L39 Protien as Macronutrient

Question 1

Difference between essential, non essential and conditionally essential AA

Answer 1

Essential: Not synthesized by humans, MUST be consumed

Non essential AA: can be synthesized in sufficient quantities, to satisfy normal requirements assuming adequate source of nitrogen available

conditionally essential: cannot be syth at required rate under some circ

• glutamine met, accelerated during stress
• argenine exceeds rate of synthesis during infance due to high demand in growth
• DEF of AA precursor can lead to new cond essential

(PKU) phynylalanine must be kept low, but its a precursor to tyrosine: cond essential

Question 2

Protien quality considerations; complete vs incomplete and complimentary

Answer 2

Complete: all the essential AA in correct amounts
-typically 
animal: meat fish eggs (not gelatin)
Dairy: milk yogurt whey
plant: quinoa, buckwheat....

incompleteL one or more of the essentials

• nuts and seeds, legumes, grains, veg
• most plants
• SOY an exception
• cannot be SOLE source of prot

complimentary: paired to make complete:
grains; high methionine, low lysine
legumes: high in lysine, low in methionine

not EVERY meal this balanced…just throughout day

Question 3

Eval of Dietary protein PER, nitrogen balance

Answer 3

Protein efficiency ratio:
not used anymore, set for animals, VERY different
-weight of growing animals and protein source: 10% protein for 10 days

Nitrogen Balance:
-asses protein quality
-nitrogen into body, excreted as urea, ammonia and other. 
-can show dietary protein reqs
nitrogen intake-nitrogen loss

can be NEG nitrogen status or POS nitrogen status

Question 4

protein turnover

Answer 4

short lived: minutes to hours
N’ aspartate, N PEST proline glutamate seriene and threonine

longl ivedL n serine: half life of one day

structural protein months to years

Question 5

Amino Acid pool and nitrogen balance

Answer 5

AA pool stays in constant balance

sources: degradation of body protiens
- digestion of dietary protein
- synthesis of NEAA

Three depletion events

• sunthesis of body protein
• syn of nitrogen containing molecules
• conversion of AA to glucose, glycogen, FA, ketone…ec

Question 6

Two methods for protein degradation

Answer 6

Ubiquition: degradation of endogenous proteins and ATP dependent and in cytoplasm

1. covalent attachment of ub to protein , chain of polyuB
2. proteasome recognizes tag, unfolds and cuts into peptide fragments (ub recycled)`
3. fragsdegrated into AA pool
   - Where is the ATP??

lysosomal proteolysis system

• acidic organelles, single membrane NOT in RBC
• more than 50 enzymes,
• acid stable proteases
• mostly for EXTRA CELLULAR PROTEINS, endo cytosed then autophagy

Question 7

biological value for protein quality

Answer 7

USE NITROGEN

how much N is retained in teh body following a protien diet

-diet witout known amount of N is fed and uring and fecal collections are assesed

BV= nitrogen returned/absorbed x100
-inherent value in certain foods

BV100: all protiens absorbed

Question 8

PDCAAS

Answer 8

Protien Digestibility Corrected AA score

gold standard by WHO

uses N balance and essential AA requirement

complete protien has PDCAAS # greater than or equal to 1
peanuts : 0.52

Question 9

Leucine content

Answer 9

protien quality (studies show)
leucine rich protien sources much better at stimulating muscle growth.
-activation of mTOR pathway- increase muscle synthesis
-whey has more leucine than soy

Question 10

protein synthesis for athletes (and AA sup)

Answer 10

MAY benefit from increased protien intake
-normal RDA: 0.8 athlete 1.2-2.4

AA supplements as well

• leucine: stim protein synthesis via mTOR path
• BCAA: E source, prevent muscle fatigue
• Arg/citruline: increased NO for increased Blood flow
• glutamine, beta alanine, creatine

Question 11

Risk of increased protien diet

Answer 11

greater than 2 g/kg daily

• hydration- increased urinary output to expel nitrogen
• kidney disease: elderly or sick cannot handle increased phosphorous as a result
• bone health: protein diet leads to increased ca loss in urine
• fatty protien sources lead to increased CV risk
• lack of carbs/fiber/vitamins

Question 12

Digestion of protien

Answer 12

ingestion
digestion (gastric)
digestion (pancreatic)
digestion by si enzymes
absorbtion of AA and peptides
transport of AA into cells

Question 13

action of digestive enzymes in general: exo and endo peptidases

Answer 13

peptidases: hydrolyze peptide bonds
endo: middle/inside (smaller frags)
exo: cleaves only peptide bond that links the C or N term amino acid (one free AA and chain)

Question 14

protien digestion in stomach

Answer 14

HCl and pepsinogen

HCL

• stomach acid too dilute to hydrolyze protiens
• from parietal cells
• kills some bacteria
• denatures protiens to prep them for proteases

Pepsin

• acid stable
• ENDO peptidase
• secreted by cheif cells as pepsinogen (hcl activates)

Question 15

release and activation of Panc enzymes

Answer 15

Release controlled by CCK and Secretin
-zymogen activation-
enteropeptidase/kinase: enzyme synthesized and presend on luminal surface of intestinal mucosa BB
-makes trypsinogen into trypsin, then trypsin will continue to cleave other trypsinogen molecueles as well as activate chymotrypsin, elastase and carboxypeptidase

Question 16

Four main enzymes and all details

Answer 16

Trypsin (panc)

• serine endopeptidase (serine at its active site)
• cleaves pepetide chain at CARBOXY side of AA
• only at Lysine or Argenine (EXCEPT WHEN FOLLOED BY A PROLINE)

Chymotrypsin (panc)

• serine endopeptidase
• trypsin cleaves it into two fragments
• larger fragment cleaves inself into 2 parts
• all linked together to form active enzyme
• cleaves peptide amids bonds at CARBOXY side or large hydrophobic AA (Ty, Tryp, Phen)
• can do others too but slowly

Elsastase (panc)

• serine endopeptidase
• cleaves peptide amide bonds at CARBOXY side
• small hydrophobic AA (ala, gly, Ser)
• has additional fxns in body (break down elastin)

Carboxypeptidase A&B
-proteases that hydrolize a peptide bond at the CARBOXY end C’ EXOPEPTIDASE
-either serine OR cystein proteaes
A-cleaves pep aminde bond at AMINE side of - ala, iso, leu, val
B-cleaves peptide amide bond at amine side of arg, lys

Question 17

peptide digestion and absorbtion in SI

Answer 17

enterocytes have aminoexopetidases (repeat cleave at amino end)

• Na+ transforters for Free AA on luminal surface
• several AA transporters exist
• also di and tri peptide transporters also Na linked
• more peptidases inside enterocyte

-cleaved to free AA, exit cell basally (on carriers) or some free, then to portal vein

Question 18

Celiac Disease

Answer 18

immune mediated intestical inflammation 1/120-300

• damage to microvilli of si
• unable to absorb nutrients
• due to respone to gluten (wheat, barley, rye)
• transglutaminase crosslinked gluten initiates immune response
• diarrhea, vomit, no nutrition
• irona nd folate deficiency lead to anemia

-G free diet

Question 19

Cysteinuria

Answer 19

most common genetic AA transporter disease

• defective transport of dibasic AA (Cystein Ornothine Argenine Lysine)
• transporter located on apical membrane of Si and renal proximal tubule
• excessive urinary secretion of cystein and dibasic amino acids
• cystein stones and kidney, ureter and bladder
• lots of fluids and plant based protiens proscribed (decreased cystein content)

Question 20

Hartnup Disease

Answer 20

autosomal recessive

defect in intestinal renal AA carrer for large neutral AA (trp, tyr, val, leu, ile)

• def in ESS especially tryp is noticed
• niacin (vit B fam) deficiency also occurs leading to dermatitis and diarrhea (pellagra like)
• tryptophan is a precursor to niacin and seritonin

must take niacin supplements and seritonin (CNS defects)

Bacterial fermentation of unabsorbed tryp makes indols with foul smelling stool

besign amino aciduria-kindey unable to reabsorb the fil Large AA

asymptomatic of high protein diet
-by di and tri AA absorbed and hydrolized within the enterocyes will yeild random assortment of AA including the large neutral AAs