Peripheral B cell maturation. I. Immature peripheral B cells in adults are heat-stable antigenhi and exhibit unique signaling characteristics.

Whether recently generated peripheral B cells in adults are functionally equivalent to immature B cells in the neonatal spleen is unknown. We have identified a splenic B cell subpopulation in adults whose phenotypic and in vitro characteristics closely resemble those of neonatal B cells. These cells are defined by the cell surface phenotype heat-stable Aghi (HSAhi), and make up 10 to 15% of the adult splenic B cell pool. HSAhi B cells in adults bear the immature phenotype B220lo sIgMhi, and are 50% sIgD+. Furthermore, after sublethal irradiation, the initial wave of newly generated splenic B cells in self-reconstituting adults express a similar phenotype. In keeping with previous data on neonatal B cells, HSAhi cells from either normal or self-reconstituting mice are refractory to stimulation with anti-IgM antibodies, yet proliferate upon LPS stimulation, and generate primary antibody responses if given appropriate T cell help. In contrast to neonatal cells, HSAhi adult B cells are refractory to stimulation with PMA plus ionomycin. Together, these data suggest that peripheral HSAhi B cells in adults correspond to recently generated B cells, whose signaling characteristics are distinct from previously described B cell subsets.     

Isoprene: New insights into the control of emission and mediation of stress tolerance by gene expression

Isoprene is a volatile compound produced in large amounts by some, but not all, plants by the enzyme isoprene synthase. Plants emit vast quantities of isoprene, with a net global output of 600 Tg per year, and typical emission rates from individual plants around 2% of net carbon assimilation. There is significant debate about whether global climate change resulting from increasing CO₂ in the atmosphere will increase or decrease global isoprene emission in the future. We show evidence supporting predictions of increased isoprene emission in the future, but the effects could vary depending on the environment under consideration. For many years, isoprene was believed to have immediate, physical effects on plants such as changing membrane properties or quenching reactive oxygen species. Although observations sometimes supported these hypotheses, the effects were not always observed, and the reasons for the variability were not apparent. Although there may be some physical effects, recent studies show that isoprene has significant effects on gene expression, the proteome, and the metabolome of both emitting and nonemitting species. Consistent results are seen across species and specific treatment protocols. This review summarizes recent findings on the role and control of isoprene emission from plants.