CD4 T Follicular Helper and Regulatory Cell Dynamics and Function in HIV Infection

Miles, Brodie, Miller, Shannon M., Connick, Elizabeth

27 December 2016

T follicular helper cells (T-FH) are a specialized subset of CD4 T cells that reside in B cell follicles and promote B cell maturation into plasma cells and long-lived memory B cells. During chronic infection prior to the development of AIDS, HIV-1 (HIV) replication is largely concentrated in T-FH. Paradoxically, T-FH numbers are increased in early and midstages of disease, thereby promoting HIV replication and disease progression. Despite increased T-FH numbers, numerous defects in humoral immunity are detected in HIV-infected individuals, including dysregulation of B cell maturation, impaired somatic hypermutation, and low quality of antibody production despite hypergammaglobulinemia. Clinically, these defects are manifested by increased vulnerability to bacterial infections and impaired vaccine responses, neither of which is fully reversed by antiretroviral therapy (ART). Deficits in T-FH function, including reduced HIV-specific IL-21 production and low levels of co-stimulatory receptor expression, have been linked to these immune impairments. Impairments in T-FH likely contribute as well to the ability of HIV to persist and evade humoral immunity, particularly the inability to develop broadly neutralizing antibodies. In addition to direct infection of T-FH, other mechanisms that have been linked to T-FH deficits in HIV infection include upregulation of PD-L1 on germinal center B cells and augmented follicular regulatory T cell responses. Challenges to development of strategies to enhance T-FH function in HIV infection include lack of an established phenotype for memory T-FH as well as limited understanding of the relationship between peripheral T-FH and lymphoid tissue T-FH. Interventions to augment T-FH function in HIV-infected individuals could enhance immune reconstitution during ART and potentially augment cure strategies.

follicular T helper cells

follicular T regulatory cells

germinal center

broadly neutralizing antibodies

HIV

Elucidating the role of BCL6 in helper T cell activation, proliferation, and differentiation

Hollister, Kristin N.

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / The transcriptional repressor BCL6 has been shown to be essential for the differentiation of germinal center (GC) B cells and follicular T helper (TFH) cells. The interaction of TFH and GC B cells is necessary for the development of high affinity antibodies specific for an invading pathogen. Germline BCL6-deficient mouse models limit our ability to study BCL6 function in T cells due to the strong inflammatory responses seen in these mice. To overcome this, our lab has developed a new BCL6 conditional knockout (cKO) mouse using the cre/lox system, wherein the zinc finger region of the BCL6 gene is flanked by loxP sites. Mating to a CD4-Cre mouse allowed us to study the effects of BCL6 loss specifically in T cells, without the confounding effects seen in germline knockout models. Using this cKO model, we have reaffirmed the necessity of BCL6 for TFH differentiation, including its role in sustained CXCR5 surface expression, a signature marker for TFH cells. This model also allowed us to recognize the role of BCL6 in promoting the expression of PD-1, another key surface marker for TFH cells. Without BCL6, CD4+ T cells cannot express PD-1 at the high levels seen on TFH cells. Our discovery of DNMT3b as a target for BCL6 suggests BCL6-deficient T cells have increased DNA methyltransferase activity at the PD-1 promoter. This data establishes a novel pathway for explaining how BCL6, a transcriptional repressor, can activate genes. Experiments with the BCL6 cKO model have also established a role for BCL6 in naïve CD4+ T cell activation. Furthermore, we did not observe increased differentiation of other helper T cell subsets, in contrast to what has been reported elsewhere with germline BCL6-deficient models. Unexpectedly, we found decreased T helper type 2 (Th2) cells, whereas mouse models with a germline mutation of BCL6 have increased Th2 cells. These results indicate that BCL6 activity in non-T cells is critical for controlling T cell differentiation. Finally, using an HIV-1 gp120 immunization model, we have, for the first time, shown BCL6-dependent GCs to be limiting for antibody development and affinity maturation in a prime-boost vaccine scheme.

T cells

follicular T helper cells

BCL6

germinal center

HIV vaccine

T cells -- Differentiation

Cell transformation -- Regulation

Repressors, Genetic -- Research

HIV (Viruses) -- Vaccination

AIDS vaccines -- Research

Inflammation -- Immunological aspects

B cells -- Research -- Analysis

Germinal centers

Immune system

Autoimmune diseases

Mice -- Diseases -- Molecular aspects

Animal models in research