Bio-Biology Topic 1 PDF

Summary

This document provides an overview of cells, their characteristics, and related concepts including reproduction, growth, and energy/metabolism. It discusses relevant topics such as different types of cells, cellular structures, and associated biological processes.

Full Transcript

Types of cells and some cellular
organelles of eukaryotes

Prof. Hossam El-Din M. Omar
Learning Objectives
By the end of the course, you will be able to:

✓ Distinguish between the prokarocyte and
eupkarocyte.
✓ List the structure and function of the cellular
organelles.
✓ Explain the how the mitochondria play an important
role in metabolism.
✓ Describe the different functions of cell membranes.
✓ Studying the types and examples for animal cells in
different tissues.
✓ Explain the role of nucleic acid in genetics and
cellular communication.
 Characteristics of Life
1. Composed of Cells
2. Reproduction
3. Growth & Development
4. Obtain & Use Energy…METABOLISM
5. Respond to environment
6. Homeostasis
7. DNA is the ‘Universal Genetic Code
8. Evolution and Adaptation
Levels of Organization…Continued
Organs

Organ Systems

Organism
Levels of
Organization
 A cell is the basic unit of life…All cells come
from preexisting cells
 Unicellular Multicellular
 Organisms composed Organisms composed of
many cells…diversity and
of a single cell
specialization of function
(over 85 types of cells in
the human body)
Complex Tissue Structure:
As multicellular organisms, most animals develop
specialized cells that group together into tissues with
specialized functions.
A tissue is a collection of similar cells that had a
common embryonic origin.
There are four main types of animal tissues: nervous,
muscle, connective, and epithelial. Nervous tissue
contains neurons, or nerve cells, which transmit nerve
impulses. Muscle tissue contracts to cause all types of
body movement. Animals also have specialized
connective tissues that provide many functions, including
transport (Blood) and structural support (bone).
 Reproduction
Asexual Reproduction:  Sexual Reproduction:
– Single parent copies its  Two different parent
DNA and then divides cells unite to produce
or ‘buds’ to produce the first cells of a new
GENETICALLY organism.
IDENTICAL OFFSPRING.
 Offspring are
– This can mean ‘rapid- GENETICALLY UNIQUE
fire’ reproduction of leading to greater
great numbers of genetic diversity and
identical organisms speciation on Earth.
 All organisms grow and develop

 Multicellular organisms
Single celled  undergo extensive
organisms (like development from a single
bacteria) growth fertilized egg dividing many,
is mostly a many times to produce the
simple increase multitude of cells in mature
in size organisms
 Differentiation is the
changing of shape and
structure to perform
different functions.
 Obtain and Use Energy
All living things obtain energy from their
environment or surroundings and use it for growth,
development, reproduction, and excretion – these
processes occur at different rates…
METABOLISM = Anabolism (synthesizing
compounds – expends energy) + Catabolism
(breaking compounds into simple components
– releases energy)
= Combination of chemical reactions (total activity) that
build and break down materials as organisms carry out
their life processes.
 Living organisms respond to the
environment
 Organisms detect and respond to a STIMULUS (signal) or
anything in the environment that causes a response
whether internal or external.
Internal stimuli are External stimuli include
things like blood light, touch, sound,
glucose level (low heat, smell, sight…
levels make you feel
hungry, possibly weak,
tired, head-achy, etc)
 Homeostasis
The autonomic (self-controlled)
processes by which organisms respond
to stimuli such that conditions in the
body are kept suitable to sustain life for
example respond of body to bleeding
and heat stress
▪ All life is based on a UNIVERSAL GENETIC
CODE…DNA, determining the inherited traits
of all organisms!
DNA is a type of biomolecule known as a
Nucleic Acid that had a three dimensional
shape called a double helix. The shape of
DNA allows for duplication and ‘reading’ or
expressions of the genes it encodes.
 EVOLUTION is ability of a group of
organisms to change over time. This
invaluable for survival in constantly changing
environments…
ADAPTATION is a trait of a living thing that
helps it compete and survive to reproduce in
its environment.
 The Cell

The cell is the lowest level of organization that can
perform all activities required for life. All cells are
enclosed by a membrane and use DNA as their
genetic information.
A eukaryotic cell has membrane-enclosed
organelles, the largest of which is usually the
nucleus
By comparison, a prokaryotic cell is simpler and
usually smaller, and does not contain a nucleus or
other membrane-enclosed organelles
 The Cell Theory
1. Cells” were named by Englishman Robert Hooke in 1665.
2. The cell is the basic unit of structure and function.
3. All organisms are made of one or more cells.
4. All cells come from pre-existing cells.
 Types of Cells

Prokaryotic Cells Eukaryotic Cells
The first and most primitive Most organisms have
cells eukaryotic cells (ex: all plant
Lack a nucleus and other and animal cells!)
membrane bound organelles All genetic material is
(mitochondria, etc) contained in a nucleus
Bacteria are the ONLY Have many membrane
prokaryotes bound organelles
Functions of the Plasma Membrane
1- Physical Barrier
Protects all the components of the cell from the outside
environment and allows separate activities to occur inside and
outside the cell.
The plasma membrane provides structural support to the cell.
2- Selective Permeability
Plasma membranes are selectively permeable, meaning that only
certain molecules can pass through them.
3- Endocytosis and Exocytosis
Endocytosis is ingestion of relatively larger molecules that pass
through channels.
Exocytosis is when the cell releases these materials.
4- Cell Signaling
Facilitate communication and signaling between cells. Proteins on
the cell “mark” that cell so that other cells can identify it. The
membrane also has receptors that allow it to carry out certain tasks
when molecules such as hormones bind to those receptors.
Passive transport across cell membranes

1. Diffusion:
Molecules and ions move freely in gases and liquids, each type of
these particles tends to spread out evenly within the space available.
Diffusion is the net movement of molecules from a region of its
higher concentration to a region of its lower concentration with no
energy is used.
Facilitated diffusion: is the movement of specific molecules down a
concentration gradient with the aid of special channel or carrier protein
and no energy is used. Ions or electrically charged molecules are not
able to diffuse through the phospholipid bilayer because they are
repelled from the hydrophobic tails. Large molecules are also unable to
move through the phospholipid bilayer freely. However, the cell
membrane contains special channel protein that provide hydrophilic
passageways for these special ions and molecules. Diffusion through
these channel proteins is called facilitated diffusion.
Phagocytosis = “cellular eating” via lysosome
Pinocytosis = “cellular drinking”
Receptor-mediated endocytosis → triggered by
ligand signal
 Exocytosis
Using a secretory vesicle to remove food, wastes
from cell
 Construction of Cell Membranes
Membrane proteins provide a variety of cell
functions
 Passive Transport - Osmosis
Direction of osmosis is determined by
comparing total solute concentrations
– Hypertonic = more solute, less water
– Hypotonic = less solute, more water
– Isotonic = equal solute, equal water
Erythrocyte equilibrium
No osmotic pressure
- cell is in an isotonic solution
- Water does not cross
membrane

Increased [Osmotic] in cytoplasm
- cell is in an hypotonic solution
- Water enters cell, swelling

Decreased [Osmotic] in cytoplasm
- cell is in an hypotonic solution
- Water leaves cell, shrinking
 Cell Lysis
Using hypotonic
solution
Or interfering with
Na+ equilibrium causes
cells to burst
This can be used to
researchers’ advantage
when isolating cells
What are Mitochondria?
Popularly known as the “Powerhouse of the
cell,” mitochondria (singular: mitochondrion)
are a double membrane-bound organelle
found in most eukaryotic organisms. They are
found inside the cytoplasm. They play a major
role in breaking down nutrients and
generating energy-rich molecules for the cell.
Many of the biochemical reactions involved in
cellular respiration take place within the
mitochondria.
Structure of Mitochondria:

The mitochondrion is a double-membraned, rod-
shaped structure. Its size ranges from 0.5 to 1.0
micrometre in diameter. The structure comprises an
outer membrane, an inner membrane, and a gel-
like material called the matrix. The outer
membrane and the inner membrane are made of
proteins and phospholipid layers separated by the
intermembrane space. The outer membrane covers
the surface of the mitochondrion and has a large
number of special proteins known as porins.
Cristae:
The inner membrane of mitochondria is rather complex in
structure. It has many folds that form a layered structure
called cristae, and this helps in increasing the surface area
inside the organelle. The cristae and the proteins of the
inner membrane aid in the production of ATP molecules.
The inner mitochondrial membrane is strictly permeable
only to oxygen and ATP molecules. A number of chemical
reactions take place within the inner membrane of
mitochondria.
Mitochondrial Matrix: is a viscous fluid that contains a
mixture of enzymes and proteins. It also comprises
ribosomes, inorganic ions, mitochondrial DNA, nucleotide
cofactors, and organic molecules. The enzymes present in
the matrix play an important role in the synthesis of ATP
molecules.
Functions of Mitochondria
1-The most important function of mitochondria is to
produce energy through the process of oxidative
phosphorylation.
2- Regulates the metabolic activity of the cell
3- Promotes the growth of new cells and cell multiplication
4- Helps in detoxifying ammonia in the liver cells
5- Plays an important role in apoptosis or programmed cell
death
6- Helps in maintaining an adequate concentration of
calcium ions within the compartments of the cell
7- It is also involved in various cellular activities like cellular
differentiation and cell signalling
8- Controlling the cell cycle and in cell growth.
Mitochondrial DNA
❖ Although most of our DNA is kept in the nucleus of each
cell, mitochondria have their own set of DNA. Interestingly,
mitochondrial DNA (mtDNA) is more similar to bacterial
DNA.
❖ The mtDNA holds the instructions for a number of
proteinsTrusted Source and other cellular support
equipment across 37 genes.
❖ The human genome stored in the nuclei of our cells
contains around 3.3 billion base pairs, whereas mtDNA
consists of less than 17,000Trusted Source.
❖ During reproduction, half of a child’s DNA comes from
their father and half from their mother. However, the child
always receives their mtDNA from their mother. Because
of this, mtDNA has proven very useful for tracing genetic
lines
Producing energy
ATP, is often referred to as the molecular unit of
currency because it powers metabolic processes.
Most ATP is produced in mitochondria through a
series of reactions, known as the citric acid cycle or
the Krebs cycle.
Energy production mostly takes place on the folds or
cristae of the inner membrane.
Mitochondria convert chemical energy from the food
we eat into an energy form that the cell can use
(oxidative phosphorylation).
The Krebs cycle produces a chemical called NADH.
NADH is used by enzymes embedded in the cristae to
produce ATP.
Cell death
▪ Cell death (apoptosis) is an essential part of life. As cells
become old or broken, they are cleared away and destroyed.
Mitochondria help decide which cells are destroyed.
▪ Mitochondria release cytochrome C, which activates caspase,
one of the chief enzymes involved in destroying cells during
apoptosis. Because certain diseases, such as cancer, involve a
breakdown in normal apoptosis, mitochondria are thought to
play a role in the disease.
Storing calcium
▪ Because calcium is critical, the cell regulates it tightly.
Mitochondria play a part in this by quickly absorbing
calcium ions and holding them until they are needed.
▪ Calcium is vital for the release of a neurotransmitter
from a nerve cell or hormones from endocrine cells,
muscle function, and blood clotting.
Symptoms of mitochondrial diseases can include:
▪ Poor growth.
▪ Muscle weakness, muscle pain, low muscle tone, exercise
intolerance.
▪ Vision and/or hearing problems.
▪ Learning disabilities, delays in development.
▪ Heart, liver or kidney diseases.
▪ swallowing difficulties, diarrhea or constipation,
unexplained vomiting.
▪ Increased risk of infection.
▪ Neurological problems.
▪ Movement disorders.
▪ Thyroid problems.
▪ Respiratory (breathing) problems.
Thanks