Immunological Studies in Patients with HBsAg-positive Chronic Active Hepatitis:

—Spontaneous Lymphocyte Transformation and Natural Killer Cell Activity—

Article information

Korean J Intern Med. 1987;2(2):221-226
Department of Internal Medicine and Cancer Research Institute, Kosin Medical College, Busan, Korea
*Department of Internal Medicine, College of Medicine, Kyungpook National University, Taegu, Korea
Address reprint requests: Byung Chae Park, M.D., Departmant of Internal Medicine and Cancer Research Institute, Kosin Medical College, Suh-ku, 34 Amnamdong, Busan 680, Korea

Abstract

The present study was to address the nature of cells which are responsible for enhanced spontaneous lymphocyte transformation (SLT) observed in patients with HBsAg-positive chronic active hepatitis (CAH). The subjects consisted of 34 cases with HBsAg-positive CAH (group I), 31 HBsAg carrier (group II), and 27 normal persons (group III) who had no serological evidence of hepatitis B virus (HBV) infection. SLT values and the number of cells bearing HLA-DR antigens in group I (1021.45±276.40 cpm, 36.94±4.90%) were significantly (p<0.01) elevated as compared to group II (103.74±30.44 cpm, 13.26± 4.72%) and III (118.92 ± 30.84 cpm, 14.93±5.10%), but there was no difference of the number of the IL-2 receptor-bearing cells among each groups. Though natural killer (NK) cell activity in both group I (65.42±15.77%) and II (59.14±14.89%) were significantly enhanced as compared to group III (46.25±20.20%), there was no difference in between group I and II. These findings indicate that the cells bearing HLA-DR antigen, but not NK cells, are responsible for the enhanced SLT in patients with CAH.

INTRODUCTION

The prominent intrahepatic mononuclear inflammatory cell infiltrate characteristic of chronic viral B hepatitis suggests that the associated hepatocellular injury may be mediated by cell-mediated autoimmune mechanisms1). This autoimmune hypothesis seems to be supported by recent reports describing the presence of relevant cytotoxic effector lymphocytes capable of killing autologous hepatocytes24) and observations of defective immunoregulatory suppressor cell function57) in the peripheral blood mononuclear cell (PBMNC) population of patients with chronic hepatitis B virus (HBV) infection.

However, since those assays concerning T cell-mediated cytotoxic reaction requiring major histocompatibility complex (MHC)-restriction8) and specific T suppressor cell function are not possible in an vivo system, and because the precise nature of target antigens aganist which effector cells are reacting is not known, the pathogenetic mechnaisms of hepatocellular damage of those patients have not yet been clarified. Moreover, since most of those assays are rather complicated in vitro tests, it is difficult to use as immune monitors in routine clinical laboratories, in assessing the activity and prognosis of chronic hepatitis.

Spontaneous lymphocyte transformation (SLT) assay has been used as an immune monitor in assessing the activity and prognosis of chronic active hepatitis (CAH)910). SLT measures an in vitro blastogenic property of circulating lymphocytes without addition of mitogens and/or antigens and represent therefore a measure of the blastogenic activity of lymphoctyes which were already stimulated in vivo11). We observed in the previous study that SLT in patients with HBsAg-positive CAH was significantly enhanced and postulated that SLT test might be a useful in vitro assay for the understanding of pathogenetic mechanisms as well as for better assessment of the activity of HBsAg-positive CAH. The present study was designed to investigate the nature of the lymphocytes which are responsible for enhanced SLT observed in those cases, by using mouse monoclonal antibodies to human HLA-DR antigens and the interleukin-2 (IL-2) receptor (Tac). In addition, we also examined natural killer (NK) cell activity of PBMNC of those patients.

MATERIALS AND METHODS

1. Subjects

Ninty-two subjects entered into this study. These included 34 patients with HBsAg-positivie CAH (group I) diagnosed by clinical12) and histological observation according to criteria of De-Groote et al13), and 31 chronic HBsAg carriers (group II) with normal serum transaminases level during observation period of at least 6 months. Twenty-seven normal control persons without clinical evidence of liver diseases and HBV infection (group III) were included as a control group. The ranges of serum transaminases and HBV serology results were summarized in Table 1. None of these subjects was receiving corticosteroid or other immunosuppressive therapy. Patients with alcoholic liver disease, advanced liver cirrhosis, primary hepatocellular carcinoma, organ transplantation or with known lymphoproliferative diseases were excluded from this study.

Laboratory Findings in Patient Groups

2. Isolation of Perepheral Blood Mononuclear Cells (PBMNC)

PBMNC were isolated using a method described elsewhere14). Briefly, blood samples form each subject were collected by venipuncture into a heparinized (10 U/ml blood) syringe. PBMNC were seperated by centrifugation on a Ficoll-Hypaque gradient15), and washed three times with phosphate-buffered saline (PBS, 0.15M, PH 7.2) without calcium and magnesium, counted and resuspended at a cell density of 106/ml in RPMI 1640 (Flow) medium supplemented with 5% fetal bovine serum (FBS, Gibco Lab., New York, NY, U. S.A.).

3. Spontaneous Lymphocyte Transformation (SLT)

SLT asay of PBMNC was carried out according to the method described by Vessella et al.11). and Crowther et al.16). with minor modifications. Four × 105 PBMNC in 0.25 ml of RPMI 1640 supplemented with 20% heat-inactivated pooled human AB plasma were cultured in a microtitration plate (round-bottomed, Costar, 205 Broadway/Camgridge, MA, U.S.A.) at 37°C in humidified atmosphere containing 5% CO2. At the start of cultivation, the cells were labelled with 1 uCi/well of 3 H-thymidine (Tritiated thymidine, SA: 20 Ci/mM, The Radiochemical Centre, Amersham) and harvested 18 hr later using a cell harvestor (Cell harvestor 530, Flow). The cell pellets on the filer paper were dissolved for 4 hr at room temperature in 2ml of Insta-gel (Packard). The radioactivity was counted by a Packard Tri-carb Liquid Scintillation Spectrometer (Model 4530). All cutures were carried out in triplicate under sterile condition.

4. Determination of HLA-DR Antigens and the IL-2 Receptor-bearing Cells

Cells bearing HLA-DR antigens and IL-2 receptor (Tac) were determined by indirect immunofluorescent staining by using mouse anti-human monoclonal antibdies (MAb). Two MAbs are used; mouse anti-human HLA-DR MAb (Ortho Pharmaceutical Corp., Raritan, NJ, U.S.A.) reacting with a varity of human cells including activated T cells, B cells, and macrogphage17) bearing HLA-DR antigens, and mouse anti-human IL-2 receptor MAb (T cell Sciences, Inc. Cambridge, MA, U.S.A.) reacting with activiated T lymphocytes18). A volumer of 0.1 ml of PBMNC suspension (2 × 106/ml) was mixed with 5 ul of each reconstituted MAb (50 ug/ml) and incubated at 4°c for 30 min. After incubation the cells were washed three times in cold PBS and resuspended in 0.1 ml PBS. They were stained at 4°C for 30 min with fluorescein-conjugated goat anti-mouse IgG (GAM/lgG-Fc/FITC, Ortho Pharmaceutical Corp., Raritan, NJ, U. S.A.) and then washed three times in cold PBS and resuspended in a drop of PBS. Membrane immunofluorescence was evaluated with AO immunofluorescent microscope equipped with an excitation filter, a barrier filter, and a incident illumination. Three to four hudred cells were counted for the calculation of percentage of the positively stained cells.

5. In Vitro Cytotoxic Assay

Nk cell activity of PBMNC from each subject aganinst the human erythroleukemic cell line K562 was carried out by using a 4hr 51Cr release assay19). Aliquots containing 1.5×106 target cells (K562) were labelled with 100 uCi of sodium Chromate solution (Korea advanced energy research institute, Seoul, Korea.) for 90 min o.5 ml of RPMI 1640 supplemented with 10% FBS. After three washings, 104 cells in 0.1 ml of medium were added into U-bottomed microtiter plates (Costar, 205 Broadway/Cambridge, MA, U.S.A.). In each assay, the effector cells were added to a constant number of target cells (104) at final effector: target cell ratio of 40:1. After incubation for 4hr at 37°c in a humidified atmosphere containing 5% CO2 in air, supernatant were harvested and counted in a gamma counter. Per cent specific 51Cr release was calculated as follows:

cpm test releasecpm spontaneous releasecpm maximum releasecpm spontaneous release×100.

Spontaneous and maximum releases are cpm release from target cells inculbated in medium alone and in 1 N HCI-added medium, respectively. The range of spontaneous release from K562 was 7–14% of the total isotope count. Maximum release determined by 1 N HCl was about 95%.

RESULTS

1. SLT Assay

The SLT values of patients with HBsAg-positive CAH (group I) was significantly (p<0.001) elevated when compared to HBsAg carrier (group II) or healthy controls (group III) who had no serological evidences of HBV infection. However, there are no appreciable differences of SLT values between HBsAg carriers (group II) and control persons (group III).

2. Determination of HLA-DR Antigens and the IL-2 Receptor-bearing Cells

As summarized in Table 2, the number of cells bearing HLA-DR antigens in HBsAg-positive CAH (group I) with enhanced SLT reaction was significaclty (p<0.01) increased as compared to those of HBsAg carriers and normal controls. However, no such differences were observed in between group II and III patients. Neither CAH patients nor HBsAg carriers showed an increased number of cells bearing IL-2 receptor defined by anti-Tac MAb when compared to normal contorls.

SLT*, HAL-DR Antigens and Tac-Assay in Patients Groups

3. NK Cell Activity

Table 2 shows comparison of NK cell activity in PBMNC from patients with HBsAg-postivie CAH, HBsAg carriers, and normal healthy controls. NK activity of CAH patients and carriers was 65.42± 15.77% and 59.04±14.89%, respectively. The difference in between these two groups was not statistically significant. On the other hand, NK activity observed in normal healthy controls was significantly (p<0.05) lower than those of CAH patients and carriers.

DISCUSSION

We previously reported that SLT of PBMNC in patients with HBsAg-positive CAH was significantly enhanced as compared to the cases of inactive CAH and HBsAg carriers10). Since enhanced SLT of PBMNC usually reflects the presence of proliferating cell population(s) in the peripheral blood and because the alterations in serum transaminases during relapsing phase of CAH lagged one to two weeks behind changes in SLT response, we postulated that abnormal SLT responses observed in those patients might be related to a primary pathogenetic determinant in on-going liver injury.

The current study was undertaken to address two issues of interest related to SLT responses observed in chronic hepatitis B viral infection; first, whether the elevated SLT value is associated with an increased number in PBMNC of activated T lymphocytes bearing HLA-DR antigens and/or the IL-2 receptor; second, whether NK cell activity might be correlated to the enhanced SLT. The results of the present study, while confirming our previous results, did not show a direct correlation between SLT values and the number of activated T cells bearing HLA-DR antigens and/or the IL-2 receptor, as tested by single and double immunofluorescent staining techniques. Instead, the enhanced SLT response was correlated with an increased number in PBMNC of cells bearing HLA-DR antigens. Although these findings, the presence of increased number of HLA-DR antigens-bearing cells but the virtual absence of IL-2 receptor-bearing cells, is consistent with our previous result that mixed lymphocyte culture (MLC) reaction in those patients were significantly enhanced in both syngeneic and allogeneic co-cultures, the immunological meaning of the data available herein are indeed open to several interpretations. Firstly, the increased number of HLA-DR antigens-bearing cells together with enhanced SLT responses in PBMNC of those patiens might be caused by an increased blastogenic transformation of B lymphocytes. This impression was indeed reported by Budillon et al20). who observed, in PBMNC of patients with HBsAg-posive CAH, a significant correlation between the decreased level of T active cells and increased blastogenic transformation of B lymphocytes as tested by spontaneous thymidine incorporation. Since B cells also express HLA-DR antigens17,21), one may speculate that the increased number of cells bearing HLA-DR antigens observed in the present study may be caused by enhanced blastogenic transformation of B lymphocytes. This impression, in conjunction with other recent report7) describing impaired suppressor cell function and subsequently increased spontaneous IgG production by B lymphocytes, provides a substantial evidences in favor of B lymphocyte series in enhancing the SLT responses. It should be, however, pointed out that alteration of SLT during relapsing and remission phase of CAH precede the changes of serum tranaminases and therefore it may probably be related to a promary pathogenetic determinatn in liver cell injury. Moreover, our recent preliminary observation shows that a substantial number of cells bearing HLA-DR antigens were still remained even after removal of B lymphocytes. Some recent studies22,23) report that the mononulear cells which infiltrated in areas of piecemeal necrosis and spotty necrosis are not killer (K) cells which are responsible for antibody dependent cellular cytotoxidity (ADCC) but are predominantly CD4-and CD8-positive T cells. These findings are in fact not consistent with the hypothesis stating that enhanced blastogeneic transformation of B cells and subsequently increased production of various antibodies may be an important pathogenetic determinant of CAH.

Secondly, in spite of the virtual absence of T cells bearing IL-2 receptor observed in patients of HBsAg-positive CAH, the possibility should still be considered that the cells bearing HLA-DR antigens may be activated T cells. It has been known that the IL-2 receptor absent in normal resting T cells appears when T cells are stimulated by antigens18,2426). Expression on T cells of the IL-2 receptor is much dependent in circulation blood on stimulating antigens and its expression on activated T cells in vivo is much more transient than HLA-DR antigens27). Although it might be possible that in vivo activated T cells in pateitns with HBsAg-poitive CAH may lose the IL-2 receptor earlier than HLA-Dr antigens and there have been a number of reports describing the presence of T cells bearing HLA-DR antigens in patients with HBsAg-positive CAH7,28), we at this stage do not have a clear explanation on the presence of cells which devoid of the IL-2 receptor in those cases. On the basis of our preliminary results stated previously, however, the remained cell population bearing HLA-DR antigens after reomval of B cells are likely to be T cells. Much more studies including simultaneous examination of T cell markers for the circulating PBMNC as well as for infiltrated cells in areas of liver cell inflammation, however, should be done for better assessment of T cell function playing in pathogenetic mechanisms of CAH.

NK cells have been implicated in resistance aganist viral infections29,30). Since enhanced cytolytic activity is usually demonstrated after activation of these cells by a variety of stimuli, including viral infections, interferons31), and IL-23233), it is quite possible to consider that activation and subsequently enhanced NK activity could be observed in patients with chronic HBV infection. We observed indeed an enhanced NK activity in both the patiehts with CAH and HBsAg carriers as compared to normal controls. However, NK activity in CAH patients with an enhanced SLT response was not different from those of HBsAg carriers and therfore NK cells may not play a role in hepatocellular injury observed in CAH. Although similar observation was also reported by other workers34), more convincing evidence supportive to this hypothesis was recently reported by Van den Oord et al23) who clearly demonstrated that mononulear cells infiltrated in areas of piece meal necrosis were not NK or K cells. All these findings indicate that NK cells do not play a role in eliminating HBV-infected cells and for actual hepatocellular damage observed in patients with CAH.

In conclusion, although we do not know yet the precise nature of HLA-DR antigen-bearing T cells in our cases, we speculate that the high SLT values together with the increased number of HLA-DR antigen-bearing cells in PBMNC of patients with HBsAg-positive CAH may be an in vitro measurement of the level of activated T cells generated in vivo by the presence of unknown neoantigen (s) against which host lymphocytes are reacting. These activated lymphocytes can be recirculated and further differentiated into cytotoxic effector cells which are infiltrated in areas of piece meal necrosis leading to hepatocellular injury.

NK Activity in Chronic Liver Diseases

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Article information Continued

Table 1.

Laboratory Findings in Patient Groups

Patient group Age (yr) SGOT(IU/L)* (5.0–45.0) SGPT(IU/L)* (5.0–40.0) HBsAg/HBcAb/HBsAb
I(n=34)HBsAg(+)CAH 37.5 ± 6.8 124.7 ± 40.4 164.98 ±50.5 + / + / −
II(n=31)HBsAg- carrier 39.4 ± 5.6 19.7 ± 3.9 20.32 ± 4.9 + / + / −
III(n=27)All HBV markers() 40.2 ±6.4 20.4 ± 4.8 19.32 ± 4.8 − / − / −

− CAH in group was diagnosed by liver biopsy findings

*

Normal values.

Table 2.

SLT*, HAL-DR Antigens and Tac-Assay in Patients Groups

Groups and number of cases SLT (cpm ± SD) HLA-DR antigens (+) cells (%) Tac (+) ** cells (%)
1 (n=34) 1021.45 ± 276.40a) 36.94 ± 4.90d) < 0.5
II (n=31) 103.74 ± 30.44b) 13.26 ± 4.72e) < 0.5
III (n=27) 118.92 ± 30.84c) 14.43 ± 5.10f) < 0.5
*

SLT: Spontaneous lymphocyte transformation

**

Tac: Interleukin–2 (IL–2) receptor p-value between; –(a) and (b): < 0.01, (a) and (c): < 0.01, – (d) and (e): < 0.01, (d) and (f); < 0.01

Table 3.

NK Activity in Chronic Liver Diseases

Groups SGPT (IU/L) NK activity (Percent ± SD)
Group I(n=13)HBsAg (+)CAH 142.42 ±49.32 65.42 ±15.77a)
Group II(n=11)HBV carrier 20.32 ± 4.90 59.04 ± 14.89b)
Group III(n=12)All HBV markers() 19.32 ± 4.80 46.25 ± 20.20 c)

P value between: (a) and (b): NS

(b) and (c): < 0.05

(a) and (c): < 0.05