Biochemistry Lecture Transcription PDF

Summary

This document is a transcription of a lecture on biochemistry, covering topics from DNA and RNA to cell theory, enzymes, and metabolism. The lecture notes highlight the fundamental principles, scope, and key components of biochemistry.

Full Transcript

DNA - stores genetic information, can explain
diseases through hereditary
RNA - delivers it in Ribosomes
CELL THEORY - Cell is the basic unit of life
ENZYME - a type of protein (ex. Amylase,
Kinase, Lipase)
PCR - Polymerase Chain Reaction
KARY MULLIS - discovered PCR
AMINO ACID - Amine + Carboxylic Acid
(COOH)
NUCLEOTIDE - has a Phosphate group
(Pentose)
NUCLEOSIDE - has no Phosphate
RIBONUCLEIC - with OH
DEOXYRIBONUCLEIC - without OH
MONOSACCHARIDE - an Exose (there are
sugars that has 3, 4… carbons)
Plants have starch, Humans have Glycogen
BIOCHEMISTRY
FATTY ACIDS - hydro chain, stored in
adipose/adipocytes
- “The study of biochemistry shows how the
Cell is made of biomolecules
collection of inanimate molecules that
constitute living organisms interact to maintain
TWO NOTABLE BREAKTHROUGHS IN THE
and perpetuate life animated solely by the
HISTORY OF BIOCHEMISTRY
physical and chemical laws that govern the non
living universe” - LEHNINGER, Principle of
1. Discovery of enzyme’s role as catalysts for
Biochemistry
biochemical reactions
2. Discovery of DNA as the carrier of genetic
- “Biochemistry asks us how the remarkable
information
properties of living organisms arise from the
thousands of different lifeless biomolecules” -
LEHNINGER, Principle of biochemistry LIFE IS CHARACTERIZED BY:

- The systematic study of the chemicals of living 1. BIOLOGICAL DIVERSITY
systems, their organization into cells, and the
principles of their chemical interactions as 2. CHEMICAL UNITY
they participate in the process of life - Compounds that make up living system obey the
fundamental laws of chemistry - THERE ARE
- Humanity is continuously challenged to seek NO NEW PRINCIPLES
understanding of the most fundamental
processes of life at the molecular level

- BIO: Life

- CHEMISTRY: study of change in matter

- BIOCHEMISTRY: Chemical reactions
happening inside the body of a living organism BASIC SCOPE OF BIOCHEMISTRY

PROTEINS (Amino Acids) - has ENZYMES 1. BIOCHEMICAL STRUCTURES
which facilitates metabolic reactions in the
body - Chemical and 3D structures
- Physical and chemical properties
LIPIDS (Fatty Acids) - if not present, there - Interaction, organization, and coordination
will be no Phospholipids bilayer in cells - Synthesis and degradation

DNA/RNA (Nucleic Acids) - involves in central
dogma (DNA - RNA - PROTEINS)
 - SI - VILLI - BLOODSTREAM - CELL GLUCOSE
- CELL GLYCOLYSIS - ATP

ANABOLISM - building up, like Photosynthesis
(CO2 + H2O + SUNLIGHT = SUGAR)

To have anabolism, there should be catabolism

METABOLIC PATHWAYS

- Series of chemical reactions occurring within a
cell
- Metabolic pathways are linked together by a
common intermediate
- Linked metabolic pathways = metabolic network

2. METABOLISM

- Describes all chemical reactions by which
complex molecules taken into an organism are
broken down to produce energy and by which
that energy is in turn used to build up complex
molecules

- Energy production, utilization, and conservation

CATABOLISM - breaking down (Catabolic
Reaction - bigger to smaller molecules)
 - Transmission, expression, and storage of
genetic information

THE CELL

- Cellular components are made up of
biomolecules
- The turnover (biosynthesis and degradation) of
biomolecules happens inside the cell
- Biochemical reactions are taking place inside
the various cellular components
- 1 cell organisms: Bacteria, Fungi, Protist
(unicellular)
- Human: Multicellular organism (cells inside
coordinate to each other)
- To observe bacteria, use OIO in microscope
- Eukaryotic is bigger to see
- Prokaryotic came to exist first
- Organelles can have their own membrane
(coating)
- Plants have cell wall for protection
- If humans have cell wall, we will be less flexible
- Plants can do Krebs cycle, also animals because
they have mitochondria
- ETC: Electron-Transport Chain
- PLASMID - transfers genetic information from
1 bacteria to another, this is where antibiotic
resistance gene is present
- gDNA: Genomic DNA, needed to live
- DNA cannot go outside the nucleus so it
created RNA to transfer informations
- Ribosomes need RRNA
- DNA can be vulnerable due to mitosis and
meiosis, nucleus may disintegrate
- RIBOSOME SMALL UNIT - came from RRNA
- RER: Protein synthesis
- SER: Lipid synthesis
- ENDOCYTOSIS: enter of substance in cell
- EXOCYTOSIS: exit of substance in cell

WHAT IS A CELL?

- Basic building block of life
- Smallest living unit of an organism
- Capable or growth, reproduction, energy
adaptation, and response to the environment
- A cell may be an entire organism or it may be
one of billions of cells that make up an organism

3. GENETIC INFORMATION
 MAJOR FUNCTIONS:
TWO TYPES OF CELL
Synthesis and degradation of biomolecules
Selective transport of biochemical substances
Metabolism
Storage, transmission, and expression of
genetic information

PROKARYOTIC CELLS

- The earliest and most primitive forms of life on
Earth
- Simple in structure
Usually unicellular organisms
No recognizable organelles
Lack a nucleus
Has its DNA concentrated in the
nucleoid region of the cytoplasm

UNIQUE ORGANELLES

ANIMAL CELLS:
Lysosomes
Flagella

EUKARYOTIC CELLS
PLANT CELLS:
Chloroplasts (Plastids)
- Have more complex structures and intracellular Central Vacuole and Tonoplast
processes Cell Wall
- Structural features: Plasmodesmata
With distinct membrane-bound
organelles
Compartmentalization allows two
incompatible reactions to occur in a
single cell at the same time
Commonly 1000-fold greater in volume
than Prokaryotic cells

ORGANELLES

- Specialized subunits within a eukaryotic cell
- Has its own specific function
- Usually separately enclosed within its own
membrane
- Suspended in thick intracellular fluid (Cytosol)
BIOMOLECULES
 FUNCTIONS OF CARBOHYDRATES

Stores and provides energy (glycogen, starch,
monosaccharides)
Structural integrity (cellulose in plant cell
walls)
As conjugates to other macromolecules
(glycoproteins)
Component of nucleic acids (ribose in RNA and
deoxyribose in DNA)

NUCLEIC ACIDS
PROTEINS

- Chemical carriers of genetic information
- Most abundant biomolecule in the cell (15%) - Biopolymers of nucleotides linked by
- Most varied and most diverse in terms of Phosphodiester bond
structure and function - TWO FORMS:
DNA (2-deoxyribonucleic acid)
FUNCTIONS OF PROTEINS RNA (ribonucleic acid)

Establishment and maintenance of structure
(collagen, histones in DNA)
Transport (hemoglobin, transferrin)
Control and regulation (hormones like insulin
and somatotropin)
Defense and immunity (immunoglobulin)

FUNCTIONS OF PROTEINS

Catalysis (enzymes)
Movement (myosin in muscles)
Storage (ferritin)

CARBOHYDRATES

- most abundant biomolecule on Earth
 AMINO ACIDS

GENERAL STRUCTURE

FUNCTIONS OF NUCLEOTIDES

Energy currency in metabolic processes (ATP,
ADP)
Structural components of cofactors and
coenzymes (NADH, FADH2)
As building blocks for molecular repositories of
genetic information (DNA and RNA)

LIPIDS

At neutral pH (pH = 7)
- Heterogenous in structure
Predominantly dipolar or Zwitterions
- Exhibits low solubility/insolubility in water and
solubility in organic solvents
- Have very large hydrophobic (non-polar)
portions

FUNCTIONS OF LIPIDS

As fuel for metabolic processes (fats and oils)
Building block and nutrients/vitamins
(phospholipids, glycolipids, cholesterol, Vitamins
A, D, E, K)
Insulation (fats and oils)
Protective coverings (cutin and suberin)

ZWITTERIONIC FORM

Explains the physical properties of amino acids
- Crystalline solid
- Very high melting point
- High solubility in water
 Except for glycine, amino acids have an
BASED ON STRUCTURE (functional groups in the
asymmetric carbon side chain)
- Four different groups of atoms bonded to the
a-carbon
Alkyl/Aliphatic
- Chiral molecule
Sulfur-containing
- Optically active
Alcohols
Aromatics
STEREOCHEMISTRY Acidic
Basic
Amino acids can exist as a pair of Enantiomers Amides

ALKYL/ALIPHATIC

Stabilize proteins through hydrophobic
interaction

D- and L- are absolute configurations around
the chiral carbon

D and L configuration:

Amino acids residues naturally occurring
protein molecules are exclusively L-isomers Proline limits structural flexibility because of
D-amino acids are found only in a few peptides its rigid ring
(eg. bacteria cell wall and some antibiotics)
SULFUR-CONTAINING

CLASSIFYING STD. AMINO ACIDS

BASED ON NUTRITIONAL REQUIREMENT

ESSENTIAL AMINO ACIDS
- Must be supplied in the diet since they cannot Methionine is very hydrophobic
be synthesized by the human body Cysteine is responsible for disulfide bridges in
- Tryptophan, Valine, Threonine, Isoleucine, proteins
Leucine, Lysine, Phenylalanine, Methionine,
Histidine, Arginine ALCOHOLS

NON-ESSENTIAL AMINO ACIDS
- Can be synthesized by the body
 ACIDIC

Have -COOH side chains which are ionized at
pH 7
Negatively charged

Stabilize protein and interact with the aqueous
environment through hydrogen bonding

AROMATICS

BASIC

Stabilize protein through hydrophobic
Have -NH2 side chains which are protonated at
interaction
pH 7; positively charged
Tyr (-OH) can participate in H-bonding
Trp and Tyr account for absorbance of light
exhibited by most proteins at 280 nm AMIDES

Absorbance at 280 nm is used for
spectrophotometric determination of protein
concentration
Amide counterparts of acidic amino acids
Can stabilize protein by hydrogen bonding

SOME UNCOMMON AMINO ACIDS
 PEPTIDES

FORMATION OF A PEPTIDE BOND

Peptide bonds are formed by condensation
reaction of amino acids

SOME TERMINOLOGIES

PEPTIDES/OLIGOPEPTIDES
- Continuous chains of a few amino acids usually
not more than 50 residues

POLYPEPTIDES
- Amino acid chains with MW molecule becomes more stable
- Accumulation of misfolded proteins are the
causes of some diseases:

1. Alzheimer’s
2. Parkinson’s
3. Mad Cow
4. Senile Dementia

PROTEIN DENATURATION

- Alteration of the secondary, tertiary, and
quaternary structure of proteins
- The primary structure of the protein is
preserved (peptide bond is not easily
disrupted)
- May result into reduction or complete loss of
biological activity of the protein
- Accomplished by the following agents of
denaturation

Physical Agents: heat, extremes of pH
Chemical Agents:

1. Strong acids and bases
2. Heavy metal cations (Pb2+ , Hg2+)
3. Alkaloidal reagents (trichloroacetic acid)
4. Organic solvents (ethanol, acetone)