1. Resistance Testing – Where Do I Start?
Iván Meléndez-Rivera, MD
Fellow, American Academy of Family Physicians
Assistant Professor of Family Medicine
Ponce School of Medicine, Ponce PR, USA
Board Member, American Academy of HIV Medicine
Faculty, Florida/Caribbean AETC
Medical Director, Centro Ararat, Inc Ponce PR, USA

2. Disclosures of Financial Relationships
This speaker has significant financial relationships with the following commercial entities to disclose:
Advisory Board or Panel: Gilead, Merck
Consultant: Bristol-Myers Squibb
Grants/Research Support: Abbott, Boehringer, GlaxoSmithKline, Napo, Pfizer
Speakers Bureau: Abbott, Boehringer, Bristol-Myers Squibb, GlaxoSmithKline, Merck, Pfizer, Tibotec
This speaker will not discuss any off-label use or investigational product during the program.
This slide set has been peer-reviewed to ensure that there are no conflicts of interest represented in the presentation.

3. Objectives
Introduce major resistance mutations for each class of HIV therapy
Order currently available resistance tests
Present illustrative case(s) of diagnosing resistance pattern resulting in treatment plan adjustment
Present objectives for the module.

4. Definition of Antiviral Drug’s Resistance
Presence of viral mutations that reduce drug susceptibility compared with the susceptibility of wild-type viruses.
Can directly or indirectly interfere with a drug's activity.
Should be distinguished from other causes of drug failure such as:
Non-adherence
Insufficient drug levels
Drug regimens with intrinsically weak antiviral activity.

5. Why does Resistance Develop?
HIV can develop resistance quickly because:
HIV reverse transcriptase makes errors in matching bases when converting HIV RNA to DNA
HIV replicates at a rapid rate: 1 to 10 billion viral particles produced daily
In an untreated infected host, every possible mutation occurs at least once every 24 hours, some of which may impart drug resistance.

6. If you have developed resistance to a drug, does that mean that you are resistant to ALL the drugs in the same class?
True
False
False

7. When does resistance occur?
Resistance occurs when the virus has an opportunity to replicate in the presence of sub-inhibitory concentrations of drugs.
Treatment with <3 active drugs
Inappropriate selection of drugs
Pharmacokinetics or drug-drug interactions lead to inadequate drug exposures
Non-adherence to the treatment regimen
Interruption of treatment (even for a few days)
Adding one drug to a failing regimen
Prolonging a failing regimen

8. Selective Pressures of Therapy
Drug-susceptible quasispecies
Drug-resistant quasispecies
Treatment begins
Selection of resistant quasispecies
Viral load
Incomplete suppression
Inadequate potency
Inadequate drug levels
Inadequate adherence
Pre-existing resistance
Time

9. What is viral resistance?
A continuum of reduced susceptibility of HIV to the inhibitory effects of drugs
More Susceptible
More Resistant
The terms "drug resistance" and "reduced drug susceptibility" have similar meanings, provided that each term is viewed as representing a continuum between susceptible and highly resistant.
Because antiretroviral drugs differ in their potencies, reductions in susceptibility must be related to the activity of the drug against wild-type viruses.

10. Wild Virus vs Mutant virus
Why is it important to measure drug resistance?
Wild Virus vs Mutant virus

11. What is wild-type virus?
HIV virus that has not been exposed to drug therapy
The predominant sequence of nucleotide bases in a heterogeneous mixture of virions
It is the most fit form of HIV in the absence of drug

12. Identifying Mutations
How do we identify a resistance mutation?
M 184 M
“184 is the codon position”
M is the “wild-type” amino acid (AA)

13. Identifying Mutations
How do we identify a resistance mutation?
M 184 V
“184 is the codon position”
V is the mutant AA
M is the “wild-type” amino acid

14. What is the Impact of HIV Mutations?
To the virus, mutations can be:
Decreasing the virus’ ability to survive and/or replicate (viral fitness) or may make the virus hypersusceptible to certain antiretrovirals (ARVs)
No effect on virus function
Changing the structure of the virus to evade antiretroviral treatment. These mutations may or may not affect viral fitness
Johnson VA, et al. Topics in HIV Medicine. 2009;17:

15. Single-base Mutations May Confer Antiretroviral Resistance
3 nucleotides specify an amino acid
HIV RNA wild type
Single-base mutation
HIV RNA mutant
Drug resistant
SPEAKING POINTS:
Sets of 3 nucleotides in the HIV RNA, which code for a single amino acid of a protein are referred to as a codon
Single-base mutations to the codon may result in coding for a different amino acid, which may result in drug resistance
Such resistance mutations occur in regions of the HIV RNA specific to the antiretroviral drug class (eg, PI, NNRTI, NRTI) and are named according to:
A letter to the left that designates the amino acid in the wild type virus
A number in the center that designates the location of the amino acid impacted by the mutation
A letter to the right that designates the amino acid in the drug-resistant virus due to the mutation
Note to Speaker:
The components of this slide build in the following order:
HIV RNA, wild type
Single base mutation
HIV RNA drug resistant mutant
AA position, 123
AA wild type, X
AA mutation, Y
123 X Y
Wild-type AA: X
Position AA: 123
Mutant AA: Y
AA=amino acid
Hoffman C et al. HIV Medicine th ed. Paris, France: Flying Publisher

16. Resistance Profile and Potential for Cross Resistance
Region of HIV RNA associated with antiretroviral drug class specific resistance
HIV RNA Mutant
Drug A
Drug B
Drug C
SPEAKING POINTS:
Single-point mutations associated with resistance to a given antiretroviral drug may also be associated with cross resistance to other antiretroviral drugs
This schematic shows how mutations that cause resistance to hypothetical antiretroviral drugs A and B can have cross resistance to drugs C and D
Drugs A and B share no cross-resistance mutations and are therefore unlikely to have any impact on efficacy when used sequentially, following virologic failure
Drug C can similarly be used sequentially after Drug A, but will be cross resistant to Drug B and likely demonstrate reduced efficacy if used sequentially
Drug D is cross resistant to Drugs A and B and C
Note to Speaker:
The components of this slide build in the following order:
Region of HIV RNA associated with ARV drug class specific resistance
Drug A associated resistance mutations
Drug B associated resistance mutations
Drug C associated resistance mutations
Highlight cross resistance of Drug C with Drug B
Drug D associated resistance mutations
Highlight cross resistance of Drug D with Drugs A, B, C
B cross resistance
Drug D
A & B & C cross resistance
Adapted from: Paredes R, et al. Antiviral Res Jan;85(1):

17. How is resistance measured?
By Genotype
Amino acid substitution on chain
By phenotype (IC50)
IC50
The minimum concentration of a drug needed to inhibit the growth of the virus by 50% in vitro
IC50 is analogous to MIC90
IC90 is not sufficiently reproducible for routine clinical use
The lower the IC50, the more potent the drug

18. Resistance mutations per HIV class therapy

19. Available Antiretroviral Agents
Nucleoside Reverse
Transcriptase
Inhibitors (RTIs)
Zidovudine (ZDV)
Didanosine (ddI)
Zalcitabine (ddC)
Stavudine (d4T)
Lamivudine (3TC)
Abacavir (ABC)
Emtricitabine (FTC)
Tenofovir DF (TDF)
Nonnucleos(t)ide RTIs
Nevirapine (NVP)
Delavirdine (DLV)
Efavirenz (EFV)
Etravirine (ETR)
Rilpivirine (RPV)
Protease Inhibitors
Saquinavir (SQV)
Ritonavir (RTV)
Indinavir (IDV)
Nelfinavir (NFV)
Amprenavir (APV)
Lopinavir/r (LPV/r)
Atazanavir (ATV)
Fosamprenavir (Fos-APV)
Tipranavir (TPV)
Darunavir (DRV)
Integrase Inhibitors
Raltegravir (RAL)
Elvitegravir(ELV)*
Dolutegravir (DTG)*
Boosters
Ritonavir (RTV)
Cobicistat (cobi)
Fusion Inhibitor
Enfuvirtide (T-20)
CCR5 Antagonist
Maraviroc (MVC)
* In expanded access
August 28, 2012

20. Nucleoside Reverse Transcriptase Inhibitors (NRTI’s)
Zidovudine (ZDV)
Didanosine (ddI)
Stavudine (d4T)
Lamivudine (3TC)
Abacavir (ABC)
Tenofovir (TDF)
Emtricitabine (FTC)
Structure of a covalently trapped catalytic complex of HIV-1 RT published by Huang H et al, Science Accessed Sept 3, 2012

21. NRTI’s Resistance Mutations
CLASSIFICATION OF MAJOR DRUG RESISTANCE MUTATIONS: NRTI-resistance mutations are classified into those that inhibit NRTI incorporation into the HIV-1 primer DNA strand ('Discriminatory' Mutations) and those that promote excision of chain-terminating NRTIs via ATP-mediated pyrophosphorolysis ('Excision' Mutations). Excision mutations are usually called TAMs (Thymidine Analog Mutations) because they are selected by AZT and d4T. Two mutation complexes are associated with high-levels of multi-NNRTI resistance: (i) A 2-amino acid insertion at codon 69, which nearly always occurs in combination with multiple TAMS; and (ii) Q151M which usually occurs with several otherwise uncommon accessory mutations: A62V, V75I, F77L, and F116Y.
Red: Primary Mutations to confer resistance Gray: Secondary Mutations
***: Increase susceptibility
Adapted from: Accessed Sept 3, 2012

22. NRTI’s Signature Mutations
Medication with decrease susceptibility
M184V
Lamivudine (3TC) and Emtricitabine (FTC)
K65R
Tenofovir (TDF)
L74V
Abacavir (ABC) and Didanosine (ddI)
Y215F
Zidovudine (ZDV) and Stavudine (d4T)
T69ins or Q151M
All except, Lamivudine (3TC) and Emtricitabine (FTC)

23. Not ALL mutations are bad
M184V/I cause high-level resistance to 3TC and FTC and low-level resistance to ddI and ABC.
M184V/I are not contraindications to continued treatment with 3TC or FTC because they increase susceptibility to AZT, TDF, and d4T and are associated with clinically significant decreased HIV-1 replication.

24. Non-Nucleoside Reverse Transcriptase Inhibitors (NNRTI’s)
Nevirapine (NVP)
Efavirenz (EFV)
Etravirine (ETR)
Rilpivirine (RPV)
The NNRTIs inhibit HIV-1 RT allosterically by binding to a hydrophobic pocket about 10 angstroms under the active site. The above figure shows the 5’ polymerase-coding region of HIV-1 RT encompassing the fingers, palm, and thumb subdomains of the p66 subunit bound to the NNRTI nevirapine (Kohlstaedt) PDB #. Positions associated with NNRTI resistance that make up the central NNRTI binding pocket are shown: L100, K101, K103, V106, V108, V179, Y181, Y188, G190, F227. Additional positions that make up the pocket include E138 which is contributed by the p51 subunit) not shown and M230, L234, P236, K238, and L318 which form part of an extended pocket. Additional accessory NNRTI-resistance abutting positions that form the NNRTI binding pocket include A98 and P225.
Non-nucleoside RT inhibitor (NNRTI)-resistance mutations
Accessed Sept 3, 2012

25. NRTI’s Resistance Mutations
MAJOR MUTATIONS: Mutations that are associated with high levels of phenotpyic resistance or clinical evidence for reduced virological response. Those in bold red are associated with the highest levels of phenotypic resistance or with the strongest clinical evidence for reduced virological response. Mutations in bold grey are intermediate to those in bold red vs. those in plain text. The mutations shown at positions 103, 106, 181, 188, and 190 are generally primary because they generally occur before the mutations L100I and K101EP (Bacheler 2000, Koval 2006, Reuman 2010). M230L is uncommon and may occur alone or with other mutations (Huang 2000, Vingerhoets 2005, RPV Prescribing Information) Position 138 is included because E138K is the most commonly occurring mutation to develop in patients receiving RPV (Rimsky 2011). V106M is more common than V106A in subtype C viruses. In contrast to V106A, V106M causes high-level EFV resistance (Brenner 2003, Grossman 2004, Cane 2004)
Red: Highest Levels of resistance Gray: Intermediate level of resistance
Adapted from: Accessed Sept 3, 2012

26. NNRTI’s Signature Mutations
Medication with decrease susceptibility
K103N
Efavirenz (EFV) and Nevirapine (NVP)
Y181I/V
Etravirine (ETR) and Rilpivirine (RPV)
Y188L
Rilpivirine (RPV)
K101P
ALL NNRTI

27. Protease Inhibitors (PI’s)
Saquinavir (SQV) Ritonavir (RTV) Indinavir (IDV) Nelfinavir (NFV) Lopinavir/r (LPV/r) Atazanavir (ATV) Fosamprenavir (FPV) Tipranavir (TPV) Darunavir (DRV)
Major protease inhibitor (PI)-resistance mutations
Accessed Sept 3, 2012

28. PI’s Resistance Mutations
MAJOR MUTATIONS: Mutations that are associated with high levels of phenotypic resistance or clinical evidence for reduced virological response. Those in bold red are associated with the highest levels of phenotypic resistance or with the strongest clinical evidence for reduced virological response. Underlined mutations are potential contraindications to the use of the indicated PIs when other alternatives are available. Positions 30, 32, 46, 47, 48, 50, 54, 82, and 84 are in or near (positions 46, 47, and 54) the substrate cleft. (Jacobsen 95; Partaledis 95; Condra 96; Carrillo 98; Patick 98; Schapiro 99; Atkinson 00; Gong 00; Scott 00; Maguire 02a; Parkin 03; Colonno 04; Doyon 05; Kagan 05; Vermeiren 07; De Meyer 08a; Marcelin 08; Sista 08; Van Marck 09; Llibre 10; Rhee 10; Schapiro 10). Positions 76, 88, and 90 interfere with PI susceptibility indirectly (Patick 98; Atkinson 00; Mahalingam 01; Malan 08; Rhee 10; Louis 11).
Red: Highest Levels of resistance Gray: Intermediate level of resistance
Adapted from: Accessed Sept 3, 2012

29. PI’s Signature Mutations
Medication with decrease susceptibility
D30N
Nelfinavir (NFV)
I50L
Atazanavir (ATV)
I47V
ALL except Saquinavir (SQV)
I54V
ALL except Darunavir (DRV)
I84V

30. Integrase Inhibitors (INI)
Raltegravir (RAL) Elvitegravir(ELV) Dolutegravir(DTG)*
* Investigational
Accessed 06/OCT/12

31. INI Resistance Mutations
MAJOR MUTATIONS: Mutations that cause high-levels of decreased susceptibility of strong clinical evidence for contributing to virological failure. Those in bold red are associated with the highest levels of phenotypic resistance or with the strongest clinical evidence for reduced virological response. Mutations in bold grey are intermediate to those in bold red vs. those in plain text. Although G140SA do not decrease INI susceptibility, they occur almost uniformly in combination with the highly potent Q148 INI-resistance mutations. The major mutations shown here have been selected in persons receiving RAL (Cooper 2008, Malet 2008, Sichtig 2009, Wittkp 2009, Canducci 2009, Baldanti 2010, Reuman 2010, Hatano 2010), or ELV (McColl HIVDRW 2007, Zolopa JID 2010) and characterized for in vitro susceptibility (Shimura 2007, Goethals 2008, Kobayashi 2008, Fransen 2009, Jones 2009, da Silva 2009, Reuman 2010, Goethals 2010, Kobayashi 2011). Mutations in bold red are associated with >5-10 fold decreased susceptibility. Although E138 and G140 mutations alone do not decrease INI susceptibility that greatly contributed to decreased susceptibility in combination with Q148 mutations.
Red: Highest Levels of resistance Gray: Intermediate level of resistance
Adapted from: Accessed Sept 3, 2012

32. INI Signature Mutations
Medication with decrease susceptibility
Q148H/K/R
Raltegravir (RAL) and Elvitegravir(ELV)
* In expanded access

33. Fusion Inhibitors (FI)
Enfuvirtide (T-20)
Accessed Sept 3, 2012

34. Fusion Inhibitor Resistance Mutations
Gray: Intermediate level of resistance
Adapted from: Accessed Sept 3, 2012

35. CCR5 Antagonist Maraviroc (MVC)
Moore J, et al. Proc Natl Acad Sci USA. 2003;100: ; Yost R, et al. Am J Health-Syst Pharm. 2009;66: Accessed Sept 3, 2012

36. CCR5 Antagonist Resistance is Associated with Amino Acid Changes in the V3 Loop of gp120*
G/A
Variable pattern of Maraviroc resistance-associated amino acid substitutions
No signature mutations have been identified
Currently, there is no assay available to assess Maraviroc resistance
Tip
Tip
Stem
Stem
Base
Base
*Substitutions outside the V3 loop of gp120 may also contribute to reduced susceptibility to Maraviroc
Change
Maraviroc-resistant
Insertion
Deletion
Adapted from Data on file. ViiV Healthcare, RTP, NC.

37. CCR5-Resistant Virus Recognizes Drug-Bound Receptors
Mutated gp120
recognizes CCR5
differently
MVCres Virus
MVCres
gp120
Binding site NOT disrupted by maraviroc
Entry
Mori J, et al. 16th IHIVDRW. Barbados, 2007.
Abstract 10.

38. Recommendations for drug resistance testing

39. In which one of the following situations would HIV resistance testing NOT usually be recommended?
Acute HIV infection, regardless of whether treatment is to be started
Chronic HIV infection, at entry into care
After discontinuation (>4 weeks) of ARVs
Suboptimal suppression of viral load after starting antiretroviral therapy (ART)
Answer: C

40. Trends of Phenotypic 1-, 2-, and 3-Class Resistance60 60 60 PI
PI and NRTI
NNRTI
PI and NNRTI
NRTI
NRTI and NNRTI 50 50 50 40 40 40
Resistant Samples (%) 30 30 30 20 20 20 10 10 10
Speaker Notes:
The study examined 68,587 resistant samples submitted for routine phenotypic and genotypic patient testing that showed phenotypic resistance to at least one drug within the ARV classes of PIs, NRTIs, and NNRTIs.
Each bar represents the percentage of samples that exhibited reduced phenotypic susceptibility to either one, two, or three drug classes (NRTI, NNRTI, PI) compared to the sum total of all samples that exhibited reduced susceptibility to any drug class (NRTI, NNRTI, or PI).
2003
2004
2005
2006
2007
2008
2009
2010
2003
2004
2005
2006
2007
2008
2009
2010
2003
2004
2005
2006
2007
2008
2009
2010
NNRTI=non-nucleoside reverse transcriptase inhibitor; NRTI=nucleoside reverse transcriptase inhibitor; PI=protease inhibitor.
Adapted from Paquet A et al. 51st Interscience Conference on Antimicrobial Agents and Chemotherapy; September 17-20, 2011; Chicago, Illinois. Abstract H2-800.
ARV=antiretroviral; NNRTI=non-nucleoside reverse transcriptase inhibitor; NRTI=nucleoside reverse transcriptase inhibitor; PI=protease inhibitor.
Paquet A et al. 51st Interscience Conference on Antimicrobial Agents and Chemotherapy; September 17-20, 2011; Chicago, Illinois. Abstract H2-800.

41. Testing for Drug Resistance
Before initiation of ART:
Transmitted resistance in 6-16% of HIV-infected patients
In absence of therapy, resistance mutations may decline over time and become undetectable by current assays, but may persist and cause treatment failure when ART is started
Identification of resistance mutations may optimize treatment outcomes
Resistance testing (genotype) recommended for all at entry to care
Recommended for all pregnant women
Patients with virologic failure:
Perform while patient is taking ART, or ≤4 weeks after discontinuing therapy
Interpret in combination with history of ARV exposure and ARV adherence
Coffey S. Guidelines for the Use of Antiretroviral Agents in Adults and Adolescents: Initiation of Therapy [PowerPoint]. AIDS Education and Training Centers, National Resource Center; March Available at Accessed Sept 03, 2012.

42. Drug Resistance Testing: Recommendations
RECOMMENDED
COMMENT
Acute HIV infection, regardless of whether treatment is to be started
To determine if resistant virus was transmitted; guide treatment decisions.
If treatment is deferred, consider repeat testing at time of ART initiation.
Genotype preferred.
Chronic HIV infection, at entry into care
Transmitted drug-resistant virus is common in some areas; is more likely to be detected earlier in the course of HIV infection.
If treatment is deferred, consider repeat testing at time of ART initiation. Genotype preferred to phenotype.
Consider integrase genotypic resistance assay if integrase inhibitor resistance is a concern.
Coffey S. Guidelines for the Use of Antiretroviral Agents in Adults and Adolescents: Initiation of Therapy [PowerPoint]. AIDS Education and Training Centers, National Resource Center; March Available at Accessed Sept 03, 2012.

43. Drug Resistance Testing: Recommendations(2)
RECOMMENDED
COMMENT
Virologic failure during ART
To assist in selecting active drugs for a new regimen.
Genotype preferred if patient on 1st or 2nd regimen; add phenotype if known or suspected complex drug resistance pattern.
If virologic failure on integrase inhibitor or fusion inhibitor, consider specific genotypic testing for resistance to these to determine whether to continue them.
(Coreceptor tropism assay if considering use of CCR5 antagonist; consider if virologic failure on CCR5 antagonist.)
Suboptimal suppression of viral load after starting ART
Coffey S. Guidelines for the Use of Antiretroviral Agents in Adults and Adolescents: Initiation of Therapy [PowerPoint]. AIDS Education and Training Centers, National Resource Center; March Available at Accessed Sept 03, 2012.

44. Drug Resistance Testing: Recommendations(3)
RECOMMENDED
COMMENT
Pregnancy
Recommended before initiation of ART or prophylaxis.
Recommended for all on ART with detectable HIV RNA levels.
Genotype usually preferred; add phenotype if complex drug resistance mutation pattern.
Coffey S. Guidelines for the Use of Antiretroviral Agents in Adults and Adolescents: Initiation of Therapy [PowerPoint]. AIDS Education and Training Centers, National Resource Center; March Available at Accessed Sept 03, 2012.

45. Drug Resistance Testing: Recommendations(4)
NOT USUALLY RECOMMENDED
COMMENT
After discontinuation (>4 weeks) of ARVs
Resistance mutations may become minor species in the absence of selective drug pressure
Plasma HIV RNA <500 copies/mL
Resistance assays cannot consistently be performed if HIV RNA is low
Coffey S. Guidelines for the Use of Antiretroviral Agents in Adults and Adolescents: Initiation of Therapy [PowerPoint]. AIDS Education and Training Centers, National Resource Center; March Available at Accessed Sept 03, 2012.

46. Available Resistance test
Accessed 06/OCT/12

47. Genotypic and Phenotypic Resistance Tests
Translation into linear string of amino acids
Folding into functional protein
HIV RNA
Phenotypic assays test this
Genotypic assays
test this

48. Available Tests NRTI, NNRTI AND PI ENTRY INHIBITORS
GENOTYPE
Virtual Phenotype
PHENOTYPE
ENTRY INHIBITORS
INTEGRASE INHIBITORS
Co-Receptor Tropism Assay
RNA
DNA

49. General Limitations of Resistance Testing
Lack of uniform quality controls across different laboratories
High cost compared with other tests routinely done in HIV care
Cannot be reliably performed with HIV RNA < copies/mL
May not be able to detect minority populations of resistant virus if they account for < 20% of the sample—especially common after drug discontinuation
Resistant strains that are in viral reservoirs also not detected
Resistance studies share certain limitations, including the lack of uniform quality controls across different laboratories, a high cost compared with other tests routinely done in HIV care, the fact that the tests cannot be reliably performed with an HIV RNA count less than copies/mL, and that they may not be able to detect minority populations which account for < 20% of the sample. In addition, resistance tests cannot detect HIV strains in unsampled viral reservoirs.

50. Reversion to Predominant Wild-Type Virus After Discontinuing ART
It is clear, however, that patients who develop resistance while on ART, then discontinue ART, tend to experience a reversion of their virus to wild-type (though again, NNRTI resistance mutations may persist as these are generally not associated with a significant loss in viral fitness).
Behrens C, Kindrick A, Harrington R. Antiretroviral Resistance Testing in the Management of HIV-Infected Patients [PowerPoint].
Northwest AIDS Education and Training Center; July Available at Accessed SEP 3, 2012.
Illustration by David Spach, MD

51. genotype

52. Advantages and Disadvantages of Genotype Testing
Rapid turnaround (1-2 wks)
Less expensive than phenotyping
Detection of mutations may precede phenotypic resistance
Widely available
More sensitive than phenotype for detecting mixtures of resistant and wild-type virus
Disadvantages
Indirect measure of resistance
Relevance of some mutations unclear
Unable to detect minority variants (< 20% to 25% of viral sample)
Complex mutational patterns may be difficult to interpret
Each type of resistance testing has advantages and disadvantages. Advantages of the genotype test include rapid turnaround time, lower cost, potential detection of mutations prior to phenotypic resistance, wide availability, and higher sensitivity than phenotype testing for detecting mixtures of resistant and wild‑type virus.
One disadvantage of genotype testing is that it is an indirect measure of resistance. Another is the difficulty in determining the relevance of certain mutations without phenotypic correlates. And, as with all resistance tests, genotype testing is unable to detect minority variants comprising less than 20% to 25% of viral samples. The most significant disadvantage of genotype testing is the difficulty of interpretation when there are many mutations or highly complex patterns.

53. Genotype Report 53

54. Genotype & Phenotype Data
The Virtual Phenotype
Genotype
Access Data
HIV RT
Protease
Genotype & Phenotype Data
Virtual Phenotype
Wild-type HIV
The virtual phenotype uses a combination of the genotypic and phenotypic techologies. Virologic, the company that offers this test, has a database containing over ten thousand samples of patient serum on which both genotypic and phenotypic assays were performed. When one submits a sample to Virologic for a virtual phenotype, a genotype is performed. From the database of paired genotype and phenotype results, patient samples having the same genotype as that obtained on the sample you submitted are drawn. The corresponding phenotypes for those samples are then analyzed, averaged, and reported to the ordering clinician as a ‘virtual phenotype’, i.e. the phenotype that might be expected if one actually performed a phenotypic assay on that sample. Potential advantages of this approach include the lower cost and quicker turn around time associated with the genotype, but the easy-to-interpret results of a phenotype. However, one should keep in mind that a phenotypic assay on the sample you submit is never actually performed, and that the clinical utility of this approach is not as clearly established as it is for the genotypic assay.
Resistant HIV
Behrens C, Kindrick A, Harrington R. Antiretroviral Resistance Testing in the Management of HIV-Infected Patients [PowerPoint].
Northwest AIDS Education and Training Center; July Available at Accessed SEP 3, 2012.
Illustration by David Spach, MD 1

55. Advantages and Disadvantages of “Virtual” Phenotype Testing
Similar advantages to genotype (turnaround time, cost, sensitivity)
Defines resistance based on database of in vivo responses in treated patients
Uses 2 clinical cutoffs (CCO) to define spectrum of resistance
CCO1: value below which response expected to be comparable to wild type
CCO2: value above which most virologic response would be lost
Indicates which drugs have partial activity
Disadvantages
Is an estimated phenotype based on the patient’s genotype, not an actual measured phenotype
Reliability will depend on the accuracy of the genotype
Available only from 1 vendor
More expensive than genotype alone
Methodology of linking genotype to phenotypic database not intuitively obvious—uses a proprietary “virtual phenotype linear regression
CCO, clinical cutoff.
“Virtual” phenotype testing has similar advantages to genotype testing in terms of turnaround time, cost, and sensitivity. Again, 2 different CCOs define the spectrum of resistance: CCO1 is the value below which response is expected to be comparable to wild‑type virus. CCO2 is the value above which most virologic activity would be lost. As a result, the virtual phenotype test can also identify drugs with partial activity.
Disadvantages of virtual phenotyping include availability from a single vendor and its higher cost compared with genotype testing. Also, the methodology for linking genotype results to the phenotypic database uses a proprietary “virtual phenotype linear regression model engine,” the derivation of which is not always intuitively obvious to the user.

56. Phenotype

57. Drug Susceptibility Testing
Involves culturing a fixed inoculum of HIV-1 in the presence of serial dilutions of an inhibitory drug.
The concentrations of drug required to inhibit virus replication by 50% (IC50) or 90% (IC90)
Drug susceptibility results depend on:
inoculum size of virus tested
cells used for virus replication
the means of assessing virus replication.
Drug susceptibility assays are not designed to determine the exact amount of drug required to inhibit virus replication in vivo but rather to identify differences in the drug concentration required to inhibit a fixed inoculum of a virus relative to the concentrations required to inhibit wild-type viruses.
Accessed 06/OCT/12

58. Advantages and Disadvantages of Phenotype Testing
Provides direct and quantitative measure of resistance
Methodology can be applied to any antiretroviral agent, including new drugs, for which genotypic correlates of resistance are unclear
Uses 2 clinical cutoffs (CCO) derived from clinical cohorts to define spectrum of resistance
CCO1: value below which reduced virologic response is likely
CCO2: value above which a virologic response is unlikely
Indicates which drugs have partial activity
Can assess interactions among mutations
Accurate with non-B HIV subtypes
Disadvantages:
Susceptibility cutoffs not standardized between assays
Clinical cutoffs not defined for some agents
May be unable to detect minority variants for some mutations (< 20% to 25% of viral sample)
Complex technology with longer turnaround (~ 3 wks)
More expensive than genotyping
Phenotype testing is significantly different from genotype testing. Its primary advantage is that it provides a direct and quantitative measure of resistance and, as such, the methodology can be applied to any antiretroviral agent, including new drugs, for which genotype correlates of resistance are unclear. Two clinical cutoffs (CCO) derived from clinical cohorts are used to define the spectrum of resistance. The lower cutoff, CCO1, is the fold change in susceptibility below which reduced virologic response is likely, whereas the higher cutoff, CCO2, is the fold change above which a virologic response is unlikely. In addition, phenotype resistance testing can assess interactions among mutations and has been shown to be accurate in non‑B clade HIV subtypes.
Disadvantages of phenotype testing include variability between assays and that not all drugs have defined susceptibility cutoffs. As with genotype testing, phenotype testing may be unable to detect minority variants of some mutations. This is a complex technology with a turnaround time of approximately 3 weeks. It is also considerably more expensive than genotyping—approximately twice as much in the United States.

59. Integrase Phenotype
Phenotypic integrase resistance assay is commercially available
Amplification threshold: HIV-1 RNA > 500 copies/mL
Biological cutoff for raltegravir is fold change (FC) > 1.5
Clinical cutoff not yet determined
Report does not detail genotypic mutations
High assay accuracy demonstrated by IC50 fold change values reported for site-directed mutants
FC, fold change; RAL, raltegravir.
For more information, go online to:
Fransen S, et al. ICAAC/IDSA Abstract Accessed SEP 3,

60. Tropisms test

61. Typical HIV Co-Receptor Usage Patterns
R5 Viruses
Use only the CCR5 co-receptor
Most prevalent in early disease
Predominate throughout infection
X4 Viruses
Use only the CXCR4 co-receptor
Emerge in later disease
Associated with accelerated CD4+ cell decline and disease progression
Slide: Typical HIV Co-Receptor Usage Patterns
HIV-1 viruses can be characterized into four broad classifications based on their tropism status.1
CCR5-tropic viruses or virus populations can use only the CCR5 chemokine co-receptor to infect CD4 cells. This is the most prevalent in early disease and predominates throughout HIV disease.1
CXCR4-tropic viruses or virus populations can use only the CXCR4 chemokine co-receptor to infect CD4+ cells. These populations of virus usually emerge in later stages of disease and are associated with an accelerated CD4 cell decline and disease progression.1
Dual (D)-tropic viruses or virus populations can use either the CCR5 or CXCR4 co-receptors to infect CD4+ cells.1
Mixed (M)-tropic virus populations may contain various combinations of R5 virus, X4 virus, and/or dual-tropic viruses.1
Reference
Tsibris AMN, Kuritzkes DR. Chemokine antagonists as therapeutics: focus on HIV-1. Annu Rev Med. 2007;58:
Dual-Tropic Viruses
Use either the CCR5 or the
CXCR4 co-receptor
Mixed-Tropic
Virus Population
Tsibris AMN, Kuritzkes DR. Annu Rev Med. 2007;58:

62. No light generated No CXCR4 Use Light generated CCR5 Use
Demonstration of R5 virus
No light generated No CXCR4 Use
Not an X4 Virus
Virus
Virus
Light generated CCR5 Use
R5 Virus
Virus
Example of CCR5 virus entering R5 cell line and generating RLU (relative light units) in the Trofile assay
CCR5
CXCR4

64. Demonstration of dual virus
Light is generated on both CCR5 and CXCR4 cell lines
This is a DUAL virus
Virus
Virus
CCR5
CXCR4
Example of CCR5 virus entering R5 cell line and generating RLU (relative light units) in the Trofile assay

65. Demonstration of mixed virus population
This population shows CCR5 AND CXCR4 co-receptor use
This is a mixed population
CCR5
CXCR4
Example of CCR5 virus entering R5 cell line and generating RLU (relative light units) in the Trofile assay

67. Virologic Failure With Resistance
Virologic failure is defined as the inability of ARV regimen to achieve virologic suppression or occurrence of virologic rebound1
A confirmed viral load >200 copies/mL can be considered virologic failure2
Resistant Virus
Viral Load
Time on Antiviral Therapy
Speaker Notes:
Virologic failure is defined as the inability of ARV regimen to achieve virologic suppression or occurrence of virologic rebound1
The DHHS Guidelines consider a confirmed viral load >200 copies/mL as a virologic failure2
Virologic suppression to <50 copies/mL is a marker for the suppression of viral replication3
Based on Clavel et al.3
AIDSinfo. Glossary of HIV/AIDS-related terms. 7th ed Available at Accessed November 18, 2011
DHHS Guidelines. Accessed November 18, 2011.
Clavel F et al. N Engl J Med. 2004;350:
ARV=antiretroviral; DHHS=Department of Health and Human Services.
1. AIDSinfo. Glossary of HIV/AIDS-related terms. 7th ed Available at Accessed November 18, 2011
2. DHHS Guidelines. GL.pdf. Accessed November 18, 2011.
3. Podsadecki TJ et al. J Infect Dis. 2007;196:

69. Case presentation

70. The follow factors leads to developing drug-resistance EXCEPT…?
Poor drug absorption
Poor adherence
High drug levels
Pre-existing resistance
Interactions with other drugs, supplements or recreational drugs
Answer: C

71. Case 1: 42 y/o AA female Dx in 2006 Current Medical Hx
Diabetes
Hyperlipidemia
Hypertension
Baseline Labs (1/06)
VL: 230,000
CD4: 320 cells/mm3
Baseline Genotype
Wild-Type
Pt request a once a day pill ARV and start 5/06 on EFV/TDF/ETC FDC
Viral Load quickly becomes undetectable and CD4+ counts raises over time

72. Case 1: 42 y/o AA female
Date VL
CD4
11/06
<400
400
05/07
<50
480
05/08
600
05/09
680
11/09
30,000
Patient experiences virologic failure on Nov 2009 while taking EVF/TDF/FTC
Pt. reports occasional poor adherence due to occasional sleep disturbances and concerns about lipid problems

73. Case 1: 42 y/o AA female What would be your next step?
Enforce patient adherence and continue with same regimen.
Perform Genotype test and keep patient on the same regiment until genotype results.
Perform a tropism and Phenotype test and remove patient from medicines because there are toxic.
Change patient regiment without any resistance test performed.

74. Case 1: 42 y/o AA female With this genotype result, is Efavirenz still available?
Answer: B
Yes No

75. Case 1: 42 y/o AA female Resistance testing result.
January 2010 patient was place on EPZ/ATV
Labs 04/10
CD4: 700 cells/mm3
VL: <50 copies
Pt. continue with non-detectable (ND) viral load until 04/12
CD4 800 cells/mm3
VL: 15,000 copies
Resistance testing result.
NRTI’s: M184V
NNTRI’s: K103N
PI’s: I50L

76. Based on new resistance pattern (NRTI’s: M184V NNTRI’s: K103N; PI’s: I50L) which statement is true?
All NNRT’s are available to use
Atazanavir still available for use
3Tc is a full active drug
Patient loss susceptibility to rilpivirine
Keeping patient on efavirenz will increase the amount of NNRTI mutations and reduce the susceptibility to all other NRTI’s
Answer: E

77. Case 2
A 45 year-old man who is highly treatment-experienced with antiretroviral therapy has virologic failure on tenofovir/emtricitabine and lopinavir/ritonavir.
His enhanced Trofile assay reveals a dual/mixed-tropic virus.
His current genotype reveals reverse transcriptase mutations M41l, V90I, K103N, M184V, L210W, T215Y and protease inhibitors mutations V32I, I47V, I54A, V82L, I84V, and L90M.
In addition, a 2006 genotype also reveled the envelope glycoprotein 41 mutation G36D.

78. Ritonavir-boosted darunavir Ritonavir-boosted tipranavir
The next BEST antiretroviral regimen for this patient would include which of the following?
Enfuvirtide
Maraviroc
Etravirine
Ritonavir-boosted darunavir
Ritonavir-boosted tipranavir
Response: C

79. Bonus Case
A 21 years-old man who acquired HIV through vertical transmission presents for routine care.
Recent genotypic analysis reveals a 69 insertion complex and K103N reverse transcriptase mutations and L10I, K20M, M46I, G48V, I50V, N88S and L90M protease mutations.

80. Which regimen would be the BEST for him?
Raltegravir, etravirine, and atazanavir/ritonavir
Raltegravir, etravirine, and darunavir/ritonavir
Raltegravir, etravirine, and fosamprenavir/ritonavir
Raltegravir, etravirine, and indinavir/ritonavir
Raltegravir, etravirine, and maraviroc
Response: B

81. Reference http://hivdb.stanford.edu/
Behrens C, Kindrick A, Harrington R. Antiretroviral Resistance Testing in the Management of HIV-Infected Patients [PowerPoint]. Northwest AIDS Education and Training Center; July Available at Accessed Sept 03, 2012.
Coffey S. Guidelines for the Use of Antiretroviral Agents in Adults and Adolescents: Initiation of Therapy [PowerPoint]. AIDS Education and Training Centers, National Resource Center; March Available at Accessed Sept 03, 2012.
Accessed Sept 03, 2012