Week 2 - Metabolism - Skildum

Question 1

what’s your favorite color?

Answer 1

blue!

Question 2

2,3 Bisphosphoglycerate is only made under what conditions?

Answer 2

Conditions of hypoxia

(Like high altitude or heavy smoking)

You don’t want to do it at other times because it requires energy to do.

Question 3

Describe the mechanism by which 2,3 biphosphoglycerate is activated by hypoxia

Answer 3

1,3 bisphophoglycerate is converted to 3 phosphoglycerate. 3 phosphoglycerate then builds up if there is no oxygen to power the electron transport chain.

When 3 phosphoglycerate builds up it actually activates bisphosphoglycerate mutase. This enzyme create 2,3 bisphosphoglycerate from 1,3 bisphosphoglcerate

Question 4

If there are problems downstream of pyruvate, where does the cell get ATP from?

Answer 4

The cell will have to get all its ATP from glycolysis with lactic acid as the end product.

Question 5

What is the turnover rate like in fatty acids?

Answer 5

VERY high. Turned over about 180 times per 12 hr. It’s because there is a lot in storage, but only a small amount in circulation. Constantly creating and burning.

Question 6

Fatty acids: Unsaturated or saturated have higher melting points? why?

Answer 6

Unsaturated that have a lower melting point!

Example: butter (saturated) is solid at room temp, whereas olive oil (unsaturated) is more liquid.

Question 7

What is the protein in serum that transports fatty acids and transports them to needy cells.

Answer 7

Albumin

Question 8

How is adipocyte stored Fatty acids different from dietary ones in the way its transported?

Answer 8

Albumin takes the ones from adipocytes. There are specific molecules for the dietary ones. (Chylomicrons, i think… etc)

Question 9

What do the lipase molecules in adipocyes genereally respond to?

Answer 9

Hormones

Insulin - inhibits the lipase

Glucagon, epinephrine, and noreprinephrine - activate it

Question 10

Sum up what happens to the Fatty Acid from when it arrives at the cell to when it arrives at the mitochrondria

Answer 10

1. FA-albumin complex binds to receptor at surface and the FA is brought into the cell
2. Coenzyme A is added through fatty acyl CoA synthetase (GIVE IT A HANDLE)
3. This can then easily pass through the outer membrane of the mitochondria

Question 11

How do we get the fatty-acyl CoA across the impermeable inner membrane of the mitochrondia

Answer 11

1. CPT1 Switches out the CoA for a carnitine molecules that the fatty acyl group will be able to ride across the inner membrane
2. The carnitine translocase is a symporter that trades a fatty-acyl-carnitine for a carnitine
3. CPT2 Then switches the carnitine for a CoA and the fatty-acyl-CoA is now ready to be beta-oxidized

Question 12

How does Acetyl CoA carboxylase (ACC) regulate fatty acid trasnport into the mitochrondria?

Answer 12

It converts acetyl CoA into malonyl CoA, which inhibits CPT1

Insulin activates it if there is a lot of glucose around because it is unecessary to make energy through beta oxidation.

AMP inactivates it if there is not a lot of excess energy around, so that more energy can be created by beta oxidation without interference from ACC

Question 13

How do you get CPT 2 deficiency and what would be the problems associated?

Answer 13

Inherited recessive disorder

Adult onset: Characterized by muscle pain, weakness and myoglobinuria after prolonged exercise or fasting.

Neonatal/Infant Onset: Irritabilty, failure to thrive, death

Causes problems because carb supplies just aren’t enough to meet all the caloric needs, burns up too fast and you cant use FA’s

In serum lipid profiles they will not show elevated ketone bodies like what would be seen in normal starvation because beta-oxidation is required to produce them. YOu would see a lot of acyl carnitine in their lipid profile.

Question 14

4 steps of fatty acid oxidation:

Answer 14

Oxidation

Hydration

Oxidation

Carbon-carbon bond cleavage

Question 15

alpha, beta, and w-ish carbon. What are they on the fatty acid chain?

Answer 15

a carbon: first carbon away from a functional group

b carbon: second carbon from the functional group

w carbon: furthest carbon from the functional group

Question 16

Do you get more ATO from glycolysis or fatty acid b-oxidation?

Answer 16

beta oxidation

Question 17

Palmitic acid (16:0) is beta oxidized. How many oxidation reactions will this require? How many acetyl-CoA groups will it create?

Answer 17

7 oxidations (NOT 8)

8 acetly CoA ‘s

Question 18

Let’s say you have medium chain acyl CoA dehydrogenase deficiency. What is the right name for that? What are the symptoms?

Answer 18

Reye Syndrome

Symptoms:

fasting hypoketotic hypoglycemia

(Not normal to be hypoketotic when you are hypoglycmeic)

Hepatic encephalopathy

sudden infant death syndrome

Diagnosed by lipid profiles of mutation identification

Question 19

What would you see in the blood serum of someone with Reye Syndome?

Answer 19

A lot of medium length fatty-acyl-CoA ‘s

Question 20

Why should you watch out for unripe fruit in Jamaica?

Answer 20

Ackee fruit that is not ripe has a chemical called hypoglycin.

Ingesting a lot can inhibit acyl-CoA-dehydrogenase similar to MCAD(REYE)

So you could get Jamaican vomiting sickness.

Usually not fatal, but also not fun.

Question 21

Are cis or trans double bonds needed in order for fatty acid catabolism to occur?

Answer 21

TRANS!

Enoyl-CoA hydratase only accepts trans double bodns

Question 22

What has to be done to catabolize a fatty acid with unsaturation?

Answer 22

Enoyl-CoA isomerase can move the double bond to the right positiion and 2,4-Dienoyl CoA reductase can reduce the fatty acid

(This is a crappy answer…)

Question 23

What can be done in the case of odd-chain lengthed fatty acids?

Answer 23

Basically the oxidation is all the same until the very last cycle when instead of 2 acetyl-CoA’s you get 1 acetyl-CoA and 1 Propionyl-CoA

Downstream the propionyl CoA can be converted to succinyl CoA (An exact intermediate in the TCA cycle)

That’s wild.

Question 24

What happens to all those ridiculously long fatty acid chains?

Answer 24

They are degraded in peroxisomes in a similar manner to beta-oxidation. Once they hit a 4-6 carbon chain then they are trasnferred to mitochondria for the regular beta oxidation

Question 25

What about fatty acid chains with branches coming off of the chain? waht happens to them?

Answer 25

They are beta oxidized the same way but can produce different end prodcucts. For example, any carbons with methyl chains will make propionyl CoA, whereas the ones without branches can still prodcue normal propionyl CoA.

Question 26

What is w oxidation?

Answer 26

It is a sosrt of inefficient way of doing oxidation where they make both ends carboxylic acids and then metabolize from both ends.

Cytochrome P450 enzymes do it.

I think this happens when there is a disruption of normal metabolism and things have to go down in the endoplasmic reticulum instead

Question 27

Outline where these parts of your body can get energy and where they prefer to get energy:

Red Blood Cells:

Brain:

Skeletal Muscle:

Answer 27

Red Blood Cells: Glucose ONLY (no mitochondria)

Brain: Prefers glucose, can use ketone bodies

Skeletal Muscle: Glucose/ Fatty Acids/ Ketone Bodies

Question 28

Where in the body are ketone bodies produced from fatty acids?

Answer 28

the liver! yep.

Question 29

If a patient comes in with ketoacidosis, what would you expect is their condition?

Also, what is Ketoacidosis?

Answer 29

Starvation or diabetes

Ketoacidosis is a depression in blood pH caused by excessive ketone body prodcution

Question 30

A couple examples of ketone bodies that can be used as fuel by brain heart and skeletal muscle?

Answer 30

3-hydroxybutyrate and acetoacetate

They are first converted to acetly CoA and then go into the TCA cycle

Question 31

Describe three types of transport systems:

Antiporters:

Symporters:

Uniporters:

Answer 31

• Antiporters transport one molecule in and another molecule out. (ATP / ADP)
• Symporters transport two molecules in or out. (pyruvate + H+, Pi + H+)
• Uniporters transport one molecule in or out. (calcium)

Question 32

Which membrane of the mitochondria can create a chemical gradient??

WHY???

Answer 32

The inner mitochorndial membrane BECAUSE it is impermeable. (this allows voltage or proton concentrations to be established)

Almost everything small enough just passes through the outer mito membrane without any problem at all

Question 33

How do we inheriit mitochondrial DNA?

Answer 33

Maternally

Question 34

What kind of things do mitochondiral DNA code for?

Answer 34

They encode for a few proteins for the electron transport chain and the tRNA’s needed to translate these proteins.

(13 genes)

HOWEVER: most mitochondrial proteins are encoded by nuclear DNA and transported over later

Question 35

Why is mitochondrial DNA hypermutable?

Answer 35

It is more likely to get breaks and become mutated because:

1. Mitochondrial DNA is “naked” (not bound to histones) so its unprotected
2. exposed to a lot of ROS reactive oxygen species (not to be confused with ROUS’s)
3. Mitochondrial genome has milited ability to repair genome when probs occur

Question 36

How does the heterogenous quality of mtDNA dampen the effects of hypermutability?

Answer 36

There are multiple copies of the mtDNA in each mitochondria and mutliple mitochrondria in each cell. So unless the probs are wide-spread there is a dampening effect

This also leads to a range of phenotypes spanning from mild to very severe problems depending on how much of the mitochondrial genome has been damaged.

Question 37

Mitochondrial disease tend to get better or worse?

Answer 37

Diseases which result from mitochondrial dysfunction tend to be progressive– they get worse with age.

Question 38

Which enzyme links glycolysis to the TCA cycle?

Answer 38

Pyruvate dehydrogenase

PDH

Question 39

Where in the cell does glycolysis happen?

TCA?

Pyruvate dehydrogenase

Answer 39

Glycolysis: Cytosol

TCA: Mitochondria

PDH: Mitochondria

Question 40

What protein complex transports pyruvate into the mitochondria?

Answer 40

Mitochondrial Pyruvate Carrier (MPC)

Point mutations affecting MPC can cause lactic acidosis and hyperpyruvatemia

Question 41

Pyruvate Dehydrogenase (PDH) has some complicated regulation:

Give an overview of how this regulation works

Answer 41

In the active unphosphorylated state, PDH converts pyruvate to acetly CoA for the TCA cycle

To inactive PDH, an enzyme called PDH kinase can phosphorylate the E1 subunit

PDH Kinase is activated or inhibited by indicators of the cell’s energy balance

Acetyl CoA and NADH activate PDH Kinase

Pyruvate and ADP inhibit PDH Kinase

In this way PDH is active when the cell needs to produce ATP in the TCA cycle.

Got it?

Question 42

ACetly CoA can be produced from what sources?

Answer 42

Fatty acids

Ketone Bodies

Sugars

Amino acids

Ethanol

Question 43

Which steps in the TCA cycle have large deltaG’s?

Answer 43

The converson of malate to oxaloacetate and the converson of citrate to isocitrate

Question 44

Which step in the TCA cycle is the KEY rate-limiting step in the cycle?

Answer 44

Isocitrate dehydrogenase

(Converts isocitrate to alpha-ketoglutarate)

Question 45

At what point in the TCA cycle do we go from 4 carbons to 6?

Answer 45

The first step where oxaloacetate is combined with acetly CoA to make citrate

Question 46

When in the TCA cycle do we lose the first carbon. Going from 6 carbons to 5

Answer 46

In the 3rd step from isocitrate to alpha-ketoglutarate. Its an oxidative decarboxylation using a dehydrogenase

Question 47

When in the TCA cycle do we lose the second CO2. Going from 5 carbons to 4?

Answer 47

The 4th step. Where we go from alpha-ketoglutarate to succinyl-CoA

This is an oxidative decarboxylation using a dehydrogenase

Question 48

Which steps of the TCA cycle contribute to the electron tranport chain?

Answer 48

3,4,6,8

Is this important?

Question 49

Which step of the TCA cycle produces GTP?

Answer 49

the 5th step from succinyl Coa to succinate.

You get this much energy from cleaving that thioester bond attached to the CoA

Question 50

Which enzyme in the TCA cycle is actually part of the electron transport chain?

Seems like a possible question. Too hard?

Answer 50

Succinate dehydrogenase

(Maybe you can remember that because FAD is a prosthetic cofactor, so in order to get the electrons into the transport chain it makes sense it would have to be a part of it)

Question 51

How can succinyl dehydogenase be a tumor suppressor?

Answer 51

Maintains low [succinate] which aids in signalling blood vessel generation (TB)

It affects the HIF (oxygen sensing) pathway

Maybe look at this again i didn’t finish the reason in my notes……..

Question 52

How many ATP prodcued per acetyl CoA?

Carbon dioxides?

Answer 52

10 ATP

2 CO2

Question 53

How does an increase in NAD have on oxaloacetate?

Answer 53

More oxaloacetate will be produced as these substrate levels increase

Increasing NADH or oxaloacetate would do the opposite.

Question 54

How would increased NADH affect citrate?

Answer 54

Citrate is actually going to increase a bunch because the TCA cycle will get stalled and the negative delta G to in the opposite direction will make this easy.

Question 55

How is isocitrate dehydogenase regulated

Answer 55

This is the main regulatory enzyme of the TCA cycle:

ADP binds to IDH and decreases its Km (activates it)

IDH is allosterically inhibited by NADH

Question 56

What is a method to form oxaloacetate to replsnish the TCA cycle?

Answer 56

Pyruvate carboxylase converts pyruvate to oxaloacetate and plugs it into the TCA cycle.

Question 57

How is oxaloacetate realted to exercise?

Answer 57

It is often the limiing factor in the production of energy from TCA during exerise.

Question 58

What is myoadenylate Deaminase Deficinecy?

Answer 58

It is characterized by a lack of the enzyme AMP deaminase.

The hallmark of the disease is exercise intolerance, muscle pain, and muscle probelms because this enzyme is part of the pathway used to recharge stores of oxaloacetate.

Question 59

In the electron transport chain:

Going from NADH to H2O, how many protons are transported across the inner mitochondrial membrane?

Answer 59

10 protons

Question 60

How many protons do complexes 1,3, and 4 tranport across the inner mito membrane?

Answer 60

I - 4H+

III - 4H+

IV - 2H+

Question 61

What are the main reactive oxygen species (ROS)

Why are they dangerous

Answer 61

superoxide, hydrogen peroxide, and hydroxyl radicals

They cause a lot of damge to the cell. THey canoften cause damage without terminating, which allows them to damage widely.

Question 62

Overview of Eletron transport chain:

Answer 62

Question 63

ATP synthase:

What does it do?

What part do protons go through?

Answer 63

It uses chemical gradeint energy of protons to make ATP.

Protons go though F0 portion

Question 64

What makes human warm blooded?

Answer 64

Heat energy produced by the electron trasnport chain

Question 65

What is uncoupling?

Answer 65

This is when the trasnfer of electrons from NADH to O2 does NOT produce ATP.

3 cases:

adaptive thermogenesis

chemcial uncoupling (toxins transport stuff through mito membrane)

mechanical uncoupling (mechanical damage)

Question 66

How does adaptive thermogenesis happen?

Answer 66

Noreprinephinre activates UCP1

UCP1 is a channel that can open and re-realse H+ back into the inner space of mitochondria without ATP being made

IMPORTANT for babies, cuz they just hang out a lot

Question 67

What is an example of a chemcial uncoupler?

Answer 67

DNP Dinitrophenol

Transports H+ across the membrane without going through ATP synthase

chemcial in explosives, people int he facory got fevers and lost a lot of weight

Question 68

Common cause of mechanial uncoupling?

Answer 68

Peroxidation by ROS’s!!!!!!!!

or mitochondrial swelling due to high water influx!

BAsically a dmaged membrane doesn’t provide a means to make a good gradient

Question 69

Main form of fatty acid storage in the body?

Answer 69

Triacyglycerols

Question 70

what molecule is integral to the firs step of fatty acid biosynthesis?

Answer 70

Citrate, which is created in the first ste of the TCA cycle

Question 71

What substrates form the TCA cycle signal the entrance of citrate into fatty acid biosynthesis?

Answer 71

In conditions of excess energy, isocitrate dehydrogenase is inhibited by a high NADH/NAD+ ratio. This drives citrate towards fatty acid synthesis rather than through the TCA cycle

Question 72

How do the cofactors produced from converting citrate back into pyruvate affect glycolysis and fatty acid synthesis?

Answer 72

When oxaloacetate is converted to malate, NAD+ is produced which helps power glycolysis forward.

When malate is converted to oxaloacetate NADPH is produced which helps to power beta oxidation

Question 73

THe pyruvate malate cycle has 2 important functions in lipogensis. What are they?

Answer 73

1) Transports acetyl CoA from the mitochondria to the cytosol.
2) Malic enzyme generates NADPH to power fatty acid synthesis.

Question 74

Acetyl CoA carboxylase is used to convert acetyl CoA to malonyl CoA in the first step of liogenesis. What must be the cofactor involved?

Answer 74

Biotin

(used in carboxylations)

Question 75

What step is the rate limiting step in fatty acid biosynthesis?

Answer 75

The first step where acetyl-CoA is converted to malonyl-CoA.

Acetyl-CoA carboxylase catalyzes this rxn using biotin

Question 76

How is acetyl CoA carboxylase regulated???

Do the activators!

Answer 76

This is THE rate-limiting step in FA synthesis!

• Citrate allosterically activates ACC (this is called feed-forward and Dr.Skildum mentioned this is the most important regulator
• Xyulose 5 phosphate increases transcription
• Insulin activates it by stimulating dephosphorylation

Question 77

How is acetyl CoA carboxylase regulated???

Do the inhibitors!

Answer 77

• Palmitoyl CoA(a product) allosterically inhibits
• AMP-PK phosphorylates to inhibit
• Glucagon –> cAMP –>PKA –> inhibitory phosphorylation
• Malonyl-CoA inhibits carnitine palmitoyl transferase I (CPT1)
• This prevents beta oxidation of newly synthesized fatty acids
• The body would not want to synthesize and break down FA’s at the same time, so this makes sense

Question 78

Give the 4 step sequence of fatty acid synthesis!!!!!!

Answer 78

Bond formation

Reduction

Dehydration

Reduction

Question 79

Fatty acid synthase has a mode of action that derives from its structure. Explain what that is

Answer 79

It has two important exposed sulphur atoms that it uses to extend the fatty acid chain.

2 carbons are added at a time going back and forth between the two

At the beginning of each cycle phosphopantetheinyl continues to recieve a malonyl CoA which then gets the full chain from cysteine transferred to it. The chain is solidified and then tranferred back over to the cystien so that the phosphapantetheinyl can recieve another malonyl CoA.

Sort of an oversimplification I guess….

Question 80

Which cofactor powers the reduction step of fatty acid synthesis?

Answer 80

NADPH!

That’s what I’m talking about!

Question 81

In the 2nd reduction step where the carbon double bond is formed, what is the cofactor powers the reaction?

Answer 81

NADPH!

Question 82

What enzyme catalyzes each subsequent step of fatty acid synthesis?

Reduction:

Dehydration

Reduction:

Answer 82

All threee catalyzed by fatty acid synthase

Question 83

What is the body’s limit for saturating Carbon-carbon bonds

Answer 83

They must be at least 9 carbons away from the w-carbon end

This is why dietary w-3 and w-6 fatty acids must be obtained from plant and fish oils in order for the body to synthesize eicosonoids. (our body can’t make those doubles bonds itself

Question 84

Most important dietary unsaturated fatty acids?

Answer 84

linoleic and linolenic acids

Question 85

What is the enzyme and energy source for unsaturation of fatty acids in the body?

Answer 85

fatty acyl-CoA desaturase

energy ultimately through NADH

Question 86

Explain that two ways and locations that glycerol-3-phosphate can be created in order to store fatty acids!

Answer 86

In the liver:

LIpolysis of triacylglycerides (TAG) will free a glycerol-3-phosphate

In adipocytes (and the liver):

Glycolysis can occur

Dihydroxyacetone phopshate (an intermediate) can be converted into glycerol -3-phosphate

Question 87

Why must FA’s be attached to a glycerol in order to be stored?

Answer 87

It makes them soluble ( they are very insoluble otherwise)

Question 88

Storage of TAG in adipocytes requires two important conditions! What are they???

Answer 88

Excess carbohydrates

AND

Glycolysis

Question 89

Explain what happens to triacylglycerides in the Golgi, how they circulate in the blood, and how they enter cells for storage or beta-oxidation!!!!!!

Explain it now!

Answer 89

The golgi packages TAG’s with the apoprotein B-100 to become Very Low Density Lipoproteins (VLDL).

VLDL’s circulate in the blood until their fatty acids are cleaved at the lumen of capillary endothelial cells by lipoprotein lipase (LPL)

The fatty acids can then enter the cells

In muscle cells they undergo beta-oxidation for energy

In adipocytes they are stored as TAG’s again.

Question 90

Do dietary fatty acids travel the same way as synthesizd ones?

Answer 90

NOPE. They travel in chylomicrons (and other kidns of structures)

Question 91

How are glycerophospholipids different from a triacylglycerol and where are they found?

Answer 91

They are similar, but have a head group.

Found in cell membranes, lipoproteins, bile, lung surfactants etc…

Question 92

What glycerophopsholipd is an important part of the inner mitochondiral membrane??

Answer 92

Cardiolipin

Question 93

Tell me about sphingolipids.

Answer 93

They use ceramid isntead of glycerol for their backbones

The most important sphingolipid is sphingomyelin, which is present in the myelin sheaths of nerve fibers

Question 94

Clinical importance of cerebrosides?

Answer 94

Most important clinical significance discussed in class:

The inability to break them down is often correlated with severe mental retardation. LEads to accumulation in neurons

ex. Tay Sachs disease

Question 95

Function of Dipalmitoylphosphatidylcholine?

Other than memorizing a very long word?

Answer 95

It is a lung surfactant

Like soapy water in a balloon, helps those alveolar walls stay open

Question 96

What is an interesting way to use surfactants to guess gestational progress?

Answer 96

The ratio of sphingomyelin to phosphatidylcholine in amniotic fluid is an indicator of gestational progress.

with more time, the ratio switches to favor phosphatidyl choline

Question 97

What hormones are release by adipocytes and what do they do?

Answer 97

Leptin:

The satiety hormone, released when TAGs levels high

Acts through JAK/STAT receptors in the hypothalamus to release factors depressign appetite

Adiponectin:

Complements leptin. Acts thru AMP-PK and PPAR to inhibit acetyl-CoA carboxylase

This stops fatty acid oxidation

In obesity adiponectin decreases! Crazy!

Question 98

Are ammonium or ammonia ions able to cross membranes????

Answer 98

Ammonium ions (NH4+) CANNOT cross

Ammonia (NH3) CAN cross

Question 99

What is the equation for nitrogen balance?

Answer 99

Nitrogen balance [grams] = nitrogen intake [g] – urinary urea nitrogen [g] – X [g]

The constant X ranges from 2g to 4 g, and depends on:
the route of nutrition intake (oral vs. perenteral)
age (X is higher in children).

.16g of N per gram of protein = the constant

Question 100

What does it mean to fix nitrogen?

Answer 100

It means to make it organic.

Question 101

What can be problematic about ammonium and ammonia in the blood?

Answer 101

Ammonia and ammonium are toxic, especially to neurons

They can cause lethargy, headaches, seizure, etc.

This is why the body is always attachign stuff to free nitrogens - to avoid toxicity

Question 102

How does pepsin act in the digestive system?

Answer 102

Preferentially cleaves peptide bonds of aromatics but some hydrophobic

Single, di-, adn tri- peptides can then move into the blood where they first go to the liver

Question 103

How is transport of Amino acids into the intestinal lumen similar to the SGLT glucose transport system???

Answer 103

They both make use of a symporter for transport and the second molecule going through the symporter is an ion that is pumped into a gradient using ATP.

The intestinal epithelial cell actively transports Na out of the endothelial cell and into the gut lumen to create a high concentration gradient of Na outside.

The Amino Acid/Na+ symporter makes use of this energy gradient to push amino acids into the cell.

The amino acids can then easily go through facilitated transport into the portal vein

Question 104

What are the key amino acids of the urea cycle!?

Also name their deaminated form and their main role. This seems hard…

Answer 104

• Glutamate - alpha ketoglutarate - represents the amino group pool in the cell
• Aspartate - oxaloacetate - Donates nitrogen to the urea cycle
• Alanine - pyruvate - key role in gluconeogenesis (when muscles working hard)
• Glutamine - glutamate - transports nitrogen to liver for irea cycle
• Arginine - important transporter in the urea cycle (can even be used as therapy in certain diseases)

Question 105

Explain what happens to dietary proteins starting at the gut.

In the FED metabolic state

Answer 105

• Dietary protein enters the gut and is digested to AA’s
• It enters pools of AA in the blood
• Insulin will then promote storage pathways for proteins in the liver and cells
• Excess amino acids can be stored as glycogen or turned into triacylglycerols that are subsequently turned to VLDL
• VLDL can be stored as TAG in adipose tissue and later used by muscles
• Glycogen will be stored until it is needed to be released as glucose in the blood

Question 106

Explain what happens to proteins :

In the FASTING metabolic state

Answer 106

Glucagon, cortisol, epinephrine, and noreprinephrine mobilize stored fuels

Protein pools in the muscle will be broken down into amino acids

Branched chain AA’s will be used in the TCA cycle

Glutamine can be used in the gut and kidney

Glutamine/Alanine used in the liver to create ketone bodies and glucose to make energy

Question 107

Let’s get a little more specific.

Can you explain how the alanine/ glucose cycle is able to use amino acids as fuel

Answer 107

1. Cortisol stimulates muscle protein breakdown
2. Alpha-ketoglutarate is a universal amine acceptor and removes the amine from an amino acid to form glutamate and an alpha-keto acid
3. Glutamate then donates the amine to pyruvate to form alanine and reform alpha-ketoglutarate
4. Alanine can then be trasnsported to the liver where it undergoes gluconeogenesis and the nitrogen converts to urea for excretion

Question 108

What are the three enzymes that can fix free ammonium?

Answer 108

Glutamate dehydrogenase - (alpha-ketoglutarate to glutamte)

glutamine synthetase - (glutamate to glutamine)

carbamoyl phosphate synthetase -

These are NOT transaminases, so they require energy to form

Question 109

Basics about glutamate dehydrogenase: go!

Answer 109

Using NADPH as an energy source it can fix ammonium to alpha-ketoglutarate to form glutamate.

It is also capable of performing the reverse reaction, which would reform NADPH from NADP

Question 110

How can liver failure cause brain problems?

Answer 110

This is called hepatic encephalopathy.

Liver failure (occurring for many reasons) can cause ammonia accumulation in the blood because it canot be fixed. As we know, ammonia accumulations can be toxic, especially to the brain

Question 111

What is the main fucntion of the urea cycle?

Answer 111

Convert nitrogen to urea, which can easily be excreted in the urine.

Question 112

How does nitrogen enter the urea cycle?

(2 ways)

Answer 112

It can enter as free ammonium from deamination of amino acids

(it then must be incorportaed into carbamoyl phosphate by carbamoyl pops)

It can also enter from aspartate -which results from transamination of amino acids

(It is then combined with citrulline by arginosuccinate synthetase to form arginosuccinate)

Question 113

What enzyme converts NH4+ and HCO3- to carbamoyl phopshate?

Answer 113

CPS-1

Carbamoyl phopshate synthetase 1

Question 114

Ornithin plays a similar role to what substrate from the TCA cycle?

Answer 114

Oxaloacetate

Question 115

Which two molecules are antiported between the cytosol and mitochondrion in the urea cycle?

What happens if this antiporter is defective?

Answer 115

Ornithine and citrulline

HHH syndrome!

hyperammonaemia, hyperornithaemia, homocitrullinaemia

Question 116

What is the main regulator of the Urea cycle????

Answer 116

The availability of substrates is the main regulator! So not so sophistaicated. Just simple feed-forward regulation

Some modulation by allosteric regulation of CPS-1 and transcriptional regulation of urea cycle enzymes

Question 117

How does arginine regulation the urea cycle?

Answer 117

Well arginine is actually an indicator of urea cycle back-up, and would encourage things to get going again.

It stimulates the urea cycle by increasing the synthesis of N-acetyl-glutamate (NAG)

NAG then allosterically activates carbamoyl phosphate synthetase-1 (CPS-1) which we know fixes NH4+ to make carbamoyl phopshate in the urea cycle’s first step

So you could say that arginine NAGs the urea cycle forward…

Question 118

Symptoms of ammonium toxicity in the brain?

(Hepatic encephalopathy)

Answer 118

refusal to eat (protein aversion)

seizures

irritability

lethargy

ataxia

tremors

Failure to thrive

Question 119

Elevated orotic acid in the urine is a characteristic of?

Answer 119

Urea cycle disorders!

Particularly ones downstream of CPS-1

Question 120

Step 1 of diagnosing an inherited disorder when you see hyperamonaemia?

Answer 120

Obtain blood pH and blood HCO3

Question 121

When a newborn has hyperamonaemia

and blood pH and HCO3 show no acidosis

What is your next step?

Answer 121

You need to check plasma amino acids to see if there is s specific amino acid elevation

Question 122

Main treatment possibilities for inherited irea cycle disorders:

Answer 122

low protein diet

N-Carbamoylglutamic acid (CPS-1 allosteric activator)

Arginine, Benzoic Acid, Phenylbutyrate (eliminate nitrogen in alternative pathways)

liver transplant/hepatocyte transfusion

Question 123

Phenyl butyrate and benzoic acids work by?

Answer 123

basically just allowing nitrogen-filled amino acids to be excreted in the urine to get rid of the nitrogen load

Question 124

How does arginine therapy work?

Answer 124

ONLY works for arginosuccinate lyase deficiency

Basically arginine can power the ureas cycle forward because the mssing enzyme would normally create arginine. And having arginine allows you to get ornithine (which is crucial)

It allows arginosuccinate to be excreted in urine once it is full of nitrogens because a lot of it will build up

Question 125

When you see liver enzyme in the blood, what should you suspect?

(AST, ALT, GGT)

Answer 125

That liver cells have been damaged and their contents spilled out.

Question 126

What are the three key cofactors for enzymes in amino acid metabolism? What kinds of reactions do they catalyze?

Answer 126

PLP - transamination, deamination, carbon chain transfer

Tetrahydrofolate (TH4) - One carbon transfers

Tetrahydrobiopterin (BH4) - ring hydroxylations - (like Phe to Tyr)

Question 127

Is M.V.Pitthall actually a useful thing to memorize?

Answer 127

No. That’s my opinion. sorry.

Question 128

How can you create Tyrosine without ingesting it in your diet?

Make sure to name the cofactor!

Answer 128

Phenylalanine hydroxylase is an enzyme that hydroxylates phenylalanine

The cofactor is tetrahydrobiopterin

Question 129

Amino acids can be turned into and drieved from?

Answer 129

glycolysis intermediates

TCS cycle intermediates

Acetyl CoA and Acetoacetate

Question 130

Lets look at glycolytic intermediates

What glucolytic intermediates can be tuned tinto amino acids?

Answer 130

Pyruvate to Alanine

3-phosphoglycerate to Serine

Question 131

Name 2 amino acids that cen be turned to glycine in one step.

What cofactors do they use?

Answer 131

Serine to glycine using PLP and FH4

Threonine to glycine using PLP

Question 132

Intersting biproducts of cysteine degradation?

Answer 132

Sulfuric Acid

OR

PAPS (an activated sulfate that can be used to negatively charge stuff)

Question 133

What happens if you have a recessive mutation in your SLC carrier?

Hint: painful

Answer 133

cysteine wil begin to precipitate in your renal tubules. Forming kidney stones

Called cystinuria

Question 134

What enzyme is used to transaminate alanine to pyruvate?

Answer 134

alanine aminotransferase (ALT)

Question 135

What TCA intermediates can be turned into amino acids?

Answer 135

oxaloacetate

and

Alpha-ketoglutarate

Question 136

What AAs can oxaloacetatebe converted to?

Answer 136

aspartate and asparagine

Question 137

What AAs can alpha-ketoglutarate be converted to?

Answer 137

Glutamate, glutamine, proline, arginine

Question 138

What can you assume if you find ALT and AST in the blood???

Answer 138

Liver damage

Alanine aminotrasnferase and aspartate aminotransferase are only found in the liver normally

Question 139

What cofactor does AST use?

Answer 139

PLP

Question 140

Describe the cause, symptoms, lab results, and treatment of an infant with maple syrup urine disease.

Answer 140

• recessive deficinecy in branched-chain alpha-keto acid dehydrogenase
• Symptoms: 1 week old, convulsions, vomiting, maple syrup urine odor
• Labs: elevated plasma/urine of Val, Iso, and Leu + hypoglycemis + ketoacidosis
• Treatment: Hydration, transfusion, low branched cahin amino acid diet

Question 141

Why could high doses of thiamine be an effective treatment for mild Maple Syrup Urine Disease?

Answer 141

You have a problem with a decarboxylase enzyme. loading up with more TPP will help the enzyme be as effective as it could be.

Question 142

A missing kinase that normally inhibits aplha keto acid dehydrogenase (enzyme responsible for Maple Syrup Urine) causes a problem. What is it?

Answer 142

A combined seizure/ autism disorder resulting from a lack of available branched chain amino acids.

Supplment these BCAA’s and symptoms lessen

Question 143

What is the problem in PKU?

Answer 143

A defect in phenylalanine hydroxylase. What normally produces tyrosine.

Phenylalanine then accumulates in the blood and brain eventually causing seizures, cognitive problems, and mousy odor

Treatment: No Phe in diet!

Question 144

How would somone get Tyrosinemia Type 2? Symptoms? treatment?

Answer 144

Tyrosinemia (Type II)

A rare autosomal recessive mutation of tyrosine aminotransferase. (build-up of tyrosine)

Patients develop plaques on the hands and feet, corneal ulcers, and frequent mental retardation.

Treatment: Synthetic diet low in phenylalanine and tyrosine.

Question 145

What is the cause, symptoms, and diagnosis of alcaptonuria?

Answer 145

A rare autosomal recessive deficiency in homogentisate oxidase.

Homogentisate accumulates and is excreted in urine, giving it a dark color. Patients are asymptomatic until middle age, when they develop arthritis, back pain, renal calculi.

Diagnosis:
Ochronosis (dark spots of polymerized homogentisic acid in the sclera and ear cartilage)
Homogentisic acid in urine.

Question 146

How do you get Tyrosinemai Type 1? Problems? Diagnosis? Treatment?

Answer 146

An inherited disorder of fumaryloacetoacetate hydrolase (FAH)

results in accumulation of succinlyacetone.

(Lots of LIVER problems!)

acute hepatic crisis at 2-4 months of age, Jaundice, hepatomegaly, elevated AST & ALT, hypoglycemia

Diagnosis: Succinylacetone in urine and blood

Treatment: Nitosinone