Biochemistry Flashcards

Question 1

Q

Carbonic Anhydrase

Answer

A

Catalyses CO2 + H2O H+ + HCO3-

Important for acid base balance
High in RBC

Question 2

Q

BPG

Answer

A

2,3-biphosphoglycerate
Binds cavity between β-subunits and stabilises deoxy-Hb (8+ve charges)
Converted from 1,3BPG by mutase (activity increases as pH becomes more alkaline)

Question 3

Q

Myasthenia Gravis

Answer

A

Anti-AChR prevents Ach binding to nicotinic receptors and activation of skeletal muscle

Question 4

Q

Phenylketonuria

Answer

A

Lack of Phenylalanine hydroxylase
Can’t break down Phenylalanine to Tyrosine, ends up being converted to Phenylpyruvate (a ketone)

Mental Retardation
Seizures/Tremors
Behavioural Disorders

Question 5

Q

Cystic Fibrosis

Answer

A

Build up of mucous in lungs & blockage of pancreatic duct

Elevated Immunoreactive Trypsin (IRT)
Delta F508 (Phe deletion in Cystic Fibrosis Transmembrane Conductance Regulator gene) - pore can no longer secrete chloride.

Question 6

Q

Ehlers Danlos Syndrome

Answer

A

Collagen mutant (fibrous proteins and enzymes)
Extra flexibility

Question 7

Q

Marfan Syndrome

Answer

A

Mutation / decreased production / delayed transport of fibrillin 1 into ECM

Question 8

Q

Sickle Cell Anaemia
Hiroshima
Hammersmith

Answer

A

beta 6 Glu -> Val - crystalline structure

beta 146 His -> Asp - disrupts salt bridge in deoxy state, and alters Bohr effect

beta 42 Phe -> Ser - attracts water into haem pocket

Question 9

Q

Porphyria

Answer

A

Haem feedback inhibition failure

Question 10

Q

Haem binding site

Answer

A

His F8

Oxy between Fe2+ and His E7

Question 11

Q

Osteogenesis Imperfecta

Answer

A

Glycine at position 748 in collage mutates to cysteine causing kink in strand and brittle bones.

Question 12

Q

Cholesterol Structure

Answer

A

ABCD rings
hydroxy group on 3rd position
hydrophobic section is planar

Question 13

Q

Cholesterol Synthesis

Answer

A

NADPH from malate -> pyruvate

AcetylCoA (2 carbons) ->
acetoacetylCoA (4 carbons) 
\+ acetylCoA ->
HMG CoA
\+ 2 NADPH (& HMG-CoA Reductase) ->
Mevalonic acid + CoA

6 x Mevalonic Acid ->
Squalene ->
Cholesterol & inhibition of HMG-CoA Reductase

Question 14

Q

Lipoproteins
ApoA-I
ApoB-100
ApoC-II

Answer

A

ApoA-I = HDL (activates LCAT enzyme allowing cholesterol scavenging)
ApoB-100 = VLDL, LDL (binds to LDL receptor)
ApoC-II = chylomicrons, VLDL, HDL (activates lipoprotein lipase, an enzyme outside of muscle and adipose tissue that uses fat as an energy source)

Question 15

Q

Familial Hypercholesterolemia (FH)

Answer

A

Inherited autosomal dominant
mutation of LDL receptor

Homozygous individuals develop waxy plaques (XANTHOMAS) beneath skin, over elbows, knees buttocks and cornea.

Normal cholesterol < 5.5mmol/L
FH > 15mmol/L

Treated with HMG-CoA reductase inhibitors (statins).

Question 16

Q

Celiacs

Answer

A

HLA DQ2 Allele

Tissue Transglutaminase 2 (tTg2) converts glutamine -> glutamate on Gliadin peptides that bind to HLA DQ2 peptide binding cleft

Question 17

Q

Calcium and smooth muscle contraction/relaxation

Answer

A

Increase contraction

Phospholipase C (activated by GPCR, activates IP3)
Inositol Triphosphate (IP3) (Ca2+ release from SR)
Rho Kinase (inhibit MLCP)
Protein Kinase C (inhibit MLCP)

Decrease contraction

Plasma Ca2+ ATPase
Sarcoplasmic Ca2+ ATPase (sequester Ca2+ in SR)
cAMP (increase Protein Kinase A)
Protein Kinase A (inhibit MLCK, activate MLCP)

Ca2+ & calmodulin phosporylates and activates Myosin Light Chain Kinase = contraction

Question 18

Q

Mediators of airway smooth muscle balance

Answer

A

CONTRACTION
ACh
Histamine
LTC
LTD

RELAXATION
PGE (cAMP)
PGI (cAMP)
Adrenaline (circulating adrenalin from adrenal glands)
b2 agonists (cAMP)

Question 19

Q

Proximal Tubule

Answer

A

LUMINAL
Na+, glucose, aa cotransporter (in) [passive]
Na+ / H+ (out) [passive]

BASAL
glucose, aa (out) [passive]
Na+ / K+ (in) ATPase [active]

Question 20

Q

Ascending Loop of Henle

Answer

A

LUMINAL
Na+, K+, 2Cl- cotransporter (in) [passive]

BASAL
Na+ / K+ (in) ATPase [active]

Question 21

Q

Familial Cold Urticaria

Answer

A

Patients develop systemic signs of ACUTE INFLAMMATION when exposed to COLD
- hive like blisters, fever, myalgia, fatigue, etc.

Due to Single Nucleotide mutations of cyopyrin (NLRP3) gene associated with Interleukin-1-converting enzyme

Question 22

Q

P450 reaction

Answer

A

RH + NADPH + H+ + O2
->
ROH + H2O + NADP+

Question 23

Q

P450

Answer

A

Oxidized all foreign chemicals with Mw < 5000

Located in ER & mitochondria

Hydrophobic foot anchors P450 into membrane

Transfers 1 electon at a time to O2 -> O22- ROS next to substrate

CYP2A6
2 - Family - share >40% protein sequence
A - Subfamily >55%
6 - Form

Question 24

Q

Ames Test

Answer

A

Histadine-requiring salmonella in His-selective agar (no his)
Drug added
Salmonella can mutate back to wild-type and grow if mutagens present
Drugs that fail the Ames test do not progress past Phase I

Question 25

Q

Bilirubin

Answer

A

open chain of tetrapyrrole ring
haem -(haem oxygenase)-> biliverdin -(biliverdin reductase) -> bilirubin

UDP-glucuronyltransferase conjugates bilirubin (twice) and makes it soluble

cMOAT/MRP2 actively pumps into canaliculi

urobilinogen (10% reabsorbed, 1% to kidneys)
stercobilin

Question 26

Q

Haptoglobin (Hp)

Answer

A

plasma protein, binds haemoglobin
high hemolysis decreases free haptoglobin levels
when Hp is depleted free Hb is excreted in urine

Question 27

Q

Hemopexin

Answer

A

carries haem (not Hb) to liver
higher affinity than albumin
low haemopexin is indicator of haemolytic anaemia

Question 28

Q

Alcohol content of 1 std drink

Answer

A

10g

Cleared in approx 1 hour

Question 29

Q

Alcohol key features

Answer

A

Ethanol - EtOH, C2H5OH
Low melting and boiling point
Almost identical energy amount as fat
Crosses BBB and makes nerve membranes leaky (impairs signal transmission)
Interferes with glutathione through membrane (unable to scavange free radicals from mitochondria)
Inhibits PDH -> reduced H20 retention by kidneys

30% absorbed stomach, 70% intestine
90% metabolised by liver, 2% kidneys, 8% stomach

Question 30

Q

Alcohol Oxidation

Answer

A

Ethanol -> Acetalaldehyde -> Acetate -> Acetyl-CoA (fat synthesis via TCA cycle)

Alcohol Dehydrogenase - produces NADH which represses gluconeogenesis (can lead to hypoglycaemia)

MEOS - induction of CYP 2E1.

CYP 2E1 consumes NADPH so less energy is produced
prevents drug clearance when alcohol is present
promotes drug clearance when alcohol is not present
produces lots of free radicals

Catalase - uses H2O2 as oxidant

Question 31

Q

GI Digestive Secretions

Answer

A

MOUTH:
Amylase

STOMACH:
Pepsinogen
HCL

SMALL INTESTINE:
HCO3-
Enteropeptidase
Disaccharidases
Peptidases
Phosphotases

LIVER:
Bile acids (detergents)

PANCREAS (EXOCRINE):
NaHCO3
NaCl
peptidases
amylase
prolipases

LARGE INTESTINE:
Mucous

Question 32

Q

Gallstones

Answer

A

Mostly cholesterol
Stained with bilirubin derivatives
Normal cholesterol crystalisation time is approx 20 days

Question 33

Q

Duodenal Gland secretion Mechanism

ACh & CCK
Secretin

Answer

A

ACh & CCK
G protein activates Phospholipase C
PLC increases intracellular Ca2+
Ca2+ stimulates secretion

Secretin
G protein activates Adenylate Cyclase
Adenylate Cyclase converts ATP to cAMP
cAMP stimulates secretion

Question 34

Q

Breakdown of sugars

Answer

A

Lactose -(Lactase)-> Galactose & Glucose (SLGT1)
Sucrose -(Sucrase)-> Fructose (GLUT5) & Glucose
Starch -(Amylase)-> Maltose -(glucosidases)> Glucose

Question 35

Q

Major Causes of Jaundice

Answer

A

PRE-HEPATIC
- Haemolysis

INTRA-HEPATIC

Drugs (rifampicin - interferes with bilirubin uptake)
Gilberts (UDP)
Crigler Najjar (UDP)
Hepatitis
Cirrhosis
Cancer
Dubin-Johnson (cMOAT)

POST-HEPATIC

Gallstones
Biliary stricture
Carcinoma of Pancreas
Cholangitis (inflamed bile duct)

Question 36

Q

Glucose-6-Phosphate Dehydrogenase (G6PD) deficiency

Answer

A

RBC depleted before 120 day life

Involved in production of GSH
GSH (reduced glutathione) protects cells from oxidative damage

Confers resistance to malaria
Chloroquine (antimalaria) contraindicated in G6PD
Chloroquine + haem produces ROS which would normally be removed by GSH. In G6PD it leads to RBC breakdown and heinz bodies (oxidized globin)

Question 37

Q

Galactosaemia

Answer

A

Difficiency of any one of 3 enzymes used to convert Galactose to Glucose-6-Phosphate

galactokinase
galactose-1-phosphate uridylyl transferase
UDP galactose-4-epimerase

Elevated AST, ALP, conjugated bilirubin
Cataract formation (due to elevated galactitol)
Hepatomegaly
Brain Damage
Jaundice

Treatment: Stop giving infant milk

Question 38

Q

Hepatocyte Enzyme Locations & Half Lives

Answer

A

ALP - Membrane (biliary canaliculi) (Bone, Liver, Placenta) (adds phosphate group to molecule)
GGT - Membrane (biliary canaliculi) (Liver, Renal) (glutathione production)
ALT/LD - Cytoplasmic (transport energy to muscle, greater in liver though)
AST - Cytoplasmic & Mitochondrial (liver & muscle)

Half Lives:
AST: 18hrs
ALT: 36hrs
GGT: 5-7 days

Question 39

Q

Liver Enzymes

Hepatocellular Damage

Answer

A

AST (mostly), LD, ALT

AST > ALT
- acute, affecting mitochondria: acute virus, EtOH

ALT > AST
- chronic, drugs, viral, metabolic

ALT = 50 = NORMAL
ALT = 250 = MILD
ALT = 1000 = MODERATE
ALT = 5000 = SEVERE
(with chronic infections ALT is usually mild/normal)

Hepatocellular death can lead to Bilary disease (obstruction)

Question 40

Q

Liver Enzymes

Biliary Disease

Answer

A

ALP, GGT
Extrahepatic biliary obstruction (intrahepatic may have slightly raised levels)
- colon/pancreatic cancer, cholestasis

Biliary Disease can lead to hepatocellular death

Question 41

Q

Liver Enzymes

Inducing Drugs

Answer

A

GGT, ALP
Antibiotics, Statins (rhabdomyopathy), EtOH, Paracetamol
GGT involved in glutathione production, important in removing ROS

Question 42

Q

Henderson-Hasselbalch for HCO3- and CO2

Answer

A

pH = pKa + log{[base] / [acid]}
= 6.1 + log ([HCO3-] / 0.03*pCO2}
= 6.1 + log (24mM / 1.2mM)
= 7.4

NB: Kidneys control HCO3-
Lungs control CO2

Question 43

Q

Gastric acid secretion (internal biochemistry)

Answer

A

H2O & CO2 diffuse into cell
Become H+ and HCO3-

HCO3- exchanged with Cl- on basolateral

H+/K+ exchange apical

K+ & Cl- diffusion out apical side

Question 44

Q

Gastric acid secretion (stimulation)

Answer

A

Gastrin causes ECLcells to release histamine

Histamine acts on H2
triggers converstion of ATP to CAMP
-> broken down to AMP by phosphodiesterase
-> acts on PKA and opens Cl- channels

ACh from vagus acts on M3
causes opening of Ca2+ channels
Ca2+ activates CAM which stimulates H+/K+ATPase

Question 45

Q

Alcohol Cytochrome

Question 46

Q

TRPV1

Answer

A

Noiceceptive transducer
Receptor for capsaicin

Capsaicin lowers heat threshold so that essentially the channel is always open (i.e. pain)

Question 47

Q

Unstable Repeat Expansions

Answer

A

repeating units of three or more nucleotides in tandem
expansion of DNA segment within specific gene above a THRESHOLD

ANTICIPATION:
# repeats increases -> age of onset decreases & severity increases

Testing: PCR, fragment analysis on capillary electrophoresis

Question 48

Q

Iodine & Thyroxine

Answer

A

Atomic number 53
Antiseptic (I2 oxidizes respiratory chain enzymes)
High abundance in sea (kelp), low on land
I-131 destroy thyroid gland
RDI 150ug
Goitrogens (soy, cabbage, broccoli) inhibit iodine uptake

Iodine deficient mothers give berth to CRETINS (mental retardation, deaf-mute)

Energy from TSH binding to TSHR (cAMP) causes uptake into Thyroid by NIS (Na+/I- symport), balanced by 3Na+/2K+ATPase
Oxidised to chemically reactive form by THYROPEROXIDASE (TPO)
reacts with tyrosines in THYROGLOBULIN protein
peptide links hydrolised and T3, T4 released
70-80% bound to Thyroid Binding Globulin (TBG)
T4 more abundant, T3 more potent
Deiodinase converts T4 to T3
bind DNA receptors & cause transcriptional activation (upregulate oxidative phosphorylation -> more ATP)

Question 49

Q

Steroid Elimination Cytochrome

Answer

A

CYP3A4
Most abundant CYP in entire body
Introduces -OH into steroid ring then other enzymes form bile acids

Question 50

Q

Where do steroids bind?

Answer

A

At Hormone Response Elements (HRE’s) in DNA

Sex steroids enter nucleus and activate DNA binding recepotrs that bind to HREs and cause gene transcription

Mineralocorticoids and glucocorticoids bind cytoplasmic receptors and displace heat shock proteins to expose active site

Question 51

Q

What is tested for in a pregnancy test

Answer

A

hCG

Human Chorionic Gonadotropin
Produced by trophoblast and placenta

Question 52

Q

Energy in ATP

Answer

A

5kj/mol

* Adenosine Triphosphate Phospate backbone stabilised by Mg2+ forming Mg-ATP as substrate

Question 53

Q

Energy in NADH

Answer

A

220kj/mol

Nicotinamide Adenine Dinucleotide (from vitamin B3)
Storage molecule for electrons from Glycolosis/Krebs to ETC

Question 54

Q

ATP production of Aerobic vs Anerobic Metabolism

Answer

A

Aerobic: 30-32ATP
Anaerobic: 2ATP

*106 ATP is generated from palmitate (fatty acid)

Question 55

Q

Glucose

structure
dangers

Answer

A

All D except 3! (OH point down)
Highly reactive adehyde, prone to glycation of amino acids and amino groups on proteins. Glycated blood vessels become brittle and prone to clots.
Esp if damage occurs faster than turnover (i.e. 3 days for vessels, 120days for RBCs)

Question 56

Q

Aldose vs Ketose sugars

Answer

A

ALDOSE:
Glucose & Galactose
Aldehydes O=CR-H

KETOSE:
Fructose
Ketones O=CR-R’

Question 57

Q

Cell Glucose Transporters

Answer

A

GLUT1 = universal
GLUT2 = liver and pancreas (respond to rising glucose)
GLUT4 = muscle and adipose (insulin responsive)
SGLT1 = Na+ cotransporter in intestinal epithelium and kidney tubules

Question 58

Q

Beta-oxidation

Answer

A

Fatty Acids -> Acetyl-CoA

If NADH is high TCA cycle is inhibited and Acetyl-CoA goes off to form ketone bodies for other cells (brain, muscle, heart, kidney). Carnitine helps transport acetyl-CoA in/out of mitochondria

Occurs in mitochondria

Question 59

Q

Glycolysis

Answer

A

Occurs in Cytosol
Produces ATP anaerobically

glucose + 2NAD+ + 2ADP + 2Pi -> 2pyruvate + 2NADH + 2ATP + 2H2O

PATHWAY:
Glucose
Glucose-6-phosphate
Fructose-6-phosphate
Fructose-1,6-bisphosphate
Glyceraldehyde 3-phosphate & Dihydroxyacetone phosphate
Glyceraldehyde 3-phosphate (2)
1,3-Bisphosphoglycerate (BPG) (2)
3-Phosphoglycerate (2)
2-Phosphoglycerate (2)
Phosphoenolpyruvate (PEP) (2)
Pyruvate (2)

Question 60

Q

Glycogenesis

Answer

A

Creation of glycogen

Question 61

Q

Glycogenolysis

Answer

A

Breakdown of glycogen

Question 62

Q

Gluconeogenesis

Answer

A

Generation of glucose from glycerol of amino acids, NOT fatty acids (they undergo beta-oxidation)

Carbon sources:
Lactate
Amino Acids
Glycerol (from TAGs) -

Question 63

Q

Anaerobic Glycolysis

Answer

A

Produces 2ATP
Occurs in cell cytosol
Produces Lactate

*Only pathway for RBCs, lens, retina, as they have no mitochondria

Question 64

Q

Normal Blood Glucose Levels

Fasting
Fed (100g glucose)

Answer

A

Fasting: 4-5mM
Fed: <10mM (the renal threshold)

Answer 64

A

Haemoglobin A1C
Diagnostic indicator of uncontrolled high glucose levels
β-subunits prone to glycation of N-termini
Normally 3-5% of Hb, rises to 15%+ in uncontrolled diabetes

Answer 65

A

Fasting reserve of glucose

Chemically intert, low osmotic profile

Answer 66

A

Catalyses Glucose -> Glucose 6-phosphate reaction in glycolysis
Transfers phosphate from ATP to glucosee

Answer 67

A

Catalyses Glucose 6-phosphate -> Fructose 6-phosphate reaction in glycolysis

Answer 68

A

Catalyses Fructose 6-phosphate -> Fructose 1,6-phosphate reaction in glycolysis
Only active when cells have low [ATP]
Irreversible in glycolysis

In gluconeogenesis fructose 1,6-bisphosphatase reverses this reaction

Answer 69

A

Enzyme in liver and kidney cells which allows them to form glucose (final stage of gluconeogenesis) and transport out of cell into the blood.

Answer 70

A

β1-4 linked disaccharide of galactose and glucose

inability to epimerise the galactose to glucose is the cause of galactosaemia

Answer 71

A

Backbone of TAGs
enters glycolisis (or exits) at GAP / DHAP stage
can also be created from fructose (via GAP / DHAP)

Answer 72

A

2-3 times sweeter than glucose and cheaper (so used in many foods)
Fails to increase leptin production by adipose cells
Fails to supress ghrelin
Fails to elect insulin release
Gets coverted to glycerol (backbone of TAGs), therefore more fat is created and stored (LDLs)

Answer 73

A

Pyruvate -> Acetyl-CoA -> TCA cycle
Acetyl-CoA -> Ketone bodies

Aging = loss of mitochondria
Electron leak from mitochondria -> ROS
Mitochondria come from mother

Disorders have characteristic Ragged Red Fibres (RRFs)

Answer 74

A

Produced from protein breakdown
100g excreted per day
Non-toxic
Highly soluble

Answer 75

A

Each turn produces:
3 molecules of NADH
1 molecule of FADH2
1 molecule of GTP or ATP

Answer 76

A

nDNA = II
mtDNA = I, III, IV, V

Answer 77

A

Transfers reducing power of NADH from cytosol to mitochondria for oxidative phosphorylation (ETC)

Answer 78

A

Rapid ENERGY DEPENDANT shuttle for transferring reducing power of NADH from cytosol to mitochondria for oxidative phosphorylation (ETC)

-> results in ATP production of 30

Answer 79

A

10MJ

All of which is radiated as heat regardless of work performed

Answer 80

A

Best sources: Diary, nuts, seaweed
Primary functions: bones/teeth, muscle contraction, nerve function, blood clotting, BP, tight junctions (bone)
Deficiency: rickets, poor clotting, OSTEOPOROSIS, stunted growth
Toxicity: constipation, malabsoprtion, impaired kidney function (stones), malignant hyperthermia

approx 1.2kg stored in bone
kidneys pass 1g per day

Calcitonin (from thyroid) lower blood [Ca2+] by depositing in bone (stimulate osteoblasts)
VitD and PTH increases [Ca2+] via kidney reabsorption, GI absorption, bone breakdown

Answer 81

A

Best sources: Meats, eggs, milk
Primary functions: Mineralisation of bone/teeth, cell integrity, phospholipids, DNA, ATP, acid-base buffers
Deficiency: weakness, bone pain, growth retardation
Toxicity: diarrhoea, calcification of non-skeletal tissue (particularly kidney)

1000mg/day

Answer 82

A

Best sources: Bananas, tomatoes, meat, milk, fruit, vegies, grains, legumes
Primary functions: fluid & electrolyte balance, nerves, muscles, cell integrity
Deficiency: irregular heartbeat, weakness, glucose intolerance
Toxicity: weakness, vomiting (if IV), cardiac arrest

2800-3800mg/day

Answer 83

A

Best sources: Proteins (methionine, cysteine)

Primary functions: Keratin in hair and nails

Answer 84

A

Best sources: Table salt, soy, milk, meat
Primary functions: fluid & electrolyte balance, nerves, muscles
Deficiency: cramps, apathy, loss of appetite
Toxicity: oedema, acute hypertension

460-920mg/day

Answer 85

A

Best sources: Table salt, soy, milk, meat
Primary functions: fluid & electrolyte balance, stomach acid & digestion
Deficiency: N/A
Toxicity: vomiting (NaCl is an emetic)

intake - N/A

Answer 86

A

Best sources: Nuts, legumes, grains, vegies
Primary functions: Bone mineralization, protein, enzymes, nerve impulse, immunity
Deficiency: weakness, immunity, convulsions, growth failure, hallucinations
Toxicity: diarrhoea, dehydration, alkalosis

310-400mg/day

Answer 87

A

Best sources: Meat, eggs, legumes
Primary functions: haemoglobin/myoglobin
Deficiency: Anaemia, fatigue, headache, impaired immunity, pallor, inability to regulate body temperature, pica (dirt)
Toxicity: Gi distress, infections, fatigue, joint pain, pigmentation, organ damage, haemochromatosis

8-18mg/day
Absorption increased by Vitamin C

Answer 88

A

Best sources: Protein-containing foods, oysters
Primary functions: Enzymes, insulin, proteins, vitA transport, wound healing, foetal development, spermatogenesis
Deficiency: Growth retardation, delayed sexual maturity, impaired immune system, hair loss, eye/skin lesions
Toxicity: loss of appetite, low HDL, copper and iron deficiency

8-14mg/day

Answer 89

A

Best sources: Seafood, nuts, grains, seeds
Primary functions: Iron absorption, electron transport chain
Deficiency: Anaemia, bone abnormality
Toxicity: liver damage, wilson’s disease, menke’s disease

1.2-1.7mg/day

Answer 90

A

Best sources: Nuts, grains, vegetables
Primary functions: enzyme cofactor, bone formation
Deficiency: Rare
Toxicity: nervous system disorders

5-5.5mg/day

Answer 91

A

Best sources: Seafood, iodised foods
Primary functions: T3/T4
Deficiency: goitre, cretanism
Toxicity: elevated TSH, goitre

150ug/day

Answer 92

A

Best sources: Seafood, meat, grains, fruit, vegies
Primary functions: defence against oxidisation, T3/T4
Deficiency: heart disease - fibrous cardiac tissue
Toxicity: hair and nail brittleness, skin rash, fatigue, irritability, CNS disorders, garlic breath

60-70ug/day

Answer 93

A

Best sources: Meats, whole grains, brewers yeast
Primary functions: enhance action of insulin
Deficiency: diabetes-like condition (impaired glucose tolerance)
Toxicity: N/A

25-35ug/day

Answer 94

A

Best sources: Legumes, cereals, nuts
Primary functions: enzyme cofactor
Deficiency: N/A
Toxicity: N/A - reproductive effect?

45ug/day

Answer 95

A

Best sources: Water, tea, seafood
Primary functions: bone/teeth
Deficiency: tooth decay
Toxicity: Fluorosis (pitting and discolouration of teeth)

3-4mg/day

Answer 96

A

We actually need vitamin B12 which contains cobalt

Answer 97

A

A, D, E, K

Answer 98

A

Coenzyme in decarboxylations (aerobic metabolism)
Carbohydrate, protein, and fat metabolism
Nerve function

Sources: vegemite, breads, cereals

Deficiency: beriberi, wernicke-korsakoff

Answer 99

A

Electron carrier (FMN, FAD)
Carbohydrate, protein, and fat metabolism

Sources: vegemite, dairy, cereals

Deficiency: magenta tongue

Answer 100

A

Coencyme
Electron carrier (NADH, NADPH)
Carbohydrate, protein, and fat metabolism

Sources: vegemite, wheat bran, cereals

Deficiency: Pellagra (dermatitis, diarrhoea, dementia, death)

Answer 101

A

Amino acid metabolism

Sources: vegemite, nuts, bananas, cereals

Deficiency: rare

Answer 102

A

Glucose, fat, amino acid biosynthesis

Sources: brewers yeast, eggyolk cooked, soy

Deficinecy: dry, shiny, scaly skin of hands

Answer 103

A

Amino acid, fat, purine (DNA) biosynthesis

Sources: green vegetables, fortified cereals

Deficiency: common in alcoholics & elderly
Concern for pregnant women
macrocytic anaemia, spina bifida
glossitis w/ papillae atrophy

Answer 104

A

Coenzyme containing cobalt
folate metabolism, transalkylations (nerves and blood)

Sources: meat, egg, dairy

Deficinecy: neurological disorders and anaemia

Intrinsic factor from parietal cells of stomach requried for B12 absorption in small intestine

Answer 105

A

Cofactor in collagen synthesis
Neurotransmitter metabolism
Iron absoroption
Antioxidant

Sources: citrus fruit, cabbage

Deficiency: scurvy

Answer 106

A

Derived from β carotine
Stored in liver
Retinal -> night vision
Retinol -> epithelium growth (skin/eyes)

Deficiency: Xeropthalmia (dry eye)

Answer 107

A

1,25-Dihydroxycholecalciferol
(liver adds OH at 25, kidney adds OH at 1)

Derived from cholesterol
Requires UV for synthesis (from 7-dehydrocholesterol)
Important in Ca2+ regulation and bone development

PTH, [Ca2+], [PO4] alter kidney enzymes for synthesis

Deficiency: rickets, osteomalacia, MS?
(PTH maintains [Ca2+] at expense of bones)

Answer 108

A

Antioxidant (in membranes, intercepts free radicals)

Signal molecule for inflammation & cell division

Answer 109

A

Important in blood clotting (factors II, VII, IX, X)

Gut flora make significant amounts of Vitamin K

Answer 110

A

weight (kg) / height squred (m2)

40 = morbidly obese

increased incidence of cancer, stroke, CVD, diabetes

Answer 111

A

Hererochromatin

light bands with giemsa stain
A+T rich
hypermethylation of CpGs
hypoacetylation of histones
contains hardly any genes, not opened easily
chromatin very condensed

Euchromatin

light bands with giemsa stain
regions that are actively transcribing genes
G+C rich
hypomethylation of CpGs
hyperacetylation of histones
located towards centre of nucleus

some chromatin never goes into euchromatic state (constitutive) vs that which can switch (facultative)

Answer 112

A

5’ to 3’

Answer 113

A

DNA
promotor region (TATA box)
transcription (RNA polymerase)
mRNA (5'cap and poly-A tail)
excision of introns (snRNPs form spliceosome loop)
translation
proteins

Answer 114

A

constitutive - ‘housekeeping’ genes, constant expression
regulated - time (development), place (cell type), signal
multiple promotors
alternative splicing
non-coding RNAs
acetylation / methylation

Answer 115

A

long non coding lncRNAs (decoy, scaffold, guide, enhance)

short interfering siRNAs (mRNA clevage and degradation)

micro miRNAs (repressed translation)

Answer 116

A

Change in DNA expression/repression with no change in DNA sequence

DNA (methylation)

histones (variants and acetylation/methylation)

nucleosomes (factors influencing how close nucleosomes are)

non-histone scaffold

location within nucleus (inactive near periphery)

non coding ncRNA gene silencing

genetic imprinting & X chromosome inactivation (Xist)

Answer 117

A

typically occurs at CpG (CG pairs)

methyl groups are chemical tags

CpG-rich islands associated with promotor regions

methylation of CpG islands = reduced gene expression

Answer 118

A

majority of genes are expressed from both gene copies

aneuploidy = unbalanced sets of chromosomes due to excess or deficiency = increased or decreased gene expression
(e.g. polyploidy, trisomy, monosomy) - can be due to failure of chromosomes to separate during division

monoallelic gene expresion

certain genes must be expressed from only one copy for normal cell function
specific mechanisms INACTIVATE one of the two copies (e.g. X chromosome inactivity in females)

Answer 119

A

cystic fibrosis, sickle cell anaemia, thalassaemia, haemochromotosis

one altered copy does not cause phenotype

can tolerate 50% sufficient for cell function

two altered non-functional copies cause phenotype

Answer 120

A

e.g. huntingtons

loss of single gene causes a specific phenotype

may have novel ‘gain of function’ or insufficient function (haploinsufficiency)

Answer 121

A

random inactivation in cells of early embryo

DNA methylation

hypochromatin structure

non-coding RNA (Xist)

female cells are mosaic (different X chromosomes inactivated in each cell)

Answer 122

A

approx 1% of genes expressed exclusively from one chromosome (maternal or paternal)

epigentic process (DNA methlylation, chromatin condensation, ncRNAs)

imprints present in paternal and maternal somatic cells

imprints erased during gametogenesis

all mature gametes absorb maternal or paternal pattern

Answer 123

A

Loss of heterozygosity (deletion of coding region from m or p chromosomes)

Uniparental disomy (two copies of chromosome inherited from one parent)

epimutation - loss of imprinting (low folate = reduced DNA methylation)

mutations of DNA sequence of imprinted gene

Answer 124

A

mutation in active maternal gene
= carrier & affected females can have affected children (but not carrier children)

carrier males and affected males cannot have affected children (but can have carrier children)

Answer 125

A

Screening

offered to all pregnant women
non invasive
not definitive

Diagnostic

offered to women at increased risk
invasive (risk of miscarriage)

Answer 126

A

chromosomal (tri 21, 18)
neural tube
genetic tests (parents)

1st trimester combined screening (T21,T18)

blood taken 9-13 weeks (2 biochem analytes)
- PAPP-A
- hCG
Ultrasound performed between 11-13 weeks
- nuchal translucency (oedema)
- crown rump length

2nd trimester screening (T21, T18, neural tube)

blood taken 14-20 weeks (4 biochem analytes)
- hCG
- inhibin A
- α-fetoprotein
- oestriol

Answer 127

A

Chorionic Villus sampling (CVS)

from 11 weeks gestation
Ultrasound guidance needle inserted
aspiration of placental tissue
~1% increased risk of miscarriage

Amniocentesis

frim 15 weeks gestation
ultrasound guidance needle inserted
aspiration of amniotic fluid
~0.5% increased risk of miscarriage

Answer 128

A

Fluorescence in situ hybridisation

performed on non-dividing cells
fluorescence binds to chromosomes in Interphase
fast but less accurate

Karyotyping

grow cells, arrest in metaphase
burst and count chromosomes & banding

Microarrays (SNPs and CNVs)

cfDNA massive parallel sequencing (NIPT)

Answer 129

A

Translocation between long arms of acrocentric chromosomes
e.g.
45,XX,der(14;21)(q10;q10)

Answer 130

A

DELETION - 46,XX,del(4)(p15)
deletion in chromosome 4 at breakpoint p15

INVERSION - 46,XY,inv(2)(p12;q12)
inversion of chromosome 2 with breakpoints at p12 and q12

TRANSLOCATION - 46,XX,t(3;9)(p14;q21)
Balanced translocation between chromosomes 3 and 9
breakpoints at band p14 on chromosome 3 and q21 on chromosome 9

DUPLICATION - 46,XX,dup(5)(p13;p14)
Segment between bands p13 and p14 on chromosome 5 is duplicated

DERIVATIVE - 45,XX,der(13,14)(q10,q10)
- balanced robertsonian translocation between chromosomes 13 and 14

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