HTLV-1 induces an inflammatory CD4+CD8+ T cell population in HTLV-1–associated myelopathy
Allison K. Maher, Aris Aristodemou, Nicolas Giang, Yuetsu Tanaka, Charles R.M. Bangham, Graham P. Taylor, Margarita Dominguez-Villar
Allison K. Maher, Aris Aristodemou, Nicolas Giang, Yuetsu Tanaka, Charles R.M. Bangham, Graham P. Taylor, Margarita Dominguez-Villar
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Research Article Immunology

HTLV-1 induces an inflammatory CD4+CD8+ T cell population in HTLV-1–associated myelopathy

Abstract

Human T cell leukemia virus type 1 (HTLV-1) is a retrovirus with preferential CD4+ T cell tropism that causes a range of conditions spanning from asymptomatic infection to adult T cell leukemia and HTLV-1–associated myelopathy (HAM), an inflammatory disease of the CNS. The mechanisms by which HTLV-1 induces HAM are poorly understood. By directly examining the ex vivo phenotype and function of T cells from asymptomatic carriers and patients with HAM, we show that patients with HAM have a higher frequency of CD4+CD8+ double-positive (DP) T cells, which are infected with HTLV-1 at higher rates than CD4+ T cells. Displaying both helper and cytotoxic phenotypes, these DP T cells are highly proinflammatory and contain high frequencies of HTLV-1–specific cells. Mechanistically, we demonstrate that DP T cells arise by direct HTLV-1 infection of CD4+ and CD8+ T cells. High levels of CD49d and CXCR3 expression suggest that DP T cells possess the ability to migrate to the CNS, and when cocultured with astrocytes, DP T cells induce proinflammatory astrocytes that express high levels of CXCL10, IFN-γ, and IL-6. These results demonstrate the potential of DP T cells to directly contribute to CNS pathology.

Authors

Allison K. Maher, Aris Aristodemou, Nicolas Giang, Yuetsu Tanaka, Charles R.M. Bangham, Graham P. Taylor, Margarita Dominguez-Villar

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Figure 10

Involvement of ThPOK and RunX3 in CD4 and CD8 coexpression.

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Involvement of ThPOK and RunX3 in CD4 and CD8 coexpression. (A and B) Re...
(A and B) Representative examples (A) and summary gMFI (B) in UC, AC lPVL, and AC hPVL of ex vivo Runx3 and ThPOK expression in CD4+ SP, CD8+ SP, and DP T cells (n = 11). (C and D) Box-and-whisker plots showing ThPOK and RunX3 gMFI in different patient groups (n = 4 UC, n = 4 AC lPVL, n = 3 AC hPVL). (E) Histogram showing the expression of RunX3 and ThPOK in sorted CD4+ and CD8+ SP T cells on day 1 of coculture with MT2 cells. (F and G) Line graph showing RunX3 and ThPOK gMFI in emerged DP T cells and CD4+ SP or CD8+ T cells during coculture with MT2 cells; data are shown as mean ± SEM (n = 5). (H and I) Representative dot plot (H) and line graph (I) showing the percentage of CD4+ SP, CD8+ SP, DP, and DN T cells that emerge from sorted naturally occurring DP T cells cocultured with MT2 cells; data are shown as mean ± SEM (n = 3). (J and K) Line graphs showing ThPOK and RunX3 gMFI in CD4+ SP, CD8+ SP, DP, and DN T cell populations that emerged from sorted naturally occurring DP T cells cocultured with MT2 cells; data are shown as mean ± SEM (n = 3). Wilcoxon signed-rank paired test with Holm correction (B); Wilcoxon signed-rank unpaired test for comparisons between UC and AC lPVL, and AC lPVL and AC hPVL (C and D); paired t test for comparisons between SP and DP T cells at each time point (F and G). *P < 0.05, ***P < 0.001.