Figure 1.
Efficacious plasma and tissue drug concentrations indicate broad dissemination of antiretrovirals during ART.
(A) ART suppressed plasma viremia to below detection (vRNA; solid line, closed symbols) while peripheral blood cell-associated vDNA (dashed line; open symbols) were unaffected (Day −3 vs. Day42, p = 0.63, signed rank test). (B) ART led to a rebound in peripheral blood CD4+ T cells to pre-infection levels. (C–E) Drug concentrations [tenofovir (C), emtricitabine (D) or raltegravir (E)] were determined within the plasma and each of the indicated tissues. For this steady state drug concentration analysis, the 4 BLT mice in (A) were harvested 21 hours following their last ART dosing and the tissue concentrations of the antiretrovirals were determined.
Figure 2.
Durable reduction of the number of vRNA+ cells occurs during ART.
Quantitative ISH analysis reveals statistically significant reductions in the numbers of productively infected cells for each tissue obtained from animals undergoing antiretroviral therapy. Exact log rank tests were utilized to generate p values. When no RNA+ cells were detected, then the number of RNA producing cells per gram tissue was set to 200 in the graph. (Closed symbols = no ART; open symbols = ART).
Figure 3.
Viral RNA production during ART rapidly declines and then enters a plateau phase in all tissues.
(A) Each data point indicates cell-associated vRNA levels (y-axis) and the days following ART initiation (x-axis) for a given BLT mouse in the indicated tissues. Both Lowess (dashed line) and a cubic (solid line) regression models were fit to the data for each tissue. (B) To facilitate comparative analyses between tissues, all of the Lowess regressions are graphed together. (C) To determine the overall impact of ART on systemic cell-associated vRNA levels, data from all of the tissues was used to generate a single Lowess curve.
Figure 4.
Each tissue analyzed exhibited a significant decline in vRNA during ART.
When cell-associated vRNA levels during the plateau stage (treated 28–64 days) are compared to those from untreated mice, the reduction in vRNA levels were significant in all tissues (p<0.001). Reductions in cell-associated vRNA levels are presented as log10 differences in medians. Mann-Whitney tests were used to generate p values. (Closed symbols = no ART; open symbols = ART).
Figure 5.
3B3-PE38 targets and systemically depletes vRNA+ cells in vivo.
Beginning on Day 28 after ART initiation 3B3-PE38 was added to the treatment regimen every other day (7 total doses: 4 at 1 µg/25 g followed by 3 at 5 µg/25 g). The ART only control includes mice treated for 28–64 days. (A) Reductions in cell-associated vRNA levels are presented as log10 differences in medians. Mann-Whitney tests were used to generate p values. (B) Reductions in cell-associated vRNA levels for all tissues in (A) are graphed alongside data from untreated mice (Wilcoxon rank-sum statistics with repeated measures corrections). (C) Quantitative ISH for No ART mice (Fig. 2), ART only mice (Fig. 2) and the ART+3B3-PE38 group revealed reductions in the total number of HIV RNA producing cells per gram. When no RNA+ cells were detected, then the number of RNA producing cells per gram tissue was set to 200 in the graph (Exact log rank tests with repeated measures corrections).
Figure 6.
The 3B3-PE38 mediated killing of vRNA producing cells leads to a more rapid reduction in vRNA levels versus ART only.
The single Lowess curve for all data points in Fig. 3C (closed symbols; solid line) is graphed together with the combined tissue data for ART+3B3-PE38 (open symbols; dashed line) to reveal the alteration in cell-associated vRNA levels over time due to the immunotoxin. The beginning of the plateau phase of decay (Day 28) is the divergence point.