Comparison of the Frequencies and Levels of Human Immunodeficiency Virus Type 1 Markers in Specimens from Chronically Infected Human T-Lymphocyte Cultures and from Patients

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Clinical and Diagnostic Laboratory Immunology, May 1999, p. 369-376, Vol. 6, No. 3
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Comparison of the Frequencies and Levels of Human Immunodeficiency Virus Type 1 Markers in Specimens from Chronically Infected Human T-Lymphocyte Cultures and from Patients

Donald J. Witt,¹^,^* Christine C. Ginocchio,² Xue-Ping Wang,² and Mi Khinkhin Soe Kaufman³

Organon Teknika Corp., Durham, North Carolina¹; North Shore University Hospital, Manhasset, New York²; and Viral Rickettsial Disease Laboratory, State Department of Health Services, Berkeley, California³

Received 1 September 1998/Returned for modification 28 October 1998/Accepted 6 February 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Together with CD4⁺-cell counts as an indicator of immune function, the use of human immunodeficiency virus type 1 (HIV-1) RNAlevels as a direct marker of viral load has gained widespreadattention for evaluation of patient clinical status. Results obtainedwith other HIV-1 markers for this purpose are often inconsistent.This study examined the relationship between various HIV-1 markersby using clinical specimens (plasma) from HIV-1-infected individualsat different stages of disease progression and supernatant fluidfrom four human T-lymphocyte cell lines chronically infected withHIV-1. Cell culture specimens were collected periodically over7 days and were tested for HIV-1 RNA levels with a nucleic acidamplification assay, for p24 with an enzyme-linked immunosorbentassay, and for reverse transcriptase activity by isotope uptake.An increase in the level of each marker was observed over the7-day period with each of the four HIV-1 strains tested (LAV1,HTLV-IIIB, MN, and ARV2); with these specimens, the frequencyof detection for each marker was 100%. In the clinical specimens,HIV-1 RNA was detected more often (143 of 183 specimens [78%])than was p24 (87 of 183 [48%]); little correlation between thelevels of the two markers was seen. In these clinical specimensevaluated, CD4⁺-cell counts were better correlated with the frequency and levelsof HIV-1 RNA than with p24. In specimens (n = 38) collected seriallyfrom six HIV-1-infected subjects, HIV-1 RNA was detected moreoften (33 of 38 [85%]) than p24 (23 of 38 [59%]). When reportedby the assays used, the levels of both HIV-1 markers fluctuatedover time for each of the subjects. Although the markers correlatedin the in vitro systems studied, the observed differences in thecorrelation of levels and frequencies of HIV-1 markers in vivoindicate that p24 has less clinical utility than does viral loadtesting when used in conjunction with CD4⁺-cell counts as a measure of immune systemfunctioning.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Both direct and indirect markers have been used to define clinical manifestations of human immunodeficiency virus type 1 (HIV-1)infection. The use of indirect markers of infection, for example,determination of neopterin levels, attempts to correlate perturbationsof physiological processes that occur as a result of HIV-1 infectionwith patient clinical status during disease progression. Use ofdirect markers of HIV-1 infection attempts to measure either viralinfectious titer, various constituent proteins, or reverse transcriptase(RT) activity associated with retroviruses. The most commonlyassayed HIV-1 constituent protein is the p24 core protein, whichis commonly referred to as HIV-1 p24 antigen. Often multiple markersof HIV-1 infection are used to assess patient status, althoughthe correlation of different markers has been inconsistent. Someinvestigators have reported a correlation of p24 with other markersfor HIV-1 infection (30), while other investigators have not(3, 10). The utilities of individual surrogate HIV-1 markersdescribed in various studies can appear to be conflicting (5),indicating a limitation for clinicalrelevance.

With the complexity of HIV-1 pathogenesis in vivo and the variability associated with commonly used surrogate markers, thedevelopment and commercialization of assays designed to detectand quantitate HIV-1 RNA in plasma or serum, referred to as theviral load, have been considered a significant advance. Thus,determination of viral load has rapidly become accepted as anintegral component of care for patients infected with HIV-1. Viralload measurements provide a means to characterize progressionof disease (18-20) and to estimate the efficacy of antiviral therapy(21). The correlation between HIV-1 RNA concentrations in plasmaspecimens and pathogenesis has resulted in the formulation ofspecific antiviral treatments that, together with the use of CD4⁺-lymphocyte counts as a measure of immune function, afford distinctmedical strategies for individual patient care. Thus, determinationof viral load has emerged as the major clinical marker for HIV-1disease (1, 2, 24).

The purpose of this study was to investigate the correlation of viral load testing with another direct marker of HIV-1 infection,p24. As the determination of viral load is based on viral RNA,presumably present as mature virions in the cell-free plasma,we examined the correlation of the presence of the virion constituentp24 with viral load determinations in clinical specimens. To gainfurther insight into the relationship between HIV-1 markers, studieswere also conducted with four in vitro laboratory strains of HIV-1.

(This study was presented in part at the 97th General Meeting of the American Society for Microbiology, Miami Beach, Fla.,4 to 8 May 1997.)

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cell culture. Four laboratory-adapted HIV-1 (group M, clade B)-infected human cell lines (MN/H9, LAV1/H9, ARV2, and HTLV-IIIB/H9) were propagatedin Dulbecco's high-glucose medium supplemented with 10% fetalbovine serum by using techniques previously described (7).The cultured cell lines were maintained at equivalent cell densities;the doubling time of the cells was approximately 4 days. The kineticsof HIV-1 markers in the cell lines were assessed over time bydaily removal of serial specimens from each cell line over a totaltime period of 7 days. The cells were separated from the culturemedium by centrifugation at 1,500 × g for 5 min. The supernatantwas removed and stored at $-$ 70°C until use. Dilutions of each specimenwere made in Dulbecco's high-glucose medium prior to analysisin order to obtain results within the dynamic range of the p24enzyme-linked immunosorbent assay (ELISA) (describedbelow).

Clinical specimens. HIV-1-infected patients from the North Shore University Hospital Center for AIDS Research and Treatment (Manhasset, N.Y.)were recruited for the study over a 27-month period from August1994 to November 1996. Demographic information concerning thesubjects' overall health status and medication was obtained fromthe subjects; there were no specific exclusionary criteria forsubject participation. Informed consent was obtained from eachsubject prior to specimen donation. Peripheral blood was collectedby venipuncture from each subject into a VACUTAINER (Becton Dickinson,Franklin Lakes, N.J.) tube with potassium EDTA. The specimenswere processed by standard techniques and stored at $-$ 70°C untiluse. For HIV-1 RNA testing, specimens were added to NASBA lysisbuffer (Organon Teknika Corp., Durham, N.C.) and stored as describedabove.

CD4⁺-cell concentration determination. CD4⁺-lymphocyte concentrations were determined by standard flow cytometrytechniques.

RT determination. Each specimen from the infected-cell cultures was evaluated with an RT assay as previously described (7).

HIV-1 p24 determination. For determination of HIV-1 p24 levels, an ELISA based on analyte capture with p24-specific monoclonal antibodies (OrganonTeknika Corp.) was used according to the manufacturer's directions.Cell culture-derived specimens were tested directly in the assay,whereas the clinical specimens were treated with a reagent designedto disrupt immune complexes (Organon Teknika Corp.). Followingaddition of the specimens to the microtiter plate and incubationat 37°C for 1 h, the microtiter plate was washed four times witha phosphate-buffered solution. An anti-p24 antibody-horseradishperoxidase conjugate was added to the microtiter plate and, followinga second 1-h incubation at 37°C, was again washed four times.Addition of tetramethylbenzidine·2 HCl substrate for 30 min resultedin the formation of color if p24 was present in the microtiterwells. The enzymatic reaction was stopped with the addition of2 N H₂SO₄, at which time the optical density was determined witha microtiter plate reader at 450 nm. The amount of p24 presentwas determined from a standard curve which was derived from theabsorbances of individual p24 standards (concentration range,5 to 80 pg/ml) included in each microtiter plate. The disruptionof potential immune complexes present in the clinical specimenswas effected by a 16- to 24-h incubation of the specimens at ambienttemperature with Base Dissociation Reagent (Organon Teknika Corp.)(11). The subsequent steps of the assay were identical to thosedescribed above. The presence of HIV-1 p24 antigen in ELISA-reactivespecimens was confirmed with an antibody neutralization assayspecific for HIV-1 p24 (Organon Teknika Corp.).

HIV-1 RNA concentration determination. HIV-1 RNA present in both cell culture specimens and clinical specimens was quantitated with the NASBA HIV-1 RNA QT System(Organon Teknika Corp.) according to the manufacturer's directions(28). Each specimen was tested with the NASBA HIV-1 RNA QT assay,using a 0.1-ml volume. The cutoff used for the assay was 400 copies.Results for HIV-1 RNA copies are presented here as copies per0.1-ml inputvolume.

Data analysis and statistical methods. Results for HIV-1 RNA and p24 from the cell culture studies were calculated as a function of the dilution of the specimentested. Data from the individual HIV-1 markers were transformedto base 10 logarithms for statistical analysis. Correlation coefficientswere derived with PROM GLM within the SAS/STAT module (SAS Institute,Cary, N.C.). Linear regression was estimated by the least-squaresmethod.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

HIV-1 markers in vitro. For specimens from each of the HIV-1-infected cell lines, a general increasing trend for each of the three viral markers studied,i.e., HIV-1 RNA, HIV-1 p24, and RT, was observed over the 7-dayobservation period (Table 1). Each viral marker for the fourHIV-1-infected cell lines was detected at each sampling time.

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TABLE 1. Kinetics of accumulation of extracellular HIV-1 markers from chronically infected human T-cell lymphocytes over a 7-day period

Differences in the kinetics of marker accumulation over time were observed in each of the four HIV-1-infected cell lines.An increase in viral RNA was evident for each observation intervalfor each cell line (15 of 16 observations [94%]), with the exceptionof day 7 for the ARV2-infected cells, at which time an 88% reductionfrom the concentration at day 6 was observed. For RT, an increasein activity was observed for each cell line for 14 of 16 (88%)of the total observations; a decrease in activity was observedat the final time point (day 7) for the LAV1- and ARV2-infectedcells. The accumulation of p24 during the observation period appearedto be the most variable of the three markers evaluated for thesecell lines. An increase in the p24 concentration was observedin 12 of 16 (75%) of the observations. For the MN- and LAV1-infectedcell lines, increasing p24 accumulation was observed through theentire observation period, whereas for the HTLV-IIIB-infectedcells, a narrow range of increased concentration of p24 was observed(range, 24,500 to 44,000 pg/ml) through the observation period.The accumulation of p24 in ARV2-infected cells appeared as a stepwiseincrease, with the first two observations being similar (5,500and 5,000 pg/ml), as were the next two time points (22,000 and19,000 pg/ml), until the highest concentration (31,000 pg/ml)was reached at day7.

Differences in the overall kinetics describing the increase in the concentration or activity for each viral marker were furtherdemonstrated for the four cell lines, as evidenced by the calculatedregression slope for each marker (Table 2). LAV1-infected cellsdemonstrated a consistent linear increase for each of the threemarkers, with a mean regression slope for the three markers of0.123. The regression slopes of the three markers were also similarin the ARV2-infected cells when the last time point for HIV-1RNA was excluded from the calculation. HTLV-IIIB- and MN-infectedcells demonstrated greater variability in the rates of accumulationamong the three markers. In these cell lines, the increases ofRT were similar (2.05 and 2.09, respectively). For HTLV-IIIB-infectedcells, the rate of p24 accumulation was approximately 50% of thatof HIV-1 RNA (0.0379 and 0.089, respectively), whereas for theMN-infected cell line, the rate of accumulation for p24 was slightlygreater than that for HIV-1 RNA (0.081 and 0.070, respectively).

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TABLE 2. Statistical summary of kinetics of extracellular HIV-1 marker accumulation in vitro^a

As shown in Table 2, comparison of the regression line slopes for the individual HIV-1 markers in each of the four cell linesindicated that the greatest variability in the rate of accumulationwas observed for p24 (range, 0.09805), while RT demonstrated theleast variability (range, 0.0115). The variability of HIV-1 RNAaccumulation was intermediate, with a range of 0.0434.

HIV-1 markers in clinical specimens. Previous studies have indicated the occurrence of immune complexes of p24 and p24-specific antibodies in HIV-1-infected individualsthat lead to a decrease in the amount of free p24 antigen thatcan be detected with an ELISA (16). Disruption of HIV-1 immunecomplexes by acidic (13) or basic (11) pH treatment resultsin greater availability of p24 for reaction in an ELISA. To determinethe efficacy of the p24 immune complex dissociation procedurewith the p24 ELISA used in the present study, 235 clinical specimensfrom HIV-1-seropositive individuals were analyzed with and withouta base specimen dissociation reagent. Use of the base dissociationreagent resulted in a significant increase in the number of clinicalspecimens reported to be reactive for HIV-1 p24 (119 of 235 [51%])compared to the number (69 of 235 [29%]) reported to be reactivewith the standard ELISA procedure without the reagent. There wasno specimen positive with the standard ELISA that was nonreactivein the ELISA after treatment with the base dissociation reagent.Agreement with both the standard technique and the base dissociationtechnique was seen for 69 positive specimens (29%) and 116 nonreactivespecimens (49%). Thus, this result indicated that the dissociationof immune complexes with the basic pH reagent was more efficaciousin detection of p24 antigenemia in clinical specimens from HIV-1-seropositiveindividuals than was the standard technique. A 72% increase inthe number of specimens with reported positive p24 results wasobserved following dissociation treatment, which was then subsequentlyused for the analysis of additional clinicalspecimens.

Upon testing of 244 individual clinical specimens from HIV-1-infected subjects collected at single time points, a reportedHIV-1 RNA copy number was obtained from 177 specimens (73%) withthe NASBA HIV-1 RNA QT System, while only 109 (45%) were reportedto be reactive for p24 antigen. Overall, the number of RNA copiesreported from the clinical specimens was inversely proportionalto the CD4⁺-cell count, as the largest amounts of HIV-1 RNA were observedin subject specimens with the lowest CD4⁺-cell counts and the smallest amounts of HIV-1 RNA were observedin specimens with the highest CD4⁺-cell counts (Table 3). A similar relationship was observed withp24 antigen.

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TABLE 3. HIV-1 marker results for clinical specimens collected at a single time point

Within this population of clinical specimens, agreement between the status of the reported viral markers (HIV-1 RNA and p24)was observed with 164 specimens (67%). Discordant results betweenthe two markers were observed with 80 (36%) of the specimens.There were approximately 8 times more specimens with only an HIV-1RNA value than with only a p24 value (Table 4).

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TABLE 4. Agreement of reported assay results for HIV-1 RNA and p24 in clinical specimens from collections at a single time point

Correlation analysis indicated a higher association between the HIV-1 RNA levels and CD4⁺-cell counts (correlation coefficient, $-$ 0.426) than between thep24 levels and CD4⁺-cell counts (correlation coefficient, $-$ 0.059). A low level ofcorrelation between the HIV-1 RNA levels and the p24 levels wasobserved when all of the data were analyzed (correlation coefficient, $-$ 0.278), and this association did not appear to be consistentfor the levels of these markers in the individual specimens (Fig.1 to 3).

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FIG. 1. Correlation between HIV-1 p24 antigenemia and HIV-1 RNA. Individual values from clinical specimens were transformed to base 10 logarithms and analyzed by least-squares regression. Least-squares regression line: $y$ = 0.35 + 0.32x.

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FIG. 2. Correlation between HIV-1 RNA and CD4⁺-cell counts. Individual HIV-1 RNA values from clinical specimens were transformed to base 10 logarithms and analyzed by least-squares regression with the square root value for the corresponding CD4⁺-cell count. Least-squares regression line: $y$ = 32.31 $-$ 4.51x.

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FIG. 3. Correlation between HIV-1 p24 antigenemia and CD4⁺-cell counts. Individual HIV-1 p24 values from clinical specimens were transformed to base 10 logarithms and analyzed by least-squares regression with the square root value for the corresponding CD4⁺-cell count. Least-squares regression line: $y$ = 13.49 $-$ 0.61x.

As antiviral regimens might be expected to affect the level of HIV-1 marker expression, further analysis of the viral markerresults and the medication regimen was done from available recordsfor 230 subjects (Table 5). The majority of the specimens evaluated(180 of 230 [78%]) in the study were obtained prior to the widespreadavailability of HIV-1 protease inhibitors and the following initiationof highly active antiretroviral therapy regimens, which are incurrent use with about 70% of the clinic's patients. The resultsof this analysis indicated that a majority of the subjects withCD4⁺-cell counts of <200 or of 200 to 499 were receiving antiretroviralmedication at the time of sampling (approximately 70% for eachgroup), whereas for the group with CD4⁺-cell counts of >500, 42.4% of the subjects were receiving antiretroviraltreatment. The antiviral treatment regimens for the three groupsranged from single therapy to triple therapy with HIV-1 proteaseinhibitors (Table 5). In the subject group with CD4⁺-cell counts of <200, 95% (21 of 22) of the subjects with no reportedantiretroviral medication and 88% (49 of 56) of the subjects withreported antiretroviral medication were positive either for HIV-1RNA and p24 or for HIV-1 RNA only. In none of these subjects wasp24 present without a positive viral load result. In the subjectgroup with CD4⁺-cell counts of 200 to 499, 84% (26 of 31) of the subjects notreceiving antiretroviral treatment were positive for viral loadand p24, while 65% (48 of 74) among those receiving antiviraltreatment were marker positive. In the latter group, 6 of 48 (12.5%)were positive for p24 only, with a range of 3 to 78 pg/ml. Fivesubjects from this group were receiving dual therapy (zidovuAdine[AZT] and lamivudine [3TC], n = 1; AZT and dideoxycytosine, n= 2; 3TC and dideoxyinosine, n = 1; and stavudine [d4T] and crixivan,n = 1), and one subject was receiving triple therapy (crixivan,3TC, and d4T). In the subject group with CD4⁺-cell counts of >500, positive marker results were reported for63% (17 of 27) of the subjects receiving no antiviral treatmentand for 55% (11 of 20) of the subjects receiving medication. Inthis group, three subjects receiving antiretroviral treatmentwere positive for p24 only; one subject was receiving monotherapy(AZT), and the other two were receiving triple therapy (crixivan,d4T, and 3TC). These results indicate that the presence of a viralload and p24 is partially related to antiretroviral treatmentbut is also strongly affected by the immune status of individualsubjects as evidenced by the CD4⁺-cell count.

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TABLE 5. Relationship between antiretroviral treatment and HIV-1 marker frequency

To determine the expression of individual markers over time in HIV-1-infected individuals, specimens from six different subjectswere collected sequentially and analyzed for the presence of HIV-1markers. More reportable results were obtained with the viralload measurement (33 of 39 [85%]) than with p24 (23 of 39 [59%]).No p24 was detected in any of the specimens from two of the individuals,while a viral load value was reported for 10 of 16 (63%) specimensfrom these subjects. With the specimens from the other four subjects,both HIV-1 RNA and p24 were detected in each of the specimens(Table 6). The levels of each marker, when reported, tended tofluctuate during the study period. In some cases (for example,with subject 1), the observed levels of either of the markersappeared to correlate with an active antiretroviral treatmentregimen, while in the other subjects this correlation was notobserved.

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TABLE 6. Immunologic status and HIV-1 marker results with sequentially collected clinical specimens

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this study, the frequencies of several HIV-1 markers present in chronically infected cell lines and in clinical specimenswere determined by different measures. The in vitro systems alsoserved as a control to characterize the performances of the twomain viral marker assays for p24 antigenemia and viral load inthe absence of the effects of the in vivo host immune system.Moreover, the characteristics of HIV-1 marker expression observedin vitro were distinctly different from those of expression inclinicalspecimens.

Direct comparison of the extracellular prevalences of the three HIV-1 markers present in the cell-free medium from infected-cell-linecultures indicated a consistent expression over a 7-day period.This result was expected in the absence of host immune regulationand indicated the utility of the assays used in the study fordetection of the HIV-1 markers. Further, the levels of the threeHIV-1 markers (RNA, p24, and RT) observed with the laboratorystrains of the virus correlated in that an increase in each markerwas observed during the culture period. In contrast, the resultsfrom clinical specimens demonstrated that the reported frequenciesof two major viral markers, HIV-1 RNA and p24 antigen, were different.This observation emphasizes that differences in viral marker expressionbetween the cell lines and the human subjects make direct comparisonsbetween the two types of host tenuous. In clinical specimens,HIV-1 RNA was detected at a greater frequency (approximately 30%)than p24, indicating a higher level of clinical sensitivity forthe viral load test. This result is in agreement with previousresults comparing these two markers (15, 17, 23, 27).However, in the clinical specimen population the more sensitivenucleic acid amplification test gave a reportable result for only72% of the specimens. This observation is in part related to thelower limit of detection of the assay. As the HIV-1 RNA copy numberin a clinical specimen diminishes to the 400-copy reportable thresholdfor this assay, a commensurate decrease in the probability ofreporting would be expected. This phenomenon is in part due tothe variability of the assay at low HIV-1 RNA concentrations,for which a low copy number may or may not be reported. However,this circumstance was not demonstrated when testing of the serialclinical specimens with RNA copy numbers below the lower limitof the assay was repeated, and none of the specimens were againreported with a HIV-1 RNA copy number. The use of more-sensitiveHIV-1 RNA amplification assays (see, e.g., references 8 and25) with enhanced detection capabilities at a copy level thresholdof <100 should further improve the clinical utility of viral loadmeasurements (9, 22). As an alternative, the use of largerspecimen input volumes may also have utility in increasing thefrequency of detection of HIV-1 RNA in specimens with low copynumbers (14).

In the clinical specimens from HIV-1-infected individuals, HIV-1 RNA levels correlated better with CD4⁺-cell counts than did p24 levels, which was the result of greaterp24 variability in this population. The levels of HIV-1 RNA presentin the clinical specimens were inversely proportional to the CD4⁺-cell counts reported, an observation in agreement with the resultsof other studies (17). Some correlation was observed betweenHIV-1 RNA levels and p24 levels, which is in agreement with previousstudies (29) which also described a correlation of proviralDNA levels with viral RNA levels. A low but significant correlationamong markers including the HIV-1 p24 level in plasma, the HIV-1RNA level in plasma, and the infectious HIV-1 titer in peripheralblood mononuclear cells has been reported (17). In our sequentiallycollected clinical specimens, the HIV-1 RNA levels and CD4⁺-cell counts were correlated; the relationship between these markerswas again inversely proportional. In four of the six specimenseries evaluated, the HIV-1 RNA levels appeared to increase overthe observation period, as did the p24 levels. These results suggestthat both markers can indicate changes in patient status overtime. In the specimens from two subjects, no p24 was detected,while HIV-1 RNA was detected in each of the specimens from thesesubjects. Thus, while p24 trend results may suggest changes inpatient status, the low correlation between p24 and HIV-1 RNAlimits the utility of p24 testing in clinical situations wheremonitoring of drug efficacy is vital (4, 12). In both ofthese earlier studies (4, 12), a significant proportion ofstudy subjects did not have measurable concentrations of p24,a result consistent with observations in the presentstudy.

In contrast to the consistent detection of HIV-1 p24 and RNA in the infected-cell cultures, the detection of these markersin clinical specimens was distinctly different. The inconsistencyof reported p24 in clinical specimens might be attributable inpart to the inherent limitations of the assays used. Thus, thestatic nature of the traditional ELISA capture detection systemfor p24 detection compared to the HIV-1 RNA amplification capabilityof the NASBA system, which increases the concentration of thetarget analyte, could account for the difference in clinical sensitivityobserved between the two assays. This general lack of sensitivityfor HIV-1 p24 detection in clinical specimens may be a characteristicof the analyte concentration in typical clinical specimens, aspolyethylene glycol precipitation of p24 complexes from clinicalspecimens results in significantly increased sensitivity of detection(6). Further complicating the detection of HIV-1 p24 is theformation of immune complexes that bind free p24 and HIV-1 virions.These immune complexes might be refractory to dissolution withthe reagent used in the present study for this purpose, whichcould offer some explanation for the lower frequency of p24 reportingcompared to that of HIV-1 RNA. Other factors that may influencethe detection of a specific HIV-1 marker involve the specificstage of disease progression, the presence of opportunistic diseaseagents (5), and use of an antiviral drug regimen (26). Inthe case of individuals receiving antiretroviral therapy, thecessation of active replication with a concomitant decrease inHIV-1 RNA present for detection might be expected prior to clearanceof residual p24 immune complexes. This sequence of HIV-1 markerrepression following antiviral treatment could account for theobservation of nine subjects with detectable p24 but no reportedRNA. Further, results from our in vitro studies suggest that differencesin HIV-1 marker concentrations might also be attributable to differentstrains of the virus and may be related to the variability amongHIV-1 strains in extracellular excretion of virions. Further analysisof viral products from both intracellular and extracellular fractionsfrom infected-cell lines is necessary to more fully understandthese relationships among different HIV-1strains.

In conclusion, determination of the HIV-1 RNA viral load provides more information about virologic status than does p24 antigenemiaand, in conjunction with the CD4⁺-cell count as a measure of immune function, affords greater clinicalutility.

	ACKNOWLEDGMENTS

We thank the nurses and patients of the North Shore Center for AIDS Research and Treatment (CART), whose generosity made thesestudies possible; Dana Gallo (Viral Rickettsial Disease Laboratory,Berkeley, Calif.) for assistance with the cell culture study;and Andrew Stead (Organon Teknika Corp., Durham, N.C.) for assistancewith the statistical analysis of thedata.

	FOOTNOTES

^* Corresponding author. Mailing address: Organon Teknika Corp., 100 AKZO Ave., Durham, NC 27712. Phone: (919) 620-2392. Fax:(919) 620-2324. E-mail: dwitt{at}orgtek.com.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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11. Hyman, J. M., D. L. Lockwood, T. J. Holody, and P. R. Youngbar. 1993. Base dissociation assay (BDA), a simplified method for immune-complex dissociation and detection of HIV-1 p24 antigen in serum and plasma, poster session no. PO-A31-0757, IXth International Conference on AIDS, Berlin, Germany, 6 to 11 June, 1993.

12. Jurriaans, S., G. J. Weverling, J. Goudsmit, J. Boogaard, M. Brok, D. van Strijp, J. Lange, M. Koot, and B. van Gemen. 1995. Distinct changes in HIV type 1 RNA versus p24 antigen levels in serum during short-term zidovudine therapy in asymptomatic individuals with and without progression to AIDS. AIDS Res. Hum. Retroviral. 11:473-479.

13. Kageyama, S., O. Yamada, S. S. Mohammad, S. Hama, N. Hattori, M. Asanaka, E. Nakayama, T. Matsumoto, F. Higuchi, T. Kawatani, and T. Kurimura. 1988. An improved method for the detection of HIV antigen in the blood of carriers. J. Virol. Methods 22:125-131[Medline].

14. Kemper, M., T. Madsen, K. Kuramoto, P. Holland, and D. Witt. 1997. Performance evaluation of an HIV-1 RNA nucleic acid amplification assay using variable sample volumes. Transfusion 37(Suppl.):S232.

15. Lafeuillade, T., C. Tamalet, P. Pellegrino, P. de Micco, C. Vignoli, and R. Quilichini. 1994. Correlation between surrogate markers, viral load, and disease progression in HIV-1 infection. J. AIDS 7:1028-1033.

16. Lange, J. M., D. A. Paul, F. de Wolf, R. A. Coutinho, and J. Goudsmit. 1987. Viral gene expression, antibody production and immune complex formation in human immunodeficiency virus infection. AIDS 1:15-20[Medline].

17. Lathey, J. L., M. D. Hughes, S. A. Fiscus, T. Pi, B. Jackson, S. Rasheed, T. Elbeik, R. Reichman, A. Japour, R. T. D'Aquila, W. Scot, B. P. Griffith, S. M. Hammer, and D. A. Katzenstein. 1998. Variability and prognostic values of virologic and CD4 cell measurements in human immunodeficiency virus type 1-infected patients with 200-500 CD4 cells/mm³ (ACTG 175). J. Infect. Dis. 177:617-624[Medline].

18. Mellors, J. W., C. R. Rinaldo, Jr., P. Gupta, R. M. White, J. A. Todd, and L. A. Kingsley. 1996. Prognosis of HIV-1 infection predicted by the quantity of virus in plasma. Science 272:1167-1170[Abstract].

19. Mellors, J. W., A. Munoz, J. V. Giorgi, J. B. Margolick, C. J. Tassoni, P. Gupta, L. A. Kingsley, J. A. Todd, A. J. Saah, R. Detels, J. P. Phair, and C. R. Rinaldo, Jr. 1997. Plasma viral load and CD4 lymphocytes as prognostic markers of HIV-1 infection. Ann. Intern. Med. 126:946-954[Abstract/Free Full Text].

20. O'Brien, W. A., P. M. Hartigan, D. Martin, J. Esinhart, A. Hill, S. Benoit, M. Rubin, M. Simberkoff, and J. D. Hamilton and the VA Cooperative Study Group on AIDS. 1996. Changes in plasma HIV-1 RNA and CD4+ lymphocytes and the risk of progression to AIDS. N. Engl. J. Med. 334:425-431.

21. O'Brien, W. A., P. M. Hartigan, E. S. Daar, M. S. Hirsch, and J. D. Hamilton. 1997. Changes in plasma HIV RNA levels and CD4⁺ lymphocyte counts predict both response to antiretroviral therapy and therapeutic failure. VA Cooperative Study Group on AIDS. Ann. Intern. Med. 126:939-945[Abstract/Free Full Text].

22. Raboud, J. M., J. S. G. Montaner, B. Conway, S. Rae, P. Reiss, S. Vella, D. Cooper, J. Lange, M. Harris, M. A. Wainberg, P. Robinson, M. Myers, and D. Hall. 1998. Suppression of plasma viral load below 20 copies/ml is required to achieve a long-term response to therapy. AIDS 12:1619-1624[Medline].

23. Revets, H., D. Marissents, S. De Wit, P. Lacor, N. Clumeck, S. Lauwers, and G. Zisses. 1996. Comparative evaluation of NASBA HIV-1 RNA QT, AMPLICOR-HIV Monitor, and QUANTIPLEX HIV RNA Assay, three methods for quantification of human immunodeficiency virus type 1 RNA in plasma. J. Clin. Microbiol. 34:1058-1064[Abstract].

24. Saag, M. S., M. Holodniy, D. R. Kuritzkes, W. A. O'Brien, R. Coombs, M. E. Poscher, D. M. Jacobsen, G. M. Shaw, D. D. Richman, and P. A. Volderding. 1996. HIV viral load markers in clinical practice. Nat. Med. 2:625-629[Medline].

25. Schockmel, G. A., S. Yerly, and L. Perrin. 1997. Detection of low HIV-1 RNA levels in plasma. J. Acquired Immune Defic. Snydr. Hum. Retrovirol. 14:179-183.

26. Schooley, R. T. 1995. Correlation between viral load measurements and outcome in clinical trials of antiviral drugs. AIDS Suppl. (UK) 9/2:S15-S19.

27. Vandamme, A. M., J. C. Schmit, S. Van Dooren, K. Van Laethem, E. Gobbers, W. Kok, P. Goubau, M. Witvrouw, W. Peetermans, E. De Clercq, and J. Desmyter. 1996. Quantification of HIV-1 RNA in plasma: comparable results with NASBA HIV-1 RNA QT and the AMPLICOR HIV monitor test. J. Acquired Immune Defic. Syndr. Hum. Retrovirol. 13:127-139[Medline].

28. van Gemen, B., T. Kievits, R. Schukkink, D. van Strijp, L. T. Malek, R. Sooknanan, H. G. Huisman, and P. Lens. 1993. Quantification of HIV-1 RNA in plasma using NASBA^{^TM} during HIV-1 primary infection. J. Virol. Methods 43:177-188[Medline].

29. Verhofstede, C., S. Reniers, F. Van Wanzeele, and J. Plum. 1994. Evaluation of proviral copy number and plasma RNA level as early indicators of progression in HIV-1 infection: correlation with virological markers and immunological markers of disease. AIDS 8:1421-1427[Medline].

30. Yerly, S., E. Chamot, B. Hirschel, and L. H. Perrin. 1992. Quantitation of human immunodeficiency virus provirus and circulating virus: relationship with immunologic parameters. J. Infect. Dis. 166:269-276[Medline].

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1.	Carpenter, C. C., M. A. Fischl, S. M. Hammer, M. S. Hirsch, D. M. Jacobson, D. A. Katzenstein, J. S. G. Montaner, D. D. Richman, M. S. Saag, R. T. Schooley, M. A. Thompson, S. Vella, P. G. Yeni, and P. A. Volberding. 1998. Antiretroviral therapy for HIV infection in 1998: updated recommendations of the International AIDS Society-USA panel. JAMA 280:78-86[Abstract/Free Full Text].
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5.	Donovan, R. M., C. E. Bush, N. P. Markowitz, D. M. Baxa, and L. D. Saravolatz. 1996. Changes in virus load markers during AIDS-associated opportunistic diseases in human immunodeficiency virus-infected persons. J. Infect. Dis. 174:401-403[Medline].
6.	Fiscus, S. A., E. B. Wallmark, J. D. Folds, J. Fryer, and C. M. van der Horst. 1991. Detection of infectious immune complexes in human immunodeficiency virus type 1 (HIV-1) infections: correlation with plasma viremia and CD4 cell counts. J. Infect. Dis. 164:765-769[Medline].
7.	Gallo, D., J. S. Kimpton, and P. J. Dailey. 1987. Comparative studies on use of fresh and frozen peripheral blood lymphocyte specimens for isolation of human immunodeficiency virus and effects of cell lysis on isolation efficiency. J. Clin. Microbiol. 25:1291-1294[Abstract/Free Full Text].
8.	Ginocchio, C. C., S. Tetali, D. Washburn, and M. H. Kaplan. 1998. A comparative study of HIV-1 RNA levels in serial plasma samples from patients on antiretroviral therapy, poster 310 In 5^th Conference on Retroviruses and Opportunistic Infections, Chicago, Ill., 1 to 5 February 1998.
9.	Ginocchio, C. C., S. Tetali, D. Washburn, F. Zhang, and M. H. Kaplan. Comparison of plasma HIV-1 RNA levels measured by the NucliSens NASBA and Quantiplex bDNA assays. J. Clin. Microbiol. 37:1210-1212.
10.	Ho, D. D., T. Moudgil, and M. Alam. 1989. Quantitation of human immunodeficiency virus type 1 in the blood of infected persons. N. Engl. J. Med. 321:1621-1625[Abstract].
11.	Hyman, J. M., D. L. Lockwood, T. J. Holody, and P. R. Youngbar. 1993. Base dissociation assay (BDA), a simplified method for immune-complex dissociation and detection of HIV-1 p24 antigen in serum and plasma, poster session no. PO-A31-0757, IXth International Conference on AIDS, Berlin, Germany, 6 to 11 June, 1993.
12.	Jurriaans, S., G. J. Weverling, J. Goudsmit, J. Boogaard, M. Brok, D. van Strijp, J. Lange, M. Koot, and B. van Gemen. 1995. Distinct changes in HIV type 1 RNA versus p24 antigen levels in serum during short-term zidovudine therapy in asymptomatic individuals with and without progression to AIDS. AIDS Res. Hum. Retroviral. 11:473-479.
13.	Kageyama, S., O. Yamada, S. S. Mohammad, S. Hama, N. Hattori, M. Asanaka, E. Nakayama, T. Matsumoto, F. Higuchi, T. Kawatani, and T. Kurimura. 1988. An improved method for the detection of HIV antigen in the blood of carriers. J. Virol. Methods 22:125-131[Medline].
14.	Kemper, M., T. Madsen, K. Kuramoto, P. Holland, and D. Witt. 1997. Performance evaluation of an HIV-1 RNA nucleic acid amplification assay using variable sample volumes. Transfusion 37(Suppl.):S232.
15.	Lafeuillade, T., C. Tamalet, P. Pellegrino, P. de Micco, C. Vignoli, and R. Quilichini. 1994. Correlation between surrogate markers, viral load, and disease progression in HIV-1 infection. J. AIDS 7:1028-1033.
16.	Lange, J. M., D. A. Paul, F. de Wolf, R. A. Coutinho, and J. Goudsmit. 1987. Viral gene expression, antibody production and immune complex formation in human immunodeficiency virus infection. AIDS 1:15-20[Medline].
17.	Lathey, J. L., M. D. Hughes, S. A. Fiscus, T. Pi, B. Jackson, S. Rasheed, T. Elbeik, R. Reichman, A. Japour, R. T. D'Aquila, W. Scot, B. P. Griffith, S. M. Hammer, and D. A. Katzenstein. 1998. Variability and prognostic values of virologic and CD4 cell measurements in human immunodeficiency virus type 1-infected patients with 200-500 CD4 cells/mm³ (ACTG 175). J. Infect. Dis. 177:617-624[Medline].
18.	Mellors, J. W., C. R. Rinaldo, Jr., P. Gupta, R. M. White, J. A. Todd, and L. A. Kingsley. 1996. Prognosis of HIV-1 infection predicted by the quantity of virus in plasma. Science 272:1167-1170[Abstract].
19.	Mellors, J. W., A. Munoz, J. V. Giorgi, J. B. Margolick, C. J. Tassoni, P. Gupta, L. A. Kingsley, J. A. Todd, A. J. Saah, R. Detels, J. P. Phair, and C. R. Rinaldo, Jr. 1997. Plasma viral load and CD4 lymphocytes as prognostic markers of HIV-1 infection. Ann. Intern. Med. 126:946-954[Abstract/Free Full Text].
20.	O'Brien, W. A., P. M. Hartigan, D. Martin, J. Esinhart, A. Hill, S. Benoit, M. Rubin, M. Simberkoff, and J. D. Hamilton and the VA Cooperative Study Group on AIDS. 1996. Changes in plasma HIV-1 RNA and CD4+ lymphocytes and the risk of progression to AIDS. N. Engl. J. Med. 334:425-431.
21.	O'Brien, W. A., P. M. Hartigan, E. S. Daar, M. S. Hirsch, and J. D. Hamilton. 1997. Changes in plasma HIV RNA levels and CD4⁺ lymphocyte counts predict both response to antiretroviral therapy and therapeutic failure. VA Cooperative Study Group on AIDS. Ann. Intern. Med. 126:939-945[Abstract/Free Full Text].
22.	Raboud, J. M., J. S. G. Montaner, B. Conway, S. Rae, P. Reiss, S. Vella, D. Cooper, J. Lange, M. Harris, M. A. Wainberg, P. Robinson, M. Myers, and D. Hall. 1998. Suppression of plasma viral load below 20 copies/ml is required to achieve a long-term response to therapy. AIDS 12:1619-1624[Medline].
23.	Revets, H., D. Marissents, S. De Wit, P. Lacor, N. Clumeck, S. Lauwers, and G. Zisses. 1996. Comparative evaluation of NASBA HIV-1 RNA QT, AMPLICOR-HIV Monitor, and QUANTIPLEX HIV RNA Assay, three methods for quantification of human immunodeficiency virus type 1 RNA in plasma. J. Clin. Microbiol. 34:1058-1064[Abstract].
24.	Saag, M. S., M. Holodniy, D. R. Kuritzkes, W. A. O'Brien, R. Coombs, M. E. Poscher, D. M. Jacobsen, G. M. Shaw, D. D. Richman, and P. A. Volderding. 1996. HIV viral load markers in clinical practice. Nat. Med. 2:625-629[Medline].
25.	Schockmel, G. A., S. Yerly, and L. Perrin. 1997. Detection of low HIV-1 RNA levels in plasma. J. Acquired Immune Defic. Snydr. Hum. Retrovirol. 14:179-183.
26.	Schooley, R. T. 1995. Correlation between viral load measurements and outcome in clinical trials of antiviral drugs. AIDS Suppl. (UK) 9/2:S15-S19.
27.	Vandamme, A. M., J. C. Schmit, S. Van Dooren, K. Van Laethem, E. Gobbers, W. Kok, P. Goubau, M. Witvrouw, W. Peetermans, E. De Clercq, and J. Desmyter. 1996. Quantification of HIV-1 RNA in plasma: comparable results with NASBA HIV-1 RNA QT and the AMPLICOR HIV monitor test. J. Acquired Immune Defic. Syndr. Hum. Retrovirol. 13:127-139[Medline].
28.	van Gemen, B., T. Kievits, R. Schukkink, D. van Strijp, L. T. Malek, R. Sooknanan, H. G. Huisman, and P. Lens. 1993. Quantification of HIV-1 RNA in plasma using NASBA^{^TM} during HIV-1 primary infection. J. Virol. Methods 43:177-188[Medline].
29.	Verhofstede, C., S. Reniers, F. Van Wanzeele, and J. Plum. 1994. Evaluation of proviral copy number and plasma RNA level as early indicators of progression in HIV-1 infection: correlation with virological markers and immunological markers of disease. AIDS 8:1421-1427[Medline].
30.	Yerly, S., E. Chamot, B. Hirschel, and L. H. Perrin. 1992. Quantitation of human immunodeficiency virus provirus and circulating virus: relationship with immunologic parameters. J. Infect. Dis. 166:269-276[Medline].