(EN)Lecture 1 - Introduction - ocw.nctu.edu.twocw.nctu.edu.tw/course/bioch051/bioch051_L1.pdf · 3Chapter 2 The Matrix of Life ... • Biochemistry is the branch of science that seeks

國立交通大學生物科技學系蘭宜錚老師 1

Lecture 1Introduction & Scope of Biochemistry

Chapter 1, Biochemistry 4th edition, Mathews, Van Holde, Appling, Anthony‐Cahill. Pearson ISBN:978‐0‐13‐800464‐4

DBT2117: Biochemistry (I) (English course)

Week Topics

1 Chapter 1 The Scope of Biochemistry

2 Chapter 1 The Scope of Biochemistry

3 Chapter 2 The Matrix of Life, Chapter 3 The Energetics of Life

4 Chapter 4 Nucleic Acids

5 Chapter 4 Nucleic Acids

6 Exam 1

Course Syllabus


Week Topics

7 Chapter 5 Introduction to Proteins

8Chapter 5 Introduction to Proteins & Chapter 6 The Three‐Dimensional Structure of Proteins

9 Chapter 6 The Three‐Dimensional Structure of Proteins

10 Chapter 7 Protein Function and Evolution

11 Chapter 8 Contractile Proteins and Molecular Motors

12 Exam 2

Course Syllabus

Week Topics

13 Chapter 9 Carbohydrates: Sugars, Saccharides, Glycans

14 Chapter 10 Lipids, Membranes, and Cellular Transport

15 Chapter 10 Lipids, Membranes, and Cellular Transport

16 Chapter 11 Enzymes: Biological Catalysts

17 Chapter 12 Chemical Logic of Metabolism

18 Exam 3

Course Syllabus


Grading policy

• Final grade will be the average of three exams

• We will review the exam in details.• Any mistakes in grading must be submitted for regrade during the review session• No regrades will be considered after the review session

• Curves in the final grade will follow the university’s rule on undergraduate course having anpassing average score of 78 ± 3.

Introduction – What is biochemistry?

• Biochemistry is the branch of science that seeks to describe the structure, organization, andfunctions of living matter in molecular terms.

• The GOAL of biochemistry is to understand life at the molecular level.• The Chemistry of life


Biochemistry can be divided into three principal areas:

1. The structural chemistry of the components of living matter and relationships ofbiological function to chemical structure.

2. Metabolism, the totality of chemical reactions that occur in living matter.(Biochemistry II)

3. Genetic biochemistry, the chemistry of processes and substances that store and transmitbiological information. (Molecular genetics)

•This third area is also the province of molecular genetics, a field that seeks to understandheredity and the expression of genetic information in molecular terms.

Introduction – What is biochemistry?

4 major biomolecules

• This course will discuss in details the properties and functions of the major biomolecules

• 4 major classes of biomolecules:

• Carbohydrates (energy storage, structure supports)

• Proteins (Enzymes, structural supports)

• Lipids (Fats, cellular membranes)

• Nucleic acids (DNA, RNA)


Carbohydrates (energy storage, structure supports)

Carbohydrates

Proteins

Proteins (Enzymes, structural supports, many more diverse functions)


Lipids

Lipids (Fats, cellular membranes, hormones)

Nucleic acids

Nucleic acids (DNA, RNA)


Elements in life

Carbon, Hydrogen, Oxygen, Nitrogen are the major ingredients of life (DNA/RNA, proteins, sugars, fats..)

Phosphorus is in found DNA (as well as many cellular metabolites‐chemicals in life)

Sulfur is found in proteins.

Bonding ability of carbon: why carbon is the most significant element

Carbon, Oxygen, Hydrogen, & Nitrogen together make up more than 99% of most cells.

Hydrogen: can only form 1 bondOxygen: 1, or 2 bondsNitrogen: 1, 2, or 3 bondsCarbon: 1, 2, 3, or 4 bonds.

Some common bonds found in biology are shown in the right.

Covalent bonds


Common functional groups in biochemistry

Carbon functional groups Oxygen functional groups

(these are less frequent)

Functional groups are groups of atoms added to carbon skeleton that have specific properties.


Nitrogen functional groups

Sulfur functional groups

Phosphur functional groups



Most biomolecules have multiple functional groups within them.

For example, Acetyl‐CoA (a common metabolite used to both synthesize lipids and respiration)

*note: Metabolites = chemical compounds found in the cell

Chirality

Biochemistry is extremely structure‐oriented

Molecules with the same empirical formula may have different chirality – Enantiomers, Diastereomers, etc. are DIFFERENT compounds


Biological macromolecules and their monomers

Macromolecule Monomer Linkage

• Protein amino acid peptide(amide)

• Polysaccharide monosaccharide glycoside(ether)

• Nucleic acids nucleotide phosphodiester

• Lipids (triglycerides) fatty acids ester

Many biomolecules are macromolecules (polymers of high molecular weight)

Below is a chart of the common macromolecules found in life:


Cellulose is a major component of plant biomass. It is a polymer of glucose (a sugar)

Looking at glucose in its linear form… what functional groups does it have?



Besides the Adenine group, what other groups are present in dAMP (a monomer of DNA)?

How about dATP (the real building block of DNA)?


A peptide bond is an amide bond between 2 amino acids

In addition to the phenol functionality, what other functional groups are present?

phenol


Bonding and resonance structures

Resonance structure = a way to describe the delocalization of electrons within a molecule.

The electrons (red) are evenly distributed among the two Oxygen atoms. This helps to provide stability for the molecule

The more “positions” that electrons can move to, the more resonance stabilization the molecule has.

Reactivity & Stability

Generally speaking, the more stable a chemical/compound, the less reactive it is.

If a compound undergoes a reaction can generate a more stable product, then that compoundis more reactive than its product

ATP is a cellular “energy carrier” used to drive chemical reactions

H2O

Lots of negative charges = repulsion ΔG'° is ‐30.5 kJ/mol


Free energy and direction of chemical equilibrium

• The Gibbs Free Energy is:

where ([C]c[D]d)/([A]a[B]b) we call Q the reaction quotientProducts / substrates

• At equilibrium, Q = Keq, and ΔG = 0,therefore‐ ΔGo = RT ln Keq

aA + bB cC + dD

For a reaction of:

Acid dissociation constant

Same idea applies also to acid dissociation (proton moving from one molecule to H2O)

Any acid dissociation can be viewed as this:

When working under dilute conditions (Water concentration doesn’t change)

Since this number could be quite large (or small) depending on the compound, its easier to use:

The lower the pKa, the more likely that proton (H+) is removed from this compound

Here H+ = H3O+

How easy is the H+ removed from the compound (HA)? ‐ That depends on how STABLE its conjugate base (A‐) is


pKa does not only apply to “acids”

Every hydrogen (proton) on a compound has a pKa

Understanding this concept is very important for understanding enzymes and enzyme mechanism

Increasin

g stability after d

eprotonatio

nDecreasin

g stability

Chemical evolution: Miller–Urey experiment

"Miller‐Urey experiment‐en" by GYassineMrabetTalk✉This vector image was created with Inkscape.iThesource code of this SVG is valid. ‐ Own work from Image:MUexperiment.png.. Licensed under CC BY‐SA 3.0 via Commons ‐ https://commons.wikimedia.org/wiki/File:Miller‐Urey_experiment‐en.svg#/media/File:Miller‐Urey_experiment‐en.svg

To simulate abiotic (nonbiological) origin of biomolecules, Stanley Miller & Harold Urey in 1953 observed the production of organic compounds, some amino acids, hydroxyacids, etc, from their reaction set up shown to the left


Central Dogma

Current understanding of central dogma

https://commons.wikimedia.org/wiki/File:Extended_Central_Dogma_with_Enzymes.jpg


Which came first? Protein or DNA?

The current understanding is that most likely RNA came first. RNA is both capable of maintaining information AND catalysis

(even capable of forming peptide bonds)

Through evolution, eventually catalysis function went to proteins (because proteins are more versatile), and information conservation went to DNA (because DNA is more stable)

Possible “RNA world” scenario

Deoxyribonucleotide ribonucleotide(for making DNA) (for making RNA)

Sizes of cellular biomacromolecules

The DNA from one chromosome has a mass of ~20 billion Daltons

Proteinmolecules have masses of 10,000 to 1 million Daltons

1 Dalton (Da) = 1 amu = 1 g/mol


1. Program ‐ organized plan for constitution and regeneration of an organism (e.g., DNA).

2. Improvisation ‐ the ability of living matter to change the program to assure survival as thesurroundings change.

3. Compartmentalization ‐ the ability of an organism to separate itself from the environment,such as with membranes.

Koshland’s seven “pillars of life”

4. Energy ‐ living matter must create complexity in order to sustain the program and the otherpillars of life.

5. Regeneration ‐ the ability to compensate for the inevitable wear involved in maintaining aphysical state far from equilibrium.

6. Adaptability ‐ the capacity of an organism to respond to environmental changes.



7. Seclusion ‐ the metabolic processes and pathways must operate in isolation from oneanother, even though they may take place within the same compartment of a cell.


Interconnected with all seven pillars of life is the function of:

Semipermeable membranes ‐ surround cells and intracellular organelles, such as the mitochondria, maintaining

Homeostasis ‐ a condition in which the chemical composition of a biological system is held constant.

Evolution


Evolution

Documents

(EN)Lecture 1 - Introduction - ocw.nctu.edu.twocw.nctu.edu.tw/course/bioch051/bioch051_L1.pdf · 3Chapter 2 The Matrix of Life ... • Biochemistry is the branch of science that seeks