hes1-protein--human and Hyperphagia

hes1-protein--human has been researched along with Hyperphagia* in 1 studies

Other Studies

1 other study(ies) available for hes1-protein--human and Hyperphagia

Article	Year
Developmental programming of appetite/satiety. Annals of nutrition & metabolism, 2014, Volume: 64 Suppl 1 Obesity is often attributed to a Western lifestyle, a high-fat diet and decreased activity. While these factors certainly contribute to adult obesity, compelling data from our laboratory and others indicate that this explanation is oversimplified. Recent studies strongly argue that maternal/fetal under- or overnutrition predisposes the offspring to become hyperphagic and increases the risk of later obesity. Both infants small for gestational age (SGA) or infants born to obese mothers who consume a high-fat diet are at a markedly increased risk of adult obesity. Specific alterations in the fetal metabolic/energy environment directly influence the development of appetite regulatory pathways. Specifically, SGA infants demonstrate (1) impaired satiety and anorexigenic cell signaling, (2) enhanced cellular orexigenic responses, (3) programmed dysfunction of neuroprogenitor cell proliferation/differentiation, and (4) increased expression of appetite (NPY) versus satiety (POMC) neurons. In both hypothalamic tissue and ex vivo culture, SGA newborns exhibit increased levels of the nutrient sensor SIRT1, signifying reduced energy, whereas maternal high-fat-exposed newborns exhibit reduced levels of pAMPK, signifying energy excess. Via downstream regulation of bHLH neuroproliferation (Hes1) and neurodifferentiation factors (Mash1, Ngn3), neurogenesis is biased toward orexigenic and away from anorexigenic neurons, resulting in excess appetite, reduced satiety and development of obesity. Despite the developmental programming of appetite neurogenesis, the potential for neuronal remodeling raises the opportunity for novel interventions. Topics: Animals; Appetite; Basic Helix-Loop-Helix Transcription Factors; Cell Proliferation; Diet, High-Fat; Disease Models, Animal; Female; Fetal Development; Gene Expression Regulation; Homeodomain Proteins; Humans; Hyperphagia; Hypothalamus; Infant; Infant, Newborn; Infant, Small for Gestational Age; Maternal Nutritional Physiological Phenomena; Nerve Tissue Proteins; Neurogenesis; Obesity; Overnutrition; Satiation; Sirtuin 1; Transcription Factor HES-1	2014

Article

Year

Developmental programming of appetite/satiety.

Annals of nutrition & metabolism, 2014, Volume: 64 Suppl 1

Obesity is often attributed to a Western lifestyle, a high-fat diet and decreased activity. While these factors certainly contribute to adult obesity, compelling data from our laboratory and others indicate that this explanation is oversimplified. Recent studies strongly argue that maternal/fetal under- or overnutrition predisposes the offspring to become hyperphagic and increases the risk of later obesity. Both infants small for gestational age (SGA) or infants born to obese mothers who consume a high-fat diet are at a markedly increased risk of adult obesity. Specific alterations in the fetal metabolic/energy environment directly influence the development of appetite regulatory pathways. Specifically, SGA infants demonstrate (1) impaired satiety and anorexigenic cell signaling, (2) enhanced cellular orexigenic responses, (3) programmed dysfunction of neuroprogenitor cell proliferation/differentiation, and (4) increased expression of appetite (NPY) versus satiety (POMC) neurons. In both hypothalamic tissue and ex vivo culture, SGA newborns exhibit increased levels of the nutrient sensor SIRT1, signifying reduced energy, whereas maternal high-fat-exposed newborns exhibit reduced levels of pAMPK, signifying energy excess. Via downstream regulation of bHLH neuroproliferation (Hes1) and neurodifferentiation factors (Mash1, Ngn3), neurogenesis is biased toward orexigenic and away from anorexigenic neurons, resulting in excess appetite, reduced satiety and development of obesity. Despite the developmental programming of appetite neurogenesis, the potential for neuronal remodeling raises the opportunity for novel interventions.

Topics: Animals; Appetite; Basic Helix-Loop-Helix Transcription Factors; Cell Proliferation; Diet, High-Fat; Disease Models, Animal; Female; Fetal Development; Gene Expression Regulation; Homeodomain Proteins; Humans; Hyperphagia; Hypothalamus; Infant; Infant, Newborn; Infant, Small for Gestational Age; Maternal Nutritional Physiological Phenomena; Nerve Tissue Proteins; Neurogenesis; Obesity; Overnutrition; Satiation; Sirtuin 1; Transcription Factor HES-1

2014