An altered REDOX environment, assisted by over-expression of fetal hemoglobins, protects from inflammatory colitis and reduces inflammatory cytokine expression.

C5BL/6 female mice receiving dextran sodium sulfate in their drinking water develop an acute inflammatory colitis within 7d, with weight loss, histopathologic signs of inflammation, and colonic expression of inflammatory cytokines. In previous studies we have reported that increased inflammatory cytokine expression in aged mice can be attenuated by oral gavage of a crude fetal extract containing glutathione (GSH), MPLA and fetal hemoglobin, or more specifically by injection of a combination of these purified reagents. We speculated that this combination led to an altered tissue redox environment in which the immune response developed, thus regulating inflammation. Accordingly, we used wild-type (WT) C57BL/6 mice, or mice lacking either murine beta Hemoglobin major (Hgbβ <sub>ma</sub> KO) or minor (Hgbβ <sub>mi</sub> KO) as recipients of DSS in their drinking water, and followed development of colitis both clinically and by inflammatory cytokine production, before/after oral treatment of mice with a crude fetal liver extract. Mice lacking an intact fetal hemoglobin chain (Hgbβ <sub>mi</sub> KO) developed severe colitis, with enhanced colonic expression of inflammatory cytokines, which could not be rescued by extract, unlike WT and Hgbβ <sub>ma</sub> KO animals. Moreover, disease in both WT and Hgbβ <sub>ma</sub> KO animals could also be attenuated by exposure to 5-hydroxymethyl furfural (5HMF), hydroxyurea or rapamycin. The former has been used as an alternative means of stabilizing the conformation of adult hemoglobin in a manner which mimicks the oxygen-affinity of fetal hemoglobin, while we show that both hydroxyurea and rapamycin augment expression of murine fetal hemoglobin chains. Our data suggests there may be a clinical value in exploring agents which alter local REDOX environments as an adjunctive treatment for colitis and attenuating inflammatory cytokine production

Regulation of fetal hemoglobin expression during hematopoietic stem cell development and its importance in bone metabolism and osteoporosis.

We have shown that an altered tissue redox environment in mice lacking either murine beta Hemoglobin major (Hgbβ <sub>ma</sub> KO) or minor (Hgbβ <sub>mi</sub> KO) regulates inflammation. The REDOX environment in marrow stem cell niches also control differentiation pathways. We investigated osteoclastogenesis (OC)/osteoblastogenesis (OB), in bone cultures derived from untreated or FSLE-treated WT, Hgbβ <sub>ma</sub> KO or Hgbβ <sub>mi</sub> KO mice. Marrow mesenchymal cells from 10d pre-cultures were incubated on an osteogenic matrix for 21d prior to analysis of inflammatory cytokine release into culture supernatants, and relative OC:OB using (TRAP:BSP, RANKL:OPG) mRNA expression ratios and TRAP or Von Kossa staining. Cells from WT and Hgbβ <sub>ma</sub> KO mice show decreased IL-1β,TNFα and IL-6 production and enhanced osteoblastogenesis with altered mRNA expression ratios and increased bone nodules (Von Kossa staining) in vitro after in vivo stimulation of mRNA expression of fetal Hgb genes (Hgbε and Hgbβ <sub>mi</sub> ) by a fetal liver extract (FSLE). Marrow from Hgbβ <sub>mi</sub> KO showed enhanced cytokine release and preferential enhanced osteoclastogenesis relative to similar cells from WT or Hgbβ <sub>ma</sub> KO mice, with no increased osteoblastogenesis after mouse treatment with FSLE. Pre-treatment of WT or Hgbβ <sub>ma</sub> KO, but not Hgbβ <sub>mi</sub> KO mice, with other molecules (rapamycin; hydroxyurea) which increase expression of fetal Hgb genes also augmented osteoblastogenesis and decreased cytokine production in cells differentiating in vitro. Infusion of rabbit anti- Hgbε or anti- Hgbβ <sub>mi</sub> , but not anti-Hgbα or anti- Hgbβ <sub>ma</sub> into WT mice from day 13 gestation for 3 weeks led to attenuated osteoblastogenesis in cultured cells. We conclude that increased fetal hemoglobin expression, or use of agents which improve fetal hemoglobin expression, increases osteoblast bone differentiation in association with decreased inflammatory cytokine release

Nectar and pollination drops: how different are they?

Background: Pollination drops and nectars (floral nectars) are secretions related to plant reproduction. The pollination drop is the landing site for the majority of gymnosperm pollen, whereas nectar of angiosperm flowers represents a common nutritional resource for a large variety of pollinators. Extrafloral nectars also are known from all vascular plants, although among the gymnosperms they are restricted to the Gnetales. Extrafloral nectars are not generally involved in reproduction but serve as ‘reward’ for ants defending plants against herbivores (indirect defence). Scope: Although very different in their task, nectars and pollination drops share some features, e.g. basic chemical composition and eventual consumption by animals. This has led some authors to call these secretions collectively nectar. Modern techniques that permit chemical analysis and protein characterization have very recently added important information about these sugary secretions that appear to be much more than a ‘reward’ for pollinating (floral nectar) and defending animals (extrafloral nectar) or a landing site for pollen ( pollination drop). Conclusions: Nectar and pollination drops contain sugars as the main components, but the total concentration and the relative proportions are different. They also contain amino acids, of which proline is frequently the most abundant. Proteomic studies have revealed the presence of common functional classes of proteins such as invertases and defence-related proteins in nectar (floral and extrafloral) and pollination drops. Invertases allow for dynamic rearrangement of sugar composition following secretion. Defence-related proteins provide protection from invasion by fungi and bacteria. Currently, only few species have been studied in any depth. The chemical composition of the pollination drop must be investigated in a larger number of species if eventual phylogenetic relationships are to be revealed. Much more information can be provided from further proteomic studies of both nectar and pollination drop that will contribute to the study of plant reproduction and evolution