BIOL-Q1-Lesson3-Plant-and-Animal-Cells.pdf

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PLANT AND ANIMAL
CELLS
Prepared by: Ianna Tacleran-Cid
 OBJECTIVES
Describe the structure and function of a plant cell
Describe the structure of an animal cell
Compare and contrast the plant and animal cell
plant Cell Animal Cell
 A phospholipid bilayer with embedded proteins that separate the
internal contents of the cell from its surrounding environment
The plasma It has two fatty acid chains and a phosphate-containing group
membrane It controls the passage of organic molecules, ions, waste products, water,
and oxygen into and out of the cell
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CYTOPLASM

The cell’s entire region between the plasma
membrane and the nuclear envelope
Comprised of organelles in the gel-like cytosol,
the cytoskeleton, and various chemicals
Consists of 70 to 80% water, but has a semi-
solid consistency
Other components include proteins, glucose
and other simple sugars, polysaccharides,
amino acids, nucleic acids, fatty acids, and

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ions (Na+, K+, Ca2+)
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THE NUCLEUS (Information center)

Most prominent organelle in the cell
It houses the cell’s DNA (chromatin) and directs the
synthesis of ribosomes and proteins
Nucleoplasm is a gel-like substance
Nucleolus is a condensed chromatin region where
ribosome synthesis occurs
Nuclear envelope is also of phospholipid bilayer
Nuclear membrane is continuous with the
endoplasmic reticulum
Nuclear pores allow substances to enter and exit the

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nucleus

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THE NUCLEUS: Nuclear Envelope
The nuclear envelope is double-membrane
structure that constitutes the outermost portion
of the nucleus
Punctuated with pores that control passage of
ions, molecules, and RNA between nucleoplasm
and cytoplasm
Nucleoplasm is the semi-solid fluid inside the
nucleus, where we find the chromatin and
nucleolus

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THE NUCLEUS:
CHROMATIN AND
CHROMOSOMES
DNA is the hereditary material
Chromosomes are linear structures, and every
eukaryotic species has specific number of chromosomes
in the nucleus of each cell – they are only visible and
distinguishable from one another when the cell is about
to divide
Chromatin is when proteins attach to chromosomes
during the growth and maintenance phase of its life
cycle – it describes the material that makes up the
chromosomes both when condensed and decondensed

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THE NUCLEUS: NUCLEOLUS
Directs the synthesis of ribosomes
Ribosome synthesis is done by some
chromosome which have sections of DNA that
encode ribosomal RNA
Nucleolus is a darkened area in the nucleus that
aggregates the ribosomal RNA with associated
proteins to assemble the ribosomal subunits that
are then transported out through the pores in
the nuclear envelope to the cytoplasm

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RIBOSOMES (Protein Factories)
Responsible for protein synthesis
Under SEM, they appear as clusters, or single, tiny dots
that float freely in the cytoplasm
They may be attached to plasma membrane cytoplasmic
side, the ER’s cytoplasmic side, or the nuclear envelope’s
outer membrane
They consists of two subunits: large and small
They receive “orders” for protein synthesis from the
nucleus where the DNA transcribes into messenger RNA,
the mRNA then travels to ribosomes which translate the
code provided by the sequence of nitrogenous bases in the

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mRNA into specific order of amino acids in a protein
Amino acids are the building blocks of proteins
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 Responsible for making the cell’s energy currency
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called adenosine triphosphate (ATP)
Cellular respiration takes place in this organelle where
glucose is transformed into ATP using oxygen while
producing carbon dioxide as a byproduct
They are oval-shaped, double-membrane organelles
that have their own ribosomes and DNA, each
membrane is a phospholipid bilayer embedded with
proteins
The inner layer has folds called cristae
The area surrounded by the folds is the mitochondrial
MITOCHONDRIA matrix
(Cell’s powerhouse) There is an inner membrane and an outer

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membrane, and between these two, there is an
intermembrane space where ATP synthesis takes place
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Peroxisomes (Oxidation)
They are small, round organelles
enclosed by single membranes
They carry out oxidation that break down
fatty acids and amino acids, detoxify
many poisons that may enter the body
The oxidation processes releases
hydrogen peroxide (H2O2) which can
damage the cells; however, they are
broken down by enzyme catalase into
water and oxygen molecules
 Specialized peroxisomes in plants are
responsible for converting stored fats into sugars

glyoxysomes Plant cell contain many different types of
peroxisomes that play a role in metabolism,
pathogen defense and stress response
 VESICLES AND VACUOLES
They are membrane-bound sacs that function in storage and support
Vacuoles are somewhat vesicles, and have very little distinction between them
Vesicle membranes can fuse with either the plasma membrane or other membrane systems within
the cell
Some agents such as enzymes within plant vacuoles break down macromolecules. The vacuole’s
membrane does not fuse with the membranes of other cellular components
 PLANT VS
ANIMAL CELL
PLANT CELLS
Has microtubule organizing centers (MTOCs)
They have cell wall, chloroplasts, and other
specialized plastids
Has a large central vacuole

ANIMAL CELLS
Has microtubule organizing centers (MTOCs)
and centrioles associated with the MTOC: a
complex called centrosome
Have centrosome and lysosomes
CENTROSOME
A microtubule-organizing center (MTOC) found near the
nuclei of animal cells
Contains a pair of centrioles, two structures that lie
perpendicular to each other
Each centriole is a cylinder of nine triplets of microtubules
In cell division, centrosomes replicate themselves before a cell
divides, and the centrioles appear to have same role in pulling
the duplicated chromosomes to opposite ends of the dividing
cell
 LYSOSOMES
The “garbage disposal” of animal cells, in
contrast, vacuoles perform this function in plant
cells
It contains enzymes that aid in breaking down
(through phagocytosis) proteins,
polysaccharides, lipids, nucleic acids, and even
worn-out organelles (autophagy)
The pH within the lysosome is much lower
than the cytoplasm
Also, a part of the endomembrane system
when needed to ingest a pathogen
Cell wall
External to the plasma membrane, which is a rigid
covering that protects the cell
It provides structural support, rigidity, and gives shape
to the cell
Fungal and other protistan cells (slime molds, algae, and
seaweeds) also have cell walls.
Prokaryotic cell wall consists of peptidoglycan, plant’s
and of most protists is of cellulose, and fungal cell wall is
of chitin
Cellulose of cell wall in plants is a polysaccharide
comprised of glucose units
 CHLOROPLAST

Plant cell organelles that carry out photosynthesis, a process that allows plants to be photoautotrophs
They have their own DNA and ribosomes, and like mitochondria, they also have inner and outer membrane
Inside the inner membrane there is a fluid called stroma, within the stroma, there is a set of interconnected
and stacked fluid-filled membrane sacs called thylakoids; each thylakoid stack is called a granum
(plural=grana)
Chloroplasts contain the green pigment, chlorophyll, which captures the light energy and drives the
reactions of photosynthesis
 Occupies majority of the plant cell’s area
Plays a key role in regulating the cell’s
CENTRAL VACUOLE concentration of water in changing
environmental conditions
When the water concentration in the central
vacuole is low, the cell wall becomes
unsupported making the plant look wilted
THE ENDOMEMBRANE
SYSTEM AND PROTEINS
It is a system consisting of group of membranes and
organelles in eukaryotic cells that works together to
modify, package, and transport lipids and proteins
Includes nuclear envelope, lysosomes, vesicles, the
endoplasmic reticulum, Golgi bodies, and the
plasma membrane
does not include mitochondria and chloroplasts
ENDOPLASMIC RETICULUM (ER)
A series of interconnected membranous sacs and
tubules that collectively modifies proteins and
synthesizes lipids
Consists of the rough and smooth ER
The ER tubules’ hollow portion the lumen or
cisternal space
The ER’s membrane, which is a phospholipid
bilayer embedded with proteins, is continuous
with the nuclear envelope
ROUGH ER
Named rough ER because of the ribosomes attached to its
cytoplasmic surface, giving it a studded appearance under
microscope
Newly synthesized proteins from ribosomes are transferred into
the RER lumen where they undergo structural modifications, such as
folding or acquiring side chains
Proteins processed in the RER incorporate into cellular
membranes – the ER or other organelles’ membranes
RER also makes phospholipids for cellular membranes
RER mainly modifies proteins (e.g., enzymes) so they are most
abundant in cells that secrete protein like in the liver
SMOOTH ER
Continuous with the RER but has few to no ribosomes on its
cytoplasmic surface
Functions include synthesis of carbohydrates, lipids, and steroid
hormones; it also detoxifies medications and poisons and stores calcium
In muscle cells, a specialized SER, the sarcoplasmic reticulum, is
responsible for storing calcium ions that are needed to trigger the
muscle cells' coordinated contractions
GOLGI APPARATUS
Sorting, tagging, packaging, and distributing lipids and proteins take
place in the Golgi apparatus which is a series of flattened membranes
The Golgi has a cis and trans face
Transport vesicle from the ER arrives at the cis face, fuse with it, and
empty their contents into the Golgi bodies’ lumen. These proteins and
lipids undergo further modification that allow them to be sorted
(usually adding sugar molecule chains)
These newly-modified proteins and lipids then tag with PO4 groups to
travel to their proper destinations
Then, these modified and tagged molecules are packaged into secretory
vesicles that bud from Golgi’s trans face
Some of these packaged vesicles deposit their contents into other cell
parts where they are used, they may also fuse with plasma membrane
and release their content outside of the cell
THE ENDOMEMBRANE SYSTEM
 THE CYTOSKELETON
Collective network of protein fibers that help maintain the
cell’s shape, secure some organelles in specific positions, allow
cytoplasm and vesicles to move within the cell, and enable cells
within multicellular organisms to move
There are three types of fibers within the cytoskeleton:
microfilaments, intermediate filaments, and microtubules
 The narrowest type of protein fiber in the
CYTOSKELETON: cytoskeleton
MICROFILAMENTS Function in the cellular movement
they have a diameter of about 7 nm, and are
comprised of two globular protein
intertwined strands, which we call actin
Also called actin filaments
They are powered by ATP to assemble their
filamentous form that becomes the track for
the movement of a motor protein called
myosin, allowing cell division
They provide rigidity and shape to the cell
They can depolymerize (disassemble) and
reform quickly, thus enabling a cell to change
its shape and move, as seen in white blood
cells’ movement to an infection site
 CYTOSKELETON: INTERMEDIATE
FILAMENTS
Several strands of fibrous proteins that are wound together comprise intermediate filaments
No role in cellular movement but function purely in the structure – they bear tension to maintain cell
shape, anchor the nucleus and other organelles in place
The intermediate filaments are the most diverse group of cytoskeletal elements
Several fibrous protein types are in the intermediate filaments, like keratin, the fibrous protein that
strengthens the hair, nails, and the skin's epidermis.
CYTOSKELETON: They are small hollow tubes, with a diameter of about 25 nm,
microtubules are cytoskeletons' widest components
MICROTUBULES they help the cell resist compression, provide a track along which vesicles
move through the cell, and pull replicated chromosomes to opposite ends of
a dividing cell; they can also disassemble and reform quickly
the structural elements of flagella, cilia, and centrioles
flagella are long, hair-like structures that extend from the plasma
membrane and enable an entire cell to move. When present, the cell
has just one flagellum or a few flagella.
Cilia are composed of many extensions along the plasma
membrane’s surface – they are short, hair-like structures that move
entire cells, or substances along the cell's outer surface like in the
fallopian tubes
 PLANT AND
ANIMAL CELLS’
COMPONENTS
 PLANT AND
ANIMAL CELLS’
COMPONENTS
 PERFORMANCE TASK #1
Create a 3D model of animal and plant cells using recyclable
materials