Biochemistry Lecture Week 14 PDF

Summary

This document contains lecture notes on biochemistry, specifically focusing on digestive enzymes, processes, and the gastrointestinal tract. The notes cover the basics of digestion and provide an overview of digestive enzyme functions. It also includes information on essential digestion and different enzymes, such as salivary amylase, lingual lipase.

Full Transcript

Biochemistry
Lecture / Week 14 / Prof. Rogelda Bongat Leila Javier (2MT-N)

DIGESTIVE ENZYMES PRESENT IN THE SALIVA
ESSENTIALS OF DIGESTION Salivary Amylase
DIGESTION - primary enzyme in saliva; breaks down
Digestion carbohydrates into smaller molecules,
- the process of breaking down food by like sugars;
mechanical and enzymatic action in the - During this process, larger carbohydrates,
alimentary canal into substances that called amylopectin and amylose, are
can be absorbed and used by the body broken down into maltose
- starts with the mouth, where amylase - Maltose is a sugar composed of subunits
and lipase are present of glucose, the human body's key source
- from the mouth, it will be broken down of energy.
into smaller pieces going down to the o A disaccharide broken down in
esophagus to the stomach, enters the the smaller intestine into
duodenum, jejunum, and ileum of small monosaccharides
intestine, then cecum and goes up to Lingual Lipase
the ascending colon then transverse - breaks down triglycerides into glycerides
colon, descending colon, sigmoid colon, and fatty acid components, thus
rectum, and finally anus. catalyzing the digestion of lipids.
- Most of the digestion happens in the - can operate at lower pH values, action
small intestine continues into the stomach.
- helps infants digest the fats in their
mother's milk; the relative proportion of
lingual lipase in saliva decreases as we
grow older, as other parts of our
digestive system help with fat digestion
- Other lipases for lipids: gastric lipase
(exists in small amounts) and pancreatic
lipase (from pancreas)

THE GASTROINTESTINAL TRACT

1. Sublingual and submandibular salivary
glands
2. Esophagus
3. Stomach
4. Duodenum
5. Jejunum
6. Ileum
7. Cecum
- Mouth – for mechanical digestion of
8. Ascending Colon
food
9. Transverse Colon
- Liver – contributes to digestion by
10. Descending Colon
producing bile which is important for the
11. Sigmoid Colon
emulsification of fats
12. Rectum
- Gallbladder – storage site of bile
13. Anus

1
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

o When we eat fatty foods, the - Stomach – no enzymatic digestion but
gallbladder will contract to mechanical breakdown occurs → mix
release bile CHO into more uniform mixture of CHYME
- Small Intestine: Chyme → pancreatic
OVERVIEW OF CARBOHYDRATE DIGESTION juice
1. Mouth: The enzyme salivary amylase - Dextrins + Pancreatic amylase → shorter
begins breaking down starch into shorter CHO chains
polysaccharides - Disaccharidases: Sucrase, Lactase, and
o Mechanical digestion of food Maltase
2. Stomach: Salivary amylase is inactivated o Sucrose + Sucrase → glucose +
and no further carbohydrate digestion fructose
occurs o Lactose + Lactase → galactose +
3. Small intestine: Majority of starch glucose
digestion and breakdown of o Maltose + Maltase → glucose +
disaccharides occur here. The enzyme glucose
pancreatic amylase breaks down starch - In the liver:
into monosaccharides, disaccharides, o Galactose converted to glucose
and oligosaccharides. o Fructose broken to smaller
4. The digestion of carbohydrates is carbon units
completed by the enzymes o Glucose stored as glycogen or
(disaccharidases) attached to the brush exported back to the blood
border of the intestinal villi. Here, the - Carbohydrate digestion begins in the
disaccharides are broken down into mouth and is most extensive in the small
monosaccharides. intestine.
5. Large intestine: Fiber and other - The resultant monosaccharides are
indigestible carbohydrates are partially absorbed into the bloodstream and
broken down by bacteria to form short transported to the liver.
chain fatty acids and gas. The remaining
fiber is excreted in the feces.

PROTEIN DIGESTION
1. Whole proteins are chewed and
swallowed into the stomach
- Large intestine – site for the indigestible 2. Hydrochloric acid denatures proteins,
(usually broken down by bacteria); not unfolding their 3-D structure to reveal the
much absorption happening polypeptide chain
- Stomach – mechanical digestion also o Stomach pH = 1.5-3.5, highest is 4
occurs → peristalsis 3. Enzymatic digestion by pepsin forms
- Chyme – fluid digested food → will be shorter polypeptides
converted to pancreatic juice o The 3D structure will be converted
into polypeptide chains which will
Carbohydrate Digestion and Absorption
be further digested by pepsin
- Amylose and amylopectin + Salivary
(inactive form: pepsinogen) in the
amylase → Dextrin + maltose
stomach
o Occurs in the stomach

2
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

4. In the small intestine, trypsin, 1. Glucose
chymotrypsin, and proteases continue 2. Fats
enzymatic digestion, forming tripeptides, 3. Proteins
dipeptides, and amino acids - If there is not enough glucose or energy
5. In enterocytes, tripeptides and available:
dipeptides are further broken down into o Amino acids are rearranged into
amino acids, which are absorbed into glucose for fuel of brain and red
the blood blood cells
o To enter the enterocytes, they ▪ Brain and red blood cells
need active transport system ONLY use glucose as a
(needs energy) source of energy
o Absorbable form of protein → ▪ Low glucose levels →
amino acids hypoglycemia
o Absorbable form of o Metabolized as fuel, for an
carbohydrates → immediate source of ATP
monosaccharides
LIPID DIGESTION AND ABSORPTION
- In the mouth: mechanical digestion,
mixing with saliva, limited enzymatic
digestion (lingual lipase)
1. A small amount of lipid digestion occurs
in the stomach due to the gastric lipase
produced in the stomach
o Gastric lipase only exists in small
amounts
2. Bile is produced in the liver, stored in the
gallbladder, and released into the small
intestine to aid in the digestion and
- from the blood, the amino acids are absorption of lipids
transported to the liver → become part o The bile will emulsify the fat to
of the amino acid pool form micelles
- If the body has enough glucose and 3. The enzyme pancreatic lipase is
other source of energy, amino acids will produced by the pancreas and released
be used for the following: into the small intestine to break down
o Protein synthesis in cells triglycerides into monoglycerides, fatty
o Produce nonessential amino acids, and glycerol
acids for protein synthesis 4. In the small intestine, the products from
o Synthesis of other nitrogen- fat digestion and bile acids form a
containing compounds micelle, which moves toward the
o Rearranged and stored as fat microvilli to allow the lipids to diffuse into
▪ If you have excess the mucosal cells
proteins, it will be 5. Inside the mucosal cells, the fatty acids
converted into fats and monoglycerides are resembled into
▪ It cannot be stored as triglycerides and incorporated into lipid
proteins/amino acids transport particles called chylomicrons,
▪ If you need energy, it will which enter the lymph vessel
undergo gluconeogenesis 6. The small intestine is very efficient in
Gluconeogenesis absorbing fat so very little is normally
– producing excreted in the feces.
glucose from non-
carbohydrate
sources such as
proteins and fats
▪ Order of energy sources:

3
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

- Once inside the intestinal cell, short- and
medium-chain fatty acids and glycerol
Lipid Digestion and Absorption in the Small can be directly absorbed into the blood
Intestine stream
1. Emulsification by bile - Long chain fatty acids and
o Large fat droplet + bile → monoglycerides reassemble into
emulsified fat droplet triglycerides within the intestinal cell, and
2. Enzymatic digestion by pancreatic lipase along with cholesterol and fat-soluble
o Triglyceride –(lipase)→ vitamins are incorporated into transport
monoglycerides + fatty acids vehicles called chylomicrons
3. Absorption of products of fat digestion - Chylomicrons are large structures with a
depends on the size core of triglycerides and cholesterol and
o Short and medium-chain fatty an outer membrane made up of
acids and glycerol (small phospholipids interspersed with proteins
products) → absorbed into blood (apolipoproteins) and cholesterol
via capillary - The outer membrane makes them water
o Long-chain fatty acids and soluble so that they can travel in the
monoglycerides (large products) aqueous environment of the body
→ form into triglycerides and are - Chylomicrons from the small intestines
transported in chylomicrons into travel first into the lymph vessels which
lymph vessels then deliver them to the blood stream
- Fatty acids and monoglycerides via the jugular vein
(resulting from fat digestion) leave
micelles and enter epithelial cell STOMACH
- Fatty acids link to form triglycerides - The stomach consists of 3 major zones:
- Fatty globules combine with proteins to o Cardiac zone
form chylomicrons (inside Golgi o Body
apparatus) o Pyloric zone
- Chylomicrons are extruded from the ▪ Antrum
epithelial cell and enter a lacteal (lymph ▪ Pyloric canal & sphincter
capillary) - End product is chyme
- Lymph in the lacteal transports
chylomicrons away from intestine

4
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

Specialized Cells in the Stomach and their o Gastric inhibitory polypeptide
Secretion (GIP)
Specialized Secretion Function ▪ Inhibits production of HCl
cells
of parietal cells
Protects the
Columnar stomach from
o Secretin
cells/foveolar Mucus digestive juice and ▪ Stimulates the release of
cells (in the provides slippery the sodium bicarbonate
lining surface that helps to neutralize the acid in
epithelia) food move the small intestine
through the
stomach
o Vasoactive intestinal polypeptide
HCl Helps breakdown (VIP)
food; kills bacteria ▪ Inhibits acid secretion
and other o pH 1.5 or less
Parietal cells microorganisms ▪ negative feedback →
inhibit parietal cells to
IF (intrinsic
Promotes
factor) absorption of Vit. release HCl
B12 in the ileum
Chief cells Pepsinogen Converts to pepsin SMALL INTESTINE
with HCl; digest - The small intestine is of 3 parts
protein
Neuroendocrine Cells
G-cells Gastrin Stimulates ECL to
release histamine
ECL-like cells Histamine Increase HCl
(Enterochro- secretion (by
maffin-like parietal cells)
cells)
D-cells (Delta Somatostatin Inhibit gastrin and
cells) production of HCl
EC-cells Regulate GIT
(Enterochro- Serotonin motility and fluid
maffin cells) secretion
Hunger hormone;
P/D1 cells Ghrelin increases appetite
Duodenum
and promote fat
storage - Shortest region (10 in.)
- final chemical digestion (pancreatic and
brush border enzymes are emptied here)
What stimulates stomach secretions? - Absorption of iron and folate
- Gastric secretions occur in response to
various stimuli: Jejunum
o Neurogenic stimuli - 3 ft. long
▪ Stimulates vagus nerve to - Major site of nutrient absorption: CHO
release HCl (carbohydrates), CHON (proteins), fats,
o Distension of the stomach minerals and vitamins.
▪ Also stimulates vagus - Circular folds → villi → microvilli →
nerve to release HCl capillaries/ lacteals
o Contact with secretagogues Ileum
▪ Secretagogues stimulates - 6 ft. long and joins the large intestine
the secretion of other - Absorbs bile acids, fluid, and vit. B-12
substances
o Gastrin SMALL INTESTINE: Digestion of Carbohydrates
▪ Stimulates the release of - Pancreatic AMS
Histamine - Brush-Border Enzymes
o 𝛼-dextrinase
Regulation of Gastric secretions: ▪ Digests dextrins
- Reduces gastric acid secretion: o Sucrase
o Maltase
5
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

o Lactase Cuts at the
▪ Lactose Intolerance: ↓↓ carboxyl terminal
lactase ▪ Aminopeptidase
Diarrheic stool Cuts at the amino
Bloating terminal
Metabolic acidosis - Brush border enzymes:
▪ Lactose Intolerance – o Aminopeptidase
cannot digest lactose o Dipeptidase
because of absence or
SMALL INTESTINE: Digestion of Lipids
reduced lactase
▪ There are special
preparation of milk that
do not contain lactose
▪ Acquired lactose
deficiency → temporary
▪ Genetic lactose - Triacylglycerol (TAG) and
deficiency → permanent polyacylglycerol (PAG) converted by
lipases to fatty acids and
monoacylglycerol, which will be
absorbed and go to the lacteals
- Enzymes that spilt up TAG and
Phospholipids are lipases
o Lingual lipase
o Gastric lipase
o Pancreatic lipase
- Fat emulsification (bile)
o no bile no digestion
- Absorbed in lacteals

SMALL INTESTINE: Digestion of Nucleic Acids
- Nucleic acids are consumed in large
quantities as nucleoproteins due to their
- Lactose Intolerant: lactose → bacterial presence in all cells
fermentation → acid and gas - Nucleoproteins = conjugated proteins
o Irritation is caused and results to: with amino acids + nucleic acids
▪ Flatulence (prosthetic part)
▪ Acidemia - Not utilized by the body but digested,
▪ Diarrhea catabolized and excreted
- Enzymes used:
SMALL INTESTINE: Digestion of Proteins
- Protein digestion starts in the stomach o Ribonucleases
o Deoxyribonucleases
o Phosphatases (for phosphate
bonds)

- Pancreatic Enzymes:
o Endopeptidases: they lyse the
bonds between peptides within
the chains
▪ Trypsin
▪ Chymotrypsin
▪ Elastase
o Exopeptidases: cuts at the
terminal ends
▪ Carboxypeptidase
6
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

- Nucleoprotein: proteolytic enzymes of o Production of pancreatic juice
gastric and pancreatic juice → will o Stimulus: acidic gastric contents
remove amino acids and produce o Inhibits Gastrin secretion
nucleic acid - Cholecystokinin
- Nucleic Acid: RNAse and DNAse of o Enteroendocrine cells
pancreatic and intestinal juice → o Stimuli: amino acids and fatty
produces nucleotide acids
- Nucleotide: Nucleotidase (intestinal o Gallbladder contraction to
phosphatase) → hydrolyzed and will release bile, Release of
produce phosphate + nucleoside pancreatic enzymes (acini)
- Nucleoside: Tissue nucleosidase →
absorbed and taken to liver, kidney, METABOLISM (PART I)
spleen, bone marrow → free purine or Metabolism
pyrimidine + ribose or deoxyribose - Biochemical processes by which all living
- Purine is metabolized to form Uric Acid organisms sustain life
- The sum of all chemical reactions that
LARGE INTESTINE occur in the body
- 5 ft. long, distal ileum to anus - Require the use of enzymes and
- Cecum, colon, sigmoid, rectum and anal coenzymes
canal
- Storage of: METABOLISM BASICS
o Undigested food particles will be Metabolism
acted upon by bacteria: - The sum of all chemical reactions that
▪ CHO → gases occur in the body
▪ CHON → amino acids → - Require the use of enzymes and
indole, skatole, H2S coenzymes
(cause of foul odor of
General Classification of chemical reactions
stool)
- Anabolic:
▪ Bilirubin → stercobilin
o Those that create larger
- Reabsorption of:
molecules via biosynthesis or
o Water absorption: 1L (200mL)
reduction
o Sodium, chloride and some
o Ex. glycogenesis
vitamins (K, B6, B12)
o All processes with -genesis are
PANCREAS anabolic processes
o Reduction reactions – gain of H⁻
- Digestive accessory gland
- 99% exocrine; glandular cells ions
- Pancreatic juices - Catabolic:
o Water, salts, sodium bicarbonate, o Those that breakdown larger
and enzymes molecules into smaller molecules;
o Sodium bicarbonate biomolecules are being
▪ Buffers acidic gastric juice degraded or oxidized
▪ Stops the action of pepsin o Ex. glycogenolysis
▪ Optimum pH for o All processes with -lysis are
pancreatic and brush catabolic processes
border enzymes o Oxidation reactions – loss of H⁻
- 1% endocrine: Islets of Langerhans cells ions
o Insulin (beta cells)
o Glucagon (alpha cells)
o gastrin in pancreatic cell tumors
o somatostatin (delta cells)

Regulation of Pancreatic Secretions
- Secretin
o Enteroendocrine cells
7
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

- Anabolic: Small molecules are - These bonds can then be broken to yield
assembled into large ones. energy, thus driving the metabolic
o Energy is required processes of life.
- Catabolic: Large molecules are broken - Hydride ions can be transferred from one
down into small ones. intermediate to another resulting in a net
o Energy is released oxidation or reduction of the
intermediate.
Anabolic or Catabolic?
- Oxidation corresponds to a loss of
- Anabolic:
hydride and reduction to the gaining of
o Photosynthesis
hydride
o Glycogenesis
- Certain reduced forms of high energy
o Translation processes
molecules such as NADH and [FADH₂]
o DNA replication (anabolic since
can donate their electrons to the
you are making copies)
electron carriers of the electron transport
o Amino acids to protein
chain (ETC) which results in the
- Catabolic:
production of ATP (only under aerobic
o Glycogenolysis
conditions).
o Glycolysis
o Protein to amino acids ATP (Adenosine Triphosphate)
- comprises high energy bonds located
Anabolic Processes Catabolic Processes between each phosphate group.
Gluconeogenesis Glycolysis
- These bonds are known as phosphoric
Pentose Phosphate Beta Oxidation
anhydride bonds.
Pathway
- Is a nucleotide consisting of an adenine
Fatty acid and Kreb’s Cycle
base attached to a ribose sugar, which is
Isoprenol/Sterol
Synthesis attached to three phosphate groups
Electron Transport
Mechanism
Fermentation

Anabolism
- Building up
- Energy-consuming (endergonic)
- Assembles more complex molecules
from simpler ones

Catabolism
- Breaking down
- Energy-producing (exergonic) - ATP hydrolysis:
- To produce simple molecules for o Hydrolysis of the terminal
synthesizing others phosphate group by ATPase
releases of 30.5 𝑘𝐽/𝑚𝑜𝑙−1 of free
IMPORTANT HIGH ENERGY MOLECULES IN energy
METABOLISM o H₂O (from the water added)
- The complex processes of metabolism becomes H⁺ and OH
wouldn't be possible without the o Products are inorganic
assistance of certain high-energy phosphate (won’t be doubly
molecules. protonated at neutral pH) and
- The main purpose of these molecules is Adenosine Diphosphate (ADP)
to transfer either inorganic phosphate
groups (Pi) or hydride (H-) ions.
- The inorganic phosphate groups are
used to make high energy bonds with
many of the intermediates of
metabolism.
8
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

o NADH → received H → reduced
(anabolism)

Dehydration-Hydrolysis
- Uses hydrolase class of enzymes
- Removing water to create larger
molecules (Dehydration)
- Adding water to split larger molecules
into smaller molecules (Hydrolysis)
- Anabolic metabolism is generally a
dehydration reaction
- The chemical reactions in metabolic
- Catabolic metabolism is generally a
pathways don’t take place
hydrolysis reaction
automatically, without guidance.
-
- Instead, each reaction step in a
pathway is facilitated, or catalyzed, by a
protein called an enzyme.

SPECIAL TYPES OF METABOLIC REACTIONS
Oxidation-Reduction
- A coupled reaction in which electrons
are transferred from one molecule to
another - In the hydrolysis of carbohydrates, water
- This is a MAJOR player in the ATP molecules are used to lyse (break)
production pathway glycosidic bonds.
- Mediated by oxidoreductase class of
enzymes Addition-Subtraction-Exchange
- Anabolic metabolism is generally a - Transferases – mediate exchanges
reduction reaction - Lyases – mediate addition/removal
- Catabolic metabolism is generally an - The addition, removal or exchange of
oxidation reaction chemical groups between molecules
- Oxidation: - Carboxylation – Decarboxylation:
o Transfers electrons from a o Carboxylation – add carboxyl
molecule to oxygen (removes e⁻) group → anabolic
o Removes H+ o Decarboxylation – remove
o A catabolic pathway carboxyl group → catabolic
- Reduction: - Phosphorylation – dephosphorylation:
o The gain of electrons from a o Phosphorylation – add phosphate
molecule → anabolic
o An anabolic pathway o Dephosphorylation – remove
- Example: Glyceraldehyde 3-phosphate is phosphate → catabolic
oxidized (and phosphorylated) to 1,3-
Bisphosphoglycerate

o Glucose + PO₄ → Glucose 6-
phosphate
▪ Hexokinase →
phosphorylation
o Glyceraldehyde 3-phosphate → ▪ Anabolic process
donated H → oxidized o Glucose 6-phosphate → Glucose
(catabolism) + PO₄

9
| Biochemistry | Lecture | Week 14 | Leila Javier (2MT-N)

▪ Glucose 6-phosphatase →
dephosphorylation
▪ Catabolic process

Ligation Reactions
- Molecular groups are joined using
energy
- Uses ligase class of enzymes
- Ex. Formation of acetyl CoA, succinyl
CoA

-----------------------------------END----------------------------

Based on ppt and discussion notes

Italicized = Discussion notes

10