Gen-bio-reviewer.pdf

Transcript

Gen-bio reviewer

Module 1 — cell theory, structure and function

Cell Theory
1839 by Schleiden & Schwann
foundation of modern biology.
The CELL THEORY, or cell doctrine, states that all organisms are composed of similar units of
organization, called cells.
1. All living things are composed of cells
2. Cells are the basic units of structure and function in living things
3. All cells are produced from other cells

Modern Tenets of the Cell Theory
all known living things are made up of cells.
the cell is structural & functional unit of all living things
all cells come from pre-existing cells by division
cells contains hereditary information which is passed from cell to cell during cell division
All cells are basically the same in chemical composition.
all energy flow (metabolism & biochemistry) of life occurs within cells.

Prokaryotes vs Eukaryotes
Prokaryotes Eukaryotes
do not have membrane bound nucleus membrane bound nucleus
DNA- bundled together in the nucleoid nucleus- where eukaryotes stores their
region genetic information
Not stored within a membrane bound
nucleus

Parts of the Cell
1. Cell membrane
2. Nucleus
3. Cytoplasm

The Cell Membrane
– Also known as the Cell membrane/cytoplasmic membrane
– A biological membrane that separates the interior of a cell from its outside environment
 – To protect cell from its surroundings
– composed of
phospholipid bilayer ( with embedded proteins)
plasma membrane
1. regulates the movement of substances in and out of the cell
2. must be very flexible to allow certain cells ( red and white blood cells) to change shape as
they pass through narrow capillaries

The Organelles
– Carries out unique functions inside the cell

Membranous Non-membranous
Mitochondria Ribosomes
Plastids Cytoskeleton
Golgi apparatus Nucleolus
Endoplasmic reticulum Centrosome

The compartmentalization of the cell into membrane-bound organelles
– allows conflicting functions (i.e., synthesis vs. breakdown) and several cellular activities to
occur simultaneously without interference from each other
– separates the DNA material of the nucleus, mitochondria, and chloroplast
– increases the surface area-volume ratio of the cell

Plans cell vs Animal cell
Plant Animal
Have plastids ( chloroplast ) Do not have plastids
Have a cell wall ( made of cellulose ) Do not have cell wall
Have a large central vacuole Have a small temporary vacuole ( in any)
May have plasmodesmata Do not have plasmodesmata
Do not have centrioles Have paired centrioles with centrosome
Do not have cholesterol in a cell Have cholesterol in the cell membrane
membrane
Store excess glucose as starch Store excess glucose as glycogen
Generally have fixed, regular shape Generally have an amorphous shape
Endomembrane System, Mitochondria, Chloroplasts, Cytoskeleton, and Extracellular
Components
– The endomembrane system (endo- = “within”)
– a group of membranes and organelles in eukaryotic cells that works together to modify,
package, and transport lipids and proteins.
– It includes a variety of organelles

Parts of the endomembrane syatemy. Endoplasmic reticulum
– rough er
– smooth er. Golgi apparatus. Lysosomes. vacuoles. Peroxisomes

endoplasmic reticulum
– modification of proteins and the synthesis of lipids.
rough ER
– gets its name from the bumpy ribosomes attached to its cytoplasmic surface
smooth ER
– continuous with the rough er but has few or more ribosomes on its cytoplasmic surface
golgi appratarus
– sorting, tagging, packaging, and distribution of lipids and proteins occur
lysosomes
– acts as the organelle-recycling facility of an animal cell.
– It breaks down old and unnecessary structures so their molecules can be reused.
vacuoles
– stores water and wastes, isolates hazardous materials, and has enzymes that can break down
macromolecules and cellular components, like those of a lysosome.
– Plant vacuoles also function in water balance and may be used to store compounds such as
toxins and pigments (colored particles).
peroxisomes
– houses enzymes involved in oxidation reactions, which produce hydrogen peroxide as a by-
product.
– The enzymes break down fatty acids and amino acids, and they also detoxify some
substances that enter the body.
Module 2

Plant Cells
- are multicellular eukaryotic cells that make up a plant
- (a group of eukaryotes belonging to the Plantae kingdom, with the ability to synthesis their own
food using water, Sunlight and CO2).

Types of plant cell
PARENCHYMA CELLS
- are live thin-walled cells with permeable walls that are undifferentiated
- do not have a specialized structure
- hence they easily adapt and differentiate into a variety of cells performing different function
TWO TYPES of PARENCHYMA CELLS:
Palisade parenchyma: columnar elongated structured cells found in a variety of leaves, lying below
the epidermal tissue.
Ray parenchyma: has both radial and horizontal arrangement majorly found within the stem wood
of the plant.
Functions of Parenchyma Cells
light penetration and absorption
and regulating gas exchange
transportation of small molecules
between the cells and the cell
cytoplasm.
assists in light absorption used in photosynthesis.
transport materials along the plant stem
transportation of water and food materials in the plant.

COLLENCHYMA CELLS
- are elongated cells found below the
epidermis and/or in young plants on the
outer layers of their stems and leaves.
- found in the vascular and/or on the plant stem corner
- occur in the peripheral region of the plant and they are not found in the plant roots.
TYPES OF COLLENCHYMA CELLS (based on thickness of wall and cell arrangement)
Angular collenchyma
- most common type of collenchyma cells.
- are found below the epidermis as hypodermis.
Annnular collenchyma
 - are uniformly thickened. The cells appear to be circular in shape
Lamellar collenchyma
- cells are thickened on the periphery making them appear tangentially arranged in rows.
- are closely packed together and therefore they don’t have intracellular spaces.
- are commonly formed and found in the leaf's petioles.
Lacunar collenchyma
- are cells are formed spaciously leaving intracellular spaces between each other.
- cell wall thickens around the intracellular spaces.
- appear spherically shaped.
- are formed and found in the walls of fruits.

FUNCTION OF THE COLLENCHYMA CELLS:
Being the living cells in plant tissues, they give support to the plant areas that are
growing and maturing in length.
They offer flexibility and tensile strength to plant tissues, allowing the plants to
bend.
They also allow the plant parts to grow and elongate.
Collenchyma can combine with the chloroplast and perform the process of photosynthesis.

3.SCLERENCHYMA CELLS
- are collenchyma cells that have an agent of the cell wall that plays a major role in hardening its cell
wall.
- are found in all plant roots and they are important in anchoring and giving support to the plants

Types of sclerenchyma cells
Fiber sclerenchyma cells
Sclereid sclerenchyma cells

Functions of the sclerenchyma cells
Due to their thickened cell wall, they
offer protection and support to other
plants’ tissues especially the tree
trunks and fibers of large herbal
trees.
The hardened cell wall discourages
herbivory. Ingestion of the hard cell
wall causes damage to the digestive
tract of larval stage insects,
especially in peach fruits.
Sclerenchyma found fibers are used
in making fabric, thread, and yarns.

4.Xylem Cells
- cells are complex cells found in the vascular tissues of plants, mostly in woody plants.
- primary function of the xylem cells is to
transport water and soluble nutrients,
minerals and inorganic ions upwardly from
the roots of the plants and its parts.
- elements flow freely through the
xylem tracheids and vessel elements with the aid of the xylem sap.

5.Phloem Cells
- cells are located outside the
xylem layer of cells.
- become alive at maturity because they need the energy to move materials.
- function to transport food from the
plant leaves to other parts of the plant.
- also have a flaccid cell
wall

6.MERISTEMATIC CELLS
- are also known as the meristems.
- are the cells in a plant that divide continuously throughout the life of a plant.
- have a self-renewal ability and high metabolisms to control the cell.

Types of meristematic cells
Apical meristems – they are found at the tips of roots and stems that have started growing and
they contribute to the length of the plant
Lateral meristems – They are found in the radial part of the stem and roots and they contribute to
the plant thickness
Intercalary meristems – they are found at the base of the leaves and the contribution to the size
variance of the leaves

Functions of the meristematic cells
They play a major role in the length and width sizes of the plants
they also give variance in the sizes of the plant leaves.
 They differentiate and mature into permanent tissues of the plants.

7.Epidermal Cells
- are the external cells of the plants
offering protection from water loss,
pathogenic invaders such as fungi.
- are placed closely together with no
intracellular spaces.
- covered with a waxy cuticle layer to reduce water loss.
- cover the plant stems, leaves, roots and plant seeds.

Types of epidermal cells
Pavement cells: maintain the plants’ internal temperature
Stomatal guard cells: There are two types of guard cells defined by the structure those that control
water availability by opening and closing the stomata by maintaining turgor pressure and
those that regulate the exchange of gases into and out of the leaves’ stomata.
Trichomes: These are also known as epidermal hairs found on the epidermal tissue. They play a
major role in protecting the plants from predators and pathogens, by acting as trappers and
poisoners to animal predators

ANIMAL CELLS
- are generally smaller than plant cells.
- defining characteristic is its irregular shape. This is due to the absence of a cell wall.

Epithelial Tissue
- cells are the cellular
components of the epithelium (pleural: epithelia).
-are layers of contiguous cells that line
the surfaces of organs and tissues.

Location
Covering the whole external surface of the body, as part of the skin.
Lining interior tracts which open to the exterior, such as the respiratory,
gastrointestinal and genitourinary tracts.
Lining interior enclosed spaces, such as blood vessels, the peritoneum, the pleura and the
pericardial sac.
 Types of Epithelial Cells According
to Layers
Simple: epithelia which are one cell layer thick
Stratified: consist of multiple layers of cells, with one layer anchored to the basement membrane,
known as the basal layer.

Types of Epithelial Cells According to Shape
cuboidal—for secretion
simple columnar—brick-shaped cells; for
secretion and active absorption
simple squamous—plate-like cells; for
exchange of material through diffusion
stratified squamous—multilayered and
regenerates quickly; for protection
pseudo-stratified columnar—single layer
of cells; may just look stacked because of
varying height; for lining of respiratory
tract; usually lined with cilia

Connective Tissue Cells
BLOOD — made up of plasma (i.e.,
liquid extracellular matrix); contains
water, salts, and dissolved proteins;
erythrocytes that carry oxygen (RBC),
leukocytes for defense (WBC), and
platelets for blood clotting.

CONNECTIVE TISSUE PROPER
(CTP)— made up of loose connective
tissue that is found in the skin and
fibrous connective tissue that is made
up of collagenous fibers found in
tendons and ligaments. Adipose tissues
are also examples of loose connective
tissues that store fats which functions to
insulate the body and store energy

Connective Tissue Cells
CARTILAGE —characterized by
collagenous fibers embedded in
chondroitin sulfate. Chondrocytes are the
cells that secrete collagen and
chondroitin sulfate. Cartilage functions as
cushion between bones.
BONE —mineralized connective tissue
made by bone-forming cells called
osteoblasts which deposit collagen. The
matrix of collagen is combined with
calcium, magnesium, and phosphate ions
to make the bone hard. Blood vessels and
nerves are found at a central canal
surrounded by concentric circles of osteons

Nervous Tissue— are composed of nerve cells called neurons and glial
cells that function as support cells. These neurons sense stimuli and transmit
electrical signals throughout the animal body. Neurons connect to other neurons to
send signals. The dendrite is the part of the neuron that receives impulses from
other neurons while the axon is the part where the impulse is transmitted to other neurons.

Cell specialization (or modification or differentiation) is actually a process that
occurs after cell division where the newly formed cells are structurally modified so
that they can perform their function efficiently and effectively.

MODULE 3
“Cell Cycle and Cell Division”

life cycle of plants, animals, and humans, the sequence begins with an adult organism.
this adults produces gametes—sperm and eggs—through a process called meiosis.
When a sperm and an egg combine in fertilization, they form a new cell called a zygote
The zygote then develops into a young organism, which eventually grows into an adult
between two types of cells:
diploid cells-which have two sets of chromosomes
haploid cells-which have just one set.
The cycle moves from diploid to haploid and then returns to diploid as it repeats.

Cell Cycle
The cell cycle is an ordered series of events involving cell growth and cell division that
produce two new daughter cells.
cycle has different stages called G1, S, G2, and M. G1 where the cell is preparing to divide

Interphase
cell undergoes normal growth processes while also preparing for cell division

STAGES OF INTERPHASE:
G1 phase-Metabolic changes prepare the cell for division.
S phase-DNA synthesis replicates the genetic material.
-Each chromosome now consists of two sister chromatids.
G2 phase-Metabolic changes assemble the cytoplasmic materials necessary for mitosis
and cytokinesis.

Cell Division/Mitotic Phase

Cell Division
the distribution of identical genetic material or DNA to two daughter cells.
most remarkable is the fidelity with which the DNA is passed along, without dilution or
error, from one generation to the next.
functions in reproduction, growth, and repair.

Types of Cell Division
Mitosis- the duplicated chromosomes are aligned, separated, and move into two new,
identical daughter cells.
Meiosis- cell division that produces haploid sex cells or gametes (contain a single copy of
each chromosome) from diploid cells (contain two copies of each chromosome).

Prophase
first phase of mitosis
process that separates the duplicated genetic material carried in the nucleus of a parent
cell into two identical daughter cells.

Prometaphase
second phase of mitosis
process that separates the duplicated genetic material carried in the nucleus of a parent
cell into two identical daughter cells.
Metaphase
stage during the process of cell division (mitosis or meiosis).
individual chromosomes are spread out in the cell nucleus.

Anaphase
shortest stage of mitosis
the sister chromatids break apart, and the chromosomes begin moving to opposite ends
of the cell.

Telophase
fifth and final phase of mitosis
separates the duplicated genetic material carried in the nucleus of a parent cell into two
identical daughter cells.

Meiosis 1
Prophase 1
chromosomes condense and attach to the nuclear envelope and begin migrating toward
the metaphase plate.
stage where genetic recombination may
occur.

Metaphase 1
chromosomes align at the metaphase plate.
homologous chromosomes-the centromeres are positioned toward opposite poles of the
cell.

Anaphase 1
homologous chromosomes separate and move toward opposite cell poles.
The sister chromatids remain attached after this move to opposite poles.

Telophase 1
cytoplasm divides producing two cells with a haploid number of chromosomes.
Sister chromatids remain together.

Meiosis 2
Prophase 2
chromosomes begin migrating to the metaphase II plate.
 These chromosomes do not replicate again.

Metaphase 2
chromosomes align at the metaphase II plate
kinetochore fibers of the chromatids are oriented toward opposite poles.

Anaphase 2
sister chromatids separate and begin moving to opposite ends of the cell.
The two cell poles also grow further apart in preparation for telophase 2.

Telophase 2
new nuclei form around daughter chromosomes.
cytoplasm divides and forms two cells in a process known as cytokinesis.

Cytokinesis
final cellular division to form two new cells.
In plants a cell plate forms along the line of the metaphase plate
in animals there is a constriction of the cytoplasm.
The cell then enters interphase - the interval between mitotic divisions.

Comparison between Mitosis and Meiosis
Meiosis Mitosis
1. Requires two nuclear divisions 1. Requires one nuclear division
2. Chromosomes synapse and cross
over 2. Chromosomes do not synapse nor cross
3. Centromeres survive Anaphase || 3. Centromeres dissolve in mitotic anaphase
4. Halves chromosome number 4. Preserves chromosome number
5. Produces four daughter nuclei 5. Produces two daughter nuclei
6. Produces daughter cells genetically
diferent from parent and each other 6. Produces daughter cells genetically
identical to parent and to each other
7. Used only for sexual reproduction 7. Used for asexual reproduction and growth

Cell Cycle Checkpoint

1. Cell Growth checkpoint
Occurs toward the end of growth phase 1 (G1).
Checks whether the cell is big enough and has made the proper proteins for the
synthesis phase.
If not, the cell goes through a resting period (GO)
until it is ready to divide.
2. DNA Synthesis Checkpoint
Occurs during the synthesis phase (S).
Checks whether DNA has been replicated correctly.
If so, the cell continues on to mitosis (M).
3. Mitosis Checkpoint
Occurs during the mitosis phase (M).
Checks whether mitosis is complete.
If so, the cell divides, and the cycle repeats.

Errors in Cell Division
1.Incorrect DNA Copy
Incorrectly paired nucleotides cause deformities in the secondary structure of the final
DNA molecule
enzymes recognize and fix these deformities by removing the incorrectly paired
nucleotide and replacing it with the correct nucleotide.

2.Chromosomes are attached to string-like spindles and begin to move to the middle of the cell
Down Syndrome, Alzheimer’s, and Leukemia

3. Aneuploidy
presence of chromosome number that is different from simple multiple of the basic
chromosome number.
an organism contains one or more incomplete chromosome sets is known as aneuploid
due to loss of one or more chromosomes (hypo-ploidy)
due to addition of one or more chromosomes to complete chromosome complement
(hyper-ploidy).

Module 4 — Transport mechanism

membrane transport refers to the collection of mechanisms that regulate the passage of
solutes such as ions and small molecules through biological membranes, which are lipid
bilayers that contain proteins embedded in them.

Plasma Membrane
The plasma membrane, also called the cell membrane
 is the membrane found in all cells that separates the interior of the cell from the outside
environment.

According to the fluid mosaic model, the plasma membrane is a mosaic of components—
primarily, phospholipids, cholesterol, and proteins—that move freely and fluidly in the plane
of the membrane.

Phospholipid Bilayer:
– A phospholipid is a lipid made of glycerol, two fatty acid tails, and a phosphate-linked head
group. Biological membranes usually involve two layers of phospholipids with their tails
pointing inward, an arrangement called a phospholipid bilayer.

Cell Transport Mechanisms
2 Types of Transport Mechanism

Passive transport:
– occurs when substances cross the plasma membrane without any input of energy from the
cell.
– No energy is needed because the substances are moving from an area where they have a
higher concentration to an area where they have a lower concentration.

Active transport
– require energy to cross a plasma membrane often because they are moving from an area of
lower concentration to an area of higher concentration.

Passive Transport

Simple Diffusion:
– molecules move down their gradients through the membrane.
– Molecules that practice simple diffusion must be small and nonpolar*, in order to pass
through the membrane.
Osmosis:
– a specific type of diffusion;
– it is the passage of water from a region of high water concentration through a semi-
permeable membrane to a region of low water concentration.
– Water moves in or out of a cell until its concentration is the same on both sides of the
 –
plasma membrane

Facilitated Diffusion:
– diffusion that is helped along (facilitated by) a membrane transport channel
– These channels are glycoproteins (proteins with carbohydrates attached) that allow
molecules to pass through the membrane.
– they are tightly linked to certain physiologic functions.

MODULE 5
“Structure and Function of Biological Molecules”

Carbon and Carbon Bonding
* bonded to other carbon atoms or other elements, form the fundamental components of many, if
not most, of the molecules found uniquely in living things.
* contains four electrons in its outer shell.
* can form four covalent bonds with other atoms or molecules.
* This diversity of its molecular forms accounts for the diversity of functions(biological
macromolecules)
* large degree on the ability of carbon to form multiple bonds with itself and other atoms

Carbohydrates
* examples of macromolecules.
* chainlike molecules called polymers made from repeating units like monomers.
* Polymers can be formed from covalently-bonded monomers
* structure can be made out of repeated building blocks linked to each other.

Lipids
* class of large biomolecules that are not formed through polymerization.
* diverse structures but are all non-polar and mix poorly, if at all, with water.
* They may have some oxygen atoms in their structure but the bulk is composed of abundant
nonpolar C-H bonds
* function for energy storage, providing nine food calories or 37 kJ of energy per gram, also for the
cushioning of vital organs and for insulation
* play important roles in plasma membrane structure, precursors for important reproductive
hormones.

PROTEINS
* large biomolecules, or macromolecules, consisting of one or more long chains of amino acid
residues.
* most abundant organic molecules in living systems
* way more diverse in structure and function than other classes of macromolecules.

AMINO ACIDS
* monomers that make up proteins.
* protein is made up of one or more linear chains of amino acids, each is called polypeptide
* share a basic structure, consists of a central carbon atom, also known as the alpha (α) carbon,
bonded to an amino group, a carboxyl group, and a hydrogen atom

PEPTIDE BONDS
* amino acids of a polypeptide are attached to their neighbors by covalent bonds known as a
peptide bond
* bond forms in a dehydration synthesis (condensation) reaction.
* protein in your cells consists of one or more polypeptide chains.
* made up of amino acids, linked together in a specific order.

Nucleic Acids
* key macromolecules in the continuity of life
* carry the genetic blueprint of a cell
* carry instructions for the functioning of the cell
* molecules made up of nucleotides that direct cellular activities such as cell division and protein
synthesis.
* nucleotide is made up of a pentose sugar, a nitrogenous base, and a phosphate group.

Enzymes
* organic or biological catalysts
* castalysts-substances that speed up a reaction without being used up, destroyed, or incorporated
into the end product.
* vital to the regulation of the metabolic processes of the cell
* many enzymes are protiens.

Module 6 — ATP-ADP cycle

ATP (adenosine triphosphate)
– the energy currency for cellular processes.
 – ATP provides the energy for both energy-consuming endergonic reactions and energy-
releasing exergonic reactions, which require a small input of activation energy.
– When the chemical bonds within ATP are broken, energy is released and can be harnessed for
cellular work.
– The more bonds in a molecule, the more potential energy it contains.
– Because the bond in ATP is so easily broken and reformed, ATP is like a rechargeable
battery that powers cellular process ranging from DNA replication to protein synthesis.

Molecular Structure
– Adenosine triphosphate (ATP) is comprised of the molecule adenosine bound to three
phosphate groups.
– Adenosine is a nucleoside consisting of the nitrogenous base adenine and the five-carbon
sugar ribose. The three phosphate groups, in order of closest to furthest from the ribose
sugar, are labeled alpha, beta, and gamma.

Glucose and ATP
– Glucose, a sugar that is delivered via the bloodstream, is the product of the food you eat, and
this is the molecule that is used to create ATP.
– Sweet foods provide a rich source of readily available glucose while other foods provide the
materials needed to create glucose.
– This glucose is broken down in a series of enzyme controlled steps that allow the release of
energy to be used by the organism.
– This process is called respiration.
Creation of ATP
– ATP is created via respiration in both animals and plants.
– The difference with plants is the fact they attain their food from elsewhere.
– Two processes convert ADP into ATP:
– 1) substrate-level phosphorylation; and
– 2) chemiosmosis.
– Substrate-level phosphorylation occurs in the cytoplasm when an enzyme attaches a third
phosphate to the ADP
– (both ADP and the phosphates are the substrates on which the enzyme acts).

ATP Hydrolysis and Synthesis

– Like most chemical reactions, the hydrolysis of ATP to ADP is reversible. The reverse reaction
combines ADP + Pi to regenerate ATP from ADP.
– Since ATP hydrolysis releases energy, ATP synthesis must require an input of free energy.
– ADP is combined with a phosphate to form ATP in the following reaction:

ADP + Pi + free energy → ATP + H2O

ATP and Energy Coupling
– The calculated ΔG for the hydrolysis of one mole of ATP into ADP and Pi is −7.3 kcal/mole
(−30.5 kJ/mol).
– However, this is only true under standard conditions, and the ΔG for the hydrolysis of one
mole of ATP in a living cell is almost double the value at standard conditions: 14 kcal/mol
 –

(−57 kJ/mol).
– ATP is a highly unstable molecule. Unless quickly used to perform work, ATP spontaneously
dissociates into ADP + Pi, and the free energy released during this process is lost as heat.
– To harness the energy within the bonds of ATP, cells use a strategy called energy coupling

Module 7 — Photosynthesis

– Light is actually energy, electromagnetic energy to be exact.
– When that energy gets to a green plant, all sorts of reactions can take place to store energy
in the form of sugar molecules.
– Even when light gets to a plant, the plant doesn't use all of it.
– It actually uses only certain colors to make photosynthesis happen. Plants mostly absorb red
and blue wavelengths.

Chloroplast
Chloroplasts are organelles found in plant cells and eukaryotic algae that conduct
photosynthesis.
Chloroplasts absorb sunlight and use it in conjunction with water and carbon dioxide gas to
produce food for the plant.
Chloroplasts capture light energy from the sun to produce the free energy stored in ATP
and NADPH through a process called photosynthesis.
ATP and NADPH through a process called photosynthesis.
 Chloroplasts are one of the many unique organelles in the body, and are generally considered
to have originated as endosymbiotic cyanobacteria.

Plastids
Plastids are a group of phylogenetically and physiologically-related organelles found in all
types of plants and algae.
In the cells, plastids are primarily involved in the manufacture and storage of food.
They are therefore involved in such processes as photosynthesis, synthesis of amino acids
and lipids as well as storage of various materials among a few other functions.
In their roles, the different types of plastids contribute to plant metabolism thus promoting
plant growth and development.
One of the main characteristics of these organelles is the fact that they have a double
membrane.

Chlorophyll
Chlorophyll is a green photosynthetic pigment found in plants, algae, and cyanobacteria.
Chlorophyll absorbs mostly in the blue and to a lesser extent red portions of the
electromagnetic spectrum, hence its intense green color.
Green substance in producers that traps light energy from the sun, which is then used to
combine carbon dioxide and water into sugars in the process of photosynthesis
Chlorophyll is vital for photosynthesis, which helps plants get energy from light.

Photosynthesis
Photosynthesis, the process by which green plants and certain other organisms transform
light energy into chemical energy.
During photosynthesis in green plants, light energy is captured and used to convert water,
carbon dioxide, and minerals into oxygen and energy-rich organic compounds.

Photosynthetic process. Light dependent reaction ( light reaction)
Light-dependent reaction requires sunlight.
In the light-dependent reactions, energy from sunlight is absorbed by chlorophyll and
converted into stored chemical energy, in the form of the electron carrier molecule NADPH
(nicotinamide adenine dinucleotide phosphate) and the energy currency molecule ATP
(adenosine triphosphate).
The light-dependent reactions take place in the thylakoid membranes in the granum (stack

of thylakoids), within the chloroplast.. Light-Independent Reaction (Calvin Cycle)
In the light-independent reactions or Calvin cycle, the energized electrons from the light-
dependent reactions provide the energy to form carbohydrates from carbon dioxide
molecules.
The light-independent reactions are sometimes called the Calvin cycle because of the
cyclical nature of the process.
Although the light-independent reactions do not use light as a reactant (and as a result can
take place at day or night), they require the products of the light-dependent reactions to
function.
The light-independent molecules depend on the energy carrier molecules, ATP and NADPH,
to drive the construction of new carbohydrate molecules.
After the energy is transferred, the energy carrier molecules return to the light-dependent
reactions to obtain more energized electrons.

MODULE 8:

PIGMENTS
- are chemical compounds which reflect only certain wavelengths of
visible light. This makes them appear "colorful". Flowers, corals, and even
animal skin contain pigments which give them their colors.
- In plants, algae, and cyanobacteria, pigments are the means by which the
energy of sunlight is captured for photosynthesis.

CLASSES OF PIGMENTS:
Chlorophylls
- are greenish pigments which contain a porphyrin ring.
- a stable ring-shaped molecule around which electrons are free to migrate.
Because the electrons move freely, the ring has the potential to gain or lose
electrons easily, and thus the potential to provide energized electrons to other
molecules. This is the fundamental process by which chlorophyll "captures" the energy of sunlight.

Carotenoids
- are usually red, orange, or yellow
pigments, and include the familiar compound carotene, which gives carrots their color.

- are composed of two small six-carbon
rings connected by a "chain" of carbon atoms. As a result, they do not dissolve in water, and must
be attached to membranes within the cell. Carotenoids cannot transfer sunlight energy directly to
the photosynthetic pathway, but must pass their absorbed energy to chlorophyll. For this reason,
they are called accessory pigments. One very visible accessory pigment is fucoxanthin the brown
pigment which colors kelps and other brown algae as well as diatoms

Phycobilins
- are water-soluble pigments, and
are therefore found in the cytoplasm, or in the stroma of the chloroplast. They occur only in
Cyanobacteria and Rhodophyta.
Phycobilins are not only useful to the organisms which use them for soaking up light energy; they
have also found use as research tools.