Cells-and-Tissues (2).pdf

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ANATOMY & PHYSIOLOGY
CELLS & TISSUES

Lecture by: Mr. Stefan Paolo Jesalva
College of Arts and Sciences Faculty
Biology Department
CELLS AND TISSUES
Cells are the building blocks of
all living beings

Tissues are group of similar cells
from the same origin that carry
out a specific function
CELLS
Anatomy of the Cell
Cells are not all the same
All cells share general structures
Cells are organized into 3 main
regions
▪ Nucleus
▪ Cytoplasm
▪ Plasma membrane
MAIN REGIONS OF A HUMAN CELL
The Nucleus
Control center of the cell
Contains genetic material (DNA)
3 regions
Nuclear membrane
Nucleolus
Chromatin
NUCLEUS
Nuclear Membrane
Barrier of nucleus
Consists of a double
phospholipid (bi-layer) membrane
Contain nuclear pores allowing
material exchange with the rest
of the cell
Nucleoli
Nucleus contains one or more
nucleoli
It is a non-membrane bound
organelle taking part in synthesis of
ribosomes, including processing of
rRNA and the assembly of them
into ribosome subunits.
Nucleoli
The Nucleus is also involved in
several other cellular processes,
such as mitosis, stress response,
and cell cycle regulation.
After the synthesis step,
ribosomes will then migrate to
cytoplasm through nuclear pores
Staining of nucleoli in human cell line A-431
Chromatin
Composed of DNA & proteins
Scattered throughout the
nucleus
Chromatin condenses to form
chromosomes when the cell
division starts
Chromatin
Chromatin and condensed chromosome structure
Plasma Membrane
Barrier for cell contents
Double phospholipid layer
Hydrophilic heads + Hydrophobic tails
Other materials in plasma membrane
Protein
Cholesterol
Glycoproteins
Plasma Membrane
Plasma Membrane:
Specializations
Microvilli
Finger-like
projections that
increase surface
area for absorption
Plasma Membrane:
Specializations
Membrane
junctions
Tight junctions
Desmosomes & hemi-
desmosomes
Gap junctions
Cytoplasm
Material outside the nucleus and
inside the plasma membrane

Cytosol: Fluid that contains other elements
Organelles: Metabolic machinery of the cell
Inclusions: Non-functioning units (Lipids
…)
 Cytoplasmic Organelles
Ribosomes
▪ Made of protein and RNA
▪ Sites of protein synthesis
▪ Found at two locations
▪ Free in the cytoplasm
▪ Attached to rough endoplasmic
reticulum
Cytoplasmic Organelles

A ribosome “at work”
 Cytoplasmic Organelles
Endoplasmic reticulum (ER): Fluid-
filled tubules for carrying substances – 2 types
of ER

- Rough Endoplasmic Reticulum: is
studded with ribosomes and where building materials
of cellular membrane are formed.
- Smooth Endoplasmic Reticulum:
Functions in cholesterol synthesis and breakdown, fat
metabolism, and detoxification of drugs
Cytoplasmic Organelles

Schema of the 2 types of ER
Cytoplasmic Organelles

3D of the 2 types of ER
 Cytoplasmic Organelles
Golgi apparatus
▪ Modifies & packages proteins
▪ Produces several types of
packages
Secretory vesicles
Cell membrane components
Lysosomes
Cytoplasmic Organelles

Golgi Apparatus
Cytoplasmic Organelles

Golgi Apparatus “at work”
 Cytoplasmic Organelles
Mitochondria
▪ “Power-houses” of the cell
▪ Provide ATP for cellular energy
▪ Change shape constantly
▪ Carry out reactions using oxygen
break down food
Cytoplasmic Organelles

A mitochondrion
 Cytoplasmic Organelles
Lysosomes: Contain enzymes that digest
non-usable materials within the cell
Peroxisomes
▪ Membranous sacs of oxidase enzymes
▪ Detoxify harmful substances
▪ Break down free radicals
▪ Replicate by pinching in halves
 Cytoplasmic Organelles
Cytoskeleton
Network of protein structures
that extend throughout the
cytoplasm
Provides the cell with an internal
framework
 Cytoplasmic Organelles

The cytoskeleton. The actin is stained red and the microtubules,
which are composed of the protein tubulin, are stained green.
 Cytoplasmic Organelles
Cytoskeleton
3 different types
▪ Microfilaments
▪ Intermediate
filaments
▪ Microtubules
 Cytoplasmic Organelles

The cytoskeleton. This organelle is the ‘skeleton’ of our cells. It
maintains cell shape. We couldn’t move without the cytoskeleton’s
contractions of microtubules, microfilaments, and intermediate fibers.
 Cytoplasmic Organelles
Centrioles
▪ Rod-shaped bodies made of microtubules
▪ Direct formation of mitotic spindle
during cell division
▪ Probably involved in other cell functions
that are still not very well known
Cytoplasmic Organelles
Centrosome

Microtubule

Centriole

Centrioles
The Cell. The basic unit of structure and function.
 Cellular Projections
Not found in all types of cells
Used for movement:
▪ Cilia move materials across the cell
surface
▪ Flagellum propels the whole cell (e.g. sperm
cell)
 Cellular Projections

Flagella and cilia differ in the way they move. Flagella use an
undulating, propeller-like motion to propel a cell. Cilia beat back and
forth, perpendicular to the cilium, bending & sweeping sideways.
 Cellular Projections

Flagella and cilia. Movement and structure.
Cell Diversity
Cell Diversity
Cell Diversity
Cell Diversity
Cellular Physiology:
Membrane Transport

Membrane Transport – movement of
substance in and out of the cells
Transport is by 2 basic methods:
▪ Passive transport: No energy is required
▪ Active transport: Metabolic energy
required
Solutions and Transport
Solution: homogeneous mixture
of 2 or more components
▪ Solvent: dissolving medium (e.g. Water)
▪ Solutes: components in smaller quantities
within a solution
Intracellular fluid: nucleoplasm & cytosol
Interstitial fluid: fluid on the exterior of
the cell (Extracellular fluid)
Selective Permeability
The plasma membrane allows
some materials to pass while
excluding others
This permeability includes
movement in and out of the
cells
Passive Transport Processes
Diffusion
Particles tend to distribute
themselves evenly within a solution
Movement is from high
concentration to low
concentration, or down a
concentration gradient
Passive Transport Processes

Diffusion.
Passive Transport Processes
Types of diffusion
Simple diffusion: Unassisted process. Solutes are
lipid-soluble materials or small enough to pass
through membrane pores.
Osmosis – simple diffusion of water: Highly
polar water easily crosses the plasma
membrane.
Facilitated diffusion: Substances require a
protein carrier for passive transport.
Diffusion through Plasma Membrane
Passive Transport Processes
Filtration: Water and solutes are
forced through a membrane by
fluid, or hydrostatic pressure.
▪ A pressure gradient must exist
▪ Solute-containing fluid is pushed from
high pressure area to lower pressure
one
Active Transport Processes
Transport of substances that are not
able to pass by diffusion because they:
▪ May be too large
▪ May be unable to dissolve in the fat of
membranes
▪ May have to move against a concentration
gradient
2 common forms of active transport:
Solute pumping & Bulk transport
Active Transport Processes
Solute pumping
▪ Amino acids, some sugars and
ions are transported by solute
pumping
▪ ATP energizes protein carriers, &
in most cases, moves substances
against concentration gradients
Solute Pumping
Active Transport Processes
Bulk transport
Exocytosis: Moves materials out of the
cell. Material is carried in a membranous
vesicle.
STEPS:
▪ Vesicle migrates to plasma membrane
▪ Vesicle combines with plasma membrane
▪ Material is emptied to the outside
Exocytosis
Active Transport Processes
Bulk transport
Endocytosis: Extracellular substances are
engulfed by being enclosed in a
membrane vesicle.
TYPES OF ENDOCYTOSIS:
Phagocytosis: cell eating
Pinocytosis: cell drinking
Endocytosis
Cell Life Cycle
Cells have 2 major periods
Interphase: Cell grows and carries
on metabolic processes
Cell division: Cell replicates itself to
produce more cells for growth and
repair processes
DNA Replication
Genetic material
duplicated and readies a
cell for division into two
cells
Occurs toward the end
of interphase
DNA uncoils and each
side serves as a template
Cell Division Steps
Mitosis: Division of the nucleus.
Results in the formation of 2 nuclei.

Cytokinesis: Division of the cytoplasm.
Begins when mitosis is near completion.
Results in the formation of 2 new cells.
Stages of Mitosis
Interphase: No cell division occurs.
The cell carries out normal metabolic
activity & growth.

Prophase: First part of cell division.
Centromeres migrate to the poles
Stages of Mitosis

Metaphase: Spindle from
centromeres are attached to
chromosomes that are aligned in the
center of the cell
Stages of Mitosis

Anaphase: Daughter chromosomes are
pulled toward the poles. The cell begins
to elongate.

Telophase: Daughter nuclei begin
forming. A cleavage furrow (for cell
division) begins to form
Stages of Mitosis
Stages of Mitosis
 Protein Synthesis
Gene: DNA segment that carries a
‘blueprint‘ for building one protein
Proteins have many functions
▪ Building materials for cells
▪ Act as enzymes (biological catalysts)
RNA is essential for protein synthesis
Role of RNA
Transfer RNA (tRNA): Transfers
appropriate amino acids to the ribosome for
building the protein
Ribosomal RNA (rRNA): Helps form the
ribosomes where proteins are built
Messenger RNA (mRNA): Carries the
instructions for building a protein from the
nucleus to the ribosome
Transcription and Translation
Transcription: Transfer of information
from DNA’s base sequence to the
complimentary base sequence of mRNA.
Translation: Base sequence of nucleic
acid is translated to an amino acid
sequence.
Remember? Amino acids are the
building blocks of proteins
Proteins Synthesis
TISSUES
Body Tissues
Cells are specialized for particular
functions

Tissues: Groups of cells with
similar origin, structure and
function
Body Tissues
4 primary types of tissues:
Epithelium
Connective tissue
Nervous tissue
Muscle
Epithelial Tissues
Found in different areas
▪ Body coverings
▪ Body linings
▪ Glandular tissue
Functions
▪ Protection
▪ Absorption
▪ Filtration
▪ Secretion
Epithelium Characteristics
Cells fit closely together
Tissue layer always has one free
surface
The lower surface is bound by a
basement membrane
Avascular (have no blood supply)
Regenerate easily if well nourished
Classification of Epithelium
1-Number of cell layers:
Simple: one layer
Stratified: more
than one layer
2- Shape of cells:
Squamous: flattened
Cuboidal: cube-shaped
Columnar : column-like
Simple Epithelium
Simple squamous

Single layer of flat cells
Usually forms
membranes (Lines body
cavities, Lines lungs and
capillaries)
Simple Epithelium
Simple cuboidal
Single layer of cube-
like cells
Common in glands
and their ducts
Forms walls
of kidney tubules
Covers the ovaries
Simple Epithelium
Simple
columnar
Single layer of tall
cells
Often includes
goblet cells, which
produce mucus
Lines digestive tract
Simple Epithelium
Pseudostratified
Single layer, but some
cells are shorter than
others
Often looks like a double
cell layer
Sometimes ciliated, such
as in the respiratory tract
May function in
absorption or secretion
Stratified Epithelium
Stratified
squamous
Cells at the free edge
are flattened
Found as a protective
covering where
friction is common
Locations: Skin, Mouth,
Esophagus.
Stratified Epithelium
Stratified cuboidal: Two layers of cuboidal
cells.
Stratified columnar: Surface cells are
columnar, cells underneath vary in size and
shape.
Stratified cuboidal and columnar: Rare
in human body. Found mainly in ducts of
large glands.
Stratified Epithelium
Transitional
epithelium
Shape of cells depends
upon the amount of
stretching
Lines organs of the
urinary system
Glandular Epithelium
Gland: one or more cells that
secretes a particular product

2 major gland types:
▪ Endocrine gland: Ductless, Secretions are
hormones.
▪ Exocrine gland: Empty through ducts to
the epithelial surface. Include sweat & oil
glands.
Connective Tissue
Found everywhere in the body
Includes the most abundant and
widely distributed tissues
Functions:
▪ Binds body tissues together
▪ Supports the body
▪ Provides protection
Connective Tissue Characteristics
Variations in blood supply
▪ Some tissue types are well vascularized
▪ Some have poor blood supply or are
avascular

Extracellular matrix: Non-living material
that surrounds living cells
Extracellular Matrix
2 main elements:
Ground substance: mostly water along
with adhesion proteins and
polysaccharide molecules
Fibers:
▪ Produced by the cells
▪ 3 types
Collagen fibers
Elastic fibers
Reticular fibers
Connective Tissue Types
Bone (osseous tissue):
Used to protect and support the body.
Composed of:
Bone cells in lacunae
(cavities)
Hard matrix of calcium
salts
Large numbers of
collagen fibers
Connective Tissue Types
Hyaline cartilage:
Most common cartilage.
The entire fetal skeleton is
hyaline cartilage.

Composed of:
▪ Abundant collagen fibers
▪ Rubbery matrix
Connective Tissue Types

Elastic cartilage
Provides elasticity
Example: supports the external ear
Connective Tissue Types

Fibrocartilage
Highly compressible
Example: forms
cushion-like discs
between vertebrae
Connective Tissue Types
Dense connective tissue
Main matrix element
is collagen fibers
Cells are fibroblasts
Examples:
Tendon – attach
muscle to bone
Ligaments – attach
bone to bone
Connective Tissue Types
Areolar connective tissue

Most widely distributed
connective tissue
Soft, pliable tissue
Contains all fiber types
Can soak up excess fluid
Connective Tissue Types
Adipose tissue (Fat)
Matrix is an areolar tissue in which fat
globules predominate. Many cells
contain
large lipid deposits.
Functions:
▪ Insulates the body
▪ Protects some organs
▪ Serves as a site of
fuel storage
Connective Tissue Types
Reticular connective tissue
Delicate network of
interwoven fibers
Forms stroma
(internal supporting
network) of
lymphoid organs
▪ Lymph nodes
▪ Spleen
▪ Bone marrow
Connective Tissue Types
Blood
Blood cells
surrounded by fluid
matrix
Fibers are visible
during clotting
Functions as the
transport vehicle for
materials
Muscle Tissue
Function is to produce movement
3 types
▪ Skeletal muscle
▪ Cardiac muscle
▪ Smooth muscle
Muscle Tissue Types
Skeletal muscle
Can be controlled
voluntarily
Cells attach to
connective tissue
Cells are striated
Cells have more than one
nucleus
Muscle Tissue Types
Cardiac muscle
Found only in the heart
Function is to pump
blood (involuntary)
Cells attached to other
cardiac muscle cells at
intercalated disks
Cells are striated
One nucleus per cell
Muscle Tissue Types
Smooth muscle
Involuntary muscle
Surrounds hollow organs
Attached to other
smooth muscle cells
No visible striations
One nucleus per cell
Nervous Tissue
Neurons and
nerve support
cells
Function is to
send impulses
to other areas
of the body
Irritability
Conductivity
Tissue Repair
Regeneration: Replacement of
destroyed tissue by the same kind of
cells
Fibrosis: Repair by dense fibrous
connective tissue (scar tissue)
Determination of method
▪ Type of tissue damaged
▪ Severity of the injury
Events in Tissue Repair
Capillaries become very permeable
Introduce clotting proteins & Wall off injured
area

Formation of granulation tissue
Regeneration of surface epithelium
Regeneration of Tissues
Tissues that regenerate easily:
▪ Epithelial tissue
▪ Fibrous connective tissue and bone
Tissues that regenerate poorly: Skeletal
muscle

Tissues that are replaced largely with scar
tissue:
▪ Cardiac muscle
▪ Nervous tissue within the brain and spinal cord
Development aspects of Tissues
Epithelial tissue arises from all 3
primary germ layers
Muscle & connective tissue arise from
the mesoderm
Nervous tissue arises from the
ectoderm
With old age there is a decrease in
mass and viability in most tissues
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