A bifurcated role for c-Maf in Th2 and Tfh2 cells during helminth infection.

Differences in transcriptomes, transcription factor usage, and function have identified T follicular helper 2 (Tfh2) cells and T helper 2 (Th2) cells as distinct clusters of differentiation 4+",(CD4) T-cell subsets in settings of type-2 inflammation. Although the transcriptional programs driving Th2 cell differentiation and cytokine production are well defined, dependence on these classical Th2 programs by Tfh2 cells is less clear. Using cytokine reporter mice in combination with transcription factor inference analysis, the b-Zip transcription factor c-Maf and its targets were identified as an important regulon in both Th2 and Tfh2 cells. Conditional deletion of c-Maf in T cells confirmed its importance in type-2 cytokine expression by Th2 and Tfh2 cells. However, while c-Maf was not required for Th2-driven helminth clearance or lung eosinophilia, it was required for Tfh2-driven Immunoglobulin E production and germinal center formation. This differential regulation of cell-mediated and humoral immunity by c-Maf was a result of redundant pathways in Th2 cells that were absent in Tfh2 cells, and c-Maf-specific mechanisms in Tfh2 cells that were absent in Th2 cells. Thus, despite shared expression by Tfh2 and Th2 cells, c-Maf serves as a unique regulator of Tfh2-driven humoral hallmarks during type-2 immunity.

Using Cytokine Reporter Mice to Visualize Type-2 Immunity In Vivo.

Type-2 cytokine production plays a critical role in the context of type 2 immunity and allergic inflammation. Interleukin-4 (IL-4) and IL-13 are key modulators of the cell-mediated and humoral immune hallmarks most commonly associated with type-2 immune responses. However, production of these cytokines by lymphocytes and their tissue localization has been difficult to detect in vivo. As such, the field has relied heavily on ex vivo restimulation and in vitro differentiation assays to understand type-2 cytokine biology. Although these studies have greatly informed our understanding of type-2 cytokine regulation, it is becoming increasingly clear that the data does not always provide a true accounting of the complexity of type-2 immune cell biology in vivo. Described below is a protocol used to detect IL-4-competent and protein-producing cells in the lung and lymph nodes of mice after infection with a helminth. Importantly, this protocol has also been used to successfully identify reporter expression and cell function in vivo using various other cytokine-reporter systems.

Live Imaging of IL-4-Expressing T Follicular Helper Cells in Explanted Lymph Nodes.

The generation of class-switched, high-affinity, antibody-producing B cells plays a critical role in the establishment of type 2 immunity to intestinal helminths as well as in the pathogenesis of allergy and asthma. The generation of these high-affinity, antibody-producing B cells occurs in germinal centers (GC) and relies on interactions with follicular dendritic cells (FDCs) and T follicular helper (Tfh) cells. One critical mediator produced by Tfh cells in GCs is interleukin-4 (IL-4). Tfh-derived IL-4 drives class switching to type 2 antibody isotypes IgE and IgG1 and is required for high-affinity IgG1 production. In vivo detection of IL-4-expressing Tfh cells is required to better understand the role of these cells during the GC response. Detection of IL-4-expressing cells has been greatly improved by the generation of the IL-44get reporter mice, which read out IL-4 expression as green fluorescent protein (GFP). Much has been learned from these mice with regard to type 2 immunity using flow cytometry and immunohistochemistry. However, these methods do not allow the study of cellular behavior and interactions in real time. In contrast, multi-photon microscopy allows for deep tissue imaging and tracking of multiple cell types in intact tissues over time. Here, we describe a protocol for in vivo detection of IL-4-expressing Tfh cells in an explanted popliteal lymph node by multi-photon microscopy. The dynamics of Tfh cell motility and their interactions with FDC networks in the GCs were analyzed.

Notch signaling represents an important checkpoint between follicular T-helper and canonical T-helper 2 cell fate.

Type-2 immunity is regulated by two distinct CD4+ T-cell subsets. T follicular helper (Tfh) cells are required for humoral hallmarks of type-2 inflammation. T-helper type-2 (Th2) cells orchestrate type-2 inflammation in peripheral tissues, such as the lung and intestine. Given the importance of Notch signaling in the establishment of other CD4+ T-helper cell subsets, we investigated whether canonical Notch activation could differentially impact Tfh and Th2 cell fate during the induction of type-2 immunity. These studies show that Tfh cell, but not Th2 cell, generation and function is reliant on Notch signaling. While early Tfh cell specification is influenced by functional Notch ligands on classical dendritic cells, functional Notch ligands on cells other than dendritic cells, T cells, B cells, and follicular dendritic cells are sufficient to achieve full Tfh cell commitment. These findings identify Notch signaling as an early lineage-determining factor between Tfh and Th2 cell fate.

Differentiation between sediment and hypolimnion methanogen communities in humic lakes.

The traditional view of carbon cycling within the pelagic zone of freshwater lakes has consisted of methane production within the anoxic sediment, followed by diffusive flux and ebullition through the water column. Methanogenic archaea have been shown to be present within the water columns of freshwater lakes; however, little is known about whether these methanogenic communities are distinct from those in the sediment or how these communities change over space and time. We used the methanogen-specific phylogenetic marker mcrA to perform a 3-year study focusing on the community structure of methanogens within the sediment and anoxic hypolimnion water layer of five humic lakes in WI, USA. The hypolimnion and sediment communities were distinct in composition, richness and phylogenetic diversity. Hypolimnion communities displayed a temporally stable biogeographical pattern among lakes, which was driven by both lake-specific environmental variables and barriers to dispersal. We conclude that the hypolimnion comprised communities of methanogens that are distinct from those in the sediment, differentiated among lakes, and likely have unique ecological roles and evolutionary trajectories in these anaerobic environments.