cytokines in liver cirrhosis induced by common bile duct ligation in rats.

MATERIALS AND METHODS

Experimental animals

Four-week old male Sprague -Dawley rats, about 200 g, were used (kindly supplied by Biogenomics Co, Charles River Technology License). The experimental group (cholestatic liver injury group by common bile duct ligation) totalled fifty rats and the control group was seven rats. All animals received humane care in compliance with the Guide for the “Care and Use of Laboratory Animals” prepared by the Natural Institute of Health (NIH Publication No. 85-23, revised 1996).

Chemicals and serologic tests

Cholestatic liver injury was induced in male rats by ligation and transection of the common bile duct. These animals were sacrificed during 12 weeks. Five rats were sacrificed every two weeks. Blood samples were obtained from cardiac punctures under ketamin with xylazine (Rumpun, Seoul, Korea) anesthesia, and centrifuged at 10,000 g for 5 minutes after 1, 2, 4, 6, 7, 8, 10 experimental week. Serum was stored at −70°C. Liver function tests were performed on each experimental week (total protein, albumin, aspartate aminotransferase, alanine aminotransferase, alkaline phosphatase, gamma glutamyl transpeptidase); and serum transforming growth factor-β1 (TGF-β1) and interleukin-10 (IL-10) concentration were analyzed using the enzyme-linked immunosorbent assay kit (Quantikine, R&D System).

Assay procedures of TGF-β1 were as follows. Prepare all reagents, working standards and activated samples as instructed. Add 200 μL standard or activated sample to each well and incubate for 3 hours. Aspirate and wash 3 times. Add 200 μL conjugate to each well and incubate for 1.5 hours. Aspirate and wash 3 times. Add 200 μL substrate solution to each well and incubate for 20 minutes. Add 50 μL stop solution to each well and read at 450 nm within 30 minutes. Serum IL-10 concentration assay was as follows. Add 50 μL assay diluting agent to the center of each well. Add 50 μL standard, control, or sample to the center of each well, and incubate for 2 hours. Aspirate and wash each well 5 times. Add 100 μL. conjugate to each well and incubate for 2 hours. Aspirate and wash each well 5 times. Add 100 μL substrate solution to each well and incubate for 30 minutes. Add 100 μL stop solution to each well and read optical density at 450 nm.

Microscopic and immunohistochemical staining

Liver specimens of experimental rats were obtained and routinely fixed in 10% formalin and embedded in paraffin blocks. Using thin tissue section, hematoxylin-eosin (HE) and Masson trichrome stains were performed. Alpha smooth muscle actin has been widely used to detect stellate cell activation. Incubate with monoclonal antibodies for alpha smooth muscle actin (anti-SMA) (Nichirei Co., Tokyo, Japan). After rinsing, tissues were incubated with a biotinylated rabbit antimouse IgG F (ab′) fragment (DAKO Japan, Kyoto, Japan). Thereafter, sections were incubated in the avidin biotin complex (ABC) solution (Vectastatin, Burlingame, CA, USA)¹¹⁾.

Statisical analysis

The results were presented as mean±standard deviations. Statistical correlations were checked by the unpaired T test and Chi-square test using SPSS 10 for the Windows program.

RESULTS

Death rate of experimental rats

A total of 11 rats died during the experimental periods. The cause of death was peritonitis in the common bile duct ligation group. There were no deaths in the control group.

Morphological change of experimental rats

Ascites appeared after the fourth week in the common bile duct ligation group and body weight increased. Cysts of bile duct were prominent and some cysts ruptured (Table 1, Figure 1).

Table 1.

Characteristics of Experimental Rats (Mean±SD)

Figure 1.

Change of serum TGF-β1 concentrations. The serum TGF-β1 levels in the control (G-I) and common bile duct ligation group (G-II) show statistically significant changes.

Changes of chemistry

Between the control group and the common bile duct ligated group, statistically significant changes of the serum liver enzymes were found in albumin, AST, ALT and alkaline phosphatase (Table 2).

Table 2.

The Changes of Serum Enzyme Values

Changes of cytokines

Serum TGF-β1 levels between the control group and the common bile duct ligation group showed statistically significant changes (p<0.05). The serum TGF-β1 levels revealed high values from the sixth experimental week to the eighth experimental week. The serum IL-10 levels of the control and bile duct ligation group did not show statistically significant changes (Table 3).

Table 3.

Changes of Serum Cytokine Values (Mean±SD)

Liver biopsies from rats

The morphological changes of the common bile duct ligation group include bile duct proliferation and dilatation and inflamatory cell infiltration. By the eighth week after common bile duct ligation, most hepatic lobular areas were replaced by proliferated bile ducts and fibrous tissue (typical biliary cirrhosis). With respect to immunohistochemical stains, most hepatic lobular areas are replaced by proliferative bile ducts and α-SMA were stained after eighth experimental week. These findings are correlated with each other.

DISCUSSION

Liver cirrhosis is defined as the end stage liver disease and as an irreversible state characterized by regenerating nodule formation and diffuse fibrotic change¹², ¹³⁾. The causes of cirrhosis are varied and include viral infection, alcohol and chemical agents and birth metabolism error, but the end results are the same. The complications of cirrhosis are ascites, variceal bleeding, hepatic encephalopathy and hepatocellular carcinoma. It is essential to understand the hepatic fibrosis in liver cirrhosis. Hepatic stellate cells (previous called Ito cell, fat-storing or perisinusoidal cells) are fat-storing perisinusoidal cells and are importamt cells in hepatic fibrosis. Hepatic stellate cells are activated during liver cell injury, including acute and chronic liver disease and then white blood-cell chemoattractant releases the various cytokines and oxygen-free radicals. Also, activated stellate cells supply the type I collagen and extracellular matrix and these materials were accumulated in the space of Disse. These processes are the beginning of hepatic fibrosis^14–17).

Transforming growth factor β1 (TGF-β1) is the most potent fibrogenic cytokine and plays an important role in the activation and regulation of hepatic stellate cells. It is known that TGF-β1 is a regulatory cytokine in the growth and differentiation of cells and plays a pivotal role in the process of wound healing and fibrogenesis. TGF-β1 is secreted from various cells including Kupffer cells, activated stellate cells and hepatocyte, and is related to the synthesis of fibronectin, type I collagen. TGF-β1 increases in advanced fibrosis but is not expressed in normal liver tissue^18–20).

This study shows that serum TGF-β1 level was higher in the common bile duct ligation group than in the control group. Similary, TGF-β1 expression increases in CCL4 induced acute hepatic injury²¹⁾.

In liver biopsy findings, bile ducts proliferate after bile duct ligation, and maximal proliferation is seen at the eighth experimental week. The changes of serum cytokines were compared with microscopic findings. Alpha smooth muscle actin is present in smooth muscle cells near the biliary structure and is a stained cytoskeletal structure in the hepatic stellate cell. The degree of α-SMA stain represents the extension of fibrosis, indirectly. In our study, TGF-β1 level was correlated with the degree of α-SMA stain.

IL-10 is a potent anti-inflammatory cytokine that inhibits the synthesis of pro-inflammatory cytokines and it down-regulates superoxide synthesis²², ²³⁾. IL-10 increases in the early stage of stellate cell activation⁹⁾. Expression of IL-10 in inflammatory tissue is related to the improvement of inflammation. IL-10 down-regulates the expression of type 1 collagen genes and up-regulates the matrix metalloprotease-1 (interstitial collagenase) and matrix collagenase-3 (stromelysin-1)²⁴⁾. Recently, it was found that IL-10 deficient knocked-out mice have more neutrophil infiltration and severe fibrosis after various hepatic injuries^25–28). Thus, IL-10 has an important role in hepatic fibrosis as an anti-fibrotic agent. A recent animal study showed that the expression of IL-10 mRNA increases in the early period in bile duct ligation rats²⁹⁾. In this study, serum concentration of IL-10 is highest at the first and second experimental weeks. Thereafter, serum concentration of IL-10 decreases. We assumed that IL-10 has a pivotal role in fibrosis as an anti-fibrotic agent, and that a therapeutic use of this cytokine can be expected. In conclusion, our findings were a long-term study compared with previous extrahepatic cholestatic study in rats, and several cytokines were involved, including TGF-β1, IL-6. Especially, IL-10 may be involved in antifibrogenesis.

Figure 2.

Change of serum interleukin-10 concentration. The serum interleukin levels in the control (G-I) and common bile duct ligation group (G-II) at early experimental weeks show statistically significant changes.

Figure 3.

Ascites and significant cysts were found the fourth week after common bile duct ligation, gross findings.

Figure 4.

Portal areas contain several bile ducts and vessels (portal vein and hepatic artery branches) and are well demarcated, first week, control group, H&E stain, ×100.

Figure 5.

The increase of the bile duct proliferation was prominent compared to first week, second week after common bile duct ligation, Masson-trichrome stain, ×100.

Figure 6.

Distorted hepatic lobules due to increase of proliferated bile ducts, with inflammatory cell infiltration, fourth week after common bile duct ligation, H&E stain, ×100.

Figure 7.

Portal-portal or portal-central areas are connected by proliferated bile ducts, and hepatic lobular structures are distorted, sixth week after common bile duct ligation, Masson-trichrome stain, ×40.

Figure 8.

Most hepatic lobular areas are replaced by proliferated bile ducts and fibrous tissues (a feature of secondary biliary cirrhosis), Masson-trichrome stain, eighth week after common bile duct ligation, ×100.

Figure 9.

Normal portal areas were preserved. Hepatic artery, bile duct and portal vein were stained with alpha-smooth muscle actin. Control group, alpha-smooth muscle actin immunohistochemical stain.

Figure 10.

Focal necrotic area in the hepatic lobule was found and alpha-smooth muscle actin stain was positive in some areas, second week after common bile duct ligation, alpha-smooth muscle actin immunohistochemical stain.

Figure 11.

Normal hepatic lobular areas are replaced by proliferated bile ducts. Areas of positive stain with alpha-smooth muscle actin were prominent compared to fourth week, sixth week after common bile duct ligation, alpha-smooth muscle actin immunohistochemical stain.

Figure 12.

Most hepatic lobular areas are replaced by proliferative bile ducts and fibrous tissue. Alpha-smooth muscle actin was stained in proliferative periductular areas, eighth week after common bile duct ligation, alpha-smooth muscle actin immunohistochemical stain.

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Week	Group	Body wt.	Liver & cyst wt.
1W	I	390.0	12.9
II	271.7±22.5	14.0±2.9
2W	I	390.0	15.4
II	297.5±36.9	23.9±6.7
4W	I	370.0	15.9
II	327.5±55.6	33.3±6.7
6W	I	500.0	18.4
II	360.0±41.1	42.4±12.4	27.2±7.7
8W	I	450.0	15.5
II	426.0±55.5	34.0±3.7	28.7±1.9
10W	I	470.0	17.1
II	454.0±60.2	37.4±8.8	28.2±9.1

Table 2.

The Changes of Serum Enzyme Values

Week	Group	T.P (g/L)	Alb (g/L)	AST (IU/L)	ALT (IU/L)	TB (mg/L)	ALP (IU/L)	GGT (IU/L)
1W	I	5.8	3.5	121.0	34.0	0.3	356.0	1.0
1W	II	5.6±0.8	3.2±0.6	452.0±151.6	129.3±68.9	5.7±4.7	376.0±74.3	4.6±2.1
2W	I	5.8	3.7	123	34.0	0.2	293.0	1.0
2W	II	6.5±0.3	3.6±0.2	870.0±234.5	167.5±63.6	7.7±5.2	433.0 ±111.4	15.3±12.0
4W	I	5.5	3.4	81.0	33.0	0.3	169.0	0.0
4W	II	6.6±0.9	2.9±0.8	572.0±223.2	111.8±58.6	8.2±1.6	428.3 ±57.1	18.0±4.9
6W	I	6.2	3.6	72.0	37.0	0.2	72	1.0
6W	II	6.4±1.3	2.3±0.4	827.3±305.8	156.9±59.5	8.7±1.6	417.9 ±98.7	28.8±23.3
8W	I	5.9	3.3	91.0	25.0	0.3	118.0	1.0
8W	II	5.9±1.1	2.2±0.4	417.2±182.8	109.6±36.0	4.5±1.1	265.8 ±76.4	18.4±6.9
10W	I	5.8	3.5	77.0	40.0	0.1	112.0	1.0
10W	II	7.0±1.2	2.5±0.6	440.8±94.8	95.6±21.7	4.4±1.6	343.8±84.6	34.8±55.5

I, Control group; II, Common bile duct ligation group; AST, aspartate aminotransferase; ALT, alanine aminotransferase; ALP, alkaline phosphatase; TB, total bilirubin; GGT, gamma glutamyl transpeptidase

Week	Group	TGF-β1 (pg/mL)	IL-10 (pg/mL)
1W	I	1115.5	6.1
1W	II	8594.6±4898.3	18.1±21.5
2W	I	1160.9	11.9
2W	II	9115.3±8688.5	26.2±34.2
4W	I	1057.0	0.0
4W	II	8337.6±3727.9	2.7±2.7
6W	I	1795.7	3.7
6W	II	13055.5±6339.3	0.7±1.7
8W	I	4898.8	0.0
8W	II	12229.7±8914.8	0.4±1.1
10W	I	5469.0	0.0
10W	II	9069.7±5450.3	1.3±3.1