Biology

Genetics

Replication

Origin of replication: sequences of
nucleotides in the DNA that are rich in AT bases because A and T only have 2 hydrogen bonds hence it's easier to break the bonds.

Helicase breaks the
hydrogen bonds, so
double helix can Separate

Topoisomerase:
Relieves the strain
or tension of the
strands so the rep.
fork won't break

Primase
creates an
RNA primer
that goes in
the replication
bubble

DNA pol III
synthesizes the new
polymer of DNA

Then DNA Pol I
replaces the RNA primers
with DNA nucleotides

synthesizes in 5' to 3'
direction; adds nucleotides
in 3' end. Needs and OH
group @ 3' end to replicate

Ligase Seals all
the gaps/fragments
by joining nucleotides
with Phosphodiester
Bonds

SSB: prevents
the DNA helix
from forming
again after
helicase forms
the bubble.

PCR: Replication in LABS.
DNA is used as a Primer and
instead of DNA pol II, Taq Pol
is used.

Transcription

Promoter sequence of
nucleotides where RNA
pol binds to start transcription
in prokaryotes.

RNA pol binds to promoter;
synthesize RNA in 5' to 3'.
The product is mRNA

In eukaryotes, Trnascription factors,
bind to the promoter(TATA Box), then
which makes RNA pol III to attacth to
promoter= Transcription Initiation Complex. This synthesize pre-mRNA

Then a Poly-A signal of AAUU
makes ribonuclease cut pre-mRNA
to stop transcribing.

A cap( Guanini+ 3 Phosphate)
is added to the 5' end.

Poly A polymerase adds A's
on 3' end which becomes
the poly A tail.

After synthesis of
pre-mRNA. it's time
for RNA processing.

Eukaryotic genes are
split into segments:
introns inegrated among
exons. In RNA spicing
introns are removed by
spliceosome. This allows
for alternative splicing.

Translation

First, small
ribosomal subunit binds
to cap and recognizes the
start codon on the mRNA; Then, the big
ribosomal unic comes and
also binds. This occurs @
cytoplasm

Then tRNA synthase attaches
to tRNA. Then the tRNA comes
attaches to the p site on the big
ribosomal unit.

Then another tRNA
comes on A site. The
1st tRNA on P site moves
to E site and leaves. While
the 2nd moves to P site
forming a peptide pond is
formed btwn the amino acid
on P site

This continues till we
see a stop codon; a
stop codon means stop
translating.

With the the help of
release factors, everything
dissociates and.

Depending on the signal,
the polypeptide will stay
to free ribosomes and go
to certain organelles like
mitochondria; Or it will go
to bound ribosomes/ER due
to the signal

The start codon
for Prokaryotes
is f- Met; while in
eukaryotes is
Met

Mutations: Error
in DNA when a gene
is altered or changed
which changes the
genetic message

Silent Mutation:
a change in base;
but doesn't change
the amino acid

Missense Mutation:
Changes Amino Acid

Nonsense Mutation:
Stops translation really
early.

FrameShift Mutation:
Adding or deleting a
base which creates
a shift in the mRNA;
However, if 3 are added
or deleted that doesn't
change. Since one codon
has 3 amino acids

Cells

prokaryotic cells: most are unicellular and have circular DNA

Bacteria: most typically unicellular and contain peptidoglycan plasma membranes

archae bacteria: it can live in harsh conditions

Extremophiles: bacteria that can live in extreme conditions.

Thermophiles: bacteria that can live in very hot environments, such as volcanoes.

Acidophiles: bacteria that can live in very acidic environments, like sulfur geysers

Halophiles: bacteria that can live in extremely salty environments; for example salt lakes.

Endospore: prokaryotes form them when living in harsh condition that can't really thrive in them.

Endosymbiotic Theory. Theory that explains why the mitochondria and chloroplast have circular DNA and double membrane. They were engulfed by a 'host' cell that now helps and be came dependent on each other to function.

Eukaryotic Cells

unicellular

mutlicelluar

animal

plant

Photosynthesis

Light reactions

Photosystem II

Photophosphorylation:
ATP is made

Photosystem I

NADPH COMPLEX: makes NADPH

Calvin Cycle

Carbon Fixation:
CO2 IS FIXED INTO 3C

Reduction:
6 ATP AND 6 NADH are used, 1 G3P Molecule is used

Regeneration:
3 ATP are used

Glucose is made

Transduction and Communication

Cell Junctions

Plasmodesmata

microscopic channels which traverse the cell walls of plant cells and some algal cells, enabling transport and communication between them

Gap

Allow the exchange of ions, second messengers, and small metabolites between adjacent cells

Desmosome

Intercellular junctions that provide strong adhesion between cells

Tight

Where membranes of 2 cells join forming a barrier virtually impermeable to fluid.

Cell signaling: Communication
that governs basic activities of
cells and cordinates cell actions

Local

Synaptic: A nerve
cell releases neurotransmitter
molecules into synapse

Long Distance

Endocrine: specialized
endocrine cells secrete
hormones into body fluids
Hormone travels in bloodstream
but a target cell specifically binds to hormone

Ion Channels

A gate opening or
closing the channel
when receptor changes shape

A ligand binds to receptor and
the channel opens, ions flow
through the channel. When ligand
dissociates from receptor, the channel closes

GPCR

Reception

Ligand binds to GPCR
this causes the G-protein
to attach to GPCR

Then, G protein
replaces GDP w/ GTP

Transduction

G protein w/
GTP binds to
enzyme, Adenyl Cyclase

This activated Adenyl Cyclase
converts ATP to cAMP

CAMP activates protein Kinase A
The protein kinase A adds a phosphate
to another protein= phoshphorylation cascade

This amplifies a signal to Transcription Factors

Response

Transcription
Factors finish
the cellular
response

Tyrosine-Kinase
Reception

2 signalling molecule
bind to 2 receptor which
causes the receptor to
form a dimer

The activate Tyrosine
on both Receptors add
phosphates to another

Now, the TKR binds
to relay proteins

This triggers
transduction
leading to celllular Response

Intracellular Reception

The receptors are
found inside the cell

The hydrophobic molecules
like hormones pass the
membrane and bind to
receptor inside the cell

The hormone-receptor
complex enters nucleus
and does it's pathways

Chemistry of Life

Energy

endergonic-absorption of energy

Photosynthesis

Light-dependent reactions

ATP

NADH

Calvin cycle

Glucose

exergonic-release of energy

cellular respiration

Glycolysis

2 pyruvate

2 NADH

2 ATP

Krebs cycle

6 NADH

2 ATP

2 FADH

electron transport

Water

34 ATP

NAD and FAD

Functional Groups

Hydroxyl

OH

Carboxyl

C-OH

Carbonyl

C-O

Sulfhydryl

S-H

Phosphate

P-OH

Amino

NH3

Solutions/Molarity

DNA: the
genetic
material
that gets
replicated

Hershey&Chase Experiment:
Concluded that DNA is the
Genetic Material that gets
transferred from one to other

Messelson-Stahl Experiment:
Aim was to find which model
of DNA Replication is correct

Conservative: keeps
the original stand and
creates a new strand

Semiconservative:
Produces both old
and new; each DNA strand contains
once complete old and new
strand. THE CORRECT MODEL

In the experiment
after centrifugation
We see a band at the
middle(Hybrid density)
and at top(light density)
*EXACTLY LIKE THE
SEMICONSERVATIVE
MODEL*

Bio Molecules

Nucleic acids

Nucleotide

Phosphodiester bond

A, G, C, T

DNA

Nucleoside

Sugar and a Base

Polysaccharides: sugars, carbohydrates. They have Glycosidic linkages. Alpha 1-4, Beta 1-4, 1-6.

Monosaccharides

Glucose

Fructose

Galactose

Lipids

Glycerol

Fatty acids

Saturated

Unsaturated

Cis

Trans

Mitosis

Replicates all chromosomes into duplicate daughter cells

Somatic Cells: identical to all of parent's genome/DNA

Meiosis

replicates 4 chromosomes into halpoid daughter cells

Gamete Cells: a reproduction cell that hold's half a parent's genome

sperm

egg

organelles

peroxisomes: dehydronate hydrogen perioxide into water and o2 through enzymes

Endoplasmic retiuculm:

SMOOTH ER: detoxifies cell, adds

ROUGH ER: protein secrete cells, and packages into transport vesicles for export.

Nucleus: controls cells activites, it holds genetic material. Replications and transcription happens here.

Nucleolus: ribosomes and rRNA are made.

Golgi Apparatus: modifies proteins and lipids, process materials to be removed from cell, packages products for transport.

Plasma membrane: regulates what goes inside and ouside the cell. It serves as a boundary

Extra Cellular Matrix: In Eukaryotes
a network of proteins and carbohydrates that binds cells together.
Surrounds and supports the cell.
regulates cell activities.
lattice for cell movement

Membrane Proteins

Active transport:
Low to high concentration with the help of a membrane protein and input of energy.

Passive transport

Diffusion:
high to low concentration, nonpolar molecules can pass through

Facilitated diffusion:
high to low concentration with the help of a membrane protein.

Osmosi:
when H2O moves over to balance solutes that cannot pass the cell membrane.

Cytosol:

Cytoskeleton: main functin is to help transport and maintain shape of cell.

Mircotubulin

Made up of alpha and beta-tubulin.

It helps line up Chromosomes during mitosis and Meiosis

Maintains Shape of cell

Helps transport vesicles

Cell motiiity

Actin Filaments

made up of actin

Along with Mysoin(enzyme), it creates muscle contractions.

Maintain cell shape

Cytoplasmic streaming

Cell Divison:
it helps aid in dividing the cell when the cleavage furrow occurs.

Changes in cell shape

cell motility

Intermediate filaments

made up of multiple proteins. (ex: kinases)

Maintains cell shape

anchorage of nucleus and certain other organelles

Formation of nuclear lamina

Ribosomes: make proteins, translate mRNA.

free

make proteins

bound

Chloroplast:

Vacuole: holds water and stores in cell.

Contractile Vacuole: contracts depending on the molarity of the solution outside of the cell.

Mitochondria: It generates, breaks down glucoses to produce ATP, energy for the cell. It also contains a percentage of DNA as it has circular DNA. It has a double membrane in order to increase surface area for reactions happening in Cellular respiration

Lysosomes: uses enzymes to break down macromolecules, waste, and recycle waste.

cell wall: supports and protects cell, and allows molecules in such as water and O2.

Pilli: where bacteria exchange DNA (bacterial sex)

Flagellum: it helps move the cells.

Capsule: only in bacteria. It protects cell from getting caught by immune cells

Cilia: in Eukaryotes and help move the cell. Very small on the outside of plasma membrane.

Bonds

Hydrogen bonds

NH3

CHCl3

Ionic

NaCl

Covalent

Polar

H2O

Nonpolar

CH4

Gene expression:
the process by
which DNA directs
synthesis of proteins;
flow of information
from gene to protein.

pH

acidic

Pepsin

basic

Bleach

GTP is hydrolyzed durign
formation of initian complex
as ribosomal subunits bind
to mRNA.

Also when translation
stops, energy is needed to
dissociate everything w/
help of release factors

Miller Urey Experiment

Set up of a closed system to mimic conditions that existaed on early Earth.

Protein Structure

Quarternsry

Number and arrangement of multiple folded protein subunits in a multi-subunit complex

Primary

Sequence of amino acids in the polypeptide chain

Secondary

When the polypeptide chains fold into regular structures like the beta sheets, alpha helix, turns, or loops

Tertiary

Hydrogen-bonds between different side chain groups

Cancer:
Results from genetic changes
that affect cell cycle control

Proto-oncogenes code
for proteins that stimulate
normal cell growth and
divison

An oncogene arises
from a genetic change that leads
to increase in proto-oncogene's
protein product or in the activity
of each protein molecule

Movement of DNA within the GENOME

Amplification of Proto-oncogene

Poing mutations in a control elements

Tumor-supressor genes:
encodes a protein that
inhibits abnormal cell division

Mutation that reduces
the activity of its protein
product may lead to
excessive cell division and cancer

Chemical Evolution Hypothesis

The formation of complex organic molecules from simple inorganic molecules through chemical reactions in the oceans during the early history of the Earth.

Excessive cell divison

Proto-oncogenes &
tumor-supressor genes
encode components of
growth-inhibiting
signalling pathways

Hyperactive Ras Protein
issues signals on its own
whether or not growth
factor is bound to the receptor

Mutation in the p53
cannot inhibit the cell
cycle-pathway

Tonicity

Hypertonic

Where the concentration of solutes is greater outside the cell than inside it

Flaccid

Cell becomes shriveled

Plasmolyzed

The cytosol and plasma membrane shrinks because H2O is coming out of the cell

Hypotonic

A solutions that has less salt and more solute and more water than another solution

Lysed

More H2O is coming in than going out so Cell can burst, become lysed.

Turgid

More H2O is coming in than going out.

Isotonic

Where concentration of the solutes is the same both inside and outside of the cell

Normal

H2O is coming in and out constantly creating an equilibrium.

Flaccid

H2O is coming in and out of the cell, but it's not the normal state for plant cells because then they don't retain water that is needs to support their functions.

Proteins

Enzymes

Amino Acids

Polar

OH

Nonpolar

CH3

Zwitterion

Dispersive: produces molecules
with old and new DNA integrated
along each strand

Floating topic

Cellular respiration:
MAIN PURPOSE IS TO MAKE ATP FROM GLUCOSE, glucose molecules go through a serious of reaction to amplify the energy made.

Gycolyosis: one glucose molecule is broken down on 10 several different steps, in step 1, 1 ATP is used, step 3, 1 ATP is used, Step 6, 2 NADH is made, Step 7, 2 ATP is made, and Step 10, 2 ATP and 2 pyruvate. A net total: 2 ATP, 2 NADH, anf 2 pyruvate. IN CYTOSOL

Krebs cycle:
main purpose is to make NADH AND FADH, a net total 6 NADH, 2 ATP, snd 2 FADH. IN INNER-MEMBRANE OF MITOCHONDRIA

Oxidative phosphorylation:
26-28 ATP. IN MITOCHONDRIA MATRIX

Electron Transport Chain: Electrons are transported through out protein complex I, III, & IV. NADH AND FADH2 are used.

Chemiosmosis:
Protein complexes are pumping H+ ions across the membrane to create a concentration gradient, in order for H+ ions to go through ATP synthase to make ATP.

anaerobic repspiration

Fermentation

Lactic acid

ethanol

ATP production: 30-32 ATP

Floating topic

NADPH AND ATP ARE MADE