Next Article in Journal
Infectious Bronchitis Coronavirus: Genome Evolution in Vaccinated and Non-Vaccinated SPF Chickens
Next Article in Special Issue
The Transmission Route and Selection Pressure in HCV Subtype 3a and 3b Chinese Infections: Evolutionary Kinetics and Selective Force Analysis
Previous Article in Journal
Transmission, Strain Diversity, and Zoonotic Potential of Chronic Wasting Disease
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Viruses
Volume 14
Issue 7
10.3390/v14071391
viruses-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

The Neutralizing Antibody Responses of Individuals That Spontaneously Resolve Hepatitis C Virus Infection

by
Vanessa M. Cowton
1,*,
James I. Dunlop
1,
Sarah J. Cole
1,
Rachael E. Swann
1,2 and
Arvind H. Patel
1
1
MRC-University of Glasgow Centre for Virus Research, University of Glasgow, Glasgow G61 1QH, UK
2
Department of Gastroenterology, Queen Elizabeth University Hospital, Glasgow G51 4TF, UK
*
Author to whom correspondence should be addressed.
Viruses 2022, 14(7), 1391; https://doi.org/10.3390/v14071391
Submission received: 28 April 2022 / Revised: 15 June 2022 / Accepted: 17 June 2022 / Published: 25 June 2022
(This article belongs to the Special Issue Impact of HCV Diversity in Natural Infection and Models of Infection)
Browse Figures
Versions Notes

Abstract

:
Hepatitis C virus (HCV) infection is a major global health problem. In the majority of cases the virus is not cleared by the host immune response and progresses to chronic infection. Studies of the neutralizing antibody responses in individuals that naturally clear infection are limited. Understanding what constitutes a successful antibody response versus one that has ‘failed’ and resulted in chronic infection is important to understand what type of antibody response would need to be elicited by a protective vaccine. Samples from spontaneous clearers are difficult to obtain therefore studies are often limited. In our study through HCV Research UK, we had access to a cohort of over 200 samples. We identified the samples that contained HCV neutralizing antibodies using ELISA and HCV pseudoparticle (HCVpp) assays. We then utilised mutagenesis and cross-competition analysis to determine the profile of the neutralizing antibody responses. In addition, we analysed a cohort of samples from chronic infection using the same techniques to enable direct comparison of the antibody profiles observed in both cohorts. We conclude that similar profiles are present in both cohorts indicating that it is not the neutralizing antibody response per se that determines the outcome of infection. These data will provide useful information for future HCV vaccine design.

1. Introduction

Hepatitis C virus (HCV) is a positive-sense RNA virus within the Flaviviridae family. The virus is extremely diverse and is classified into seven distinct genotypes and 67 subtypes [1]. Globally an estimated 70 million people are infected with HCV contributing to around 400,000 deaths annually. In recent times significant advances have been made in the development of very effective direct-acting antiviral drugs (DAAs) that can clear viral infection. However, due to the silent nature of the initial infection which is often asymptomatic many of those infected remain undiagnosed. Additionally, a significant proportion of infected individuals live in the developing world and do not have access to DAA treatment. Therefore, development of a protective vaccine is important to contribute to the prevention and eradication of this disease.
In natural infections, roughly 20–25% clear acute infection and 75–80% proceed to chronic infection [2,3]. Factors including female gender, younger age of infection, co-infection with hepatitis B virus (HBV) and specific alleles of the Il-28B (interferon-λ3) and HLA class II genes are associated with spontaneous resolution of infection [4,5,6]. While T-cell responses have long been demonstrated to be associated with spontaneous clearance [2,7,8], the role of neutralizing antibody (nAb) responses is less clear. An early study failed to detect nAbs in five out of seven individuals that spontaneously cleared the virus [9]. More recently there is evidence that an early neutralizing antibody response is involved in spontaneous clearance [10,11]. Classical spontaneous clearance refers to clearance during the acute phase of infection (6–24 months) post-infection, however spontaneous clearance of chronic infection is often overlooked despite multiple reports in the literature [12,13,14,15,16,17,18]. In many cases, clearance of chronic infection has been associated with another event including infection with other hepatitis viruses, surgery or withdrawal of antiretroviral therapy (ART). Bulteel et al. (2016) concluded that similar to spontaneous clearance during acute infection, clearance of chronic infection was also positively associated with female gender, younger age of infection and co-infection with HBV [17].
In order to inform vaccine design, it is important to understand nAb responses during spontaneous clearance. In this study we have investigated the antibody responses in a cohort of individuals that have cleared HCV infection without treatment. We compared these responses to those from individuals that have chronic HCV infection to understand if the antibody profiles are fundamentally different between these two groups. We show that the neutralizing antibodies produced by both groups target the same domains of the HCV E2 glycoprotein. Our data indicate that it is not the nature of the antibody response per se that determines outcome of infection.

2. Materials and Methods

2.1. Patient Characteristics of Spontaneous Resolver Cohort

Serum samples for the study were requested from the HCV Research UK Clinical Database and Biobank [19]. The cohort has >10,000 individuals recruited from 56 centres across the UK. The biobank provided us with 233 serum samples from individuals that had been identified in medical records as having cleared HCV infection without treatment. Ethical approval for the study was granted by the HCV Research UK Tissue and Data Access Committee.

2.2. Patient Characteristics of Chronic HCV (CHCV) Cohort

Subjects infected with chronic genotype (gt) 1 or gt 3 HCV were recruited from three local liver clinics. Those individuals with BMI over 30, co-existing liver pathologies or hepatocellular carcinoma were excluded from the study. Also recruited were healthy individuals with no liver pathologies or significant co-morbidities. All subjects completed a symptom questionnaire, baseline biochemistry, IL-28B profiles and virology, and clinical details were checked and recorded. Serum and whole blood samples were obtained and stored at −70 °C. Ethical approval was granted for this study by regional ethics committees and all patients gave informed consent.

2.3. Cell Lines

Human hepatoma Huh-7 cells and HEK-293T cells were grown in Dulbecco’s modified Eagle’s medium supplemented with 10% foetal calf serum, 5% nonessential amino acids and 200 mM l-glutamine.

2.4. Antibodies

The HCV anti-E2 human monoclonal antibodies (HmAb) CBH-4B, CBH-7, HC-1, HC-11 and HC33.1 have been described previously [20,21] and were a generous gift from Steven Foung. The sequences of the heavy and light chain sequences of monoclonal antibody 1:7 were obtained from a publish patent, synthesized and subcloned into the appropriate pFuse-ss human IgG vectors (Invivogen, San Diego, USA) [22]. The plasmids were verified by Sanger sequencing then expressed in the Expi293 expression system as per the manufacturers’ instructions (ThermoFisher Scientific, Waltham, MA, USA). After 3–5 days the medium was harvested, and IgG was purified using a HiTrap Protein G column on an ÄKTA Pure system (Cytiva, Marlborough, MA, USA).

2.5. IgG Purification

Triton X-100 was added to patient serum samples at a final concentration of 0.05% (v/v) and IgGs therein purified using Protein G IgG purification spin columns (ThermoFisher Scientific, Waltham, MA, USA). The final concentration was determined using a Nanodrop 1000 spectrophotometer (ThermoFisher Scientific, Waltham, MA, USA).

2.6. GNA Capture Assay

The ELISA to detect antibody binding to E1 and E2 glycoproteins was performed as described previously [23]. HEK-293T cells were transfected with plasmid expressing H77 Gt1a E1E2, then incubated for three days. The E1E2 glycoproteins present in the cell lysates were captured on GNA (Galanthus nivalis agglutinin) lectin coated Immulon 2HB enzyme immunoassay plates (ThermoFisher Scientific, Waltham, MA, USA). Patient sera were added at 1:500 dilution in PBS-T and bound antibodies were detected using HRP-conjugated anti-human IgG antibody (A0170, Sigma-Aldrich, St. Louis, MO, USA) and TMB (3,3′, 5,5′-tetramethylbenzidine, Thermofisher Scientific, Waltham, MA, USA) substrate. A positive control serum from an individual with chronic HCV infection was included on all plates. Absorbance values were measured at 450 nm and normalized according to the positive control, to enable comparison of separate ELISA plates. Binding to HEK-293T lysate lacking HCV glycoproteins was used as a control to eliminate false positives.

2.7. Generation of HCV Pseudoparticles (HCVpp) and Neutralization Assays

The Gt1 E1E2 HCVpp panel is composed of 11 diverse Gt1 HCVpp, as we described previously [24]. HEK-293T cells were co-transfected with plasmids expressing MLV Gag-pol, the MLV transfer vector carrying firefly luciferase reporter and HCV E1E2. After 72 h, the medium was harvested, filtered through a 0.45 µM membrane and used as a source of HCVpp as described previously [25]. For neutralization assays HCVpp and purified human IgG at 100 µg/mL were incubated together for 1 h at 37 °C, and then the mixture used to infect Huh7 cells for 3 h. The HCVpp-IgG mix was removed, and fresh media was added. At 3 days post-infection, cells were lysed and luciferase activity measured using the GloLysis Luciferase substrate assay (Promega, Madison, WI, USA).

2.8. Mutagenesis of E2 Epitopes

E1E2 mutants L413A, W420A, W529A and G530A have been described previously [26]. Site-directed mutagenesis PCR using the QuikChange II kit (Agilent, Santa Clara, CA, USA) was used to generate H77 gt1a E1E2 containing alanine substitutions at positions E2 L441 and F442. The sequence of E1E2 L441A and E1E2 L442A clones was verified by sanger sequencing. The panel of mutant E1E2 cell lysates was produced by transfecting 8µg of each plasmid into HEK-293T cells. The cells were lysed after 72 h.

2.9. Normalisation ELISA for Mutant Lysates

Lysate was added to Immulon 2HB plates (Thermo Scientific) coated with GNA and incubated at RT for 2 h. Anti-E2 mouse monoclonal (mAb) antibody ALP98 at 0.1 µg/mL was added and incubated for 1 h. Bound ALP98 was detected with 1:1000 anti-mouse-HRP (A4416, Sigma-Aldrich, St. Louis, MO, USA) then TMB reagent. Plates were washed in PBS-T (x3) between steps. Absorbance was measured at A450 nm.

2.10. Mutagenesis ELISA Assay

The GNA ELISA was adapted to detect binding to the E1E2 mutant panel. The normalised lysate was added to Immulon 2HB plates coated with GNA and incubated for 2 h. For each sample 20 µg/mL purified IgG was added and incubated for 1 h to allow binding to E1E2. A positive control of 0.1 µg/mL mouse mAb ALP98 was also included. The plates were washed in PBS-T (x3) then secondary anti-human-HRP antibody (A0170 Sigma, 1:5000) or anti-mouse-HRP (A4416 Sigma, 1:1000) was added for 1 hr. The plates were washed again in PBS-T (x6) then developed with TMB substrate. Absorbance was read at 450 nm.

2.11. Epitope Targeting by Cross-Competition Assay

Soluble gt 1a E2 (H77) protein (sE2) was purified following expression in High Five insect cells. Briefly, cells were infected with recombinant baculovirus expressing sE2 and harvested after 4 days. sE2 protein was purified from the supernatant via a His-tag using affinity chromatography on a Ni-NTA column. The sE2 at 1 µg/mL was used to coat Immulon 2HB plates then incubated with purified patient IgG at 200 µg/mL in PBS-T. The biotinylated antibodies to known epitopes were then added at a concentration close to their EC50 [27,28,29,30]. Finally, Streptavidin-HRP was added, binding was detected using TMB substrate by measuring the absorbance at 450 nm. The reduction in the relative binding of each biotinylated antibody (calculated as percentage reduction in absorbance) on addition of patient IgG compared to the PBS-T control was determined.

2.12. Analysis

The parametric t-tests and correlation statistical analysis was performed using GraphPad Prism 6 Software (GraphPad Software, San Diego, CA, USA) and SPSS v. 19.09 (IBM, New York, NY, USA).

3. Results

A retrospective cohort (SR cohort) of 233 samples from HCV spontaneous resolvers collected from 28 centres across the UK was provided by HCV Research UK [19]. All individuals included in the study have been clinically diagnosed as spontaneous clearers and critically, have never received any treatment for HCV. The demographics for the cohort are shown in Table 1. As expected for the UK, the cohort is predominantly Caucasian (90.6%) and two-thirds of the cohort are male (66.7%). The main route of infection is through intravenous drug use (67.9%). The mean age at sample collection is 45.6 yrs (range 20–80 yrs). Due to the retrospective nature of the study the clinical data for all subjects is incomplete, where it is known, the median duration from the first positive HCV test to serum collection is 5.5 yrs (range 0–23.1 yrs, no data for 13 samples) and the median duration from the first negative HCV test to serum collection is 0.38 yrs (range 0–19.9 yrs, no data for 114 samples). The median duration from confirmed positive HCV test to negative HCV test is 2.1 yrs (range 0–20.2 yrs, no data for 119 samples). Unfortunately, in many cases the true date of infection and indeed clearance could not be estimated, as a result it is difficult to determine if individuals cleared infection during the acute or chronic phase. Therefore, we did not attempt to separate the samples further into these groups The majority of samples were not genotyped, however, for the small group that we do have data for, as expected for the UK, they are evenly distributed between Gt1 and Gt3, There was also one Gt2 and one Gt4 sample.

3.1. E1E2 Binding of Spontaneous Resolver Cohort

In order to identify samples that had detectable levels of HCV antibodies we screened the sera for HCV E1E2 binding antibodies by ELISA. To setup the assay we compared two dilutions of sera (1:500 and 1:1000) and different concentrations of secondary antibody. We found that 1:500 sera dilution and 1:10,000 secondary antibody were optimal. A 1:500 sera dilution is roughly equivalent to 15–44 ng IgG based on the average range of IgG present in human sera (7.5–22 mg/mL). The binding to gt1a E1E2 strain H77 lysate was assessed for all the samples. The HCV genotype was not known for the majority of the samples therefore we chose to use strain H77 E1E2 for the screen. It is possible that we may have missed some positive sera in the screen although in our experience E1E2 antibodies present in sera from gt1–6 infected individuals can bind to strain H77 E1E2. Indeed, our positive sera group includes samples from individuals infected with HCV gt 1,2,3 and 4. A positive control sera from a chronic HCV infection was included on all ELISA plates, to enable comparison between experiments. Eighty-eight samples from the cohort tested positive for binding to H77 E1E2, these were subsequently screened for false positives by testing binding to negative control lysate that does not contain HCV E1E2. Forty-nine samples (21%) had >10% E1E2 binding relative to the positive control, thereby confirming the presence of HCV E1E2 antibodies in these samples (Figure 1a). The clinical data of these samples is provided in Supplementary Materials Table S1.

3.2. Neutralization Profile of Spontaneous Resolver Cohort

To investigate the neutralizing capacity of the spontaneous clearer samples we monitored neutralization of a panel of eleven representative gt1 panel of HCVpp which we had reported previously [24]. Neutralization was assessed using purified IgG to avoid the possibility of anomalies caused by other sera components. This also allowed a standard amount of IgG to be tested although the actual levels of E1E2 binding antibodies within the IgG population was not measured. In total, about 50% (24/49) of samples could neutralize at least one HCVpp isolate by at least 50% (Table 2). However, only five serum samples were classified as broadly-neutralizing i.e., able to neutralize six or more members of the panel by at least 50%.

3.3. Comparison with Sera from HCV Chronic Infection

We were interested to determine how the results obtained from the spontaneous resolver cohort would compare in the same assays to sera from individuals with chronic HCV infection. To address this question, we selected a small cohort of 41 serum samples from the Glasgow chronic HCV cohort [24]. This had similar demographics to the spontaneous clearer cohort. The cohort was predominantly male Caucasians and the principal route of infection was through IVDU. The samples were all either Gt1 or Gt3 (Table 1).

3.4. E1E2 Binding of Chronic Cohort

The sera were screened for binding to H77 gt1a E1E2 lysate and in parallel to the negative control lysate. The same positive control for normalization between experiments was included on the ELISA plate. For this group, perhaps not surprisingly as they have an ongoing HCV infection, we found much stronger binding to E1E2. In addition, a higher proportion of the cohort (38/41 (92.7%)) had >10% binding to H77 gt1a E1E2 lysate (Figure 1b).

3.5. Neutralization of Chronic Cohort

To enable comparison of the neutralization activity between the two cohorts, the IgG was purified from the strongest binding chronic sera (33) and neutralization of the Gt1 HCVpp panel was assessed under the same conditions. Similar to the observations for E1E2 binding, overall the chronic cohort was much more potent for neutralization. All chronic sera could neutralize at least one HCVpp isolate by at least 50% (Table 3) and more than half the cohort (18/33) was classified as broadly neutralizing. Interestingly, but perhaps not surprisingly, in both cohorts we found a significant correlation between the level of E1E2 binding and the neutralization activity of the sera (Figure 2a). In addition, there was a highly significant difference between the E1E2 binding of the cohort samples, this may explain why the chronic sera have stronger neutralization activity overall (Figure 2b).

3.6. Analysis of Neutralizing Epitopes

To address the question of whether the generated antibody response has enabled clearance of the virus because it is fundamentally distinct from the ‘failed’ antibody response during chronic infection we investigated the neutralizing epitopes targeted by sera from both cohorts. We analysed all the samples in the SR cohort that neutralized at least two HCVpp. For the CHCV cohort we randomly selected a pair of sera that neutralized two to nine HCVpp respectively. The epitopes targeted by many bNAbs have been reported in the literature. Most of these epitopes lie on the neutralizing face of the E2 molecule [31,32]. Three important regions each bound by several bNAbs are Domain E (E2 aa412-423), Domain D (E2 aa 420-428, 441-443, 616) and Domain B (E2 aa 431-439, 529-535). Within these regions it is notable that particular highly conserved residues are recognised by multiple bNAbs. We created a small group of E1E2 mutants, in a gt1a H77 background, each with a key epitope-binding residue mutated to alanine. Within Domain E we selected L413 and W420, for Domain D, L441 and F442 and finally for Domain B, W539 and G530. Cell lysates containing the mutant E1E2 proteins were produced and used in a GNA-ELISA. The binding of purified IgG to wildtype (wt) gt1a H77 E1E2 and the E1E2 carrying the mutant epitope was measured and expressed relative to the wt gt1a H77 E1E2 control (Table 4). The Domain E mutants did not strongly inhibit binding of any sera, however several sera, bound more strongly (>150%) to L413A and W420A. This suggests that there are no antibodies binding directly to these residues in the sera, at least at a level sufficient for detection in this assay. The increase in binding suggests that mutation of L413A or W420A has altered the conformation of E1E2 such that some epitopes are more available, most likely within the E2 hypervariable region 1 (HVR-1) which is immediately upstream to Domain E. In contrast, mutation within the Domain D region, particularly at residue L441 reduced binding of the majority of sera in both cohorts. This suggests that within each serum, Domain D-binding antibodies are present. More interesting are the observations for Domain B, in both groups, mutation at either W529 or G530 reduced E1E2 binding indicating the presence of antibodies that bind this region. However, the G530A mutation has a significantly greater effect on the sera in the spontaneous resolver cohort than sera from the chronic cohort. This suggests that the spontaneous resolver cohort has more antibodies binding to Domain B.
In order to investigate further the epitopes bound by serum IgGs from both cohorts we performed cross-competition ELISA analysis with a group of well-characterized monoclonal antibodies (mAbs) that target different epitope regions; Domain A (CBH-4B), Domain B (HC-1, HC-11, 1.7), Domain C (CBH-7) and Domain E (HC33.1). Importantly, we assessed the cross-competition activity of each mAb against itself and the other mAbs (Table 5). As expected, in all cases the strongest competition was observed between each mAb and itself. We observed similar trends in both cohorts; none of the sera tested could compete with antibody to Domain E (HC33.1). In both cohorts there were one or two samples that could compete with the remaining antibodies targeting different regions, the non-neutralizing Domain A (CBH-4B) and Domain C (CBH-7). The majority of cross-competition between mAbs and the purified IgG from the sera was observed against the Domain B antibodies (HC-1, HC-11, 1.7). Similarly, 8/15 (53%) of SR cohort samples and 10/17 (58%) of the CHCV cohort samples could significantly inhibit binding of at least one of the Domain B antibodies (HC-1, HC-11, 1.7). A slightly higher proportion of the SR cohort (7/15 (47%)) compared to (7/17 (41%)) of the CHCV cohort samples could not cross-compete significantly with any of the mAbs tested even though they could effectively neutralize at least two different HCVpp suggesting that they contained nAbs that bound other epitopes. The most interesting of these was C1001 which could still neutralize seven different HCVpp even though it did not cross-compete with any of the mAbs tested.

4. Discussion

Our study of the neutralizing antibody responses of a large retrospective cohort of individuals that have spontaneously cleared HCV infection found that most of the SR Cohort samples did not contain detectable levels of E1E2 glycoprotein antibodies. This could be due to multiple reasons; firstly, there are examples of spontaneous clearance samples where nAbs could not be detected [9], secondly, it has been shown that while HCV antibodies can be detected within weeks of infection, antibodies to E1E2 could not be detected until much later timepoints [9,16]. In addition, studies have also shown that the antibody response wanes over time post-clearance, presumably due to lack of the presence of viral antigen [16,33] therefore even if nAbs were present initially, they may no longer be detectable as in many cases samples were collected up to several years post-clearance. Comparison of the level of detectable E1E2 glycoprotein antibodies in the sera was lower in the SR cohort than that detected in samples taken from individuals with a persistent chronic infection. Again, this is consistent with previous reports whereby the level of antibody detected in spontaneous clearers was lower than in chronic infection [9,16,34].
Similarly, when we investigated the neutralizing response against a panel of diverse Gt1 HCVpp we found that the SR cohort had lower levels of neutralization overall, compared to the CHCV cohort. This is in concordance with a previous study [9]. This could simply be a consequence of the lower levels of E1E2 binding antibodies detected in the SR cohort, indeed, we observed a strong correlation between the level of E1E2 binding and the level of neutralization. Alternatively, the lower levels of neutralization may be indicative of the breadth of neutralizing response present in the samples. We are unable to assess the level of autologous neutralization in the SC cohort samples as we do not have virus from the individuals, indeed in many cases we do not even know what genotype they were infected with. Therefore, we are reliant on assessing how efficiently the antibodies present can neutralize a heterologous, diverse panel of HCVpp. It is possible that for those individuals that cleared early during infection, they mounted effective neutralizing responses against autologous virus but as this was cleared the antibody response did not mature and diversify over time to become efficient at neutralizing different viruses. However, this is perhaps less likely as our cohort is composed of individuals that have cleared during both acute and chronic infection.
Further investigation to characterize the type of neutralizing response for both cohorts using mutagenesis and mAb cross-competition approaches showed broadly similar results for both cohorts. Interestingly, in the mutagenesis study the SR cohort samples were more sensitive to mutation of G530A in Domain B than the CHCV cohort samples. While in the cross-competition analysis, samples within both cohorts could effectively compete with the Domain B antibodies. The mutagenesis analysis indicates that a higher proportion of E1E2 antibodies present in the SR cohort bind to this region than in the CHCV cohort. Although the cross-competition analysis suggests that even though antibodies recognizing Domain B appear to be less prevalent in the CHCV samples, they are more efficient at cross-competing with the Domain B mAbs. This implies that the CHCV Domain B antibodies, though fewer, may have higher affinity for this epitope. Investigation of Domain E by mutagenesis or cross-competition analysis did not indicate the presence of antibodies binding to this region in either cohort. This is perhaps not surprising as it is well-documented that Domain E antibodies are rare [35]. Although interestingly, mutation of Domain E did increase E1E2 binding in several samples in both cohorts, this is most likely caused by these mutations making other E1E2 epitopes more accessible. The domain E region is notably a very flexible region of the E2 protein [36,37,38,39], thus mutagenesis may alter the conformation of the protein [40]. Mutagenesis analysis also indicated that most of the samples in both cohorts developed antibodies that could bind to domain D of E2. Domain B and Domain D antibodies both bind to the neutralizing face of the E2 protein and inhibit the critical interaction of E2 with the CD81 receptor, indeed the epitopes for Domain B and D overlap [21,41]. Only one sample in each cohort could compete with CBH-7 which binds to the Domain C region of E2, and this is also on the neutralizing face but does not overlap with Domains B and D [29]. Similarly, only three samples could compete with the non-neutralizing antibody CBH-4B which binds to Domain A.
A limitation of our analysis of the antibody response is that using the mutagenesis approach and the cross-competition analysis we were confined to those nAbs that have well-documented epitopes and were suited to the cross-competition assay. Consequently, with these methods we cannot detect nAbs that bind other regions of the E1E2proteins. These may be epitopes that have already been described for other HCV nAbs such as the AR4A mAb which recognises the E1E2 heterodimer [42], the recently described E1 nAbs [43], or novel nAbs which are yet to be described. We do, however, observe in both cohorts, samples that could neutralize HCVpp but could not cross-compete with any of the mAbs tested indicating the presence of different nAbs in these samples. While the mutagenesis analysis indicates Domain D antibodies in these samples, it is likely that other nAbs are also present.
Our study of nAb responses of individuals that have spontaneously cleared infection or are chronically infected with HCV has identified similar profiles of nAb responses in both cohorts. This suggests that the neutralizing responses that succeed in clearing virus infection are similar to those that ‘fail’ and lead to chronic infection. The fact that samples from both cohorts had varied nAb profiles also indicates that with the methodological approaches described in this study, there is no singular immune response that is required for clearance, suggesting that multiple factors likely contribute to clearance vs. chronicity. The timing of the antibody response has been suggested to be important both in clearance of acute infection and chronic infection [11,16,18]. Furthermore, development of nAbs stimulates virus evolution to escape the immune pressure, which in some cases has been shown to result in reduced viral ‘fitness’ [30,44,45,46]. Thus, it is probable that a complex interplay between host and virus dictates the outcome of infection.
Our findings agree with other studies that have investigated this question by other methods. Keck et al. (2019) analysed in detail broadly neutralizing antibodies present in an individual that had cleared multiple HCV infections and concluded that the specificity of the antibody response was similar to that of a chronic infection [47]. Equally, Bailey et al. (2017) isolated nAbs from a spontaneous clearer and showed that even though the antibodies had fewer somatic mutations than those isolated from chronic infection, the epitopes of these nAbs mapped to Domains B and D [48]. A further study by Eliyahu et al. (2018) and colleagues analysing the antibody repertoire of spontaneous clearers concluded that nAbs were different compared to those found in chronic infection in that they had fewer somatic mutations [49]. This agrees with the report by Bailey et al. (2017), although critically, while Eilyahu et al. (2018) confirmed that antibodies from spontaneous clearers were broadly neutralizing they did not identify the epitopes that were targeted [48,49]. These data together with our findings bode well for the potential development of an effective HCV vaccine in that it seems likely that a vaccine does not need to elicit a highly specific nAb or nAb profile.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/v14071391/s1, Table S1: Clinical data of spontaneous resolvers with E1E2 binding activity.

Author Contributions

Conceptualization: A.H.P., J.I.D. and V.M.C.; methodology: J.I.D. and V.M.C.; investigation: S.J.C., V.M.C., J.I.D. and R.E.S.; resources: R.E.S.; writing: first draft V.M.C.; writing: editing V.M.C., S.J.C., J.I.D., R.E.S. and A.H.P.; project administration: A.H.P.; supervision: V.M.C., J.I.D. and A.H.P.; funding acquisition: A.H.P. All authors have read and agreed to the published version of the manuscript.

Funding

This study was funded by the UK Medical Research Council grant MC UU12014/2 awarded to AHP. HCV Research UK was funded by the Medical Research Foundation, award no. C0365.

Institutional Review Board Statement

The study was conducted in accordance with the Declaration of Helsinki and approved by the regional ethics committee (CHCV cohort) or HCV Research UK Tissue and Data Access Committee (SR cohort).

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

Not applicable.

Acknowledgments

We thank all the individuals who graciously consented to provide samples for both HCV Research UK and the CHCV cohort that enabled this study.

Conflicts of Interest

The authors declare that there are no conflicts of interest.

References

  1. Smith, D.B.; Bukh, J.; Kuiken, C.; Muerhoff, A.S.; Rice, C.M.; Stapleton, J.T.; Simmonds, P. Expanded Classification of Hepatitis C Virus Into 7 Genotypes and 67 Subtypes: Updated Criteria and Genotype Assignment Web Resource. Hepatology 2014, 59, 318–327. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Cooper, S.; Erickson, A.L.; Adams, E.J.; Kansopon, J.; Weiner, A.J.; Chien, D.Y.; Houghton, M.; Parham, P.; Walker, C.M. Analysis of a successful immune response against hepatitis C virus. Immunity 1999, 10, 439–449. [Google Scholar] [CrossRef] [Green Version]
  3. Micallef, J.M.; Kaldor, J.M.; Dore, G.J. Spontaneous viral clearance following acute hepatitis C infection: A systematic review of longitudinal studies. J. Viral Hepat. 2006, 13, 34–41. [Google Scholar] [CrossRef] [PubMed]
  4. Grebely, J.; Dore, G.J.; Kim, A.Y.; Lloyd, A.; Shoukry, N.H.; Prins, M.; Page, K. Genetics of spontaneous clearance of hepatitis C virus infection: A complex topic with much to learn. Hepatology 2014, 60, 2127–2128. [Google Scholar] [CrossRef] [Green Version]
  5. Zhang, M.; Rosenberg, P.S.; Brown, D.L.; Preiss, L.; Konkle, B.A.; Eyster, M.E.; Goedert, J.J. Correlates of spontaneous clearance of hepatitis C virus among people with hemophilia. Blood 2006, 107, 892–897. [Google Scholar] [CrossRef] [PubMed]
  6. Duggal, P.; Thio, C.L.; Wojcik, G.L.; Goedert, J.J.; Mangia, A.; Latanich, R.; Kim, A.Y.; Lauer, G.M.; Chung, R.T.; Peters, M.G.; et al. Genome-wide association study of spontaneous resolution of hepatitis C virus infection: Data from multiple cohorts. Ann. Intern. Med. 2013, 158, 235–245. [Google Scholar] [CrossRef] [Green Version]
  7. Gruner, N.H.; Gerlach, T.J.; Jung, M.C.; Diepolder, H.M.; Schirren, C.A.; Schraut, W.W.; Hoffmann, R.; Zachoval, R.; Santantonio, T.; Cucchiarini, M.; et al. Association of hepatitis C virus-specific CD8(+) T cells with viral clearance in acute hepatitis C. J. Infect. Dis. 2000, 181, 1528–1536. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  8. Thimme, R.; Oldach, D.; Chang, K.M.; Steiger, C.; Ray, S.C.; Chisari, F.V. Determinants of viral clearance and persistence during acute hepatitis C virus infection. J. Exp. Med. 2001, 194, 1395–1406. [Google Scholar] [CrossRef]
  9. Logvinoff, C.; Major, M.E.; Oldach, D.; Heyward, S.; Talal, A.; Balfe, P.; Feinstone, S.M.; Alter, H.; Rice, C.M.; McKeating, J.A. Neutralizing antibody response during acute and chronic hepatitis C virus infection. Proc. Natl. Acad. Sci. USA 2004, 101, 10149–10154. [Google Scholar]
  10. Pestka, J.M.; Zeisel, M.B.; Blaser, E.; Schurmann, P.; Bartosch, B.; Cosset, F.L.; Patel, A.H.; Meisel, H.; Baumert, J.; Viazov, S.; et al. Rapid induction of virus-neutralizing antibodies and viral clearance in a single-source outbreak of hepatitis C. Proc. Natl. Acad. Sci. USA 2007, 104, 6025–6030. [Google Scholar] [CrossRef] [Green Version]
  11. Osburn, W.O.; Snider, A.E.; Wells, B.L.; Latanich, R.; Bailey, J.R.; Thomas, D.L.; Cox, A.L.; Ray, S.C. Clearance of hepatitis C infection is associated with the early appearance of broad neutralizing antibody responses. Hepatology 2014, 59, 2140–2151. [Google Scholar] [CrossRef] [PubMed]
  12. Ishii, K.; Rosa, D.; Watanabe, Y.; Katayama, T.; Harada, H.; Wyatt, C.; Kiyosawa, K.; Aizaki, H.; Matsuura, Y.; Houghton, M.; et al. High titers of antibodies inhibiting the binding of envelope to human cells correlate with natural resolution of chronic hepatitis C. Hepatology 1998, 28, 1117–1120. [Google Scholar] [CrossRef] [PubMed]
  13. Somsouk, M.; Lauer, G.M.; Casson, D.; Terella, A.; Day, C.L.; Walker, B.D.; Chung, R.T. Spontaneous resolution of chronic hepatitis C virus disease after withdrawal of immunosuppression. Gastroenterology 2003, 124, 1946–1949. [Google Scholar] [CrossRef]
  14. Scott, J.D.; McMahon, B.J.; Bruden, D.; Sullivan, D.; Homan, C.; Christensen, C.; Gretch, D.R. High rate of spontaneous negativity for hepatitis C virus RNA after establishment of chronic infection in Alaska Natives. Clin. Infect. Dis. 2006, 42, 945–952. [Google Scholar] [CrossRef]
  15. Akbar, H.O. Can chronic hepatitis C resolve spontaneously? Case report and review. Arab. J. Gastroenterol. 2011, 12, 51–53. [Google Scholar] [CrossRef]
  16. Raghuraman, S.; Park, H.; Osburn, W.O.; Winkelstein, E.; Edlin, B.R.; Rehermann, B. Spontaneous clearance of chronic hepatitis C virus infection is associated with appearance of neutralizing antibodies and reversal of T-cell exhaustion. J. Infect. Dis. 2012, 205, 763–771. [Google Scholar] [CrossRef] [Green Version]
  17. Bulteel, N.; Partha Sarathy, P.; Forrest, E.; Stanley, A.J.; Innes, H.; Mills, P.R.; Valerio, H.; Gunson, R.N.; Aitken, C.; Morris, J.; et al. Factors associated with spontaneous clearance of chronic hepatitis C virus infection. J. Hepatol. 2016, 65, 266–272. [Google Scholar] [CrossRef] [Green Version]
  18. Soares, J.; Santos, J.V.; Sarmento, A.; Costa-Pereira, A. Spontaneous Viral Clearance in Sixteen HIV-Infected Patients with Chronic Hepatitis C. Intervirology 2018, 61, 64–71. [Google Scholar] [CrossRef]
  19. McLauchlan, J.; Innes, H.; Dillon, J.F.; Foster, G.; Holtham, E.; McDonald, S.; Wilkes, B.; Hutchinson, S.J.; Irving, W.L. Cohort Profile: The Hepatitis C Virus (HCV) Research UK Clinical Database and Biobank. Int. J. Epidemiol. 2017, 46, 1391–1391h. [Google Scholar] [CrossRef] [Green Version]
  20. Hadlock, K.G.; Lanford, R.E.; Perkins, S.; Rowe, J.; Yang, Q.; Levy, S.; Pileri, P.; Abrignani, S.; Foung, S.K. Human monoclonal antibodies that inhibit binding of hepatitis C virus E2 protein to CD81 and recognize conserved conformational epitopes. J. Virol. 2000, 74, 10407–10416. [Google Scholar] [CrossRef] [Green Version]
  21. Keck, Z.Y.; Li, T.K.; Xia, J.; Gal-Tanamy, M.; Olson, O.; Li, S.H.; Patel, A.H.; Ball, J.K.; Lemon, S.M.; Foung, S.K. Definition of a conserved immunodominant domain on hepatitis C virus E2 glycoprotein by neutralizing human monoclonal antibodies. J. Virol. 2008, 82, 6061–6066. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  22. Johansson, D.X.; Voisset, C.; Tarr, A.W.; Aung, M.; Ball, J.K.; Dubuisson, J.; Persson, M.A. Human combinatorial libraries yield rare antibodies that broadly neutralize hepatitis C virus. Proc. Natl. Acad. Sci. USA 2007, 104, 16269–16274. [Google Scholar] [CrossRef] [Green Version]
  23. Patel, A.H.; Wood, J.; Penin, F.; Dubuisson, J.; McKeating, J.A. Construction and characterization of chimeric hepatitis C virus E2 glycoproteins: Analysis of regions critical for glycoprotein aggregation and CD81 binding. J. Gen. Virol. 2000, 81, 2873–2883. [Google Scholar] [CrossRef] [PubMed]
  24. Swann, R.E.; Cowton, V.M.; Robinson, M.W.; Cole, S.J.; Barclay, S.T.; Mills, P.R.; Thomson, E.C.; McLauchlan, J.; Patel, A.H. Broad Anti-Hepatitis C Virus (HCV) Antibody Responses Are Associated with Improved Clinical Disease Parameters in Chronic HCV Infection. J. Virol. 2016, 90, 4530–4543. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  25. Tarr, A.W.; Owsianka, A.M.; Szwejk, A.; Ball, J.K.; Patel, A.H. Cloning, expression and functional analysis of patient-derived hepatitis C virus glycoproteins. Methods Mol. Biol. 2007, 379, 177–197. [Google Scholar] [PubMed]
  26. Owsianka, A.M.; Timms, J.M.; Tarr, A.W.; Brown, R.J.; Hickling, T.P.; Szwejk, A.; Bienkowska-Szewczyk, K.; Thomson, B.J.; Patel, A.H.; Ball, J.K. Identification of conserved residues in the E2 envelope glycoprotein of the hepatitis C virus that are critical for CD81 binding. J. Virol. 2006, 80, 8695–8704. [Google Scholar] [CrossRef] [Green Version]
  27. Eren, R.; Landstein, D.; Terkieltaub, D.; Nussbaum, O.; Zauberman, A.; Ben-Porath, J.; Gopher, J.; Buchnick, R.; Kovjazin, R.; Rosenthal-Galili, Z.; et al. Preclinical evaluation of two neutralizing human monoclonal antibodies against hepatitis C virus (HCV): A potential treatment to prevent HCV reinfection in liver transplant patients. J. Virol. 2006, 80, 2654–2664. [Google Scholar] [CrossRef] [Green Version]
  28. Keck, Z.Y.; Xia, J.; Cai, Z.; Li, T.K.; Owsianka, A.M.; Patel, A.H.; Luo, G.; Foung, S.K. Immunogenic and functional organization of hepatitis C virus (HCV) glycoprotein E2 on infectious HCV virions. J. Virol. 2007, 81, 1043–1047. [Google Scholar] [CrossRef] [Green Version]
  29. Keck, Z.Y.; Li, T.K.; Xia, J.; Bartosch, B.; Cosset, F.L.; Dubuisson, J.; Foung, S.K. Analysis of a highly flexible conformational immunogenic domain a in hepatitis C virus E2. J. Virol. 2005, 79, 13199–13208. [Google Scholar] [CrossRef] [Green Version]
  30. Keck, Z.Y.; Saha, A.; Xia, J.; Wang, Y.; Lau, P.; Krey, T.; Rey, F.A.; Foung, S.K. Mapping a region of hepatitis C virus E2 that is responsible for escape from neutralizing antibodies and a core CD81-binding region that does not tolerate neutralization escape mutations. J. Virol. 2011, 85, 10451–10463. [Google Scholar] [CrossRef] [Green Version]
  31. Tzarum, N.; Wilson, I.A.; Law, M. The Neutralizing Face of Hepatitis C Virus E2 Envelope Glycoprotein. Front. Immunol. 2018, 9, 1315. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  32. Schlotthauer, F.; McGregor, J.; Drummer, H.E. To Include or Occlude: Rational Engineering of HCV Vaccines for Humoral Immunity. Viruses 2021, 13, 805. [Google Scholar] [CrossRef] [PubMed]
  33. Strasak, A.M.; Kim, A.Y.; Lauer, G.M.; de Sousa, P.S.; Ginuino, C.F.; Fernandes, C.A.; Velloso, C.E.; de Almeida, A.J.; de Oliveira, J.M.; Yoshida, C.F.; et al. Antibody dynamics and spontaneous viral clearance in patients with acute hepatitis C infection in Rio de Janeiro, Brazil. BMC Infect. Dis. 2011, 11, 15. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  34. Messick, K.; Sanders, J.C.; Goedert, J.J.; Eyster, M.E. Hepatitis C viral clearance and antibody reactivity patterns in persons with haemophilia and other congenital bleeding disorders. Haemophilia 2001, 7, 568–574. [Google Scholar] [CrossRef] [PubMed]
  35. Tarr, A.W.; Urbanowicz, R.A.; Jayaraj, D.; Brown, R.J.; McKeating, J.A.; Irving, W.L.; Ball, J.K. Naturally occurring antibodies that recognize linear epitopes in the amino terminus of the hepatitis C virus E2 protein confer noninterfering, additive neutralization. J. Virol. 2012, 86, 2739–2749. [Google Scholar] [CrossRef] [Green Version]
  36. Pantua, H.; Diao, J.; Ultsch, M.; Hazen, M.; Mathieu, M.; McCutcheon, K.; Takeda, K.; Date, S.; Cheung, T.K.; Phung, Q.; et al. Glycan Shifting on Hepatitis C Virus (HCV) E2 Glycoprotein Is a Mechanism for Escape from Broadly Neutralizing Antibodies. J. Mol. Biol. 2013, 425, 1899–1914. [Google Scholar] [CrossRef] [Green Version]
  37. Li, Y.; Pierce, B.G.; Wang, Q.; Keck, Z.Y.; Fuerst, T.R.; Foung, S.K.; Mariuzza, R.A. Structural basis for penetration of the glycan shield of hepatitis C virus E2 glycoprotein by a broadly neutralizing human antibody. J. Biol. Chem. 2015, 290, 10117–10125. [Google Scholar] [CrossRef] [Green Version]
  38. Meola, A.; Tarr, A.W.; England, P.; Meredith, L.W.; McClure, C.P.; Foung, S.K.; McKeating, J.A.; Ball, J.K.; Rey, F.A.; Krey, T. Structural flexibility of a conserved antigenic region in hepatitis C virus glycoprotein E2 recognized by broadly neutralizing antibodies. J. Virol. 2015, 89, 2170–2181. [Google Scholar] [CrossRef] [Green Version]
  39. Balasco, N.; Barone, D.; Iaccarino, E.; Sandomenico, A.; De Simone, A.; Ruvo, M.; Vitagliano, L. Intrinsic structural versatility of the highly conserved 412–423 epitope of the Hepatitis C Virus E2 protein. Int. J. Biol. Macromol. 2018, 116, 620–632. [Google Scholar] [CrossRef]
  40. Cowton, V.M.; Angus, A.G.N.; Cole, S.J.; Markopoulou, C.K.; Owsianka, A.; Dunlop, J.I.; Gardner, D.E.; Krey, T.; Patel, A.H. Role of Conserved E2 Residue W420 in Receptor Binding and Hepatitis C Virus Infection. J. Virol. 2016, 90, 7456–7468. [Google Scholar] [CrossRef] [Green Version]
  41. Keck, Z.Y.; Xia, J.; Wang, Y.; Wang, W.; Krey, T.; Prentoe, J.; Carlsen, T.; Li, A.Y.; Patel, A.H.; Lemon, S.M.; et al. Human monoclonal antibodies to a novel cluster of conformational epitopes on HCV E2 with resistance to neutralization escape in a genotype 2a isolate. PLoS Pathog. 2012, 8, e1002653. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  42. Giang, E.; Dorner, M.; Prentoe, J.C.; Dreux, M.; Evans, M.J.; Bukh, J.; Rice, C.M.; Ploss, A.; Burton, D.R.; Law, M. Human broadly neutralizing antibodies to the envelope glycoprotein complex of hepatitis C virus. Proc. Natl. Acad. Sci. USA 2012, 109, 6205–6210. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  43. Colbert, M.D.; Flyak, A.I.; Ogega, C.O.; Kinchen, V.J.; Massaccesi, G.; Hernandez, M.; Davidson, E.; Doranz, B.J.; Cox, A.L.; Crowe, J.E., Jr.; et al. Broadly Neutralizing Antibodies Targeting New Sites of Vulnerability in Hepatitis C Virus E1E2. J. Virol. 2019, 93, e02070-18. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  44. Keck, Z.Y.; Olson, O.; Gal-Tanamy, M.; Xia, J.; Patel, A.H.; Dreux, M.; Cosset, F.L.; Lemon, S.M.; Foung, S.K. A point mutation leading to hepatitis C virus escape from neutralization by a monoclonal antibody to a conserved conformational epitope. J. Virol. 2008, 82, 6067–6072. [Google Scholar] [CrossRef] [Green Version]
  45. Keck, Z.Y.; Li, S.H.; Xia, J.; von Hahn, T.; Balfe, P.; McKeating, J.A.; Witteveldt, J.; Patel, A.H.; Alter, H.; Rice, C.M.; et al. Mutations in hepatitis C virus E2 located outside the CD81 binding sites lead to escape from broadly neutralizing antibodies but compromise virus infectivity. J. Virol. 2009, 83, 6149–6160. [Google Scholar] [CrossRef] [Green Version]
  46. Velazquez-Moctezuma, R.; Galli, A.; Law, M.; Bukh, J.; Prentoe, J. Hepatitis C Virus-Escape Studies for Human Monoclonal Antibody AR4A Reveal Isolate-Specific Resistance and a High Barrier to Resistance. J. Infect. Dis. 2019, 219, 68–79. [Google Scholar] [CrossRef]
  47. Keck, Z.Y.; Pierce, B.G.; Lau, P.; Lu, J.; Wang, Y.; Underwood, A.; Bull, R.A.; Prentoe, J.; Velazquez-Moctezuma, R.; Walker, M.R.; et al. Broadly neutralizing antibodies from an individual that naturally cleared multiple hepatitis C virus infections uncover molecular determinants for E2 targeting and vaccine design. PLoS Pathog. 2019, 15, e1007772. [Google Scholar] [CrossRef]
  48. Bailey, J.R.; Flyak, A.I.; Cohen, V.J.; Li, H.; Wasilewski, L.N.; Snider, A.E.; Wang, S.; Learn, G.H.; Kose, N.; Loerinc, L.; et al. Broadly neutralizing antibodies with few somatic mutations and hepatitis C virus clearance. JCI Insight 2017, 2, e92872. [Google Scholar] [CrossRef]
  49. Eliyahu, S.; Sharabi, O.; Elmedvi, S.; Timor, R.; Davidovich, A.; Vigneault, F.; Clouser, C.; Hope, R.; Nimer, A.; Braun, M.; et al. Antibody Repertoire Analysis of Hepatitis C Virus Infections Identifies Immune Signatures Associated with Spontaneous Clearance. Front. Immunol. 2018, 9, 3004. [Google Scholar] [CrossRef]
Viruses 14 01391 g001 550
Figure 1. Binding to E1E2 lysate. Serum samples diluted 1:500 were screened for binding to gt1a H77 E1E2 lysate in a GNA ELISA assay. The binding activity is expressed as a percentage relative to binding of a control HCV sera sample and is adjusted for binding to control lysate with no E1E2. Values shown are the mean of two independent replicate experiments. (a) Sera from the spontaneous resolver cohort. (b) Sera from the chronic HCV cohort.
Figure 1. Binding to E1E2 lysate. Serum samples diluted 1:500 were screened for binding to gt1a H77 E1E2 lysate in a GNA ELISA assay. The binding activity is expressed as a percentage relative to binding of a control HCV sera sample and is adjusted for binding to control lysate with no E1E2. Values shown are the mean of two independent replicate experiments. (a) Sera from the spontaneous resolver cohort. (b) Sera from the chronic HCV cohort.
Viruses 14 01391 g001
Viruses 14 01391 g002 550
Figure 2. Correlation of binding and neutralization. (a) For each sample, the relative binding (%) to gt1a H77 E1E2 lysate was plotted against the number of HCVpp that were neutralized. SR cohort (top panel) and CHCV cohort (lower panel). Spearman’s rho correlation was plotted for both graphs. (b) The relative binding (%) to gt 1a H77 E1E2 lysate of samples within both cohorts were plotted. A parametric t-test was used to compare binding between both groups, (**** denotes that the p-value is less than 0.0001).
Figure 2. Correlation of binding and neutralization. (a) For each sample, the relative binding (%) to gt1a H77 E1E2 lysate was plotted against the number of HCVpp that were neutralized. SR cohort (top panel) and CHCV cohort (lower panel). Spearman’s rho correlation was plotted for both graphs. (b) The relative binding (%) to gt 1a H77 E1E2 lysate of samples within both cohorts were plotted. A parametric t-test was used to compare binding between both groups, (**** denotes that the p-value is less than 0.0001).
Viruses 14 01391 g002
Table
Table 1. Cohort demographics.
Table 1. Cohort demographics.
DemographicsSR Cohort (233)CHCV Cohort
(41)
Age (yrs)Median (Range)45 (20–80)46 (34–68)
Gender (M/F)No. male (%)156 (66.9%)28 (68.3%)
EthnicityNo. Caucasian (%)212 (91%)37 (90.2%)
Source of infectionNo. IVDU (%)159 (68.2%)26 (63.4%)
Estimated duration (yrs)Median (Range)2.15 (0–20.2 a)29 (2–58 b)
GenotypeNo. Gt1, No. Gt3Gt1 (12), Gt3 (13) cGt1 (23), Gt3 (18)
a no data for 122 subjects, b no data for 10 subjects, c no data for 199 subjects.
Table
Table 2. Neutralization activity of SR cohort. The relative neutralization activity (%) of the Gt1 panel is shown. The data is the mean value from triplicate independent experiments.
Table 2. Neutralization activity of SR cohort. The relative neutralization activity (%) of the Gt1 panel is shown. The data is the mean value from triplicate independent experiments.
Sera IDRelative Neutralization (%) of HCVpp in Panel Gt1 aNo.HCVpp Neutralized by >50%
H77UKN1B5.23UKN1A14.38UKN1A14.43UKN1B14.818UKN1A20.8GC12.02GC13.01GC34.11GC.37.04ET10
S9356811356650652794311661269266145536839
S3767539106135217543865783995826306538
S922721331068151472530856943563154466118
S256123114424341834331161136155015035407
S8876232544735215931614334185635105926
S107665399388321061321649625115475844844
S95342584144324443055684185334133933
S125383213433610529271043213185264443723
S785310449374193586319395−6213944155373
S1976141853273217464321252721155444014143
S9343773463643416233064722925725354713
S104513−34343266594−1453583095203863132
S154892564244745822533272215973773442
S5860440934533255643348529104084814012
S8934312593563325251210511281037114514072
S135392279143263542251040612113214133521
S151415180226131599231735815638136113131
S888233138421645892423331−13263263283711
S890317206271261054642331173543204263161
S924591147228366446311635131153523972951
S927369422282226515−17425615122641329101
S93036121192472015502613462693893322991
S93933721123261717587101532112083174464241
S94841135033428116063914232623924203631
>50%12034210721265
<20%06240706100
a Values in bold show the neutralization of HCVpp >50% and values that are underlined show neutralization of HCVpp <20%. The superscript number indicates the standard error of the mean (SEM).
Table
Table 3. Neutralization of CHCV cohort. The relative neutralization activity (%) of the Gt1 panel. The mean value from triplicate independent experiments is shown.
Table 3. Neutralization of CHCV cohort. The relative neutralization activity (%) of the Gt1 panel. The mean value from triplicate independent experiments is shown.
Sera IDRelative Neutralization (%) of HCVpp in Panel Gt1 aNo.HCVpp Neutralized by >50%
H77UKN1B5.23UKN1A14.38UKN1A14.43UKN1B14.818UKN1A20.8GC12.02GC13.01GC34.11GC.37.04ET10
C1003 b887354648925575553849010
C1013 b86176772813761588981889
C1023 b84355668721774657671779
C1032 b86448182902857708974749
C1035 b78436162764567657167839
C1012 b80347658872454506784798
C101687555566549494244235084056377588978
C1031 b77375656702846647272688
C10427872578599772112258648961107677758
C1001 b69147261811129455253737
C1022 b77394946652455535566767
C1036 b79414250572851445569707
C10466992725375747412213501049153105984347
C1010 b78314656871844415577706
C1021794605369504693151150133795686055296
C1037 b94285434771645417962756
C1050778392261325176656165284045685145366
C10297883452952617666189371018185685745265
C103866735137250262714530122875475426085
C10615272841831666371514384371461105355445
C1015511028821144166241712289211145151262104
C1055585271358251115841218109151233345431114
C10565611213218228616620411732342554115224
C10185313212012271158620112612401051637635113
C1030 b58452720631623202148603
C1045 b7012292870033305348493
C1060 b51402433581536304856493
C1034 b4724242450183242253422
C10495033321416241755214134513894454973172
C1054646322146122752721644132874324354072
C10625752452172011396161037542125034243762
C10403011177−58521526−11252171312−123471229121
>50%3031315310138232422
<20%044302115100
a Values in bold show the neutralization of HCVpp >50% and values that are underlined show neutralization of HCVpp <20%. The superscript number indicates the standard error of the mean (SEM). b Neutralization data for many Gt1 samples in the CHCV cohort has been published previously [24].
Table
Table 4. E1E2 mutagenesis binding analysis.
Table 4. E1E2 mutagenesis binding analysis.
SampleDomain EDomain DDomain BNo. HCVpp Neutralized
L413AW420AL441AF442AW529AG530A
SPONTANEOUS RESOLVERSR93510329816419049548009
SR3798198264296310328948
SR922993992760111211028958
SR251136103347380976107717
SR887108810046213842081166906
SR10711041094738108411052854
SR911541015601294168685823
SR1211271014559711378107323
SR7810541375828116512646083
SR19711341214674101897114143
SR93415412121849169511084813
SR10828801049771117196622
SR15119813512671011916133198062
SR58124610814347788776112
SR893138512331016037636462
CHRONICC1003108711676631105115493310
C10131061010910511112811478759
C103510011989506111161172099139
C10129689910578911482118548
C104210891188504104610698248
C1001112121166443105411027437
C102283111051180101049110891197
C1010101121061267610451120111196
C1050163718912101416211129710486
C103810831179592112611578135
C10291545173878515810140512855
C105522017244155778869437254
C1056180621365137528024834
C10188614101127311151511648943
C104510271198481121713419793
C104918517135121153323132442
C105414022148101555755494342
ALP981024112713091118134111237Control
The relative binding (%) of purified IgG to a group of E1E2 lysates containing a single alanine mutation of key antibody binding residues. The mean value of three independent experiments is shown. The superscript number indicates the standard error of the mean (SEM). The values are shaded to reflect the level of binding compared to the wt control (brown = 0–30%, orange = 31–50%, light orange = 51–80%, white = 81–120%, light blue = 121–150%, blue = >150%).
Table
Table 5. Cross-competition analysis with neutralizing mAbs.
Table 5. Cross-competition analysis with neutralizing mAbs.
Biotinylated AntibodyNo. HCVpp Neutralized
CBH-7HC-1HC-111.7HC33.1CBH-4B
ControlCBH-797.8168.0282.5186.52−5.6882.28
HC-112.1496.2193.0297.701.1634.716
HC-117.5539.4592.9182.3112.31512.07
1.710.1654.9887.9488.6323.62311.56
HC33.123.7243.3854.31157.8886.2531.34
CBH-4B10.219.4724.7722.3622.11095.11
Spontaneous resolversS93530.5964.1582.7578.451.9540.769
S92264.6462.3672.7977.74−1.3539.978
S3731.51064.3659.51168.69−7.5113.658
S255.0436.9956.71552.710−1.8311.347
S88723.4948.41063.9868.196.4857.066
S10711.7113.7232.0332.44−22.2427.134
S125.0116.2335.3532.910−10.71−5.353
S9345.8315.7230.5533.27−11.328.943
S910.3223.0224.7626.15−5.1215.843
S7838.1448.2174.1263.03−4.0263.343
S19720.1248.5270.1261.21−9.4123.653
S580.3310.344.9321.91-23.31013.442
S1512.4318.0225.8427.92−6.3611.862
S1028.8531.9150.6349.93−17.0332.632
S8931.1313.9411.0921.05−8.47−3.442
ChronicC100319.7259.2379.0879.56−7.551.6510
C10132.0344.4764.3870.120.8612.099
C103523.9747.9468.8258.570.55−4.349
C101245.6755.3578.9480.2215.2754.948
C10429.6474.9294.5289.216.1123.888
C102226.3221.8492.0287.30−3.6122.497
C100118.9920.948.4624.973.23087
C101054.6156.0289.3187.41−6.9134.3146
C105017.1766.0567.4674.75−0.2732.476
C103812.7216.4114.0616.166.480.645
C102913.0765.9680.9576.960819.135
C10557.7425.9932.2637.785.5413.074
C10567.8257.1370.4570.047.7614.214
C1018−0.4619.3310.9632.46−10.58−1.753
C10458.0319.7312.5425.220.635.733
C10495.0430.7534.9849.23−4.2615.672
C10545.5539.9639.5451.120816.352
Competition of purified IgG against a panel of well-characterized control E2 mAbs (CBH-7, HC-1, HC-11, 1.7, HC33.1 and CBH-4B) was performed in triplicate. The mean percent competition, reduction in mAb binding in the presence of IgG is shown. The superscript number indicates the standard error of the mean (SEM). The values are shaded to reflect the level of reduced binding compared to the no antibody control. (brown = 90–100%, orange = 70–89%, light orange = 50–69%; white = 0–49%, light blue = −1– −19%, blue = >−20%).
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Cowton, V.M.; Dunlop, J.I.; Cole, S.J.; Swann, R.E.; Patel, A.H. The Neutralizing Antibody Responses of Individuals That Spontaneously Resolve Hepatitis C Virus Infection. Viruses 2022, 14, 1391. https://doi.org/10.3390/v14071391

AMA Style

Cowton VM, Dunlop JI, Cole SJ, Swann RE, Patel AH. The Neutralizing Antibody Responses of Individuals That Spontaneously Resolve Hepatitis C Virus Infection. Viruses. 2022; 14(7):1391. https://doi.org/10.3390/v14071391

Chicago/Turabian Style

Cowton, Vanessa M., James I. Dunlop, Sarah J. Cole, Rachael E. Swann, and Arvind H. Patel. 2022. "The Neutralizing Antibody Responses of Individuals That Spontaneously Resolve Hepatitis C Virus Infection" Viruses 14, no. 7: 1391. https://doi.org/10.3390/v14071391

APA Style

Cowton, V. M., Dunlop, J. I., Cole, S. J., Swann, R. E., & Patel, A. H. (2022). The Neutralizing Antibody Responses of Individuals That Spontaneously Resolve Hepatitis C Virus Infection. Viruses, 14(7), 1391. https://doi.org/10.3390/v14071391

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop