SUMMARY Neuronal activity causes the rapid expression of immediate early genes that are crucial for experience-driven changes to synapses, learning, and memory. Here, using both molecular and genome-wide next-generation sequencing methods, we report that neuronal activity stimulation triggers the formation of DNA double strand breaks (DSBs) in the promoters of a subset of early-response genes, including Fos, Npas4, and Egr1. Generation of targeted DNA DSBs within Fos and Npas4 promoters is sufficient to induce their expression even in the absence of an external stimulus. Activity-dependent DSB formation is likely mediated by the type II topoisomerase, Topoisomerase IIβ (Topo IIβ), and knockdown of Topo IIβ attenuates both DSB formation and early-response gene expression following neuronal stimulation. Our results suggest that DSB formation is a physiological event that rapidly resolves topological constraints to early-response gene expression in neurons.
Summary Regulatory B cells (Bregs) have been shown to play a critical role in immune homeostasis and in autoimmunity models. We have recently demonstrated that combined anti-TIM-1 and anti-CD45RB antibody treatment results in tolerance to full MHC-mismatched islet allografts in mice by generating Bregs that are necessary for tolerance. Bregs are antigen-specific and are capable of transferring tolerance to untreated, transplanted animals. Here we demonstrate that adoptively transferred Bregs require the presence of Tregs to establish tolerance, and that adoptive transfer of Bregs increases the number of Tregs. Interaction with Bregs in vivo induces significantly more Foxp3 expression in CD4+CD25− T cells than with naive B cells. We also show that Bregs express the TGF-β associated latency-associated peptide (LAP) and that Breg-mediated graft prolongation post-adoptive transfer is abrogated by neutralization of TGF-β activity. Regulatory B cells, like regulatory T cells, demonstrate preferential expression of both CCR6 and CXCR3. Collectively, these findings suggest that in this model of antibody-induced transplantation tolerance, Bregs promote graft survival by promoting Treg development, possibly via TGF-β production.
Defining how arginine vasopressin (AVP) acts centrally to regulate homeostasis and behavior is problematic, as AVP is made in multiple nuclei in the hypothalamus (i.e., paraventricular [PVN], supraoptic [SON], and suprachiasmatic [SCN]) and extended amygdala (i.e., bed nucleus of the stria terminalis [BNST] and medial amygdala [MeA]), and these groups of neurons have extensive projections throughout the brain. To understand the function of AVP, it is essential to know the site of origin of various projections. In mice, we used gonadectomy to eliminate gonadal steroid hormone-dependent expression of AVP in the BNST and MeA and electrolytic lesions to eliminate the SCN, effectively eliminating those AVP-immunoreactive projections; we also quantified AVP-immunoreactive fiber density in gonadectomized and sham-operated male and female mice to examine sex differences in AVP innervation. Our results suggest that the BNST/MeA AVP system innervates regions containing major modulatory neurotransmitters (e.g., serotonin and dopamine) and thus may be involved in regulating behavioral state. Furthermore, this system may be biased toward the regulation of male behavior, given the numerous regions in which males have a denser AVP-immunoreactive innervation than females. AVP from the SCN is found in regions important for the regulation of hormone output and behavior. Innervation from the PVN and SON is found in brain regions that likely work in concert with the well-known peripheral AVP actions of controlling homeostasis and stress response; female-biased sex differences in this system may be related to the heightened stress response observed in females.
The role of B cells in transplant tolerance remains unclear. Although B cell depletion often prolongs graft survival, sometimes it results in more rapid rejection, suggesting that B cells may have regulatory activity. We previously demonstrated that tolerance induction by anti-CD45RB antibody requires recipient B cells. Here we show that anti-CD45RB in combination with anti-TIM-1 antibody has a synergistic effect, inducing tolerance in all recipients in a mouse islet allograft model. This effect depends on the presence of recipient B cells, requires B cell IL-10 activity, and is antigen-specific. These data suggest the existence of a regulatory B cell population that promotes tolerance via an IL-10-dependent pathway.
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