Lesson 3: Cell Structures And Functions PDF

Summary

This document details information about cell structures and functions. It includes a prayer and lesson objectives about cell organelles and their function. Sections on cell components such as the plasma membrane, cytoplasm, DNA, ribosomes, and bacterial cells are included.

Full Transcript

Lesson 3:
CELL STRUCTURES
AND FUNCTIONS
OPENING PRAYER
Dear Lord and Father of all, Thank you for today.
Thank you for ways in which you provide for us all.
For Your protection and love we thank you.
Help us to focus our hearts and minds now on what we are
about to learn. Inspire us by Your Holy Spirit as we listen
and write.
Guide us by your eternal light as we discover more about
the world around us.
We ask all this in the name of Jesus. Amen…
Learning Competency:
▪ The learners shall be able to
describe the structure and
function of major and subcellular
organelles
▪ (STEM_BIO11/12-Ia-c-2)
Specific Objectives:
At the end of the lesson, the learners should be able
to:
A. explain cell organelle functions.
B. differentiate between plant, animal and bacterial cells
in terms of structure and function
C. describe the structure and function of major and
subcellular organelles
5
A. Plasma Membrane
▪ Acts as the boundary between the outside
and inside of a cell.
▪ The integrity and function of the plasma
membrane are vital to a cell because this
membrane acts much like a gatekeeper,
regulating the passage of molecules and ions
into and out of the cell.
▪ The plasma membrane is composed of a
phospholipid bilayer.
▪ The polar heads of the phospholipids
are at the surfaces of the membrane;
the nonpolar tails make up the
interior of the membrane.
▪ Proteins embedded in the membrane
have various functions
 B. Cytoplasm
▪ A semifluid interior, where chemical
reactions occur.
▪ Consists of mainly water (80-85%).
The remaining constituents are
proteins (10-15%), lipids (2-4%),
polysaccharides (1%) and nucleic
acids (1%).
C. DNA
▪ DNA = Deoxyribose nucleic acid
▪ Genetic material of all cellular organisms and most
viruses.
▪ Made out of sugars (deoxyribose), phosphates
and nitrogen bases
▪ DNA carries the information needed to direct protein
synthesis and replication
 D. Ribosomes
▪ Is a complex molecule made of ribosomal
RNA molecules and proteins that form a
factory for the protein synthesis in cells.
▪ Discovered by George E. Palade in 1955 –
small particles in the cytoplasm that
preferentially associated with the
endoplasmic reticulum membrane.
PROKARYOTIC CELL
STRUCTURE
BACTERIAL CELL
▪ A. FLAGELLA
▪ 3 parts
□ filament – long, thin, helical
structure composed of
proteins
□ hook- curved sheath
□ basal body – stack of rings
firmly anchored in cell wall
▪ rotates 360o
▪ 1-2 or many distributed over
entire cell
▪ functions in motility
BACTERIAL CELL ▪ A. FLAGELLA
▪ Flagellar arrangements
▪ monotrichous – single
flagellum at one end
▪ lophotrichous – small
bunches arising from one
end of cell
▪ amphitrichous – flagella
at both ends of cell
▪ peritrichous – flagella
dispersed over surface of
cell, slowest
▪ B. FIMBRIAE
▪ fine hairlike
bristles from the
cell surface
▪ function in
adhesion to
other cells and
surfaces
 C. PILI
rigid tubular structure
made of pilin protein
found only in Gram
negative cells
Functions
BACTERIALjoins bacterial cells for DNA
transfer (conjugation)
CELL adhesion
▪ D. GLYCOCALYX
▪ Coating of molecules external
to the cell wall, made of sugars
and/or proteins
▪ 2 types
□ capsule - highly organized,
tightly attached
□ slime layer - loosely organized
and attached
▪ functions
□ attachment
□ inhibits killing by white blood cells
□ receptor
▪ E. CELL WALL
Peptidoglycan
▪ unique macromolecule composed of a
repeating framework of long glycan
chains cross-linked by short peptide
fragments
▪ provides strong, flexible support to
keep bacteria from bursting or
collapsing because of changes in
osmotic pressure
Gram positive cell wall
▪ Consists of
□ a thick, homogenous sheath of
peptidoglycan 20-80 nm thick
□ tightly bound acidic polysaccharides,
including teichoic acid and lipoteichoic
acid
▪ Retain crystal violet and stain purple
Gram negative cell wall
▪ Consists of
□ an outer membrane containing
lipopolysaccharide (LPS)
□ thin shell of peptidoglycan
□ periplasmic space
□ inner membrane
▪ Lose crystal violet and stain red from
safranin counterstain
▪ F. CYTOPLASM
▪ dense gelatinous
solution of sugars,
amino acids, & salts
▪ 70-80% water
▪ serves as solvent for
materials used in all
cell functions
▪ G. CHROMOSOME
▪ single, circular, double-
stranded DNA molecule that
contains all the genetic
information required by a
cell
▪ DNA is tightly coiled around
a protein, aggregated in a
dense area called the
nucleoid
▪ H. PLASMIDS
▪ small circular, double-stranded DNA
▪ free or integrated into the chromosome
▪ duplicated and passed on to offspring
▪ not essential to bacterial growth &
metabolism
▪ may encode antibiotic resistance, tolerance
to toxic metals, enzymes & toxins
▪ used in genetic engineering- readily
manipulated & transferred from cell to cell
I. RIBOSOMES
▪ site of protein

synthesis
▪ have a small and

large subunit
EUKARYOTIC CELL
STRUCTURE
Basic Structure of a Eukaryotic Cell
✓ Plasma membrane
✓ Cytoplasm (semifluid)
✓ Cytoskeleton - microfilaments and microtubules
that suspend organelles, give shape, and allow
motion
✓ Presence of characteristic membrane enclosed
subcellular organelles
✓ A membrane-bound nucleus
PLANT CELL
STRUCTURE
Cell Wall
▪ Functions for protection and support for the entire cell
▪ Consists of the primary wall, middle lamella and
secondary wall
□ Middle lamella – intercellular layer composed of
pectin. Pectin is a viscous and gelatinous substance
which acts as a cementing material to hold the cells
together.
□ Primary wall – consists mainly of bundles of
intertwined molecules of cellulose, cutin and waxes
Cell Wall
□ Secondary wall – produced and
deposited between the primary wall
and the protoplast after cell
enlargement ceases and is composed
mainly of cellulose and lignin. Lignin
is a complex material responsible for
hardness and decay-resisting
qualities of many woods.
Plasmodesmata
▪ Protoplasmic connections which aid in
the movement of materials from one
cell to another
▪ microscopic channels which traverse
the cell walls of plant cells enabling
transport and communication
between them
Plastids
▪ Essential in food making and storage of food
□ Proplastid – young plastids capable of dividing, usually
colorless
□ Chromoplastid – colored plastids containing red, yellow or
orange pigments
□ Chloroplastid – contain the green pigment chlorophyll
□ Leucoplastid – colorless plastid and usually functions for
storage
□ Amyloplastid – stores starch
□ Elaioplastid – stores oil
□ Aleurone plastid – stores protein
Animal Cell
Structures
Diagram of a typical animal (eukaryotic) cell,
showing subcellular components.
▪ Organelles:
▪ (1) nucleolus
▪ (2) nucleus
▪ (3) ribosome
▪ (4) vesicle
▪ (5) rough endoplasmic reticulum (ER)
▪ (6) Golgi apparatus
▪ (7) Cytoskeleton
▪ (8) smooth endoplasmic reticulum
▪ (9) mitochondria
▪ (10) vacuole
▪ (11) cytoplasm
▪ (12) lysosome
▪ (13) centrioles within centrosome
Centrioles
▪ help to organize the assembly of
microtubules during cell division.
Organelles found
in Most
Eukaryotes
MEMBRANE-
BOUND
ORGANELLES
1. Nucleus
▪ control center of the cell
56
Nuclear membrane
▪surrounds the nucleus.
▪ It is also called
nuclear envelope.
Nucleoplasm

▪ the liquid inside the
nucleus.
▪ It is also called

Karyoplasm
Nucleolus
▪ produces ribosomes
2. ENDOPLASMIC RETICULUM
▪ transport system of the cell

2.1 Rough Endoplasmic Reticulum
– has attached ribosomes and is
involved in protein synthesis
2.2 Smooth Endoplasmic Reticulum
– involved in synthesis and
breakdown of lipid and carbohydrate
(The word
endoplasmic
means
"within the
cytoplasm,~ and
reticulum is
Latin for "little
net~)
62
3. Golgi Complex/Bodies/Apparatus
▪ also called dictyosome
▪ modifies, packages and distributes molecules
made at one location of the cell and used at
another.
64
4. Vacuoles
▪ serve as storage
organelles within the cell.
▪ they are typically smaller
and less prominent in
animal cells.
67
4. VESICLE
▪ small, spherical, or irregularly shaped organelles
that can be found in various eukaryotic cells,
including both plant and animal cells. They are
also membrane-bound, enclosed by a lipid
bilayer.
FUNCTIONS:
▪ Transport
▪ Secretion
▪ Endocytosis and Exocytosis
5. Mitochondrion
▪ powerhouse of the cell
▪ sites of cellular respiration, the metabolic process
that generates ATP by extracting energy from sugars,
fats, and other fuels with the help of oxygen.
▪ Surrounded by a DOUBLE membrane
□ Folded inner membrane called CRISTAE
(increases surface area for more chemical
reactions)
□ Interior called MATRIX
6. Lysosomes
▪ small membrane-bordered structures that contain chemicals and
enzymes necessary for digesting certain materials in the cell.
▪ They are formed in the Golgi bodies. They are known as suicidal
bags for they can destroy cell structures that have outlived their
usefulness
7. Microbodies/cytosomes
▪ small membrane-bound organelle originating from
the endoplasmic reticulum containing enzymes.
▪ For example, peroxisomes are a type of microbody
with specific enzymes for detoxifying harmful
substances.
NON-MEMBRANE
BOUND
ORGANELLES
1. Ribosomes
▪ protein factories of the

cell
2. CENTRIOLES
▪ are cylindrical, microtubule-based organelles
found in animal cells, including human cells.
▪ They play a crucial role in cell division, particularly
during the process of mitosis and meiosis.
3. Cytoskeleton
▪ composed of a variety of filaments and fibers that support
cell structure and drive cell movement.
▪ Helps cell maintain cell shape
▪ Made of proteins
□ Microtubules – contain long thin cylindrical fibrils that
provide support for cell shape and help move organelles
through the cell and during cell division.
□ Microfilament – contains actin for movement and
support of the cell. They also permit movement of the
cytoplasm within the cell called cytoplasmic streaming.