General Biology 1 Week 6 PDF

Summary

This document contains lecture notes on General Biology, covering topics like fermentation, respiration, cell membranes, and different types of cellular transport. The document contains diagrams meant to illustrate the topic.

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GENERAL
BIOLOGY
1
WEEK 6
LESSON 1: FERMENTATION
AND AEROBIC
RESPIRATION
LESSON 2: “COOL BUT FEARFUL”
CELL MEMBRANE
Activity 1: LET’S DEFFERENTIATE?
Direction: Differentiate the two pictures below..
Activity 1: LET’S DEFFERENTIATE?
Direction: Differentiate the two pictures below..
Is it wonderful to see plants, animals and
other living organisms? Have you ever
questioned how these living organisms
grow? How water from soil enter the roots?
How oxygen and carbon dioxide enter
and leave the lungs? Also how glucose
from the small intestine enter the blood?
 In this lesson you will find out that there
are simple and complex activities that are
happening in the cell. The cell has transport
mechanisms namely the Passive and active
transport that allow selective materials to
come in and come out of the cell. You will
be able to understand how passive
transport and active transport works.
LESSON 1: TRANSPORT
MECHANISMS IN CELL

LESSON 2: EXOCYTOSIS AND
ENDOCYTOSIS
OBJECTIVES:
a. Explain transport mechanisms in cells
(diffusion osmosis, facilitated transport,
active transport) and
b. Differentiate exocytosis and endocytosis.
LESSON 1: TRANSPORT
MECHANISMS IN CELL
LESSON 2: EXOCYTOSIS AND
ENDOCYTOSIS
 Membrane transport refers to the
collection of mechanisms that regulate
the passage of solutes such as ions and
small molecules through cell/plasma
membranes, which are lipid bilayers that
contain proteins embedded in them.
 The regulation of passage through
the membrane is due to selective
membrane permeability - a
characteristic of biological membranes
which allows them to separate substances
of distinct chemical nature. In other words,
they can be permeable to certain
substances but not to others.
 The movements of most solutes through the
membrane are mediated by membrane
transport proteins which are specialized to
varying degrees in the transport of specific
molecules.
As the diversity and physiology of the
distinct cells is highly related to their capacities to
attract different external elements, it is
postulated that there is a group of specific
transport proteins for each cell type and for every
specific physiological stage.
 This differential expression is regulated
through the differential transcription of the genes
coding for these proteins and its translation, for
instance, through genetic-molecular
mechanisms, but also at the cell biology level:
the production of these proteins can be
activated by cellular signaling pathways, at the
biochemical level, or even by being situated in
cytoplasmic vesicles.
There are two major ways in which molecule or particles can move across
a membrane. It is either by passive or active transport.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

PASSIVE TRANSPORT This process does not require
energy for molecules to pass through
the plasma membrane.
Molecules move down their
concentration gradient.
A gradient is any imbalance in the
concentration.
Passive transport moves molecules
from higher concentration to lower
concentration.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

PASSIVE TRANSPORT
This process is carried out to
maintain an equilibrium level
in a cell.
Passive transport moves
molecules by Simple Diffusion,
and Facilitated Diffusion or
Osmosis.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

PASSIVE TRANSPORT
Simple Diffusion allows non polar
molecules such as oxygen (O2)
and carbon dioxide (CO2) to
pass directly on the membrane.
Facilitated Diffusion does not
require energy but needs a
membrane transport channel or
carrier protein to transport ions
such as sodium (Na+) and
potassium (K+).
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

PASSIVE TRANSPORT
Osmosis is a special type of diffusion
specifically associated with the
movement of water molecules.
A solution with higher concentration of
solutes is said to be hypertonic while a
solution with a lower concentration of
solutes is hypotonic. Water crosses the
membrane until the solute concentrations
are equal on both sides. Solutions of equal
solution concentration are said to be
isotonic.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

PASSIVE TRANSPORT
Osmosis is a special type of diffusion
specifically associated with the movement of
water molecules.
A solution with higher concentration of solutes
is said to be hypertonic while a solution with a
lower concentration of solutes is hypotonic.
Water crosses the membrane until the solute
concentrations are equal on both sides.
Solutions of equal solution concentration are
said to be isotonic.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

ACTIVE TRANSPORT
is the movement of molecules from
region of low concentration to high
concentration. It occurs against a
concentration gradient that is why
it requires energy released from
ATP (Adenosine triphosphate) for
molecules to pass through the cell
membrane.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

ACTIVE TRANSPORT
Primary active transport uses
energy usually through ATP
hydrolysis. Secondary active
transport relies on primary active
transport, it requires energy and
moves against a concentration
gradients.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

ACTIVE TRANSPORT Exocytosis, endocytosis and
sodium-potassium pump are a
few examples of active
transport.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

ACTIVE TRANSPORT Large molecules enter the cell by
generalized non-selective process
known as ENDOCYTOSIS.
Phagocytosis is endocytosis of a
particulate material while pinocytosis
is endocytosis of liquid material. In
this process, the plasma membrane
engulfs the particle or fluid droplet
and pinches off a membranous sac
or vesicles with a particular fluid
inside into the cytoplasm.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

ACTIVE TRANSPORT Large molecules enter the cell by
generalized non-selective process
known as ENDOCYTOSIS.
Phagocytosis is endocytosis of a particulate
material while pinocytosis is endocytosis of
liquid material. In this process, the plasma
membrane engulfs the particle or fluid
droplet and pinches off a membranous sac
or vesicles with a particular fluid inside into
the cytoplasm.
 There are two major ways in which molecule or particles can move across a membrane. It is either
by passive or active transport.

ACTIVE TRANSPORT
EXOCYTOSIS is the reverse process
where a membrane- bound vesicle
filled with bulky materials moves to
the plasma membrane and fuses
with it. In this process, the vesicles
contents are released out of the
cell.
DIFFERENCES
BETWEEN
ENDOCYTOSIS AND
EXOCYTOSIS
LESSON 2: EXOCYTOSIS AND
ENDOCYTOSIS
 In addition to moving small ions and
molecules through the membrane, cells also
need to remove and take in larger molecules and
particles. Some cells are even capable of
engulfing entire unicellular microorganisms. You
might have correctly hypothesized that the
uptake and release of large particles by the cell
requires energy. A large particle, however,
cannot pass through the membrane, even with
energy supplied by the cell.
 In this lesson, we'll discover how some cells
can eat, drink, and digest their dinner through the
process of endocytosis and a structure called the
lysosome. Furthermore, we'll learn how a cell can
throw out the leftovers across the cell membrane
during exocytosis
 In this lesson, we'll discover how some cells
can eat, drink, and digest their dinner through the
process of endocytosis and a structure called the
lysosome. Furthermore, we'll learn how a cell can
throw out the leftovers across the cell membrane
during exocytosis
DIFFERENCES
BETWEEN
ENDOCYTOSIS AND
EXOCYTOSIS
 ENDOCYTOSIS AND EXOCYTOSIS:
DIFFERENCES AND SIMILARITIES

Endocytosis and exocytosis are the processes by which
cells move materials into or out of the cell that are too large
to directly pass through the lipid bilayer of the cell
membrane. Large molecules, microorganisms and waste
products are some of the substances moved through the
cell membrane via exocytosis and endocytosis.
Why is bulk transport important for cells?

Cell membranes are semi-permeable, meaning they allow
certain small molecules and ions to passively diffuse
through them. Other small molecules are able to make
their way into or out of the cell through carrier proteins or
channels.
Why is bulk transport important for cells?

Endocytosis and exocytosis are the bulk transport
mechanisms used in eukaryotes. As these transport processes
require energy, they are known as active transport processes.
WHAT IS ENDOCYTOSIS?
Endocytosis is the process by which
cells take in substances from outside of the
cell by engulfing them in a vesicle. These
can include things like nutrients to support
the cell or pathogens that immune cells
engulf and destroy.
Endocytosis occurs when a portion
of the cell membrane folds in on itself,
encircling extracellular fluid and various
molecules or microorganisms. The resulting
Endocytosis serves many purposes, including:

Taking in nutrients for cellular growth, function and repair: Cells need
materials like proteins and lipids to function.
Capturing pathogens or other unknown substances that may endanger
the organism: When pathogens like bacteria are identified by the
immune system, they are engulfed by immune cells to be destroyed.
Disposing of old or damaged cells: Cells must be safely disposed of
when they stop functioning properly to prevent damage to other cells.
These cells are eliminated through endocytosis.
Types of endocytosis
There are two types of endocytosis: phagocytosis and pinocytosis.

PHAGOCYTOSIS
Phagocytosis, also known as cell eating, is
the process by which cells internalize large particles
or cells, like damaged cells and bacteria. 8 Within
the human body, and in other mammals,
phagocytosis is how immune cells engulf and
destroy dangerous microorganisms or toxic
compounds. Macrophages and neutrophils, types
of white blood cells, are the two primary
phagocytes. These white blood cells are responsible
for clearing out aged and damaged cells, as well
as disposing of infectious microorganisms.
Types of endocytosis
There are two types of endocytosis: phagocytosis and pinocytosis.

Pinocytosis
Pinocytosis, also known as cell
drinking, is common in plant and animal
cells. During pinocytosis, the cell takes in
substances from the extracellular fluid that
it needs to function. These include things
like water and nutrients
The steps of endocytosis
The following is an outline of the basic steps of the two types of
endocytosis.
Phagocytosis:
A particle or substance binds to receptors on
the cell’s surface, stimulating the release of
pseudopodia (extensions of the plasma
membrane filled with cytoplasm).
Pseudopodia surround the object until their
membranes fuse, forming a phagocytic
vesicle.
The phagocytic vesicle pinches off from the
cell membrane, entering the cell.
The phagocytic vesicle fuses with lysosomes,
which recycle or destroy the vesicle’s
contents.
The steps of endocytosis
The following is an outline of the basic steps of the two types of
endocytosis.
Pinocytosis:
Molecules bind to receptors located along
the surface of the cellular membrane.
The plasma membrane folds in, forming a
pinocytic vesicle that contains the molecules
and the extracellular fluid.
The pinocytic vesicle detaches from the cell
membrane inside the cell.
The vesicle fuses with early endosomes where
the contents found within
Endocytosis example
Macrophages are a type of white blood cell that play a central
role in protecting mammals against pathogens like bacteria and
viruses. When a macrophage comes into contact with a virus, say a
cold virus in the bloodstream, it can bind to the virus’s cell surface. Next,
the macrophage will form a vesicle around the virus, completely
ingesting it. The vesicle then travels to the cytosol and fuses with the
lysosome, where the virus is broken down. Some viruses replicate by
“tricking” host cells into endocytosing them, at which point the cell is
hijacked by the virus and is instructed to replicate the virus genome and
capsid.
WHAT IS EXOCYTOSIS?
Exocytosis is the process by which
cells move materials from within
the cell into the extracellular fluid.
Exocytosis occurs when a vesicle
fuses with the plasma membrane,
allowing its contents to be
released outside the cell.
Exocytosis serves the following purposes:

Removing toxins or waste products from the cell’s interior: Cells
create waste or toxins that must be removed from the cell to
maintain homeostasis. For instance, in aerobic respiration, cells
produce the waste products carbon dioxide and water during ATP
formation. Carbon dioxide and water are removed from these cells
via exocytosis.
Exocytosis serves the following purposes:

Facilitating cellular communication: Cells create signaling molecules
like hormones and neurotransmitters. They are delivered to other cells
following their release from the cell through exocytosis.

Facilitating cellular membrane growth, repair, signaling and
migration: When cells absorb materials from outside the cell during
endocytosis, they use lipids and proteins from the plasma membrane
to create vesicles. When certain exocytotic vesicles fuse with the
cellular membrane, they replenish the cell membrane with these
materials.
TYPES OF EXOCYTOSIS:

REGULATED EXOCYTOSIS
Most exocytotic vesicles contain substances created
within the endoplasmic reticulum for use elsewhere in the
body, such as neurotransmitters or hormones. These
molecules are then packaged within a layer of membrane
called a vesicle.
TYPES OF EXOCYTOSIS:

REGULATED EXOCYTOSIS
Once excreted from the endoplasmic reticulum, these
vesicles are transported to the Golgi apparatus (also known
as the Golgi complex) for further modification. The molecules
are then packaged once again in a vesicle that makes its
way to the plasma membrane.
TYPES OF EXOCYTOSIS:

REGULATED EXOCYTOSIS
The release of these molecules from the cell is termed
regulated exocytosis because the expulsion of the materials
is controlled, or regulated, by extracellular signals that cause
membrane depolarization.
TYPES OF EXOCYTOSIS:

CONSTITUTIVE EXOCYTOSIS
Constitutive exocytosis, in contrast, doesn’t require any
extracellular signals. The majority of molecules traveling to
the plasma membrane do so using this pathway.
TYPES OF EXOCYTOSIS:

CONSTITUTIVE EXOCYTOSIS
After exocytosis, some exocytotic vesicles are
incorporated into the plasma membrane (full vesicle fusion),
while others return to the interior of the cell after their
contents have been released (this is termed the “kiss-and-
run” pathway). Others remain docked to the membrane,
where they can be used multiple times (the “kissand-stay”
pathway).
THE STEPS OF EXOCYTOSIS:
1. A vesicle is formed, typically within the
endoplasmic reticulum and the Golgi
apparatus or early endosomes.
2. The vesicle travels to the cell
membrane.
3. The vesicle fuses to the plasma
membrane, during which the two
bilayers merge.
4. The vesicle’s contents are released
into the extracellular space.
5. The vesicle either fuses with or
separates from the cell membrane.
Exocytosis example
Let’s take the macrophage that we discussed in our endocytosis
example. Once the white blood cell has engulfed a foreign pathogen
eliminate it, certain parts of the pathogen are no longer needed. The
macrophage gets rid of this waste material through exocytosis, during
which vesicles carry out the unwanted pathogen material.