Prevalence of transmitted HIV drug resistance since the availability of highly active antiretroviral therapy

The paper presents the results of 12 years surveillance on the prevalence of HIV-1 associated transmitted drug resistance (TDR) in Victoria following the first availability of highly active antiretroviral therapy (HAART) in 1996. The main outcomes measured were the prevalence by year of TDR to any antiretroviral drug class; the number of infected individuals with TDR involving multiple drug classes; and the resistance mutations implicated in all cases.

Page last updated: 18 September 2009

A print friendly PDF version is available from this Communicable Diseases Intelligence issue's table of contents.

Introduction | Methods | Results | Discussion | Acknowledgements | References

Jessica S Russell, Doris Chibo, Matthew B Kaye, Megan L Gooey, Louise A Carolan, Anastasia Papadakis, Jodie A Nicholls, Chris J Birch

Abstract

We investigated the prevalence of HIV-1-associated transmitted drug resistance (TDR) in Victoria from the time of first availability of highly active antiretroviral therapy. Drug resistance genotyping was performed on virus present in blood samples collected from individuals with serologically confirmed primary infection, between 1996 and 2007. The significance of any mutations detected was interpreted according to a standardised list of drug resistance mutations. The main outcomes measured were the prevalence by year of TDR to any antiretroviral drug class, the numbers of infected individuals with TDR involving multiple drug classes, and the resistance mutations implicated in all cases. There was an average annual prevalence of TDR of 16%, predominantly associated with nucleoside and non-nucleoside reverse transcriptase (RT) inhibitors and most commonly occurring at codons 41, 103 and 215 in the RT. The prevalence of thymidine-associated mutations remained high throughout the period of study. While mutations known to cause resistance to protease inhibitors were uncommon, they were present in several individuals infected with virus resistant to multiple drug classes. The prevalence of TDR in Victoria is similar to geographical locations outside Australia where HIV-specific drug treatment is widely available. Primary infection with drug resistant HIV is a future treatment issue for the individual patient and for the wider population at risk of infection. At this time TDR shows no sign of waning and our data support recent treatment guidelines recommending baseline testing for TDR before therapy is initiated. Commun Dis Intell 2009;33:216–220.

Top of page

Introduction

The availability of highly active antiretroviral therapy (HAART) has produced significant decreases in the morbidity and mortality of patients infected with HIV. However, drug resistance is generated in a proportion of treated patients and may be directly transmitted from them to treatment-naïve individuals at the time of their primary infection. This process and its outcome is referred to as transmitted drug resistance (TDR).

Reports on TDR published during the last 10 years show average prevalences in developed countries ranging from 10 to 20% where use of HAART is widespread, with some variation from year-to-year in certain locations.1–5 In regions where HAART-usage is less common, for example some areas of Asia and Africa, TDR has also been documented.6,7 TDR has been regularly demonstrated for 3 antiretroviral drug classes, the nucleoside and non-nucleoside reverse transcriptase inhibitors (NRTIs and NNRTIs, respectively) and protease inhibitors (PIs).1,8 A single case of transmitted resistance to the fusion inhibitor enfuvirtide has been reported.9 Several cases of acquired resistance to the first available HIV integrase inhibitor (raltegravir) have been described10 but there are no reported cases of transmitted resistance to this drug.

The presence of resistance mutations in HIV strains transmitted at the time of infection theoretically diminishes the efficacy of individual drugs to which the mutations apply and may lower the genetic barrier to other drugs in the same class. While a large clinical study has shown the clinical impact of TDR to be subtle during first-line therapy,11 a number of reports suggest it limits treatment options and clinical response is improved by genotype-directed therapy.2,12 The impact of TDR on second-line and subsequent treatments is largely unknown. Drug resistance testing prior to commencement of antiretroviral (ARV) drug therapy is now incorporated in the HIV treatment guidelines of many countries including Australia, where it is recommended as a baseline test even if treatment is not being considered immediately.13

Evidence for TDR in the above studies has been obtained by genotyping. This is also the recommended method in Australia because of its availability in State HIV reference laboratories. The interpretation applied to specific mutations detected by genotyping may influence the reported prevalence, and a standardised mutation list has been proposed that will enable TDR surveillance programs, which are increasing in number and location, to produce comparable estimates of TDR rates.14 It is important, therefore, that laboratory testing reliably distinguishes recently infected cases from newly diagnosed cases.

This report presents the results of 12 years of surveillance of TDR in Victorian patients, commencing in 1996 when HAART became widely used for the first time, and concluding with cases to the end of 2007. The results have important implications for first-line therapy in many patients and emphasise the continuing need for baseline resistance testing as part of HIV clinical practice.

Top of page

Methods

Genotyping for TDR was performed on available plasma samples from individuals infected with HIV according to one of the following test results: western blot evolving from negative or indeterminate profile to full profile within 12 months, full western blot profile following a negative enzyme immunoassay (EIA) within 12 months, or (only for patients infected in 1999 and 2000) a detuned EIA test result suggesting recent infection.15 A total of 466 patient samples were tested by the Victorian Infectious Diseases Reference Laboratory (VIDRL), representing approximately 15% of likely new cases of infection over the study period. Because the VIDRL is the reference laboratory for HIV diagnosis in Victoria, this cohort is not thought to be subject to referral bias. The testing period included the years 1996 to 2007 inclusive. Statistical analysis was undertaken using the Pearson chi squared test. Formal ethical approval for the study was not sought. Testing was performed as a result of doctors' requests for genotyping or, prior to the widespread availability of genotyping, as part of the laboratory's surveillance role.

Genotyping of the reverse transcriptase and protease regions was performed on all samples as previously described.16 Genotyping of the HIV gp41 region for enfuvirtide susceptibility was performed only on samples from the year 2000 onwards as previously described.17 Testing for evidence of TDR associated with raltegravir therapy was not undertaken. Inclusion of mutations as being associated with TDR was made according to a proposed standardised list of drug-resistance mutations.14 To enable comparison of the prevalence of transmitted mutations with that of acquired mutations, the results of genotyping performed since 1996 on samples from more than 1,500 patients with acquired drug resistance, were extracted from our electronic laboratory reporting system to generate a database providing the frequency of all recognised resistance mutations. These results were then compared to those obtained on patients with known recent infections according to the above criteria.

Top of page

Results

Genotypic evidence for TDR was present in 75 of 466 (16%) recently infected individuals tested between 1996 and 2007, inclusive (Table 1). Of the cohort investigated 449 were males and 17 were females. The median age was 35. The majority of individuals were infected via homosexual transmission. Of the 75 patients in whom resistant virus was detected, 72 (96%) were male. All cases involved subtype B HIV strains except for 1 female infected with subtype C virus and a male with a subtype CRF01-AE infection.

Although some fluctuation in the peak annual prevalence of TDR occurred (33% in 1996 versus 9% in 2007, Table 1), in the intervening years the prevalence was broadly stable and overall there was no statistically significant difference from year to year (P=0.75). Resistance was mainly associated with NRTIs and involved 50 cases (67%). Resistance to NNRTIs was present in 27 cases (36%), while resistance to PIs was relatively uncommon (10 cases, 13%). Ten patients were infected with HIV strains resistant to more than 1 drug class and two of these were infected with virus resistant to 3 classes. There were no cases of resistance to enfuvirtide.

Top of page

Table 1: Number and percentage of cases of transmitted drug resistance, the drug classes implicated according to the mutations detected and the number of cases infected with viruses containing thymidine-associated mutations, 1996 to 2007

Year
Number of tests performed
TDR patients Drug classes TAMs
n % PI NRTI NNRTI PI/NRTI NRTI/NNRTI All classes n %
1996
9
3
33
3
3
100
1997
12
1
8
1
0
0
1998
14
3
21
2
2
67
1999
27
7
26
6
1
7
100
2000
63
12
17
1
8
1
1
10
83
2001
21
3
14
2
1
2
67
2002
48
7
15
2
3
1
1
3
43
2003
38
6
16
1
4
1
2
33
2004
43
7
16
5
2
6
86
2005
55
8
15
1
2
1
5
63
2006
72
12
17
6
5
1
5
42
2007
64
6
9
1
5
0
0
Total
466
75
16
6
40
19
2
6
2
45
60

TDR Transmitted drug resistance.

TAMs Thymidine-associated mutations.

PI Protease inhibitor.

NRTI Nucleoside reverse transcriptase inhibitor.

NNRTI Non-nucleoside reverse transcriptase inhibitor.

Top of page

Codons in RT and protease associated with TDR are shown in Table 2. Mutations associated with resistance to PIs were rare. The 2 most common individual mutations, M41L and K103N, were present in 25% and 28% of TDR cases, respectively, compared with 29% and 19%, respectively, in cases of acquired resistance. Thymidine-associated mutations (TAMS) 41L, 67N, 70R, 210W, 215Y (plus any 215-revertant) and K219Q were also very common, with no obvious evidence for a decline in their prevalence over time (Table 1). Although T215Y mutations were less common in the TDR population than in patients with acquired resistance (4% versus 23%, respectively), the inclusion of 215-revertants raised the incidence of any mutation at codon 215 to 45% in the TDR cohort.

Table 2: Resistance mutations associated with transmitted drug resistance cases

NRTI NNRTI PI
Mutation n Mutation n Mutation n
T215S/D/C/E/I
31
K103N
21
L90M
4
M41L
19
Y181C
4
M46I
3
K219Q
7
L100I
1
I84V
2
M184V
5
V106A
1
L24I
1
L210W
5
Y188H
1
G48V
1
D67N
4
Y188L
1
I54L
1
K70R
4
L190S
1
I54T
1
T215Y
3
I54V
1
M184I
2
V82A
1
K65R
1
L74V
1
V75A
1
V75M
1

Mutations were included according to a published list.14 The numbers indicated refer to the total number of individuals with this mutation during the study period. Some individuals had more than one mutation.

PI Protease inhibitor.

NRTI Nucleoside reverse transcriptase inhibitor.

NNRTI Non-nucleoside reverse transcriptase inhibitor.

Five of the 75 (7%) cases involved a methionine (M) mutation at codon 184, a prevalence considerably lower than observed in patients in our database with acquired resistance (35%).

Top of page

Discussion

Over the 12 years of this investigation the overall prevalence of TDR in Victoria was 16% and this was mainly associated with treatment involving NRTIs, zidovudine in particular. More than half the TDR cases we identified were infected with virus containing TAMs, although in 1996 and 2007 none were detected. However, in each subsequent year including 2008 (results not shown), these mutations were once again present in some cases. Therefore it appears that many of the cases in this and other studies occur as a result of the long-term use of zidovudine, including monotherapy and dual therapy prior to the advent of HAART.

As more potent drugs have become available for use in clinical practice and the once-widespread use of zidovudine has declined, a concomitant decrease in TDR prevalence might have been expected. However, despite increasing use of abacavir/lamivudine and tenofovir/emtricitabine in first-line therapy in recent years, we identified only 1 case involving the K65R mutation associated with tenofovir resistance18 and the M184V resistance mutation remained uncommon. In our acquired resistance database, M184V is the single most common mutation, present in nearly one third of all patients with resistance. However it was only detected in 7% of TDR cases, which is consistent with previous reports. This observation is likely to be related to a combination of reduced transmission efficiency associated with low viral titre and poor replicative fitness of these mutants in the transmitter, as well as impaired fitness in the absence of a selective drug pressure in the TDR cases.19

It is unclear why the prevalence of K103N mutations was higher in TDR cases than cases of acquired resistance and it is possible that the apparent difference between the 2 populations is coincidental. Nevertheless, we have previously reported the common occurrence of both mutations in patients with untreated primary HIV infection in Melbourne,19 suggesting that viruses with a K103N mutation may be preferentially transmitted.

Top of page

In contrast to the many reports from Europe and the United States of America, only 1 study on TDR in Australia has been described.21 It showed a low and stable rate of resistance to PIs (consistent with this and many other studies in a variety of geographical locations) and a decrease in resistance to inhibitors of the HIV RT between 1992 and 2001, a period overlapping introduction of HAART to Australia in 1996. This decline is likely to reflect the addition of NNRTIs and PIs to ARV treatment that until that time comprised a choice of zidovudine, didanosine or zalcitabine. The increased antiviral potency associated with HAART is likely to have reduced resistance rates associated with monotherapy and, as a consequence, the incidence of TDR. From 1997, the rates of TDR in Sydney and Melbourne have been similar.21 Nevertheless there are differences between the data gathered in these cities when the study times overlapped. In particular, several patients living in Melbourne were infected with virus resistant to multiple drug classes whereas none were seen in Sydney during the study period examined. Whether this difference has been sustained will require further studies on patients with primary infection in Sydney.

There are some drawbacks to investigations of the type we describe. In particular we studied only a proportion of the total number of newly infected patients detected on an annual basis in Victoria. In addition, the time post-infection of blood samples for genotyping varied from patient to patient, possibly biasing the proportions of individual mutations observed. This limits any generalisation that can be made between mutations considered to be transmitted versus those likely to be acquired as a result of failure of drug therapy. Finally the genotyping method employed, while standard in most reference laboratories undertaking such studies, has limited sensitivity. As such the overall TDR prevalence is possibly underestimated.

With the exception of a small number of published studies,5,21,22 investigations on the prevalence of TDR have involved relatively short time frames post the availability of HAART. This approach highlights the importance of TDR but does not show changes in either its prevalence or the ARV drug classes implicated, both of which would be predicted to evolve as new drugs become available clinically and the use of some drugs declines. Our study is one of the longest reported to date on the prevalence of TDR. As such, it reveals a stable prevalence in Victoria over 12 years on a background of a high incidence of TAMs. Despite the relatively stable TDR rate in this location, the overall prevalence of 16% highlights the need for baseline resistance testing prior to commencing HAART.

Top of page

Acknowledgements

The investigation of enfuvirtide-associated mutations in TDR cases was supported by a grant from Roche Products Pty Ltd under its Fuzeon Initiatives for National Discoveries Awards (2005). We thank Dr Gillian Hales (Roche Products) for her interest in the study. We also thank Dr Fraser Drummond for supplying the dates of first clinical use of antiretroviral drugs in Australia.

Author details

Jessica S Russell, Medical Scientist

Doris Chibo, Senior Medical Scientist

Matthew B Kaye, Medical Scientist

Megan L Gooey, Medical Scientist

Louise A Carolan, Medical Scientist

Anastasia Papadakis, Medical Scientist

Jodie A Nicholls, Medical Scientist

Chris J Birch, Senior Medical Scientist

HIV Characterisation Laboratory, Victorian Infectious Diseases Reference Laboratory, North Melbourne Victoria

Corresponding author: Ms Jessica Russell, Victorian Infectious Diseases Reference Laboratory, 10 Wreckyn Street, NORTH MELBOURNE VIC 3051. Telephone: +61 3 9342 2628. Facsimile: +61 3 9342 2666. Email: jessica.russell AT mh.org.au

Top of page

References

1. Grant RM, Hecht FM, Warmerdam M, Liu L, Liegler T, Petropoulos CJ, et al. Time trends in primary HIV-1 drug resistance among recently infected persons. JAMA 2002;288(2):181–188.

2. Little SJ, Holte S, Routy JP, Daar ES, Markowitz M, Collier AC, et al. Antiviral drug resistance among patients recently infected with HIV. N Engl J Med 2002;347(6):385–394.

3. Simon V, Vanderhoeven J, Hurley A, Ramratnam B, Louie M, Dawson K, et al. Evolving patterns of HIV-1 resistance to antiretroviral agents in newly infected individuals. AIDS 2002;16(11):1511–1519.

4. Ibe S, Hotta N, Takeo U, Tawada Y, Mamiya N, Yamanaka K, et al. Prevalence of drug-resistant human immunodeficiency virus type 1 in therapy-naïve patients and usefulness of genotype testing. Microbiol Immunol 2003;47(7):499–505.

5. Shet A, Berry L, Mohri H, Mehandru S, Chung C, Kim A, et al. Tracking the prevalence of transmitted antiretroviral drug-resistant HIV-1: a decade of experience. J Acquir Immune Defic Syndr 2006;41(4):439–446.

6. Choi JY, Kim EJ, Park YK, Lee JS, Kim SS. National survey for drug-resistant variants in newly diagnosed antiretroviral drug-naïve patients with HIV/AIDS in South Korea: 1999–2005. J Acquir Immune Defic Syndr 2008;49(3):237–242.

7. Barth RE, Wensing AM, Tempelman HA, Moraba R, Schuurman R, Hoepelman AI. Rapid accumulation of nonnucleoside reverse transcriptase inhibitor-associated resistance: evidence of transmitted resistance in rural South Africa. AIDS 2008;22(8):2210–2212.

8. Masquelier B, Bhaskaran K, Pillay D, Gifford R, Balestre E, Jørgensen LB, et al. Prevalence of transmitted HIV-1 drug resistance and the role of resistance algorithms: data from seroconverters in the CASCADE collaboration from 1987 to 2003. J Acquire Immune Defic Syndr 2005;40(5):505–511.

9. Peuchant O, Capdepont S, Ragnaud JM, Aurillac-Lavignolle V, Thiébaut R, Fleury H, et al. Primary resistance to enfuvirtide (T20) in recently infected, antiretroviral-naïve patients from the ANRS Aquitane cohort. Antivir Ther 2007,12(4):559–562.

10. Malet I, Delelis O, Valantin MA, Montes B, Soulie C, Wirden M, et al. Mutations associated with failure of Raltegravir treatment affect integrase sensitivity to the inhibitor in vitro. Antimicrob Agents Chemother 2008;52(4):1351–1358.

11. Pillay D, Bhaskaran K, Jurriaans S, Prins M, Masquelier B, Dabis F, et al. The impact of transmitted drug resistance on the natural history of HIV infection and response to first-line therapy. AIDS 2006,20(1):21–28.

12. Oette M, Kaiser R, Däumer M, Petch R, Fätkenheuer G, Carls H, et al. Primary HIV drug resistance and efficacy of first-line antiretroviral therapy guided by resistance testing. J Acquire Immune Defic Syndr 2006;41(5):573–581.

13. Australasian Society for HIV Medicine. Australian Commentary on Guidelines for the Use of Antiretroviral Agents in HIV-1-infected Adults and Adolescents [Online]. Available from: http://www.ashm.org.au/images/publications/guidelines/dhhsadult_04_03_09%20-%20final.pdf

14. Shafer RW, Rhee SY, Pillay D, Miller V, Sandstrom P, Schapiro JM, et al. HIV-1 protease and reverse transcriptase mutations for drug resistance surveillance. AIDS 2007;21(2):215–223.

15. Guy RJ, Breschkin AM, Keenan CM, Catton MG, Enriquez AM, Hellard ME. Improving HIV surveillance in Victoria: the role of the detuned enzyme immunoassay. J Acquir Immune Defic Syndr 2005; 38(4):495–499.

16. Middleton T, Smith D, Larder B, Law M, Birch C. Baseline antiretroviral drug susceptibility influences treatment response in patients receiving saquinavir-enhancing therapy. HIV Clin Trials 2001;2(6):445–452.

17. Chibo D, Roth N, Roulet V, Skrabal K, Gooey M, Carolan L, et al. Virological fitness of HIV in patients with resistance to enfuvirtide. AIDS 2007;21(14):1974–1977.

18. White KL, Margot NA, Wrin T, Petropoulos CJ, Miller MD, Naeger LK. Molecular mechanisms of resistance to human immunodeficiency virus type 1 with reverse transcriptase mutations K65R and K65R+M184V and their effects on enzyme function and viral replication capacity. Antimicrob Agents Chemother 2002;46(11):3437–3446.

19. Wainberg MA. The impact of the M184V substitution on drug resistance and viral fitness. Expert Rev Anti Infect Ther 2004;2(1):147–151.

20. Kaye M, Chibo D, Birch C. Phylogenetic investigation of transmission pathways of drug-resistant HIV-1 utilising pol sequences derived from resistance testing. J Acquir Immune Defic Syndr 2008;49(1):9–16.

21. Ammaranond P, Cunningham P, Oelrichs R, Suzuki K, Harris C, Leas L, et al. No increase in protease resistance and a decrease in reverse transcriptase resistance mutations in primary HIV-1 infection: 1992–2001. AIDS 2003;17(2):264–267.

22. Yerly S, von Wyl V, Ledergerber B, Böni J, Schüpbach J, Bürgisser P, et al. Transmission of HIV-1 drug resistance in Switzerland: a 10-year molecular epidemiology survey. AIDS 2007;21(16):2223–2229.

Communicable Diseases Intelligence subscriptions

Sign-up to email updates: Subscribe Now

This issue - Vol 33 No 2, June 2009