1. Cellular Respiration & Protein Synthesis

2. Anabolism Anabolism (add)
Large molecules are synthesized from smaller molecules
Dehydration Synthesis – H2O is released when bonds are formed
Connects monosaccharides to form polysaccharides
Connects fatty acids to glycerol
Joins nucleotides together
Joins amino acids together = peptide bonds

3. Catabolism Catabolism (cut) Reverse of anabolism
Large molecules are broken down into smaller molecules
Hydrolysis reaction – requires H2O to break molecules
Breaks down polysaccharides into monosaccharides & disaccharides
Removes fatty acids from glycerol
Breaks down polypeptides into amino acids
Breaks down nucleic acids into nucleotides

5. Requirements for reactions
Activation energy
Energy needed to start a reaction-may be heat
Enzymes
Characteristics of enzymes
Almost always proteins
Catalyze (speed up) reactions
Reusable-not consumed by reaction
Anabolic & catabolic reactions require different enzymes
Specificity- each enzyme acts only on one molecule or substance
End in ___ase
Examples:
Lipase digests lipids
Protease digests proteins

7. Metabolic Pathway

8. Energy Energy = capacity to change something, or to do work
Examples of energy: heat, sound, light, electrical, chemical, mechanical
Energy cannot be created or destroyed. Only changed or transferred

9. Adenosine Triphosphate (ATP)
Currency of energy for cells
Nucleotide with 3 high energy phosphate bonds
Phosphate bond can be broken, releasing energy for cell
• Hydrolysis reaction releases Phosphate & transfers energy
• Product = Adenosine Diphosphate (ADP)

10. IMPORTANT PROCESS Cellular Respiration
Transfer of energy from chemical bonds of molecules to make available for cellular use
Oxidation reaction- controlled burning of molecules. Chemical bonds are broken releasing energy. Energy is used by cells.

11. Through CELLULAR RESPIRATION
Phosphate bond can be added to ADP to reuse ATP
Phosphorylation = adding phosphate to ADP
Requires energy to add Phosphate to ADP
Makes ATP reusable

12. Phosphorylation: ADP + Phosphate + Energy → ATP
Hydrolysis: ATP → ATP + Phosphate + Energy

13. Cellular Respiration Anaerobic Aerobic Does not require Oxygen
Makes only little energy (ATP)
Aerobic
Requires Oxygen
Makes more energy (ATP)

14. Steps of Respiration Glycolysis Conversion of pyruvate into Acetyl CoA
Citric Acid Cycle
Electron Transport Chain
What you’ll need to know:
The order they occur
Does it require oxygen?
Where is the reaction?
What do you start with and what do you end with in each reaction step
Which one creates the most ATP

15. Electron Carrier Molecules
NAD H: → NADH: + H (NADH: carries electrons)
FADH2
FAD H: → FADH2: (FADH2: carries electrons)
NADH & FADH2 carry electrons from metabolic reactions to electron transport chain

16. 1.Glycolysis Breaking of glucose Occurs in cytosol Anaerobic Yields:
2 ATP (net gain)
1 NADH molecule
2 Pyruvic Acids

18. 2. Synthesis of Acetyl CoA
Aerobic Reaction
Occurs within Mitochondria
Primes 3 Carbon Pyruvic Acid for Citric Acid Cycle
Reaction
3 Carbon Pyruvic Acid is decomposed into 2 Carbon Acetic Acid
Releases 1 CO2 molecule as waste
Releases 1 NADH molecule (carries 2 electrons to ETC)
Acetic Acid synthesizes with Coenzyme A (CoA) → Acetyl CoA
Acetyl CoA = substrate for Citric Acid Cycle

20. 3. Citric Acid Cycle or Kreb Cycle
Aerobic Reaction
Occurs within Mitochondria
Begins & ends with Oxaloacetic Acid
8-9 total reactions involved
Reaction
Oxaloacetic Acid (4 Carbon) + Acetyl CoA (2 Carbon) → Citric Acid (6 Carbon)
Citric Acid is converted to new Oxaloacetic Acid in a series of reactions
Oxaloacetic Acid is used in the next Citric Acid cycle
Yields
2 CO2 waste
1 ATP
3 NADH
1 FADH2
3 NADH + 1 FADH2 = carries 8 electrons to electron transport chain

22. 4. Electron Transport Chain
Occurs on inner mitochondrial membrane
Cristae = folding of inner membrane
Requires Oxygen as final electron acceptor
Involves 4 Proteins
3 Transport Chain Complex Proteins
Powered by e- transfer from NADH or FADH2
Uses energy from e- transfer to power ATP Synthase
ATP synthase
Enzyme
Converts ADP + Phosphate → ATP
Obtains energy from Transport Chain Complexes

24. Protein Synthesis DNA →transcription→ RNA → translation → Proteins

25. 4 Nitrogenous bases Purines: Adenine (A) Guinine (G)
Pyrimidines: Thymine (T) Cytosine (C)
Complimentary Base Pairs
A pairs with T
C pairs with G

27. Creates a copy of DNA molecule Occurs within Nucleus
DNA Replication
Creates a copy of DNA molecule
Occurs within Nucleus
DNA must unwind & separate
Catalyzed by DNA polymerase
DNA polymerase uses one strand of DNA as template & adds a new 2nd DNA strand
Semiconservative = half of replicated DNA is new, half is original DNA
Steps
H bonds break & DNA strands separate
DNA Polymerase adds new DNA strand to template
Yields 2 new DNA strands from 1

29. Ribonucleic Acid (RNA)
Single Stranded
Bases:
Adenine (A) Uracil (U)
Cytosine (C) Guinine (G)
Uracil Replaces Thymine.
A & U are Complimentary base pairs

30. Transcription DNA→RNA
Messenger RNA (mRNA) is transcribed from DNA
Steps
Hydrogen bonds of DNA break & strands separate
RNA Polymerase builds mRNA using DNA as template
mRNA transcript is transported to ribosomes in cytoplasm
Video

32. Codon = 3 bases code for 1 amino acid
mRNA transcript
Begins with AUG
Codon = 3 bases code for 1 amino acid
GGG = glycine
AUG = methionine

33. Translation mRNA→protein
Occurs on ribosomes in cytosol
Ribosome = ribosomal RNA + protein
Transfer RNA (tRNA) carries amino acids to mRNA on ribosomes
Anticodons on tRNA bind to codons on mRNA
Sequence of codons on mRNA determines amino acid sequence
Ribosomes link amino acids together by peptide bonds
tRNA releases amino acid & picks up another amino acid
Video