Abbreviations
3TC, lamivudine; ADV, adefovir; ART, antiretroviral therapy; cccDNA, covalently closed circular DNA; CHB, chronic hepatitis B virus infection; ETV, entecavir; HBsAg, hepatitis B surface antigen; HBV, hepatitis B virus; HIV, human immunodeficiency virus; LdT, telbivudine; NA, nucleos(t)ide analogue; RAM, resistance-associated mutation; RT, reverse transcriptase; TAF, tenofovir alafenamide; TDF, tenofovir disoproxil fumarate; TFV, tenofovir (the active component of both TAF and TDF); YMDD, tyrosine methionine aspartate aspartate motif in HBV RT.
Introduction
Nucleot(s)ide analogues (NA) are the most widely used antiviral treatments for chronic hepatitis B virus (HBV) infection1, with tenofovir (TFV) being a safe, cheap, and widely available agent. NA agents inhibit the action of HBV reverse transcriptase (RT), acting as DNA chain terminators. NA therapy can be effective in suppressing HBV viraemia, thus reducing the risks of inflammation, fibrosis and hepatocellular carcinoma (HCC) as well as lowering the risk of transmission1. However, NAs are not curative due to the persistent intracellular hepatic reservoir of HBV covalently closed circular DNA (cccDNA). Long-term administration is therefore typically required2, with a potential risk of selection of resistance-associated mutations (RAMs) in the virus3,4. RAMs are mostly likely to arise in the context of high viral replication, arising as a result of the error prone RT enzyme1.
Lamivudine (3TC), telbivudine (LdT) and adefovir (ADV) have been phased out of use in HBV management, mainly due to the predictable selection of RAMs over time1. The best recognised 3TC RAM arises at RT-M204, representing the second position of the tyrosine-methionine-aspartate-aspartate (‘YMDD’) motif in viral RT1,4. Resistance to TFV, formulated either as tenofovir disoproxil fumarate (TDF) or tenofovir alafenamide (TAF) (Suppl Fig 1, Extended data5), remains controversial. Unlike other NAs, TFV has a high genetic barrier to resistance1, corroborated by studies that report no resistance after many years of treatment6. An on-line tool, ‘geno2pheno hbv’, lists only one position (RT N236T) in association with reduced TFV susceptibility, while other reports also include A181T/V7. However, there are emerging reports of a wider range of amino acid substitutions that are associated with reduced TFV sensitivity, described in both treatment-experienced and treatment-naïve individuals with chronic HBV infection (CHB)8,9.
There is some degree of homology between the sequence, structure and function of HIV and HBV RT enzymes, explaining why certain NAs are active against both viruses10. Although no crystal structure has been resolved for HBV RT, some studies have modelled this enzyme based on the HIV crystal structure10–12, suggesting that insights into HBV drug resistance mechanisms might be inferred from what is known about HIV.
A better understanding of the role of NA therapy in driving HBV elimination at a population level is crucial to underpin efforts to move towards international targets for elimination by the year 20303,13. For populations in which HIV and HBV are both endemic, as exemplified by many settings in sub-Saharan Africa, there are particular concerns about drug resistance in HBV, given the widespread population exposure to TDF as a component of first-line antiretroviral therapy (ART) for HIV3. In order to progress towards these targets, many more people will need to be treated in the decade ahead.
We have therefore undertaken a systematic approach to assimilate the current evidence for the development of clinical or virological HBV breakthrough during TFV therapy. The evidence on this topic is not currently sufficiently advanced to underpin definitive conclusions regarding specific genetic signatures that underpin TVF resistance, or the extent to which these are significant in clinical practice. However, we add to the field by providing a comprehensive summary of relevant publications, together with a quality appraisal of the evidence. We used this process to assimilate a ‘long-list’ (all putative TFV RAMs) and a ‘short-list’ (a refined catalogue containing only the polymorphisms most robustly supported by existing data). We highlight gaps in the existing data and the urgent need for more research.
Methods
Search strategy and quality appraisal
We undertook a systematic search of PubMed and Scopus in February 2019, using PRISMA criteria (Suppl Fig 2, Extended data5). Data extraction was performed independently using the search terms (“Hepatitis B virus” [Mesh] OR "hepatitis b" OR HBV) AND (Tenofovir OR TDF OR TAF OR “Tenofovir alafenamide” OR “Tenofovir Disoproxil Fumarate”) AND (resista* OR drug muta* OR DRMs OR RAMs OR viremia OR replica*). We reviewed the titles and abstracts matching the search terms and included those reporting virological HBV breakthrough after exposure to TFV, only including studies that presented original data and had undergone peer review. All retrieved articles were in English, therefore no exclusion in relation to language was required. For each study, we extracted information on type of study, characteristics of study participants, sequencing method, genotype, HBV treatment used, mutations associated with TFV resistance and method used to define TFV resistance. We used the Joanna Briggs Institute Critical Appraisal tool checklist to assess for quality of case reports14. For assessment of quantitative studies, we used the BMJ adapted Quality Assessment Tool for Quantitative Studies15.
Appraisal of putative sites of drug resistance
Recognising that there is sparse and varied evidence to support TDF RAMs, we divided our data into two categories. First, we generated a ‘long list’ of all polymorphisms that have been reported in association with TFV resistance, to summarise all the available data in the most inclusive way. We then refined this into a ‘short list’ including just those sites supported by the most robust evidence, based on reporting in ≥2 studies and a combination of in vivo and in vitro evidence.
Sequence analysis
To assess similarity between HIV and HBV RT, we downloaded HIV (HXB2 - K03455); and HBV reference sequences (Geno A – FJ692557, Geno B - GU815637, Geno C – GQ377617, Geno D - KC875277, Geno E - GQ161817) from publicly available repositories: HIV sequence database16 and Hepatitis B Virus Database17. We aligned amino acid RT sequences using MAFFT version 718. The alignment illustrates regions of similarity and differences between HIV and HBV RT. We obtained RAMs associated with HIV resistance to TFV published in the Stanford University HIV drug resistance database under drug resistance summaries for nucleoside RT inhibitors.19.
Structural analysis
The crystal structure for HBV RT has not been solved, However, the enzyme is homologous to HIV RT. In order to further assess the relevance of sites included in a ‘long list’ of all polymorphisms, we therefore considered evidence for a mechanistic influence by mapping HBV RAMs onto a previously solved crystal structure of HIV RT (Protein Data Bank (PDB) code 3dlk)20 using ICM-Pro platform, which provides a direct link to the PDB21
Results
Nature and quality of the evidence identified
We identified 15 studies that met our search criteria. Although some studies used hybrid methods, we classified them broadly as seven studies arising from clinical case reports8,9,22–26, (one of these also presented in vitro evidence for drug resistance9), four from in vitro studies27–29 and four from longitudinal studies of CHB (with or without HIV coinfection)30–33. Studies were from Asia8,9,22,24,29, Australia33, Europe23,26,28,30–32 and USA25,27,34. Despite the high prevalence of HBV infection in Africa, and the widespread use of TFV for HIV across this continent, it is striking that no African data have been published to date. Eight studies reported HBV genotypes, representing genotypes A-G9,22,25–27,30–32,34. Metadata for individual studies are provided in Suppl Table 1 (see Extended data5).
A detailed quality assessment of each individual reference is included in Suppl Table 2 (see Extended data5). Among the case reports, three were of high quality as they clearly described patients’ characteristics, clinical details, diagnosis, treatment and follow-up, and concluded with take away lessons22–24. Three further case reports did not describe diagnostic or assessment methods8,25,26, and one study did not describe post-intervention follow-up9. The overall quality rating for four cohort studies was strong because participants selected represented the target population, characteristics of participants were clearly described, there was a clear hypothesis for the study, and inclusion/exclusion criteria were specified30–33. Two studies had a weak rating because there was no description of the characteristics of participants and it was not clear to what extent participants were representative of the target population27,34. Two natural experimental studies were not rated because the quality assessment questions were not applicable28,29.
Approach to defining resistance
Resistance was studied based on exposure to TDF in 13 studies and TAF in two studies; we therefore refer to TFV throughout the results section. TFV resistance was determined using a range of strategies, which can be summarised as follows:
In 12/15 studies, HBV mutations were reported in association with TFV resistance (suggesting complete virologic escape from the impact of a drug) or reduced TFV susceptibility (evidenced by incomplete suppression of viraemia, but not complete drug resistance)9,22,23,26–32,34. In the remaining three studies, persistent viraemia was reported among individuals with chronic HBV infection while on TFV but either no RAMs were identified25,33 or viral sequencing was not performed due to low viral load24.
Location and number of RAMs associated with TFV resistance
We generated a ‘long-list’ of 37 different sites of polymorphism, arising both within (n=15) and outside (n=22) enzymatically active sites in RT (Figure 1; Suppl Table 3, Extended data5). HBV mutations outside active sites of the enzyme occurred in combination with RAMs located within active sites, with the exception of A194T. Only two studies reported TFV resistance arising from the selection of a single mutation, S78T and A194T23,28. S78T was defined by sequencing HBV from two individuals in whom viraemia was not suppressed by TDF, combined with in vitro assays23, while A194T was only defined in vitro28. In all other studies, ≥2 RAMs were required to confer TFV resistance (2 RAMs in four studies27,29,30,34, 3 RAMs in one study32, 5 RAMs in one study9, and ≥8 RAMs in a further four studies8,22,26,31). This pattern supports the high genetic barrier to selection of TFV resistance.
Enlarge this image.Figure 1. Mutations associated with TFV resistance located within and outside the active sites of the HBV RT enzyme.
Polymerase numbering shown in the grey bars is based on genotype A sequence (accession number X02763). Yellow bar represents RT; green bars represent subdomains which are designated finger, palm and thumb; orange rectangles represent active sites of the enzyme referred to as regions A-G. Mutations associated with TFV resistance (n=37 sites) are listed according to their location within active sites of the enzyme (orange table) or outside active sites (green table). The sites shown in bold represent the nine mutations in our short-list with best literature support (evidence summarised in Table 1). Note that in most cases, individual mutations are unlikely to be sufficient to mediate resistance, and a resistant phenotype arises only as a result of combinations of ≥2 polymorphisms.
TFV, tenofovir; HBV, hepatitis B virus; RT, reverse transcriptase; RAM, resistance-associated mutation; TDF, tenofovir disoproxil fumarate; TAF, tenofovir alafenamide.
Table 1. Mutations most commonly reported in association with TFV resistance in HBV, identified from a systematic literature review.
This table reports a ‘short-list’ of mutations identified in two or more different studies8,9,22,26–28,30–32,34. The symbols *, ** and *** indicate the method(s) used to determine drug resistance. All positions are in HBV RT, listed in numerical order. The ‘long-list’ of 37 mutations identified in 15 included studies is reported in Suppl Table 3 (see Extended data).
| Mutations | Park et al. 2019 | Cho et al. 2018 | Lee et al. 2014 | Mikulska et al. 2012 | Liu et al. 2014 | Amini-Bavil-Olyaee et al. 2009 | Van Bommel et al. 2012 | Lada et al. 2012 | Sheldon et al. 2005 | Liu et al. 2017 | Total number of studies | Associated with 3TC resistance | Associated with ETV resistance |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| S106C/G | *** | * | 2 | No | No | ||||||||
| R153W/Q | * | *** | 2 | No | No | ||||||||
| V173L | * | *** | 2 | Yes | Yes | ||||||||
| L180M | * | * | *** | *** | 4 | Yes | Yes | ||||||
| A181T/V | ** | * | *** | ** | 4 | Yes | Yes | ||||||
| A194T | ** | *** | 2 | No | No | ||||||||
| M204I/V | *** | * | * | *** | *** | 5 | Yes | Yes | |||||
| N236T | ** | * | ** | 3 | No | No | |||||||
| I269L | *** | * | 2 | No | Yes | ||||||||
| KEY: | Method used to identify TFV resistance | ||||||||||||
| * | Sequencing HBV sequence from individuals in whom viraemia was not suppressed by TDF | ||||||||||||
| ** | In vitro assays to measure the effect of TDF on viral replication in cell lines | ||||||||||||
| *** | Two above approaches (* and **) in combination | ||||||||||||
HBV, hepatitis B virus; RT, reverse transcriptase; TFV, tenofovir; 3TC, lamivudine; ETV, entecavir; TDF, tenofovir disoproxil fumarate.
We narrowed the list of 37 sites down to compile a ‘short-list’ of TFV RAMs that have been identified in ≥2 studies, regarding these sites as having the strongest evidence base (nine sites; Table 1). The most frequently described RAMs were L180M22,31,32, A181T/V27,30,31,34, M204I/V9,22,31,32, and N236T27,30,34, which were all identified through sequencing and tested in in vitro assays to measure the effect of TDF on viral replication in cell lines. Among these, the M204 mutation (within the ‘YMDD’ motif) is well established in association with 3TC resistance, commonly arising in combination with substitutions at positions V173, L180 and A181, while N236 substitutions appear to be more specifically associated with reduced susceptibility to ADV and TFV7. Mutations at sites 177, 194 and 249 may also be more specific to TFV resistance, having been less clearly reported in association with resistance to other agents3,35. Polymorphisms at positions 80, 173 and 184 have been described as compensatory changes to allow the virus to accommodate the primary drug escape substitution7. These mutations on their own may not be sufficient to mediate TVF resistance but may be a necessary compensatory contribution to combinations of mutations that underpin resistance.
Some reported polymorphisms associated with drug resistance represent wild type sequence in some genotypes (Y9H, F122L, H126Y, R153W/Q, F221Y, S223A, C256S, D263E, V278IV and A317S), and our assimilation shows more resistance in genotype D (Suppl Table 4, Extended data5). Most of these polymorphisms are located outside the active site of the enzyme, with the exception of position 256. The barrier to selection of TFV resistance may therefore be lower in certain genotypes, (Figure 1; Suppl Table 4, Extended data5). The same phenomenon has been described for HCV resistance, in which certain sub genotypes are predicted to be intrinsically resistant to certain direct acting antiviral agents due to the presence of resistance associated polymorphisms in the wild type sequence36,37.
One study assessed the replication competence and susceptibility to TFV of mutated HBV clones in vitro and in vivo using mice models. The introduction of P177G and F249A mutations (substitutions in active sites of the RT enzyme) in HBV clones resulted in a reduction in their susceptibility to TFV29.
RAMs occurring as minor quasispecies
There is limited evidence for the significance of TFV RAMs occurring as minor quasispecies. One study that performed ultra-deep pyrosequencing enrolled HIV/HBV co-infected individuals on (or about to start) TFV-containing ART, reporting minor variants present at <20% with mutations (V173, L180M, A181T/V and M204V) in 2/50 TFV naïve samples and 1/14 sample obtained from a TDF-experienced individual33. One other study performed deep sequencing using Illumina on HBV clones9, revealing that RAMs S106C, H126Y, D134E, M204I/V & L269I were predominant. Only one study reported sequencing the whole HBV genome, but this was undertaken following in vitro introduction of RAMs into a clinically isolated virus34, so does not provide any evidence of the association between TFV RAMs and other polymorphisms that might arise on the same viral haplotype.
Duration of therapy and treatment compliance prior to detection of tenofovir resistance
Five studies reported the duration in which individuals were on TFV prior to treatment failure, with virological breakthrough occurring between 48 weeks and 48 months of therapy (48 weeks22, 18 months24, 20 months31, 26 months9, and 48 months8,23). Compliance was assessed in six studies, among which virological breakthrough despite good treatment compliance was reported in five9,22,24,31,32, and one reported concerns with compliance26. Quantification of drug levels in plasma supported good compliance in two studies9,31.
Comparison between HIV and HBV RT
HBV RT has been classified into subdomains which are further divided into regions A – G38, which form the main catalytic core of the enzyme (Figure 1). Alignment of sequences of HBV and HIV RT demonstrates 25-27% homology between HBV and the HXB2 HIV reference sequence (Figure 2). Comparing sites that have been reported in association with drug resistance in HBV vs HIV (Figure 3; Suppl Table 5, Extended data5), we found that among our long-list of 37 HBV RAMs, two sites had identical substitutions in HIV RT (M204 and L229 in HBV10,12, corresponding to M184 and L210 in HIV, respectively; Stanford University HIV drug resistance database; Figure 3). Other sites reporting an association with TVF resistance in HBV have substitutions that overlap with HIV RAMs, but not all of these are associated with TFV resistance (Suppl Table 6, Extended data5).
Enlarge this image.Figure 2. Heatmap showing identity comparison matrix of reference sequence alignment of HBV RT and HIV RT.
Chart shows a comparison based on sequences downloaded from HIV sequence database and Hepatitis B Virus Database and aligned using MAFFT version 7. HIV reference sequence is HIV HXB2 (K03455). HBV reference sequences are Geno A – FJ692557, Geno B - GU815637, Geno C – GQ377617, Geno D - KC875277, Geno E - GQ161817.
HBV, hepatitis B virus; HIV, human immunodeficiency virus; RT, reverse transcriptase.
Sequences downloaded from HIV sequence database and Hepatitis B Virus Database. Sequences were aligned using MAFFT version 7. HIV subtype B reference sequence is shown in light green (accession number K03455). HBV reference sequences are shown in yellow (Geno-A: FJ692557; Geno-B: GU815637; Geno-C: GQ377617; Geno-D: KC875277; Geno-E: GQ161817). Sites of TFV resistance are highlighted in red, based on the data assimilated in this study. HIV tenofovir RAMs were obtained from the online Stanford University HIV drug resistance database. Sites marked * have the same amino acid in HIV and HBV RT after alignment, and those coloured blue also share TFV resistance mutations. This section is shown as it contains the only two homologous TFV RAMs that we have identified using this approach. Sequence alignments and RAMs throughout the whole RT protein is shown in Suppl Table 5 (see Extended data). Note that in most cases, individual mutations are unlikely to be sufficient to mediate resistance, and a resistant phenotype arises only as a result of combinations of ≥2 polymorphisms.
HBV, hepatitis B virus; HIV, human immunodeficiency virus; RAM, resistance-associated mutation; RT, reverse transcriptase; TFV, tenofovir.
Six established TFV RAMs in HIV RT (M41L, K65R, K70E, Y115F, Q151M and T215F/Y)19 do not correspond to an equivalent mutation in HBV RT, although three of these HIV RAMs have an HBV RAM within three amino acids up- or down-stream in the equivalent sequence, suggesting there may be homology in the mechanism through which drug resistance is mediated.
We mapped HBV RAMs onto the crystal structure of the likely structurally-related HIV RT (PDB code 3dlk) in order to visualise their approximate 3D locations and infer possible functional consequences (Figure 4; Suppl Table 6, Extended data5). The RAMs are primarily located within the ‘fingers’, ‘palm’, ‘thumb’ and ‘connection’ subdomains of the p66 polymerase domain of HIV RT, with the majority within the ‘palm’. A number of RAMs (e.g. V207, M204, F249) are spatially adjacent to the catalytically critical (and highly conserved) residues D110, D185 and D186 in HIV RT (D83, D204 and D205 in HBV), suggesting that these RAMs are highly likely to affect catalytic competency. The 22 HBV RAMs that map to HIV RT residue positions are likely to cause polymerase structure destabilisation if mutated, suggesting that many of these RAMs are likely to impact upon resistance.
Enlarge this image.Figure 4. Cartoon to show the sites of TFV drug resistance polymorphisms, using the homologous crystal structure of HIV RT as a model.
The sequence alignment of HBV was extended with HIV RT’s p66 domain and then projected onto a high-resolution HIV RT structure (PDB code 3dlk). Sub-domains of the HIV RT are coloured and annotated. Positions associated with resistance are scattered primarily throughout the finger and palm subdomains of the p66 domain (purple space-filled representations, left whole-molecule view, purple stick representation on the zoomed in view on the right). Three aspartate residues, D83, D205 and D206 (indicated by grey space-filled representation) form the catalytic triad of the enzyme and are shown as a point of reference. Of the 37 sites identified as potential TFV RAMs, 24 residues which are visible in the structure are labelled (using HBV numbering). This excludes seven putative HBV mutations at sites which do not have a homologous site in the HIV structure (sites 78, 80, 130, 134, 153, 163 and 256), and six sites which are beyond the end of the sequence of the solved crystal HIV structure (267, 269, 278, 317, 333 and 337). Figure produced using the ICM platform. Note that in most cases, individual mutations are unlikely to be sufficient to mediate resistance, and a resistant phenotype arises only as a result of combinations of ≥2 polymorphisms.
HBV, hepatitis B virus; HIV, human immunodeficiency virus; RAM, resistance-associated mutation; RT, reverse transcriptase; TFV, tenofovir.
Discussion
Summary of key findings
TFV is a safe and effective treatment choice for CHB in the majority of cases, and large case series have not raised significant concerns about clinically significant drug resistance. However, it is important to consider the potential for the emergence of resistance, demonstrated by persistent viraemia on therapy and/or reduced virologic suppression in vitro. Based on existing evidence, TFV resistance seems likely to depend on the selection of suites of mutations (most commonly including L180M, A181V/T, M204I/V and/or N236T), overlapping with RAMs that allow escape from other NA drugs. There is also a suggestion that, rarely, single mutations can confer TFV resistance, best demonstrated for S78T.
Notably, the literature to date is limited and heterogenous, and there remains a lack of evidence about the frequency and likely impact of proposed TFV RAMs, either within individual patients or at population level. At present, we have tackled this uncertainty by dividing our catalogue of polymorphisms into a ‘long-list’ (all reported RAMs) and a ‘short-list’ (RAMs with the best evidence-base of support).
Tools that have been designed to identify drug resistance may bias against detection of relevant mutations if they do not scrutinise all relevant sites that contribute to reducing TFV susceptibility. For example, ‘TRUGENE’ a commercially available HBV drug resistance interpretation system, captures common HBV RAMs but does not include positions 78, 177, or 249 which may be pertinent to TFV resistance39 and ‘geno2pheno hbv’ only lists one TFV mutation at position 236.
Overlap of TFV RAMs with RAMs to other NA agents
RAMs L180M, M204I/V and A181T/V have been associated with resistance to 3TC, telbivudine (LdT) and entecavir (ETV)3,40–43; their reported association with TFV resistance is of concern in suggesting that prior NA exposure can increase the likelihood of cross-resistance to TFV. A study of HIV/HBV co-infected individuals demonstrated a decreased likelihood of HBV DNA suppression with TDF among individuals exposed to prolonged 3TC treatment, possibly due to accumulation of such mutations44. A large study in China reported A181 and/or N236 substitutions in 11% of the population42, which may underpin reduced susceptibility to TFV. The structural similarities between ADV and TFV, and similar interaction with HBV polymerase1,2 explain why the ADV RAMs A181T/V and N236T are also reported to confer resistance to TFV1,45.
Although TFV has been considered effective in the context of resistance to other NAs46, the current evidence suggests that there may be common pathways to resistance47. There is some evidence showing co-location of RAMs conferring resistance to different antiviral agents on the same viral haplotype48. These findings suggesting cross-resistance are of concern, especially for settings in which there has been widespread use of NA therapy as a component of ART for HIV3.
Sites of TFV RAMs in HBV RT
Resistance to TFV can be explained by RAMs both within and outside the active site of the RT enzyme, some of which may have similar mechanisms to those described in HIV10,38. The mechanism of resistance in most of these polymorphisms remains unknown, but may interfere with drug access to sites of activity through steric hindrance. Mutations within active sites of the enzyme may be associated with a higher fitness cost to the virus than mutations at other locations in the RT sequence, as they are more likely to interfere with the RT function. Some polymorphisms listed as RAMs may in fact represent compensatory mutations, which are co-selected in the presence of primary RAMs. For example, substitution at position 269 has been previously described as a compensatory mutation that restores impairments to RT function49.
Currently, HBV genotyping is not routinely undertaken in clinical practice, so it is difficult to amass data for any potential relationship between resistance and viral genotype. However, there are some clues that genotype may be relevant. For example, C256S has been linked to TFV resistance, but S256 is wild type in genotype C (Suppl Table 4, Extended data5), suggesting that the genetic barrier to TFV resistance in genotype C might be lower than in other genotypes. However, a study of >1000 individuals in China found no differences in drug resistance rates between genotype B vs genotype C infection42. The identification of Y9H as a TFV RAM should be viewed with caution as H9 is frequently the wildtype residue, irrespective of genotype.
Other factors associated with persistent vireamia
In addition to RAMs, there are other explanations for incomplete suppression of HBV viraemia on therapy25,33, including a higher baseline HBV DNA level, positive baseline HBeAg status, history of 3TC exposure, a lower nadir CD4+ T cell count in the context of HIV coinfection, and high serum HBV RNA levels44,50,51. Given that HBV DNA is inhibited in a dose-dependent manner2, it is also possible that insufficient drug delivery to the infected hepatocyte could be the cause of persistent viraemia even in the absence of specific RAMs.
Incomplete adherence to therapy can also contribute to virological breakthrough52. Two studies included in our review assessed treatment compliance by measuring drug concentration in plasma9,31. Assessment of adherence in chronic HBV has been through the use of questionnaires53, but these are subject to self-reporting bias. Evidence of potential TFV resistance may emerge when individuals with HIV/HBV coinfection are treated with a TFV-containing regimen leading to suppression of HIV but with sustained HBV vireamia54.
It has been reported to take three years for 90% of HBV infected individuals to reach viraemic suppression on therapy55, in contrast to HIV, in which 88% of patients suppress the virus within the first year of TDF-based treatment56. In the studies we have reported in this review, persistent HBV viraemia on therapy could be due to the prolonged timeline for viraemic suppression; however, in most studies there was a reduction in viral load when TDF was initiated, with subsequent virological breakthrough that is more in keeping with the selection of resistance.
Implications for patient management
There are not currently sufficient data about TFV RAMs to underpin robust universal guidelines for clinical practice. However, the evidence that we have gathered here can underpin some practical recommendations:
Caveats and limitations There is sparse literature on HBV resistance to TFV, and studies are of varying quality. While there is a high genetic barrier to selection of TFV resistance, it is likely that there is under-reporting of cases of resistance, particularly in low/middle income settings in which routine monitoring of HBV viral load on treatment is not undertaken. It can be difficult to infer the impact of common polymorphisms on drug resistance phenotype; for example, it is plausible that M204I/V may be enriched among TFV resistant strains simply as a ‘footprint’ of prior exposure to 3TC.
Most studies to date have used Sanger sequencing, and it is possible that significant minority variants may be under-represented, as suggested by one report in which phenotypic TFV resistance was associated with RAMs in <20% of minor variants33. Low HBV DNA viral loads are a further barrier to sequencing, and bias existing data towards samples from individuals with high viral loads, in which the full spectrum of relevant RAMs may not occur. It is therefore important to invest in deep sequencing platforms that offer the opportunity to explore the full landscape of HBV variants isolated from an infected individual, and to improve sensitivity of sequencing methods including both Sanger and ‘next-generation’ approaches. Some sequencing methods, such as Oxford Nanopore Technologies, can generate long reads that allow reconstruction of complete viral haplotypes, providing improved certainty about linkages between sites57. To be able to undertake an appropriate haplotypes analysis, datasets with robustly phenotyped patients (displaying clinical evidence of drug resistance), together with full length viral sequence data, would be required; such datasets have not been generated to date but are an important long-term aim.
We recognise the limitations of drawing direct comparisons between HIV and HBV RT, given the limited (<30%) sequence homology between the two enzymes, and the finding that only 2/37 sites associated with TVF resistance in HBV are homologous RAMs in HIV. This highlights a need for future work to solve the crystal structure of HBV RT.
Conclusions
We have assimilated emerging evidence for HBV polymorphisms that reduce susceptibility to TFV, also acknowledging the potential influences of other viral and host factors in cases of persistent viraemia on therapy. While the genetic barrier to resistance is high, evidenced by the large number of mutations that typically have to be selected to produce resistance, of concern is the overlap with other NA resistance mutations, and the instances in which individual amino acid polymorphisms may be sufficient to produce phenotypic resistance. Enhanced studies representing larger numbers of patients, tracking longitudinal viral sequence changes, and monitoring viral suppression over time are needed. In addition, the evolution of better in vitro models will support experiments to investigate the effect of individual and combined RAMs. In order to optimise the use of NA therapy as a tool in driving advancements towards elimination at a population level, improved insights into drug resistance are essential. If resistance emerges as a substantial clinical problem, there will be a need for consideration of synergistic drug regimens, new agents that inhibit a target other than viral RT, and for the development of new therapeutic strategies that can bring about cure.
Data availability
Source data
HIV HXB2 reference sequence on GenBank, Accession number K03455
HBV Geno A reference sequence on GenBank, Accession number FJ692557
HBV Geno B reference sequence on GenBank, Accession number GU815637
HBV Geno C reference sequence on GenBank, Accession number GQ377617
HBV Geno D reference sequence on GenBank, Accession number KC875277
HBV Geno E reference sequence on GenBank, Accession number GQ161817
Extended data
Figshare: Tenofovir resistance in HBV. https://doi.org/10.6084/m9.figshare.8427746.v25
This project contains the following extended data:
Reporting guidelines
Figshare: PRISMA checklist for ‘Tenofovir resistance in HBV’. https://doi.org/10.6084/m9.figshare.8427746.v25
Data are available under the terms of the Creative Commons Attribution 4.0 International license (CC-BY 4.0).
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Jolynne Mokaya 1, Anna L McNaughton 1, [...] Phillip A Bester2, Dominique Goedhals2, Eleanor Barnes1,3,4, Brian D Marsden 5,6, Philippa C. Matthews 1,4,7
1 Nuffield Department of Medicine, University of Oxford, Medawar Building, South Parks Road, Oxford, OX1 3SY, UK
2 Division of Virology, National Health Laboratory Service/University of the Free State, Bloemfontein, South Africa
3 Department of Hepatology, Oxford University Hospitals NHS Foundation Trust, John Radcliffe Hospital, Headley Way, Oxford, OX3 9DU, UK
4 National Institutes of Health Research Health Informatics Collaborative, NIHR Oxford Biomedical Research Centre, Garsington Road, Oxford, OX4 2PG, UK
5 Structural Genomics Consortium, University of Oxford, Oxford, UK
6 Kennedy Institute of Rheumatology, Nuffield Department of Orthopaedics, Rheumatology and Musculoskeletal Sciences, University of Oxford, Roosevelt Drive, Headington, Oxford, UK
7 Department of Microbiology and Infectious Diseases, Oxford University Hospitals NHS Foundation Trust, John Radcliffe Hospital, Headley Way, Oxford, OX3 9DU, UK
Jolynne Mokaya
Roles: Conceptualization, Data Curation, Formal Analysis, Funding Acquisition, Investigation, Methodology, Project Administration, Visualization, Writing – Original Draft Preparation, Writing – Review & Editing
Anna L McNaughton
Roles: Writing – Review & Editing
Phillip A Bester
Roles: Visualization, Writing – Review & Editing
Dominique Goedhals
Roles: Writing – Review & Editing
Eleanor Barnes
Roles: Supervision, Writing – Review & Editing
Brian D Marsden
Roles: Formal Analysis, Visualization
Philippa C. Matthews
Roles: Conceptualization, Data Curation, Formal Analysis, Funding Acquisition, Investigation, Methodology, Project Administration, Resources, Supervision, Validation, Visualization, Writing – Original Draft Preparation, Writing – Review & Editing
© 2020. This work is published under http://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
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; McNaughton, Anna L
; Bester, Phillip A; Goedhals, Dominique; Barnes, Eleanor; Marsden, Brian D
; Matthews, Philippa C