PKC signaling contributes to chromatin decondensation and is required for competence to respond to IL-2 during T cell activation.

The clonal proliferation of antigen-specific T cells during an immune response critically depends on the differential response to growth factors, such as IL-2. While activated T cells proliferate robustly in response to IL-2 stimulation, naïve (quiescent) T cells are able to ignore the potent effects of growth factors because they possess chromatin that is tightly condensed such that transcription factors, such as STAT5, cannot access DNA. Activation via the T cell receptor (TCR) induces a rapid decondensation of chromatin, permitting STAT5-DNA engagement and ultimately promoting proliferation of only antigen-specific T cells. Previous work demonstrated that the mobilization of intracellular calcium following TCR stimulation is a key event in the decondensation of chromatin. Here we examine PKC-dependent signaling mechanisms to determine their role in activation-induced chromatin decondensation and the subsequent acquisition of competence to respond to IL-2 stimulation. We found that a calcium-dependent PKC contributes to activation-induced chromatin decondensation and that the p38 MAPK and NFκB pathways downstream of PKC each contribute to regulating the proper decondensation of chromatin. Importantly, we found that p44/42 MAPK activity is required for peripheral T cells to gain competence to properly respond to IL-2 stimulation. Our findings shed light on the mechanisms that control the clonal proliferation of antigen-specific peripheral T cells during an immune response.

The NICU Environment: Infusing Single-Family Room Benefits into the Open-Bay Setting.

Two distinct architectural designs are found in today's NICUs-the open-bay (OPBY) and the single-family room (SFR) designs. When neonatology was recognized as a medical subspecialty in the 1970s, the OPBY design was the only platform offered to neonates and families. The OPBY design facilitated communication between staff, collegiality, and interprofessional collaboration among members of the neonatal team. Over time, pitfalls to the design were recognized, including increased transmission of sound and light. As a result, the SFR design emerged offering a family-centered, customizable environment. Through recognition and adoption of best practices, the neurodevelopmental benefits to SFRs can be infused within the OPBY unit. This article aims to identify best practices to infuse the benefits of SFR design (such as low light, low sound, and less overstimulation) into the OPBY NICU to reduce negative stimulation and optimize developmental outcomes for vulnerable neonates.

Calcium mobilization is both required and sufficient for initiating chromatin decondensation during activation of peripheral T-cells.

Antigen engagement of the T-cell receptor (TCR) induces a rapid and dramatic decondensation of chromatin that is necessary for T-cell activation. This decondensation makes T-cells competent to respond to interleukin-2 providing a mechanism to ensure clonotypic proliferation during an immune response. Using murine T-cells, we investigated the mechanism by which TCR signaling can initiate chromatin decondensation, focusing on the role of calcium mobilization. During T-cell activation, calcium is first released from intracellular stores, followed by influx of extracellular calcium via store operated calcium entry. We show that mobilization of intracellular calcium is required for TCR-induced chromatin decondensation. However, the decondensation is not dependent on the activity of the downstream transcription factor NFAT. Furthermore, we show that the influx of extracellular calcium is dispensable for initiating chromatin decondensation. Finally, we show that mobilization of calcium from intracellular stores is sufficient to induce decondensation, independent of TCR engagement. Collectively, our data suggest that chromatin decondensation in peripheral T-cells is controlled by modulating intracellular calcium levels.