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Transmitted raltegravir resistance in an HIV-1 CRF_AG-infected patient: 2nd case report - pdf attached
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Download the PDF here
Antiviral Therapy March 4 2011
"Given the lack of evidence of transmitted raltegravir resistance to date, treatment guidelines currently do not recommend obtaining an integrase genotype prior to starting a raltegravir-based regimen. Here, we report a case of transmitted multiclass drug resistance, including raltegravir, PIs, NNRTIs and NRTIs, and the difficulty in achieving viral suppression.......Although pretreatment integrase genotypes are not current standard of care, practitioners may consider obtaining one before starting a raltegravir-based regimen in a treatment-naive patient if significant resistance mutations are present on the standard genotype......To our knowledge, this case is the first report of transmitted raltegravir resistance mutations in a treatment-naive patient infected with HIV-1 CRF_AG. Raltegravir transmitted resistance has been reported in the United States [8]; as raltegravir use and subsequent failure increases, the number of patients with integrase mutations is likely to increase. The frequency of raltegravir resistance and risk of transmitting raltegravir-resistant HIV is unclear, and whether the prevalence of transmitted integrase resistance will be similar to NRTIs and NNRTIs or relatively low as with PIs remains to be seen. Our case adds to the evidence that raltegravir resistance can be acquired during primary infection and, furthermore, transmission of four-class drug resistance is possible."
Sarita D Boyd1,2,3,*, Frank Maldarelli4, Irini Sereti2, G Laissa Ouedraogo1,2,5, Catherine A Rehm2, Valerie Boltz6, Diana Shoemaker2, Alice K Pau2
1SAIC-Frederick, Inc., Frederick, MD, USA
2National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, MD, USA
3Present: Center for Drug Evaluation and Research, US Food and Drug Administration, Silver Spring, MD, USA
4HIV Drug Resistance Program, National Cancer Institute, National Institutes of Health, Bethesda, MD, USA
5Present: Henry Jackson Foundation, Division of AIDS, Bethesda, MD, USA
6HIV Drug Resistance Program, National Cancer Institute, National Institutes of Health, Frederick, MD, USA
*Corresponding author e-mail: sarita.boyd@fda.hhs.gov
doi: 10.3851/IMP1749
Date accepted: 16 January 2010
Date published online: 04 March 2011
Copyright (c) 2011 International Medical Press, all rights reserved.
Abstract
Here, we describe an HIV-infected patient with pretreatment resistance to raltegravir, nucleoside reverse transcriptase inhibitors, non-nucleoside reverse transcriptase inhibitors and protease inhibitors, and the ultimate ability to achieve viral suppression. Pretreatment integrase resistance testing is not routinely performed because transmitted integrase mutations conferring resistance to raltegravir are currently thought to be negligible. We suggest obtaining a pretreatment integrase genotype in patients with transmitted multiclass drug resistance in order to create an optimal first regimen and increase the chance for virological suppression.
Introduction
Transmitted drug resistance occurs at a reported percentage of 8-15% of HIV-infected patients in the United States and commonly involves mutations affecting nucleoside reverse transcriptase inhibitors (NRTIs), non-nucleoside reverse transcriptase inhibitors (NNRTIs) and, to a lesser extent, protease inhibitors (PIs) [1-3]. As a result, treatment guidelines recommend obtaining a standard genotype prior to starting antiretroviral therapy (ART) [4]. Raltegravir, the first FDA-approved HIV integrase strand transfer inhibitor (INSTI), commonly used in salvage regimens, is now an option for use as part of first-line ART in treatment-naive patients. Given the lack of evidence of transmitted raltegravir resistance to date, treatment guidelines currently do not recommend obtaining an integrase genotype prior to starting a raltegravir-based regimen [4]. Here, we report a case of transmitted multiclass drug resistance, including raltegravir, PIs, NNRTIs and NRTIs, and the difficulty in achieving viral suppression.
Case
The patient is a 47-year-old female who immigrated to the United States from Cameroon in 2001 and was well until September 2009 when she was hospitalized with cerebral toxoplasmosis and found to be infected with HIV-1 CRF_AG. The patient had an HIV RNA of 179,826 copies/ml and a CD4+ T-cell count of 4 cells/mm3 . She was treated with sulfadiazine, pyrimethamine and leucovorin for 3 weeks during hospitalization and for 4 weeks after discharge, with radiographic improvement of the toxoplasmosis lesions. Her course was complicated by a new onset seizure, which was treated with phenytoin and subsequently changed to levetiracetam 5 days prior to ART initiation to avoid potential cytochrome P450 (CYP)-mediated drug interactions. Because of the desire to avoid efavirenz and PIs until washout of CYP induction effects of phenytoin and based on the pretreatment genotype test (TRUGENETM HIV-1; Siemens Healthcare Diagnostics, Deerfield, IL, USA), which noted the presence of major and minor PI resistance mutations and one thymidine analogue mutation, the patient was started on raltegravir and tenofovir disoproxil fumarate/emtricitabine treatment. Figure 1 shows the patient's antiretroviral regimens, HIV RNA, CD4+ T-cell count and resistance testing results up to week 48 of therapy.
At week 2 after initiating ART, the patient's HIV RNA declined 100-fold from baseline to 1,915 copies/ml. At week 4, however, her HIV RNA remained relatively unchanged at 5,228 copies/ml. In order to better assess adherence, a stored sample from week 2 was sent to determine a raltegravir concentration (HPLC assay; University of Florida, College of Pharmacy, Infectious Disease Pharmacokinetics Laboratory, Gainesville, FL, USA), which was 300 ng/ml. The therapeutic trough of raltegravir, although not definitively established, has widely varied, ranging from <20 to 2,470 ng/ml with a median of 90 ng/ml [5]. Based on a therapeutic raltegravir concentration, pill count, refill history and self-report, the patient appeared to be adherent to her medications. At week 4, raltegravir was changed to efavirenz for patient convenience. By week 8, however, the patient's HIV RNA returned to pretreatment level (268,036 copies/ml) and a standard genotype revealed K103N and M184V mutations. Although resistance to NNRTIs was not seen on the pretreatment standard genotype, an allele-specific PCR (NCI Drug Resistance Program Core Laboratory, Frederick, MD, USA) performed on a pretreatment stored sample suggested that low-level K103N was present above background levels. Pretreatment NNRTI resistance mutations Y181C and G190A and the NRTI mutation M184V were not detected by allele-specific PCR.
At week 12, the patient's regimen was switched to darunavir/ritonavir (600 mg/100 mg twice daily) with re-initiation of raltegravir and continuation of tenofovir disoproxil fumarate/emtricitabine. Her HIV RNA declined but failed to remain <50 copies/ml. Adherence was again confirmed by pill count, refill history, pillbox check, self-report and family report. Darunavir trough levels (1,320 ng/ml and 1,740 ng/ml; HPLC assay) measured 10 weeks apart were at the lower end of the therapeutic trough range seen in treatment-experienced clinical trials (1,255-7,368 ng/ml) [6], prompting an increase in darunavir dose to 800 mg twice daily. At the same time, raltegravir was switched to etravirine, and her HIV RNA consequently declined to <50 copies/ml.
An integrase genotype (HIV GenoSURE; LabCorp, Research Triangle Park, NC, USA) performed on a stored sample from week 2 revealed a major raltegravir mutation, N155H, and minor mutations E157Q and G163R. A raltegravir phenotype (PhenoSense Integrase; Monogram Biosciences, Inc., San Francisco, CA, USA) from a week 4 stored sample showed a 25-fold increase in resistance, indicating substantial reduction in susceptibility to raltegravir, and 36% replication capacity, suggesting a virus with reduced replication compared with the pNL43 laboratory strain. These results prompted us to obtain an integrase genotype (HIV-1 Integrase Genotype; Quest Diagnostics, Nichols Institute, San Juan Capistrano, CA, USA) on a pre-ART stored sample, which revealed that the raltegravir resistance mutations were present before raltegravir exposure. The patient repeatedly denied receiving any antiretroviral medications prior to entering into care at our clinic and admitted to potential HIV exposure in the United States as late as December 2008 with a male partner from Cameroon. Her history and pretreatment genotypes, including a number of mutations in the surveillance drug resistance mutation list [7] (Table 1), strongly suggest she acquired resistance to four antiretroviral drug classes, including INSTI, via transmission.
Discussion
To our knowledge, this case is the first report of transmitted raltegravir resistance mutations in a treatment-naive patient infected with HIV-1 CRF_AG. Raltegravir transmitted resistance has been reported in the United States [8]; as raltegravir use and subsequent failure increases, the number of patients with integrase mutations is likely to increase. The frequency of raltegravir resistance and risk of transmitting raltegravir-resistant HIV is unclear, and whether the prevalence of transmitted integrase resistance will be similar to NRTIs and NNRTIs or relatively low as with PIs remains to be seen. Our case adds to the evidence that raltegravir resistance can be acquired during primary infection and, furthermore, transmission of four-class drug resistance is possible.
Transmitted resistance mutations affecting NRTIs, NNRTIs and, to a lesser extent, PIs have been reported in patients with CRF_AG [9,10], similar to patients with other HIV subtypes and recombinant forms. Although many of our patient's pretreatment protease mutations are highly prevalent in treatment-naive CRF_AG patients, 2-3 are major protease mutations [11,12] prevalent in <0.5% of treatment-naive CRF_AG patients [7] (Table 1). Many of her pretreatment mutations are considered drug resistance mutations by the International AIDS Society-USA and the Stanford University database [11,12], but the observation that she harboured surveillance drug resistance mutations T215Y/S, K103N and M46L (Table 1) supports the notion that she had transmitted drug resistance [7].
Transmitted integrase resistance regardless of subtype or recombinant form has not yet been widely reported given that raltegravir is a relatively new drug with a novel mechanism of action. Integrase genotypic and phenotypic studies in INSTI-naive patients have shown that E157Q and G163R can occur naturally, particularly in CRF_AG viruses, but cause little-to-no raltegravir resistance [13-15]. By contrast, the major mutation N155H has not been routinely detected in INSTI-naive patients, even by allele-specific PCR [16], and primarily occurs as a result of raltegravir treatment failure [17]. Therefore, it is highly likely that our patient acquired N155H through infection but possible that the minor mutations occurred naturally.
Current standard commercial genotyping/phenotyping assays do not detect resistance mutations below a threshold of 10-20% and do not routinely include analysis of integrase resistance. Based on the pretreatment standard genotype test result, our patient's first regimen of raltegravir plus tenofovir disoproxil fumarate/emtricitabine presumably contained three fully active drugs and was a currently preferred regimen for treatment-naive patients based on the Department of Health and Human Services guidelines [4]. Pre-existing raltegravir resistance was not found until a stored sample was sent for integrase genotype testing. Furthermore, the baseline standard genotype did not detect the NNRTI resistance mutation K103N, which was later found at very low levels. A lack of these test results prior to treatment initiation, neither of which are current standard of care, contributed to failure of the patient's first two regimens.
Our determination of her lack of prior therapy is based on her denial of having received any medical care from 2001 until late 2008. She has been a resident of the United States for many years, and she reports sexual contact with a man from Cameroon since arriving in the United States from whom she may have been infected. Specifically, she resides in Maryland, where the rate of non-subtype B infection has been reported to be approximately 13%, of which CRF_AG is most common [18]. The peripheral CD4+ T-cell count measured in this patient was profoundly suppressed, suggesting that she was infected for a prolonged period or had a rapid loss of CD4+ T-cells as a consequence of infection. The patient's human leukocyte antigen type was B*07, which has not been associated with rapid progression to AIDS [19]. If she was initially infected prior to raltegravir availability, she may have been re-infected with a resistant virus more recently. Despite lack of information of HIV transmission in this patient, these data highlight the potential for multidrug resistance even in non-B subtypes circulating in the United States.
HIV RNA decline at weeks 2 and 4 in the presence of an adequate raltegravir concentration and raltegravir mutations may represent residual activity of raltegravir despite the major mutation N155H. Upon restarting raltegravir at week 12 in a salvage-like regimen, HIV RNA reached <50 copies/ml, which was likely because of the high potency of darunavir/ritonavir and activity of tenofovir disoproxil fumarate rather than residual activity of raltegravir. Subsequent increase of HIV RNA by >10-fold by week 26 confirmed insufficient raltegravir activity in the presence of N155H and increased risk of virological failure. Raltegravir was discontinued after virological rebound as continuation of a raltegravir-based regimen in the face of raltegravir resistance with ongoing viral replication may select for additional integrase mutations [20], which may or may not affect the use of future, second-generation integrase inhibitors [21,22]. First-generation integrase inhibitors, raltegravir and elvitegravir, appear to share major resistance pathways, but second-generation integrase inhibitors may have activity in the presence of some integrase mutations [21,22]. Despite multiclass resistance, it was still possible to construct a suppressive regimen with PI, NNRTI and NRTI components for this patient.
Integrase inhibitors represent a new class of antiretroviral drugs with increasing usage in both treatment-naive and treatment-experienced patients. This case provides evidence that raltegravir resistance mutations can be acquired at the time of HIV transmission. Although pretreatment integrase genotypes are not current standard of care, practitioners may consider obtaining one before starting a raltegravir-based regimen in a treatment-naive patient if significant resistance mutations are present on the standard genotype.
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