Molecular mechanisms of IL-4 effect on HIV expression in promonocytic cell lines and primary human monocytes.

HIV-1 can productively infect mononuclear phagocytes derived from blood, bone marrow, brain, and lung. Interleukin-4 (IL-4) and tumor necrosis factor-alpha (TNF-alpha) have previously been shown to stimulate HIV replication in monocytes and macrophages. The mechanism of IL-4 stimulation was investigated and compared with the known effects of TNF-alpha. IL-4 up-regulated the expression of HIV mRNA within the first 2 days after infection of promonocytic U-937 cells and 3 to 4 days after infection of plastic-adherent blood macrophages with HIV-1. TNF-alpha also up-regulated production of HIV RNA but to a greater degree than IL-4, reaching a peak 3-4 days after addition. Northern blot analyses showed an increase in genomic and spliced RNAs at these times. However, there was reduced stimulation of HIV mRNA production when IL-4 and TNF-alpha were combined. These techniques are being used to further elucidate the mechanism of action of cytokines that inhibit HIV replication in purified human monocytes and macrophages.

The inhibition of HIV replication in monocytes by interleukin 10 is linked to inhibition of cell differentiation.

The effect of exogenous recombinant interleukin 10 on the replication of low-passage HIV-1 strains in blood-derived monocytes and monocyte-derived-macrophages (MDMs) was examined at various stages of cell maturation after adherence to the plastic substrate. Interleukin 10 inhibited extracellular production of HIV-1 to a greater degree in monocytes infected within 24 hr of adherence than those infected at 5-7 days. Inhibition of viral production as extracellular p24 antigen was most marked when interleukin 10 was preincubated with monocytes for 24-96 hr (optimum, 48 hr), and increased between 2 and 100 ng/ml. Neutralizing antibody to IL-10 reversed the inhibition. Inhibition of HIV production from monocytes and macrophages was maximal at 1 week after a single addition of cytokine, but then HIV production rose to control levels. Interleukin 10 was also found to inhibit reversibly the normal increase in size and maturation of both uninfected and HIV-infected monocytes during 10-15 days of adherence. In addition, cytoplasmic and membrane expression of CD26, a marker of macrophage maturation, was markedly inhibited but the proportion of detaching, apoptotic, or necrotic cells was also not increased. Hence, interleukin 10 reversibly inhibits both monocyte maturation and HIV production from infected monocytes with similar kinetics, suggesting that inhibition of monocyte maturation by IL-10 may have a marked effect of HIV production by these cells.

Inhibition of human immunodeficiency virus replication in differentiating monocytes by interleukin 10 occurs in parallel with inhibition of cellular RNA expression.

The mechanism of inhibition of HIVBa-L replication by interleukin 10 (IL-10) in primary monocytes and macrophages at various stages of maturation was investigated using semiquantitative PCR for reverse-transcribed HIV DNA, and Northern hybridization for HIV mRNA expression in comparison with extracellular p24 antigen. Pretreatment of monocytes with IL-10 markedly inhibited expression of both unspliced and spliced HIV RNA, reaching a nadir at 7 days and recovering to normal levels by 10 days after a single application. The optimum inhibitory concentration was 25 ng/ml. Less inhibition of HIV RNA expression was observed when IL-10 was added after HIV infection of monocytes and the inhibitory effect progressively declined to negligible levels as monocytes matured into macrophages over 10 days. IL-10 also downregulated the expression of cellular genes, including the transferrin receptor, 28S rRNA, and GAPDH. The kinetics of the inhibition of cellular mRNAs correlated with the inhibition of HIV RNA and also declined as monocytes matured into macrophages. In contrast, IL-10 did not inhibit cellular mRNA expression in the macrophage cell line THP-1. Neutralizing polyclonal antibody to IL-10 reversed all its inhibitory effects. Interaction of IL-10 and TNF-alpha in combination were generally antagonistic in their effects on HIV transcription. IL-10 prevented stimulation of HIV RNA expression by TNF-alpha after preincubation with monocytes for 48 hr. IL-10 had no effect on the levels of HIV cDNA or the process of initiation and completion of reverse transcription. The inhibitory effect of IL-10 on HIV replication in maturing monocytes was probably mediated mainly by inhibition of cellular gene expression and inhibition of maturation of monocytes into macrophages and their activation, with consequent downregulation of HIV mRNA.

The state of maturation of monocytes into macrophages determines the effects of IL-4 and IL-13 on HIV replication.

The molecular mechanisms of the effects of IL-4 and IL-13 on HIV infection in human monocytes as they matured into monocyte-derived macrophages over 7 days were investigated using HIV-1(BaL), and low passage clinical strains. IL-4 and IL-13 up-regulated the expression of both genomic and spliced HIV mRNA in monocytes cultured on Teflon, as determined by Northern analysis and p24 Ag assay. Using a nuclear run-on assay, IL-4 stimulation was shown to enhance transcription by two- to threefold. IL-4 stimulated nuclear factor-kappaB nuclear translocation and binding before enhancement of HIV RNA expression. Conversely, IL-4 and IL-13 markedly and significantly inhibited HIV replication at the transcriptional level in monocyte-derived macrophages, and this occurred whether these cytokines were added before or after HIV infection. The reversal from stimulation to inhibition occurred after 3 to 5 days of adherence to plastic. IL-4 had no significant effect on HIV reverse transcription. The effect of both cytokines on the monocyte maturation/differentiation (CD11b, CD13, and CD26) and other macrophage markers (CD14 and CD68) was examined. IL-4 enhanced CD11b, but inhibited CD26 expression and delayed CD13 loss. IL-13 had similar effects on CD11b and CD13, but no effect on CD26. Hence, these cytokines do not simply enhance monocyte differentiation, but have complex and slightly divergent effects that impact on HIV replication probably through cell signaling pathways and nuclear factor-kappaB translocation.