Biochemistry Lecture Objectives 24 (1) PDF

Summary

This document presents lecture objectives in biochemistry. It covers topics like amino acid structure, function, and protein formation, carbohydrate, lipid, and vitamin classifications, enzyme function, and metabolic pathways like glycolysis and gluconeogenesis.

Full Transcript

**FMS**

**Biochemistry Lecture Objectives**

1. **Describe amino acid structure, function and relation to formation
of peptides and proteins.**

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2. **Recall essential ammino acids.**

The mnemonic \"PVT TIM HiLL\" is a way to remember the nine
essential amino acids (IAA):

P: henylalanine

V: aline

T: tryptophan

T: hreonine

I: soleucine

M: ethionine

H: istidine

L: eucine

L: ysine

3. **Describe the degradation of amino acids.**

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4. **Describe the conversion of amino acids into other molecules and
how that relates to Krebs cycle.**


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5. **Describe protein structure and how they are classified.**

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6. **Describe role and function of carbohydrates including
monosaccharides of importance (glucose, fructose, galactose,
ribose).**


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7. **Describe lipids: classification, structure, and function.**

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Fatty acid synthesis is crucial for cell function as it produces the
building blocks for cell membranes (phospholipids) and energy storage
molecules (triglycerides), and cell signaling (steroids)

I. Saponifiable lipids can be hydrolyzed under alkaline conditions to
yield salts of fatty acids. II. Nonsaponifiable lipids do not undergo
hydrolysis reactions in alkaline solution.

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8. **Recall function of water-soluble vitamins and implications related
to vitamin deficiency.**

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\"The Fat cat is in the ADEK\". The fat-soluble vitamins are A, D, E,
and K.

9. **Recall function of fat-soluble vitamins and implications related
to vitamin deficiency.**

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10. **Recall function of select minerals (calcium, magnesium, sodium,
phosphate, copper, potassium).**


11. **Describe function of enzymes.**

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12. Describe nucleic acid formation and degradation.

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Also have a purine salvage pathway refer to pwp


13. **Describe the process of glycolysis: substrates, products, where it
takes place, and regulation.**

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14. **Describe the process of gluconeogenesis: substrates, products,
where it takes place, and regulation.**

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15. **Describe the process of lactate and the Cori Cycle are used to
generate glucose.**

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16. **Describe glycogen metabolism: how it's made, how it's broken down,
where it's stored, and how it's regulated.**

Embedded file printout Biochem Part 2 3\_4.pptx Machine generated
alternative text: Glycogen Stores of glycogen in the liver are
considered the main buffer of blood glucose levels. De novo glycogen
synthesis is initiated by the attachment of the first glucose residue to
a tyrosine residue in the protein known as glycogenin. The attached
glucose then serves as the primer required by glycogen synthase to
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17. **Describe the function and importance of the pentose phosphate
pathway.**

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alternative text: PPP Cells of the liver, adipose tissue, adrenal
cortex, testis, and lactating mammary gland have high levels of the PPP
enzymes. 30% of the oxidation of glucose in the liver occurs via the
PPP. Erythrocytes utilize the reactions of the PPP to generate large
amounts of NADPH used in the reduction of glutathione Highest levels
of PPP enzymes (in particular glucose-6-phosphate dehydrogenase ) are
found in neutrophils and macrophages. These leukocytes are the
phagocytic cells of the immune system They utilize NADPH to generate
reactive oxygen species (ROS) from molecular oxygen These ROS are then
used to kill phagocytized microorganisms Ink Drawings Ink Drawings Ink
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alternative text: PPP The PPP supplies the erythrocyte with NADPH
needed to maintain the reduced state of glutathione. The inability to
maintain reduced glutathione in erythrocytes leads to increased
accumulation of peroxides, predominantly H 2 O 2 Results in oxidation
of hemoglobin causing it to precipitate which is visible by histology as
Heinz bodies. The increase in ROS also oxidizes lipids in the plasma
membrane, weakening the membrane resulting in a concomitant hemolysis
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alternative text: Pentose Phosphate Pathway Ink Drawings Ink Drawings
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18. **Describe the function of pyruvate oxidation: substrates, products,
where it takes place, and regulation.**

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19. Describe Krebs cycle (citric acid cycle): substrates, products,
where it takes place, and regulation.

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20. **Describe beta oxidation: substrates, products, and implications.**

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Embedded file printout Biochem Part 2 3\_4.pptx Machine generated
alternative text: Beta oxidation & ketogenesis Ketone bodies generated
when B-oxidation overwhelms rate of Krebs cycle Acetoacetate, beta
hydroxybutyrate, acetone Released into bloodstream during:
Fasting/starvation Low carbohydrate diet Prolonged strenuous
exercise Uncontrolled diabetes\* Metabolized by other tissues back
into acetyl-CoA Primarily brain, also heart Ink Drawings Ink Drawings
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21. Describe the electron transport chain process: substrates, products,
where it takes place.

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alternative text: Electron transport chain Definition Final harvest
of energy from e- Location Inner membrane of mitochondria O2
Requires Oxygen Substrates NADH FADH2 ADP + Pi Products ATP
NAD+ FAD Ink Drawings Ink Drawings Ink Drawings ](media/image91.png)

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alternative text: space- FAD FANt NAD\* loco Oxidative phosphorylation
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OVERVIEW

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