Background
Hepatitis C virus (HCV) infects >2 % of the world population, with an estimated >500,000 new infections annually in the highest endemic country, Egypt [
1]. Although some HCV-infected individuals can resolve infection without drug treatment, ~70 % develop chronic hepatitis and, over a period of 20–30 y, 20–30 % will develop liver cirrhosis and 1–5 % will develop hepatocellular carcinoma [
2]. HCV is classified in the
Hepacivirus genus within the
Flaviviridae family. The structural HCV proteins include the core protein and transmembrane glycoprotein, E1 and E2 [
3]. HCV has six nonstructural proteins; NS2, NS3, NS4A, NS4B, NS5A and NS5B [
4].
The humoral response to HCV infection is broadly targeted, with antibodies to both structural and non-structural proteins found in most cases [
5]. Although the commercial methodology to detect HCV-specific RNA and antibody responses in patient sera has greatly advanced in recent years, there is no detailed information of the immunogenicity of different HCV proteins in patients suffering from chronic HCV infection [
6]. On the other hand, healthy carriers of HCV infection exhibit a specific antibody response against HCV antigens, which could play a role in disease control. Detection of these antibodies may permit a thorough characterization of this response and further identify particular antibodies with potential clinical value [
7].
HCV antibody screening tests with enzyme-linked immunosorbent assays (ELISA), were proven to be both highly reliable and cost effective, which led to their almost universal utilization as a first-level screening procedure. However, both
false positive [HCV-positive according to ELISA, but negative with a second-level recombinant immunoblot assay (RIBA)] and
indeterminate results (HCV-positive with ELISA, indeterminate results with RIBA) may occur [
8]. RIBA is the preferred supplementary serological testing method due to its robust specificity [
9].
In this study, our primary aim was to determine the qualitative differences in host antibody responses to different HCV proteins in Egyptian chronic HCV infection and health care workers and their correlation to clinical outcome. Our secondary aim was to assess the need for RIBA testing in a high prevalence setting as found in Egypt to discriminate true positive from false positive anti-HCV antibody status.
Methods
Subjects and sample collection
Prior to initiation, this study received approval by the Ethical Committee of the Faculty of Medicine, Ain Shams University. The study included a total of 167 individuals in three groups. Group I: included 77 ELISA HCV antibody positive high risk HCWs (22 males and 55 females) with a mean age of 41.1 ± 10.9 years who worked at Ain Shams University laboratory and blood bank and were thus considered a high risk health care population. Group II: included 56 presumably uninfected individuals (34 males and 22 females) with a mean age of 56.2 ± 12.5 years enrolled from Ain Shams University Hospital who were well characterized asymptomatic patients with normal liver enzymes and negative for HCV RNA. Their ELISA HCV antibody S/C ratio ranged from 0.9 to <5. Group III: This group included 34 patients (17 males and 17 females) with a mean age of 42.5 ± 8.1 years enrolled from outpatient clinics of Ain Shams University Hospital with persistent HCV viral replication, elevated liver enzymes and chronic HCV related liver disease.
Venous blood samples (5 mL) were obtained from all participants. Samples were allowed to clot and sera were then separated by centrifugation (3500 rpm, 20 min, 25 °C) and then stored in aliquots at −20 °C until used for analysis of the various parameters outlined below.
Measurement of liver enzymes
Serum levels of Alanine aminotransferase (ALT) and aspartate aminotransferase (AST) were determined on a Synchron CX-9 chemistry analyzer (Beckman Instruments Inc., CA, USA). ALT and AST levels below 40 were considered normal.
Detection of HCV antibodies by ELISA
Presence of Anti-HCV antibodies was assessed using by 3rd generation ELISA (Diasorin S.P.A., Italy). The samples were considered positive for anti-HCV antibodies when the index values (S/CO) were >1.1, non-reactive when values were ≤0.9 and indeterminate when values ranged between >0.9 and 1.1.
Detection of HCV RNA
Real time polymerase chain reaction was used for detection and quantitation of HCV RNA. HCV RNA was extracted from serum using QIAamp Viral RNA Mini Kit (Qiagen, Duesseldorf, Germany), then, the extract was added to Brilliant QRT-PCR 1-step Master Mix (Stratagene, La Jolla, USA) and real-time RT-PCR was done on Stratagene Mx3000P device.
Recombinant immunoblot assay
The amount and profile of the HCV antibody was confirmed by the semiquantitative recombinant immunoblot assay (RIBA), using INNO-LIA™HCV Score supplied by INNOGENETICS, Belgium. The INNO-LIA® HCV Score assay utilizes well-defined antigens derived from HCV immunodominant proteins from the core region, the E2 hypervariable region (HVR), the NS3 helicase region and the NS4A, NS4B and NS5A regions. Band reactivity is graded by visual calibration against IgG control bands present on each strip. The intensity of the colored bands is proportional to the amount of bound antibody and is graded as - (none), ± and 1+ to 4.
A sample was considered positive when at least two HCV bands had reactivity of ± or higher, indeterminate when either a single NS3 band had a reactivity of ± or higher, or any other single band had reactivity of +1 or higher, and a result was considered negative either when no band reactivity was present or when only one HCV antigen line had a reactivity of ±, except when the reactivity was observed for NS3.
HCV Antibody results’ interpretation
Interpretation of RIBA results with ELISA results was done as follows; sera were considered 1- true positive: anti-HCV antibodies indeterminate or positive by ELISA and positive by RIBA, 2- false positive: anti-HCV antibodies positive by ELISA with either indeterminate or negative RIBA or anti-HCV antibodies indeterminate by ELISA with negative RIBA, 3- indeterminate: anti-HCV antibodies are indeterminate by both ELISA and RIBA and 4- false negative: anti-HCV antibodies negative by ELISA and positive or indeterminate by RIBA.
Statistical analyses
Statistical analysis was carried out with SPSS statistical software version 22.0 (SPSS Inc., Chicago, IL, USA) for Windows and a p-value < 0.05 was considered as significantly different and a p-value < 0.01 was considered as highly significant.
Discussion
Hepatitis C virus is a global health problem and the World Health Organization estimates that at least 170 million people are infected with HCV worldwide, with most of these concentrated in developing countries. The high incidence of HCV in Egypt (14.7 % of the adult population is HCV seropositive) provides the unique opportunity to learn a lot about HCV [
1].
The diagnosis of HCV infection is based on the detection of anti-HCV and HCV RNA. Detection of anti-HCV by immunoassay is the screening test used to evaluate HCV exposure [
10]. However, among populations with low (<10 %) prevalence of HCV infection, assays for anti-HCV antibodies show high false-positive rates [
11] which require confirmation with other more specific supplementary tests. Recombinant immunoblot assay is the preferred supplementary serological testing method due to its robust specificity [
9,
12,
13]. According to the 2003 Centers for Disease Control and Prevention (CDC) guidelines, positive anti-HCV screening results should be confirmed using RIBA to confirm positive screening results and differentiate false positivity from true HCV exposure [
14]. However, the only Food and Drug Administration (FDA) licensed supplemental anti-HCV test in the united states, Chiron RIBA HCV 3.0, has been permanently discontinued in 2011. In May of 2013, CDC issued an update on the HCV testing approach, in which it stated that the only other FDA approved supplemental tests for HCV infection are those that detect HCV viremia and recommended that future studies are needed to evaluate the performance of HCV testing without RIBA [
15]. In spite of the CDC decision to remove RIBA from the diagnostic algorithm for HCV, our results indicate the necessity for continuing the use of RIBA. Egypt has the highest prevalence of HCV in the world and our results show that screening by ELISA resulted in a false positive status of 28.6 % (22/77) in HCW and 8.9 % (5/56) in presumably uninfected individuals. These cases all had a negative PCR and would have been considered as previous exposure to HCV for follow up. With the use of RIBA, their HCV status is negative with no need for follow up.
False positive results showed a highly significant increase in HCW when compared with both the presumably uninfected and chronic HCV cases. The higher percentage of false positive results of anti HCV in populations with high risk (HCW) may reflect either a past resolved infection [
16] or may be the product of cross-reactivity with other viral infections such as HIV or hepatitis B [
8].
Indeterminate RIBA was found in 28 cases in all the studied groups with the majority of them found in the presumably uninfected group with no viremia mainly due to a single peptide NS3 and was associated with older age. Indeterminate RIBA results with no detected viremia is consistent with results that have been previously reported [
11,
17,
18] and could involve instances in which past HCV infections occurred and were eliminated without total elimination of the antibodies [
17].
It has been thought that indeterminate RIBA results represent false positive reactions, however, Makuria et al., [
19] have shown that the majority represent waning antibody responses in persons who have recovered from a distant HCV infection. They studied cell mediate immune responses to HCV peptides using interferon gamma elispot assay. They found out that RIBA indeterminates had strong cell mediated immune (CMI) responses, similar to those who had spontaneously recovered from HCV infection and different from those chronically infected and normal controls. They also used Luciferase Immunoprecipitation System (LIPS), and reported a stepwise diminution in antibody level from being a chronic carrier, to spontaneously recovered, to RIBA indeterminate.
The association of indeterminate RIBA results with older age is consistent with what Makuria et al. [
19] has also reported in their study. They reported that RIBA-indeterminate blood donors were older than spontaneously recovered subjects or chronic HCV carriers. The older age of this group suggests that their HCV exposure might have been in the remote past allowing time for some anti-HCV antibody responses to have waned. Supporting this concept is the finding of Seeff et al. [
20] who found that complete loss of antibody was shown in a retrospective-prospective study where 7 % of subjects who had anti-HCV in their original stored sample, no longer had antibody when recalled 23 years later. Interestingly, Sillanpää and coworkers [
6] analysed sera from five HCV RNA and antibody positive patients during a period of 18 to 25 month. The antibody levels against the major immunogenic proteins were found to remain relatively constant. However, in three patients there were some changes in anti-HCV antibody levels, namely a weak decrease in the core and NS specific antibody levels during the follow-up period. Similar analysis by Muerhoff et al. [
21] revealed that while in most cases anti-HCV antibodies remain at a constant level, there were some individuals whose antibody levels showed some fluctuation.
While waning antibody responses could explain RIBA indeterminates in HCV RNA negative individuals, we think that RIBA indeterminate results in the HCV RNA positive patients (2 chronic HCV patients), in our study, could be due to poor humoral immune response.
We found that the majority of RIBA indeterminates in presumably uninfected subjects presented antibodies that bind to HCV NS3 peptides. Similar results have been reported previously by Pereira et al. [
9] who found anti-NS3 antibodies (86 %; 12/14) and anti-core antibodies (14 %; 2/14) when examining blood donors.
We focused on the study of the immunogenicity of various HCV proteins in order to reveal which viral proteins are the targets of humoral anti-HCV immune responses in humans. We examined the frequency of anti-HCV antibody responses against individual HCV proteins using RIBA test in chronic HCV, HCW and presumably uninfected subjects.
The frequency distribution of the antibody reactivity in the studied groups showed that antibodies to NS3 were lower in HCW than the other two groups and were not the most frequent antibody detected. Antibodies to NS3 have been previously associated with viral persistence. Individuals with viral persistence had higher antibody responses to NS3 as compared with individuals with apparent viral clearance from blood. Apparent viral clearance from blood was associated with a significant decrease of antibodies to NS3, independent of HCV genotype, as compared with individuals with persistent viremia [
22].
In the present study, although HCV infection elicits different antibody profiles in studied group, Core 2 and NS3 were identified to separate the chronic state from HCW, while antibodies against both Core 1 and NS4 can differentiate chronic from presumably uninfected subjects. The highly significant increase of core protein in chronic HCV may be due to the fact that HCV core protein was identified as an immune-modulatory molecule suppressing T lymphocyte responsiveness through its interaction with complement receptor (gC1qR). The binding of extracellular core to gC1qR displayed on T cell surface leads to CD4+ T cell deregulation and suppression of CD8+ T cell function [
23]. Moreover, HCV-core and non-structural components; NS3 and NS5A proteins, directly induce OS that results in liver damage during HCV infection [
24]. These results show that antibody responses to various HCV proteins show considerable differences in frequency with certain proteins being highly immunogenic in all HCV-infected individuals while E2 were very poorly immunogenic. Beld et al. [
22] stated that their findings suggest that NS3 and NS5 antibody titers may be a marker for chronicity and an alternative for monitoring efficacy of HCV therapy.
The presence of E2 in low frequency in presumably uninfected subjects and its highly significant increase in chronic and HCW subjects were concordant with a study carried out by Chen and coworkers [
25] among 60 chronic HCV patients. They revealed E2 antibodies in 98 %, core in 97 %, NS3 in 88 %, NS5 in 68 % and NS4 in 48 % of the cases. Similarly, in a another study, anti-envelope protein antibodies (anti E2) were present less frequently in patients with serological viral clearance compared with those with viral persistence, showing that anti-envelope antibody titer correlates with HCV viremia [
26].
The reactivity to three or more bands in the RIBA analysis was significantly increased in chronic HCV and HCW in comparison to presumably uninfected subjects. However, the number of positive bands present on the RIBA strips was not correlated with the viral load in chronic HCV. Although, Pereira et al., also reported that it was not possible to confirm any relationship between the presence of viremia and the number of bands with observed reactivity using RIBA, they found that HCV viral load is high (>850,000 IU/m) in 65 % (15/23) of the samples that showed reactivity in all four bands [
9].
Acknowledgments
The authors would like to acknowledge the Egyptian Science and Technology Development Fund (STDF) for their support and thank the study participants.