General Biology 1 - Cell Types, Functions, and Modification (PDF)

Summary

This document is a general biology lesson plan concerning cell types, functions, and modifications. It investigates prokaryotic and eukaryotic cells, distinguishing their features. The lesson also details animal and plant tissues, and their functions.

Full Transcript

General Biology 1

CELL: TYPES,
FUNCTIONS, AND
MODIFICATION
SHERWIN M. BERNABE
Subject Teacher
[email protected]
 MOST ESSENTIAL LEARNING
COMPETENCIES (MELCS)

3 4 5
STEM_BIO11/12-Ia-c-3 STEM_BIO11/12-Ia-c-4 STEM_BIO11/12-Ia-c-5
Distinguish Classify different cell Describe some cell
prokaryotic and types (of plant/animal modifications that
eukaryotic cells tissues) and specify lead to adaptation to
according to their the functions of each carry out specialized
distinguishing functions (e.g.,
features microvilli, root hair)
INTRODUCTION
Label Me
PROKARYOTIC CELLS
AND EUKARYOTIC
CELLS.
Cells are the basic structures of all living
organisms. Every organism is composed of
one or two structurally different types of
cells: prokaryotic cells and eukaryotic cells.
 PROKARYOTES

Prokaryotes come from the Greek term pro meaning “before”
and karyon meaning “kernel” referring to the nucleus.
Prokaryotic cells have no nucleus, and their genetic material
(DNA) is concentrated in a region called the nucleoid which
does not have a membrane separating it from the rest of the
cell. The major parts of a prokaryotic cell include cell wall, cell
membrane, ribosomes, and a nucleoid.
 PROKARYOTES

Two domains of organisms comprise prokaryotes: Bacteria and
Archaea. Bacteria make up most of the prokaryotes. In
addition, Archaea are found in extreme environments such as
hot springs or near volcanoes. The difference between
Bacteria and Archaea is their type of cell wall: Archaea have a
thicker cell wall that is very strong and protects it from the
heat and chemicals found in harsh environments, while
Bacteria have a more permeable cell wall that provides less
protection from high temperatures or extreme pH, but takes
less energy to build.
PROKARYOTES
PROKARYOTES
 PROKARYOTES

Both Bacteria and Archaea consist of unicellular organisms.
Prokaryotes are important to all life on Earth for a number of
reasons. They play a critical role in the recycling of nutrients by
decomposing dead organisms and allowing their nutrients to
be re-used. They are also important for many metabolic
processes. Bacteria in our guts and mouth help with the
digestion of food by breaking down difficult to digest
carbohydrates and other compounds.
 PROKARYOTES

A prokaryotic cell is a simple, single-celled (unicellular)
organism that lacks a nucleus, or any other membrane-bound
organelle. We will shortly come to see that this is significantly
different in eukaryotes.

Prokaryotic DNA is found in the central part of the cell: a
darkened region called the nucleoid.
PROKARYOTIC CELL
EUKARYOTES

The oldest fossil evidence of eukaryotes is about 2 billion
years old. Eukaryotes are combination of two Greek terms
eu meaning “true” and karyon meaning “nucleus.” Thus,
eukaryote means “true kernel” or “true nucleus,” alluding
to the presence of the membrane-bound nucleus in these
cells. The word organelle means “little organ,” and
organelles have specialized cellular functions, just as the
organs of your body have specialized functions.
EUKARYOTES

A cell has a membrane-bound nucleus and other
membrane-bound compartments or sacs, called
organelles, which have specialized functions. The major
organelles found in a eukaryotic cell are cell membrane,
cell wall, ribosomes, nucleus, mitochondria, endoplasmic
reticulum, and lysosomes. They are both unicellular and
multicellular eukaryotes. The four kingdoms of eukaryotic
organisms are Kingdom Plantae, Kingdom Animalia,
Kingdom Fungi, and Kingdom Protista.
EUKARYOTES

Plants are photosynthetic organisms containing cell walls
and specialized reproductive tissue. Animals are
organisms that lack cell walls, are capable of locomotion,
and have a digestive tract. Fungi digest their food
externally and then absorb it through their cell walls.

Plants, animals, and fungi are all multicellular organisms.
Protists are single-celled motile organisms that can be
either photosynthetic or heterotrophic.
EUKARYOTIC CELL
ANIMAL CELLS

Animals are capable of movement, although not all animals
have muscles used for movement. In the most commonly
encountered animals, the mobile stage is the adult,
although some animals (such as corals and sponges) have
sessile (or nonmobile) adult phases and mobile juvenile
forms. Both animal and plant evolutionary history show the
development of multicellularity and they move from water
to land (as well as a secondary adaptation back to water,
for example dolphins, whales, duckweed, and elodea).

Animals developed external or internal skeletons to provide
support, skin to prevent or lessen water loss, muscles that
allowed them to move to search for food, brains and
nervous systems for integration of stimuli, and internal
digestive systems.
 ANIMAL TISSUES ARE DIVIDED
INTO FOUR MAIN TYPES:

1. Epithelial Tissue

This type of tissue is commonly seen outside
as coverings or as linings of organs and
cavities. It is characterized by closely-joined
cells with tight junctions. Being tightly
packed, tight junctions serve as barriers for
pathogens, mechanical injuries and fluid
loss. Cells that make up epithelial tissues
have distinct arrangements: cuboidal, simple
columnar, simple squamous, stratified
squamous, and pseudo-stratified columnar
 EPITHELIAL TISSUES

A. Cuboidal- for secretion
B. Simple columnar- brick-shaped cells; for secretion
and active absorption
C. Simple squamous - plate-like cells; for exchange of
material through diffusion
D. Stratified squamous- multilayered and regenerates
quickly for protection
E. Pseudo-stratified columnar - single layer of cells;
may just look stacked because of varying height; for
lining of respiratory tract; usually lined with cilia (i.e., a
type of cell modification that sweeps the mucus)
EPITHELIAL TISSUES
 ANIMAL TISSUES ARE DIVIDED
INTO FOUR MAIN TYPES:

2. Connective Tissue

These tissues are composed of the following:

A. BLOOD- made up of plasma (i.e., liquid extracellular
matrix): contains water, salts and dissolve proteins,
erythrocytes that carry oxygen (RBC), leukocytes for
defense (WBC), and platelets for blood clotting.
 CONNECTIVE TISSUE

B. 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

C. CARTILAGE

Characterized by collagenous fibers
embedded in chondroitin sulfate.
Chondrocytes are the cells that secrete
collagen and chondroitin sulfate. Cartilage
functions are cushion between bones.
 CONNECTIVE TISSUE

D. BONE

Mineralized connective tissue made by
bone-forming cells called osteoblasts
which deposits collagen. Blood vessels
and nerves are found at a central canal
surrounded by concentric circles of
osteon.
CONNECTIVE TISSUES
ANIMAL TISSUES ARE DIVIDED
INTO FOUR MAIN TYPES:

3. Muscle Tissue

These tissues are composed of long cells called muscle
fibers that allow the body to move voluntary or
involuntary. It gives rise to muscles' ability to contract. This
is opposed to other components or tissues in muscle such
as tendons or perimysium. It is formed during embryonic
development through a process known as myogenesis.
Muscle tissue consists of elongated cells also called as
muscle fibers. This tissue is responsible for movements in
our body. Movement of muscles is a response to signals
coming from nerve cells.
 MUSCLE TISSUE

3. Muscle Tissue

In vertebrates, these muscles can be
categorized into the following:
A. Skeletal- striated: voluntary movements,
attached to the skeleton
B. Cardiac- striated with intercalated disk
for synchronized heart contraction,
involuntary, located in the walls of the
heart
C. Smooth- not striated; involuntary,
located in walls of hollow visceral organs
 ANIMAL TISSUES ARE DIVIDED
INTO FOUR MAIN TYPES:

3. Muscle Tissue
 ANIMAL TISSUES ARE DIVIDED
INTO FOUR MAIN TYPES:

4. Nervous Tissue

These tissues are composed of nerve cells
called neuron and glial cells that function as
support cells. These neurons sense stimuli
and transmit electrical signals throughout
the animal body. Neurons connect to other
neuron that receives impulses from other
neurons, while the axon is the part where
the impulse is transmitted to other neurons.
 NERVOUS TISSUE
4. Nervous Tissue
 PLANT TISSUE
Plant cells with similar structure
and functions form plant tissue.
Plant tissues come in several
forms: vascular, epidermal,
ground, and meristematic. Each
type of tissue consists of different
types of cells, has different
functions, and is located in
different places.
 PLANT TISSUES ARE DIVIDED
INTO TWO MAIN TYPES:
1. Meristematic tissue - is actively dividing to
produce new cells. Meristematic tissue
consists of undifferentiated small cell, with
dense cytoplasm and large nuclei. The cells
differentiate into new tissue of the plant.
Meristematic tissue is found at the meristems
of plants:

A. Apical Meristem- are located at the
growing points at the tips of roots and stems
and results in an increase in the length of
these structures.
 MERISTEMATIC TISSUE
B. Lateral Meristem

Results in the growth in thickness or
width of woody roots and stems. This
tissue is also called cambium; cork
cambium divides to form the cork cells
that form the outer bark of a woody
plant. Vascular cambium divides to make
xylem and phloem tissue
 PLANT TISSUES ARE DIVIDED
INTO TWO MAIN TYPES:
2. Permanent Tissue

These are specialized in function and
do not divide constantly.
Differentiation of cells begins as soon
as cells have been formed by cell
division, and results in changes in
structure. There are three groups of
permanent tissue:
 PERMANENT TISSUE
A. Epidermal Tissue a. Guard cells - are bean- shaped
epidermal cells that occur on
This is the outermost layer either side of a stoma- which is
the opening that occurs on the
of cells that covers the surface of a leaf. The guard cells
roots, stems, and leaves. function to open and close the
They are tightly packed, stoma, thus controlling the loss of
water by transpiration.
with no intercellular air
spaces. The main function b. Hair cells - are formed by an
of the epidermal cells is to extension of the cell wall. The hair
functions to increase the surface
protect the underlying area of the root to maximize the
tissue from injury. uptake of water and nutrients.
GUARD CELLS
HAIR CELLS
 PERMANENT TISSUE
B. Vascular tissue a. Xylem Tissue- transport water and
mineral salts from the ground water
through the roots to the stems and
Functions to leaves. It consists of vessels and
tracheids- both cells have cell walls that
transport and are strengthened with lignin and both
support. types of cells are dead at maturity.

b. Phloem Tissue- transport food from
the leaves, where photosynthesis takes
place, to areas undergoing growth or
storage sites. Phloem tissue consists of
long columns of sieve tubes and
companion cells.
 GROUND TISSUE
This type of tissue forms the B. Collenchyma - thick
body of the plant and is walled and alive at maturity
responsible for support,
storage, and photosynthesis. C. Sclerenchyma- thick
walled and dead at
There are three types of maturity
ground tissue:

A. Parenchyma - thin walled
and alive at maturity; often
multifaceted.
GROUND TISSUE
WHAT IS CELL MODIFICATION?
Cell specialization or modification occurs after cell division
wherein newly formed cells are structurally modified so that
they can perform their function efficiently and effectively.
APICAL MODIFICATION
It is a cell modification found on the apical surface
of the cell.

Cilia and flagella
Cilia are usually short, hair-
like structures that move in
waves.
Flagella are long whip-like
structures.
Formed from microtubules
APICAL MODIFICATION
APICAL MODIFICATION
Both cilia and
flagella function
for cell locomotion.
APICAL MODIFICATION
Villi and microvilli
Villi are finger-like projections that arise from
epithelial layer in some organs. They help to
increase surface area allowing for faster and
more efficient adsorption.

Microvilli are smaller projections that arise
from the cell’s surface that also increase
surface area allowing faster and more efficient
adsorption.
APICAL MODIFICATION
Structure of Microvilli These projections
increase the
surface area of the
small intestine for
the absorption of
nutrients, and as a
higher surface
area = higher rate
of transportation
processes such as
diffusion, they thus
increase the rate
of absorption.
APICAL MODIFICATION
Pseudopods
Temporary, irregular
lobes formed by
amoebas and some
other eukaryotic cells
Bulge outward to move
the cell or engulf prey
From the Greek word
pseudes and podos,
meaning “false” and
“feet”.
APICAL MODIFICATION
Extracellular matrix (ECM)
Compound secreted by the cell
on its apical surface
Cell wall in the extracellular
structure in plant cells that
distinguishes them from animal
cell
Glycoprotein is the main
ingredient of ECM in animal
cells.
They cover external surface,
line up internal organs, take up
nutrients, export wastes, and
interact with the external
environment.
BASAL MODIFICATION
Cell modification found on the
basal surface of the cell
desmosomes/hemidesmosomes
Anchoring junction on the
basal surface of the cell
Rivet-like links between
cytoskeleton and extracellular
matrix components such as the
basal lamina that underlie
epithelia. Primarily composed
of keratin, integrin, and
cadherin.
BASAL MODIFICATION
LATERAL MODIFICATION
A cell junction that provides contact
between neighboring cells or between the
cell and extracellular matrix.

Tight Junction
Acts as barriers that
regulate the movement
of the water and solutes
between epithelial layers
Prevent leakage of ECF
LATERAL MODIFICATION
Adhering Junction
Anchoring
junction on the
lateral surface of
the cell
Very similar to the
anchoring
junction of the
basal surface of
the cell
Fasten cells to
one another
LATERAL MODIFICATION
Gap Junction
Also known as
communicating junctions
Closable channel that
connect the cytoplasm of
adjoining animal cells
Presence of connexon that
allow direct exchange of
chemical between the
cytoplasm of the cells
THANK YOU