During fasting, hepatocytes produce glucose in response to hormonal signals. Glucagon and glucocorticoids are principal fasting hormones that cooperate in regulating glucose production via gluconeogenesis. However, how these hormone signals are integrated and interpreted to a biological output is unknown. Here, we use genome-wide profiling of gene expression, enhancer dynamics and transcription factor (TF) binding in primary mouse hepatocytes to uncover the mode of cooperation between glucagon and glucocorticoids. We found that compared to a single treatment with each hormone, a dual treatment directs hepatocytes to a pro-gluconeogenic gene program by synergistically inducing gluconeogenic genes. The cooperative mechanism driving synergistic gene expression is based on ‘assisted loading’ whereby a glucagon-activated TF (cAMP responsive element binding protein; CREB) leads to enhancer activation which facilitates binding of the glucocorticoid receptor (GR) upon glucocorticoid stimulation. Glucagon does not only activate single enhancers but also activates enhancer clusters, thereby assisting the loading of GR also across enhancer units within the cluster. In summary, we show that cells integrate extracellular signals by an enhancer-specific mechanism: one hormone-activated TF activates enhancers, thereby assisting the loading of a TF stimulated by a second hormone, leading to synergistic gene induction and a tailored transcriptional response to fasting.
In a comparison of sprinkle, furrow and trickle irrigation applied during the growing season from August to December to muskmelon (Cucumis melo L. cv. Haogen-2), vegetative growth was found more rapid and yields were earlier and higher with the trickle method. No yield differences were detected between sprinkle and furrow irrigation. Salt accumulation on the leaves was greater with sprinkling than with the other 2 methods which do not wet the foliage. The chloride concn in the leaves was also high throughout the entire growing season with sprinkle irrigation. Soil chloride content during the growing season varied according to the method of irrigation.
Pepper plants (Capsicum annuum L. cv. California Wonder) were irrigated by trickling at a constant frequency of 1-2 days with 4 different amounts of water based on evaporation from a Class A pan. The amounts applied were 0.82, 0.95, 1.33, and 1.75 of the pan evaporation. An optimum curve was obtained for the relation between yield and water application, with the maximum yield resulting from use of the 1.33 factor. Determinations of salt content in the soil and plants, and measurements of soil moisture showed that even the smallest water application was adequate to leach the root zone and to maintain a low and almost constant soil moisture tension. The optimum curve was found to be primarily due to a relatively small yield increase during the latter part of the harvest period when the potential evapotranspiration is increasing.
During fasting, hepatocytes produce glucose in response to hormonal signals. Glucagon and glucocorticoids are principal hormones secreted during fasting that cooperate in regulating glucose production via increasing hepatic gluconeogenesis. However, how these hormone signals are integrated in hepatocytes and translated to a biological output is unknown. We used genome-wide profiling of gene expression, enhancer dynamics and transcription factor binding in primary mouse hepatocytes to uncover the mode of cooperation between glucagon and corticosterone (the major glucocorticoid in mice). We found that compared to a single treatment with either hormone alone, a dual treatment initiates a pro-gluconeogenic gene program in hepatocytes by synergistically inducing gluconeogenic genes. We show that the mechanism driving synergistic gene expression is based on glucagon-mediated enhancer activation, leading to increased binding of the glucocorticoid receptor (GR) upon corticosterone stimulation. This was shown by glucagon-dependent increases in the active enhancer mark H3K27ac at GR binding sites (both signals were measured genome-wide via chromatin immunoprecipitation sequencing). Thus, glucagon-dependent enhancer activation, mediated by the glucagon-activated transcription factor CREB, assists GR loading to specific enhancers located near synergistic gluconeogenic genes. This 'assisted loading' mechanism is enhancer-specific as GR was able to efficiently bind other enhancers without assistance by CREB. Interestingly, we found that the glucagon-CREB axis does not only activate single enhancers but is also able to activate entire enhancer clusters. Indeed, CREB binding in one enhancer unit within a cluster, led to cluster-wide enhancer activation, thereby assisting the loading of GR in other enhancer units within the cluster that are unbound by CREB directly. These chromatin and gene expression changes collectively lead to synergistic glucose production from hepatocytes in the presence of glucagon and corticosterone. In summary, we show that hepatocytes integrate extracellular signals by an enhancer-specific mechanism: glucagon activates enhancers, thereby assisting the loading of GR upon stimulation by corticosterone. This chromatin-bound integration of endocrine signals leads to synergistic gene induction and a tailored response to fasting. Presentation: Saturday, June 11, 2022 12:00 p.m. - 12:15 p.m.
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