Regulation of Food Intake (Lopez)

Question 1

Where are neuronal centers located that control feeding/satiety?

Answer 1

hypothalamus:

• lateral nucleus (LH)
• ventromedial nucleus (VM)
• paraventricular nucleus (PV)
• dorsomedial nucleus (DM)
• arcuate nucleus (Arc)

Question 2

How is energy balance maintained within the body?

Answer 2

• crosstakl between neural and hormonal regulations
• hypothalamus receives many types of signals: neural signals from GI, chemical signals from nutrients in blood, signals from GI hormones, signals from adipose tissue, signals from cerebral cortex (sight, smell, taste)

Question 3

Where does most of the signaling integration take place regulating food intake/energy expenditure and what are the specific pathways?

Answer 3

arcuate nucleus

two pathways:

• part I: α-melanocortin (α-MSH) - α-MSH released by pro-opiomelanocortin (POMC) neurons, α-MSH binds to MCR-4 present in second-order neurons, anorexigenic pathway
• part II: neuropeptide Y (NPY) - hunger signals stim release of NPY, NPY binds to Y1R, agouti-related peptide (AGRP) also released (antagonist of MCR-4), orexigenic pathway
• both pathways antagonize each other: peptides that stim the α-MSH pathway inhibit the NPY system, AGRP is an antagonist of MCR-4
• some cases of obesity have been related to mutations in POMC and MCR-4 genes (pathway 1)

Question 4

genetic cause of obesity

• disease/disorder:
• sx: early-onset severe obesity, infertility (hypogonadotropic hypogonadism), hyperphagia, infections
• finding:

Answer 4

genetic cause of obesity

• disease/disorder: leptin or leptin receptor gene deficiency
• sx: early-onset severe obesity, infertility (hypogonadotropic hypogonadism), hyperphagia, infections
• finding: leptin

Question 5

genetic cause of obesity

• disease/disorder:
• sx: early-onset severe obesity, increased linear growth, hyperphagia, hyperinsulinemia, most common known genetic cause of obesity, homozygous worse than hetero
• finding:

Answer 5

genetic cause of obesity

• disease/disorder: melanocortin 4 receptor gene mutation
• sx: early-onset severe obesity, increased linear growth, hyperphagia, hyperinsulinemia, most common known genetic cause of obesity, homozygous worse than hetero
• finding: MC4R mutation

Question 6

genetic cause of obesity

• disease/disorder:
• sx: neonatal hypotonia, slow infant growth, small hands/feet, mental retardation, hypogonadism, hyperphagia leading to severe obesity, paradoxically elevated ghrelin
• finding:

Answer 6

genetic cause of obesity

• disease/disorder: Prader-Willi syndrome
• sx: neonatal hypotonia, slow infant growth, small hands/feet, mental retardation, hypogonadism, hyperphagia leading to severe obesity, paradoxically elevated ghrelin
• finding: partial deletion of chromosome 15 or loss of paternally expressed genes

Question 7

genetic cause of obesity

• disease/disorder:
• sx: obesity, red hair, adrenal insufficiency due to ACTH deficiency, hyperproinsulinemia, hyperphagia, pale skin, cholestatic jaundice
• finding:

Answer 7

genetic cause of obesity

• disease/disorder: proopimelanocortin (POMC) deficiency
• sx: obesity, red hair, adrenal insufficiency due to ACTH deficiency, hyperproinsulinemia, hyperphagia, pale skin, cholestatic jaundice
• finding: loss of function mutations of POMC gene

Question 8

How could the vagus nerve be used in feeding behavior therapies?

Answer 8

• several peptides that stim satiety/decrease feeding activate receptors on vagal afferents
• vagal > NTS > hypothalamus circuit prod responses related to feeding behavior/metabolism
• if vagal activity is blocked, the amnt of material in stomach no longer influences meal size

Question 9

What is the role of vagal > NTS > hypothalamus circuit in feeding behaviors?

Answer 9

• NTS: crucial in interpretation and relaying of peripheral signals
• vagal signaling to NTS is integrated w/ info received by hypothalamus to prod appropriate feeding behavior/metabolic responses
• hindbrain is able to regulate food intake in response to peripheral signals even in absence of higher centers’ input

Question 10

• hunger center within the hypothalamus
• neurons project throughout brain and release the orexigenic peptides melanin-concentrating hormone (MCH) or orexins A and B

Answer 10

lateral hypothalamic area (LHA)

Question 11

satiety center within the hypothalamus

Answer 11

ventromedial hypothalamic nucleus (VMN)

Question 12

nucleus within the hypothalamus that contains neurons that project to both cerebral cortex and areas of the brainstem

Answer 12

paraventricular nucleus (PVN)

Question 13

Hormones released for the ___ ______, ________, and _______ _______ regulate feeding behaviors.

Answer 13

Hormones released for the GI tract, pancreas, and adipose tissue regulate feeding behaviors.

Question 14

• secreted in the stomach by endocrine cells
• binds to growth hormone secretagogue receptors (GHSR)
• stimulates neurons that release NPY
• actions, increase appetite, gastric motility, gastric acid secretion, adipogenesis, decrease insulin secretion (although evidence for both inc/dec insulin)
• appears to initiate the feeding response

Answer 14

ghrelin

Question 15

• hormone that binds to receptors in POMC (stimulates) and NPY (inhibits) systems
• actions: decrease appetite, increase metabolism
• in patients w/ type DM, there is an increase in food intake a/w decrease in this hormone

Answer 15

insulin

Question 16

• hormone released by I cells in duodenum
• elicits satiety: acts on vagal > NTS > hypothalamus circuit to decrease ghrelin; and decreases gastric emptying by increasing gastric distention

Answer 16

CCK

Question 17

• hormone released by L cells of the ileum and colon following a meal
• binds to Y2R in the hypothalamus: inhibits NPY neurons, releases inhibition of POMC neurons

Answer 17

PYY

Question 18

• hormone secreted by cells in adipose tissue
• binds to receptors in POMC (stimulates) and NPY (inhibits) systems
• appetite-supressing hormone: decreases appetite and ghrelin release, increases metabolism
• in obese children w/ congenital deficiency of this hormone, subcu administration of recombinant hormone reduces fat mass, hyperinsulinemia, and hyperlipidemia
• obesity in adults is often a/w high hormone levels and failure to respond to exogenous hormone (hormone resistance)

Answer 18

leptin

Question 19

Hormone regulation summary:

Answer 19

Question 20

summary of the integration of signals regulating food intake and energy expenditure:

Answer 20

Question 21

What is the differences between adipose signaling vs gut signaling?

Answer 21

• adipose signals (leptin) are involved in long-term regulation of energy
• gut peptides (PYY from intestines, ghrelin from stomach) modulate food intake on a meal by meal basis

Question 22

• proglucagon derived peptide
• co-secreted w/ PYY from L cells in the intestine
• type of incretin (group of metabolic hormones that stimulate a decrease in blood glucose levels)
• levels rise after a meal and fall during fasting
• reduces food intake, suppresses glucagon secretion, delays gastric emptying

Answer 22

glucagon-like peptide (GLP-1)

Question 23

• proglucagon derived peptide
• released from L cells of intestine in response to ingested food and in proportion to caloric intake
• anorectic affect

Answer 23

oxyntomodulin

Question 24

• secreted from cells in pancreatic islets of Langerhands
• putatively, decreases food intake directly through Y4R in the brainstem and hypothalamus
• may also act via vagus nerve to prod anorectic effects

Answer 24

pancreatic peptide (PP)

Question 25

• secreted by α cells of pancreatic islets
• increases blood glucose levels and insulin secretion
• reduces food intake

Answer 25

glucagon

Question 26

• stored and released w/ insulin in response to food intake
• anorectic effects (inhibition of NPY release)

Answer 26

amylin

Question 27

• condition characterized by self-starvation and excessive weight loss
• patients become severely malnourished and significantly emaciated, leading to endocrinological and cardiological dysfunctions, and abnormalities within digestive, skeletal, and repro systems

Answer 27

anorexia nervosa

Question 28

What biological factors related to gut-brain axis support restricted eating in patients w/ anorexia?

Answer 28

• polymorphisms present in genes involved in eating attitudes, regulation of eating behavior, motivation, and reward mechanisms (e.g. AgRP)
• basal and pulsatile secretion of leptin is reduced in a/w reduction in fat mass
• ghrelin resistance appears to be a conducive factor to a restrictive diet
• elevated levels of PYY: might contribute to decreased nutrient intake and disordered eating psychopathology