Association of differentiation state of CD4+ T cells and disease progression in HIV-1 perinatally infected children

Central Memory CD4 T Cells from Persons with HIV Accumulate DNA Content Defects During Proliferative Response

Central memory (TCM) cells are a subpopulation of CD4 T cells that sustain overall CD4 T cell counts in HIV infection. The mechanisms underlying their eventual demise, which leads to loss of CD4 T cell counts, are not known. To understand their proneness to death despite their increased movement to proliferation, we examined cell division together with possible cell accumulation in different phases of the cell cycle. Purified circulating TCM cells from untreated people living with HIV (PLWH) (n = 9) and healthy controls (n = 10) were stimulated in vitro using anti-CD3/CD28 agonistic antibodies plus IL-2 and cultured for 4 days. Cell viability, DNA content, proliferation, and cyclin A and cyclin B expression were measured. We found that PLWH TCM cells more frequently had a DNA content lower than G0/G1, compared with controls (p = .043). These cells accumulated with each division. The proportion of cells with sub-G0/G1 DNA content that were cycling (expressing cyclin A) was greater in the PLWH group (p = .003). The percentage of TCM cells expressing cyclin A+ among those in G0/G1 and was also greater in the PLWH group (p = .043), suggesting arrest before G2/M. While TCM cells from PLWH can proliferate, during this process some of them accumulate defects in DNA content that are incompatible with viability, suggesting that they could be intrinsically prone to cell cycle-dependent death. This provides a possible mechanism underlying the increased TCM cell turnover in HIV infection.

The role of TEMRA cell-mediated immune senescence in the development and treatment of HIV disease

Human Immunodeficiency Virus (HIV) has plagued human society for a long time since its discovery, causing a large number of patients to suffer and costing hundreds of millions of medical services every year. Scientists have found that HIV and antiretroviral therapy accelerate immune aging by inducing mitochondrial dysfunction, and that terminal effector memory T cells (TEMRA cells) are crucial in immune aging. This specific subset of effector memory T cells has terminally differentiated properties and exhibits high cytotoxicity and proinflammatory capacity. We therefore explored and described the interplay between exhaustion features, essential markers, functions, and signaling pathways from previous studies on HIV, antiretroviral therapy, immune senescence, and TEMRA cells. Their remarkable antiviral capacity is then highlighted by elucidating phenotypic changes in TEMRA cells during HIV infection, describing changes in TEMRA cells before, during, and after antiretroviral therapy and other drug treatments. Their critical role in complications and cytomegalovirus (CMV)-HIV superinfection is highlighted. These studies demonstrate that TEMRA cells play a key role in the antiviral response and immune senescence during HIV infection. Finally, we review current therapeutic strategies targeting TEMRA cells that may be clinically beneficial, highlight their potential role in HIV-1 vaccine development, and provide perspectives and predictions for related future applications.

Persistent subclinical immune defects in HIV-1-infected children treated with antiretroviral therapy

OBJECTIVES

With the introduction of combined antiretroviral therapy (cART), HIV-infected children can reach adulthood with minimal clinical complications. However, long-term HIV and cART in adults are associated with immunosenescence and end-organ damage. Long-term consequences of HIV and cART in children are currently unknown.

DESIGN AND METHOD

We studied 69 HIV-infected children and adolescents under cART (0-23 years) for the occurrence of subclinical immunological aberrations in blood B and T cells, using detailed flow cytometric immunophenotyping and molecular analyses.

RESULTS

Children with undetectable plasma HIV viral loads for more than 1 year showed near-normal to normal CD4 T-cell numbers and near-normal numbers of most class-switched memory B cells. Furthermore, expansions of aberrant CD21 B cells contracted in patients with virus suppression. In contrast, CD8 effector T cells were increased, and CD4 memory T cells, Vγ9Vδ2 T cells and CD27IgA memory B cells were decreased and did not normalize under ART. Moreover, Vγ9Vδ2 T cells showed defects in their T-cell receptor repertoire selection.

CONCLUSION

Our results show the effectiveness of current cART to enable the build-up of phenotypically diverse B-cell and T-cell memory in HIV-infected children. However, several subclinical immune abnormalities were detected, which were partially caused by defective immune maturation. These persistent abnormalities were most severe in adolescents and therefore warrant long-term follow-up of HIV-infected children. Early identification of such immune defects might provide targets for monitoring future treatment optimization.

Inhibitory phenotype of HBV-specific CD4+ T-cells is characterized by high PD-1 expression but absent coregulation of multiple inhibitory molecules

Background

T-cell exhaustion seems to play a critical role in CD8⁺ T-cell dysfunction during chronic viral infections. However, up to now little is known about the mechanisms underlying CD4⁺ T-cell dysfunction during chronic hepatitis B virus (CHB) infection and the role of inhibitory molecules such as programmed death 1 (PD-1) for CD4⁺ T-cell failure.

Methods

The expression of multiple inhibitory molecules such as PD-1, CTLA-4, TIM-3, CD244, KLRG1 and markers defining the grade of T-cell differentiation as CCR7, CD45RA, CD57 and CD127 were analyzed on virus-specific CD4⁺ T-cells from peripheral blood using a newly established DRB1*01-restricted MHC class II Tetramer. Effects of in vitro PD-L1/2 blockade were defined by investigating changes in CD4⁺ T-cell proliferation and cytokine production.

Results

CD4⁺ T-cell responses during chronic HBV infection was characterized by reduced Tetramer⁺CD4⁺ T-cell frequencies, effector memory phenotype, sustained PD-1 but low levels of CTLA-4, TIM-3, KLRG1 and CD244 expression. PD-1 blockade revealed individualized patterns of in vitro responsiveness with partly increased IFN-γ, IL-2 and TNF-α secretion as well as enhanced CD4⁺ T-cell expansion almost in treated patients with viral control.

Conclusion

HBV-specific CD4⁺ T-cells are reliably detectable during different courses of HBV infection by MHC class II Tetramer technology. CD4⁺ T-cell dysfunction during chronic HBV is basically linked to strong PD-1 upregulation but absent coregulation of multiple inhibitory receptors. PD-L1/2 neutralization partly leads to enhanced CD4⁺ T-cell functionality with heterogeneous patterns of CD4⁺ T-cell rejunivation.