General Biology Reviewer PDF

Summary

This document provides a review of general biology concepts, particularly energy transformation in cells. It covers topics such as adenosine triphosphate (ATP), endergonic and exergonic reactions, and the role of pigments in photosynthesis. The document also touches on various types of chlorophyll and carotenoids.

Full Transcript

GENERAL BIOLOGY REVIEWER Exergonic Reaction - Catabolic Reaction,
spontaneous and or favorable chemical
ENERGY TRANSFORMATION reactions wherein the products are at low
Adenosine Triphosphate (ATP) - It is the energy level than the reactants (occur
major energy currency of the cell that without the addition of energy)
provides the energy for the most energy Energy - ability to do work (Kinetic:
consuming activities of the cell. One big energy possessed by being in
molecule that is made up of 5 smaller motion, Potential - energy stored
molecules bonded together. due to position

ATP-ADP CYCLE

Composition:
1 Adenine
1 Ribose (Sugar)
3 Phosphate Group

Adenosine Diphosphate (ADP) - a
molecule that is composed of Adenosine
and phosphates just like ATP, the only (Think of ATP as a charged battery and
difference is ADP has only 2 phosphates. ADP as a battery that needs to be charged)

ATP to ADP: It transfers energy from the
breakdown of food molecules to cell
function.

ADP to ATP: It is changed into ATP when
the phosphate group is added (P) from the
Composition:
breakdown of food
1 Adenine
1 Ribose (Sugar)
Process of ATP-ADP Cycle:
3 Phosphate Group
1. When the third phosphate group of
ATP is removed by hydrolysis (ATP
Two Types of Reaction:
+ H2O > ADP + Pi), a substantial
Endergonic Reaction - also known as
amount of free energy is released.
Anabolic reaction, nonspontaneous and
usually occur in organisms, because they
(ADP is adenosine diphosphate and Pi is
need to synthesize complex molecules such
inorganic phosphate)
as fats, amino acids, and sugars (Needs
energy input to synthesize.
When energy is… Pigment Types
Chlorophyll a - found in the chloroplast and
is the site for photosynthesis. It converts
solar energy to chemical energy. Green in
color

Structure:

2. When ATP breaks apart and
releases its energy, the now ADP
uses that energy and gains an extra
P and is recharged back to ATP (Practically the same with chlorophyll b
except for one functional group)
3. The now recharged ATP assists
activities inside the cell (powers up Chlorophyll b - reflects olive green and
all activities which needs energy) absorbs blue and orange light. Does not
participate directly in light reactions. It is
PIGMENTS present only in algae and higher plants, it
also breaks down faster than other
pigments

Structure:

Fact: The color reflected by the plants is
what we see it as, meaning plants absorb
the colors blue and red and reflects green
and yellow (Most plants we see are green
and/or yellow) Carotenoids - reflects various shades of
red, orange, and yellow while absorbing
Pigments - organic molecules built in the mainly violet, blue, and green light. It starts
thylakoid membranes of plants, selectively to appear when chlorophyll starts to break
absorb light on specific wavelengths down (Ex. Autumn leaves, ripe bell peppers)
- Some plants reflect varying colors Divided into two:
which reduces their photosynthetic - Carotenes: includes alpha-carotene,
ability but protects them from beta carotene, and lycopene
predators because animals do not - Xanthophyll: includes lutein and
see the plant as food due it being a fucoxanthin
color that is not green
Chlorophyll c - accessory pigment, brown Process of Light Dependent Stage:
in color (Brown algae)

Chlorophyll d - accessory pigment, red in
color (Brown algae)

Phycobilins - found in red algae and
cyanobacteria. It is water soluble and Light-dependent reactions involve the
present in the aqueous cytoplasm or stroma striking of light to P680 (photosystem II
of plants primary donor) and P700(photosystem I
primary donor), which results in a series of
LIGHT REACTIONS OF electron flow that drives the synthesis of
PHOTOSYNTHESIS ATP and NADPH.
Sun - the primary source of light energy on
our planet. Photosystem - consists of a number of light
harvesting complexes (LHC) surrounding a
Photosynthesis - process that converts reaction-center complex
solar energy to chemical energy. Happens
only to autotrophs (another name for Photosystem II:
plants), specifically, it occurs in the 1. Light striking photosystem II which
chloroplasts absorbs light energy and transfers it
Overview of Photosynthesis to chlorophyll a reaction center, the
center that excites two electrons
(gain energy)

Light Dependent Reaction - takes place in
thylakoid membrane and is the reason how
light energy is converted to chemical energy
(ATP and reduced NADP). Only occur when
solar energy is available
2. The “excited” electrons are ejected
from the chlorophyll a reaction
center and grabbed by the first
protein in the electron transport
chain that links the two
photosystems.

(Pigment molecules capture kinetic energy
from photons and store it as potential
energy in the chemical bonds of two
molecules, ATP and NADPH)
3. The two electrons are replaced by Photosystem I (functions as much as
electrons from water molecules that photosystem II does):
donate two electrons when it splits 1. The reactive chlorophyll molecule
into oxygen gas (O2) and two ejects electrons to an electron
protons (H+ ). carrier molecule in the second
electron transport chain in the
thylakoid membrane.

4. As the electrons continue to move in
the electron transport chain, their
energy is used to pump protons (H+) 2. The boosted electrons in
from the stroma across the photosystem I are then replaced with
membrane into the thylakoid lumen electrons passing down from the first
or space. electron transport chain from
photosystem II.
3. The second electron transport chain
passes the electrons to a molecule
of NADP+, reducing it to NADPH
(This NADPH is the electron carrier
that will reduce CO2 in the next
phase, while ATP will provide the
5. The H+ will diffuse through a protein energy)
in the thylakoid membrane called
ATP synthase. The diffusion of H+
will rotate the ATP synthase to
produce ATP

Noncyclic pathway - linear mechanism of
electron transport from photosystem II to
photosystem I, including the electron
transport chains. This is the standard
mechanism of light dependent reactions.
Ultimately, it produces NADPH and ATP
molecules
Cyclic pathway - involves only the - Phase 1 results in the formation of
photosystem I and the electron transport an unstable six-carbon molecule,
proteins. The electron chain in this pathway which spontaneously splits into two
uses the electron’s energy to move H+ into 3-PGA.
the thylakoid compartment. The resulting H+
gradient drives ATP formation, just as it
does in the noncyclic pathway

For easier understanding, please watch this
video:
2. Reduction - process involves the gain of
Photosynthesis (Light Dependent Stage) electrons from the NADPH (reduced).
https://www.youtube.com/watch?v=1D74e1 Steps:
BL_Jg - ATP and electrons donated from
NADPH reduce molecules of 3-PGA
Light Independent Stage (Calvin Cycle): into G3P.
The chloroplast is the site for both
light-dependent and light-independent
reactions. Light reactions take place in the
thylakoids while Calvin Cycle takes place in
the stroma. Energy from photons are
not directly required for the chemical
reactions to proceed. It ultimately
produces glucose, a sugar, in the fluid-filled
stroma of chloroplasts. - After the reduction process, one
phosphate group and electrons are
Three Phases of Light Independent Stage: transferred to the PGA, thus also
1. Carbon Fixation - process that involves forming ADP and NADP+. These will
incorporating carbon atoms from an return to light-dependent reactions
inorganic source into an organic molecule. for them to be reenergized.
Steps:
- The enzyme RuBisCo catalyzes the
reaction between the carbon dioxide
and the five carbon sugar RuBP
3. Regeneration - process involves Whole Process of Calvin Cycle:
regenerating RuBP.
Steps:
- For every three CO2 molecules
fixed, one G3P molecule leaves the
cycle as a product which contributes
to the formation of glucose.

- During the Calvin cycle, an input of CELLULAR RESPIRATION
three CO2 molecules will produce Cellular Respiration - process that involves
six G3P molecules. One of those the oxidation and reduction of molecules
G3P molecules will be used to to produce energy in the form of adenosine
create glucose. triphosphate (ATP).

Formula of Cellular Respiration:

- Since six CO2 molecules are
needed in photosynthesis, the
products shown above will be
doubled. Take note that two G3P
molecules (total of six carbons) are
needed to make glucose (likewise a
total of six carbons.
- The remaining ten G3P molecules
(total of 30 carbons), from six CO2
molecules that are fixed, will be
regenerated to six RuBP (likewise, a
total of 30 carbons). Cellular Respiration is divided into two:
Aerobic and Anaerobic
Flowchart:
 During glycolysis, each glucose molecule is
broken down into two pyruvate
Four Processes of Aerobic Respiration: molecules. The redox reactions also yield
1. Glycolysis ATP molecules in the process.
2. Krebs cycle
3. Electron Transport Chain Overall Glycolysis process:
4. Chemiosmosis

Reactants and Products of Cellular
Respiration:

Ten Steps of Glycolysis:
1. Phosphorylation of glucose to
glucose-6-phosphate

GLYCOLYSIS
Glycolysis - First phase of Aerobic
Respiration. It is divided into two: 2. Isomerization of glucose-6-phosphate to
- Energy-investment phase: involves fructose-6-phosphate
the use of ATP molecules.
- Energy-harvesting phase involves
the production of ATP and NADH.
3. Phosphorylation of fructose-6-phosphate 7. The phosphate released from 1,3-BPG
into fructose-1,6-bisphosphate will be picked up by ADP (adenosine
diphosphate) to form ATP. In this process,
one ATP molecule is produced for every
3-PGA.

4. The fructose-1,6-bisphosphate splits into
two molecules DHAP and G3P, which are
8. Phosphoglyceromutase transfers a
considered as isomers.
phosphate group from the third carbon of
3-PGA to its second carbon, which results in
the 2-phosphoglycerate (2-PGA).

9. 2-PGA becomes phosphoenolpyruvate
(PEP), which is accomplished by the
5. Triosephosphate isomerase catalyzed the removal of water from 2-PGA through an
transformation of DHAP into G3P. enzyme called enolase.

10. PEP releases its phosphate molecules
and are picked up by ADP to form ATP.
This process is catalyzed by pyruvate
kinase and results in the formation of
6. Oxidation and phosphorylation of G3P
pyruvate and ATP molecules. (Pyruvate
molecules
undergoes oxidation and becomes acetyl-
CoA, which enters the Krebs cycle)
Total molecular products of Glycolysis: 2. Formation of Isocitrate: the citrate is
rearranged to form an isomeric form
isocitrate by an enzyme acontinase. A water
molecule is removed from the citric acid and
then put back in another location.
3. Oxidation of isocitrate to α-ketoglutarate:
The net products of glycolysis are 2 ATP, 2 Isocitrate dehydrogenase catalyzes
NADH, and two pyruvate molecules. oxidative decarboxylation of isocitrate
to form α-ketoglutarate. In this reaction,
KREBS CYCLE generation of NADH from NAD is seen.
Krebs Cycle - It is also known as citric acid 4. Oxidation of α-ketoglutarate to
cycle or tricarboxylic cycle. Sequence of succinyl-CoA: Alpha-ketoglutarate is
reaction by which most living cell generate oxidized, carbon dioxide is removed and
energy during the process of aerobic coenzyme A is added to form the 4-carbon
respiration. Takes place in mitochondria of compound succinyl-CoA. During this
cell consuming oxygen, producing CO2 oxidation, NAD+ is reduced to NADH + H+
and converting ADP-ATP. by the enzyme alpha-ketoglutarate
dehydrogenase.
Hans Adolf Krebs - He is a German-British 5. Conversion of succinyl-CoA to succinate:
scientist who discovered the Krebs cycle in CoA is removed from succinyl-CoA to
the 1930s. produce succinate. The energy release is
used to make guanosine triphosphate
Eight steps of the Krebs Cycle: (GTP) from guanosine diphosphate (GDP)
and Pi by substrate-level phosphorylation.
6. Oxidation of succinate to fumarate:
During the oxidation of succinate to
fumarate, FAD is reduced to FADH2. The
enzyme succinate dehydrogenase catalyzes
the removal of two hydrogens
from succinate.
7. Hydration of fumarate to malate:
Reversible hydration of fumarate to L-
malate is catalyzed by fumarase (fumarate
hydratase).
8. Oxidation of malate to oxaloacetate:
Malate is oxidized to produce oxaloacetate,
the starting compound of the citric acid
cycle by malate dehydrogenase.
1. Formation of Citrate: the condensation of
acetyl CoA with oxaloacetate to form citrate,
catalyze by citrate synthase. Once
oxaloacetate is joined with acetyl CoA, a
water molecule attacks the acetyl leading to
the release of coenzyme A form the
complex.
Products of Krebs Cycle: 3. Complex 3

The series of redox reactions during the
Krebs cycle produces NADH, FADH2, CO2,
and GTP. The CO2 is released into the
environment. NADH and FADH2 are used to
produce more ATP in the electron transport
chain. GTP is used to drive chemical
reactions similar to how cells use ATP.

ELECTRON TRANSPORT CHAIN AND
CHEMIOSMOSIS
Electron transport chain - series of four
multiprotein complexes embedded in the
inner membrane of the mitochondrion where
NADH and FADH2 are oxidized to release
electrons.

ETC Process:
1. Complex 1

2. Complex 2 and Ubiquinone
4. Complex 4

5. Electron Transport Chain and Proton
Pumps
NADH and FADH2 are oxidized to release
electrons into the protein complexes.
These electrons pass through protein
complexes and cause the pumping of
hydrogen ions from the matrix to the
intermembrane space.

Chemiosmosis - involves the downhill
transport of hydrogen ions from the
intermembrane space to the matrix. This
movement provides energy to ATP synthase
to phosphorylate ADP into ATP.

Chemiosmosis Process:
ATP Synthase
- The hydrogen ions return to the
matrix through ATP synthase.
ATP Yield of of the Electron Transport Chain
and Chemiosmosis:

Net ATP yield for the whole aerobic
respiration process: