Lecture 1: Cell Biology PDF

Summary

This lecture provides an introduction to cell biology, covering basic concepts and techniques like microscopy and tissue culture. It explores the molecular organization and functions of cell membranes, including transport mechanisms and processes like endocytosis and exocytosis.

Full Transcript

Introduction
 Cell biology is the study of cells and how they function, from the subcellular
processes which keep them functioning, to the way that cells interact with
other cells.
Whilst molecular biology concentrates largely on the molecules of life (largely
the nucleic acids and proteins), cell biology concerns itself with how these
molecules are used by the cell to survive, reproduce and carry out normal cell
functions.
In biomedical research, cell biology is used to find out more about how cells
normally work, and how disturbances in this normal function can result in
disease. An understanding of these processes can lead to therapies which work by
targeting the abnormal function.
 Common Cell Biology Techniques

1. Tissue culture : The controlled conditions in cell and tissue culture
allows researchers to carry out experiments with a lower number of
variables which may affect the outcome of the test.
Tissue culture is a powerful tool which provides an almost limitless
supply of test material for researchers to use without resorting to
using whole organisms.
2. RNA Interference
3. Microscopy – the basic tool of cell biology is microscopy.
Types of microscopic techniques which are used include:
A. Bright-field – traditional microscopy, (uses visible light) it gives a general
picture of cell function
B. Electron Microscopy –( uses a focused beam of electrons) is useful in
obtaining detailed information about sub-cellular structures.
C. Fluorescence Microscopy – uses fluorescent materials to indicate structures
in a specimen
D. Immunofluorescence – (uses antibodies)
E. Timelapse Microscopy (cellular processes) Imaging cells over a period of time
 Cell biology and other biological sciences

Due to its wide application in various branches of biological science, many
new hybrid biological sciences, have sprung up. Some of them are as the
follows:
1. Cytotaxonomy (Cytology and Taxonomy)
2. Cytogenetics (Cytology and Genetics)
3. Cell physiology (Cytology and Physiology)
4. Cytochemistry (Cytology and Biochemistry)
5- Ultrastructure and Molecular biology
6. Cytopathology (Cytology and Pathology)
7. Cytoecology (Cytology and Ecology).
Animal cell Plant cell
Plasma Membrane
 Plasma membrane
An external envelope surrounding the cell that separates and
protects the cell from the external environment and provides
a connecting system of the cell with its environment
All cells are enveloped by plasma membrane that is usually
about 7.5 nm thick.
The membranes of prokaryotic and eukaryotic cells have
common overall structure, which consist of assemblies of
lipids and proteins held together by noncovalent forces.
 Chemical composition
1. Lipid: phospholipid, galactolipid, cholesterol.
2. Proteins:
1. Peripheral (extrinsic):
- Separated by mild treatment - soluble in aqueous Solution - usually free from lipid.
2. Integral proteins (intrinsic):
- Represent more than 70%. - Separated by drastic procedure.
- Insoluble in water. - Need the presence of detergents.
- May be attached to other non-proteins (glycoprotein, phosphoprotein, and
lipoproteins).
3. Carbohydrate: hexose - hexoseamine – fucose.
4. Enzymes about 30 enzymes..
 Molecular organization of membranes

About sixty years ago the plasma membrane was described as a lipid
bilayer (by relatively indirect evidence).
Sandwich model OR Danielli- Davson Model Proposed by Davson
and Danielle in 1935 “Cell membrane is lipid bilayer sandwiched with two
monolayer of globular proteins”.
 Molecular organization of membranes
In the early 1960s, J. David Robertson proposed a modified version of the
Danielli-Davson model, which assumed that the proteins were extended
rather than globular conformation on both surface of the phospholipid
bilayer (by. M+ membrane function).
He proposed that the uniform thickness of 7.5 nm and the consistent dark
light dark staining pattern of the cellular membranes.
Could be explained if each protein coat was 2nm thick and the phospholipid
bilayer sandwiched in between about 3.5 nm thick.
Various objections to the available models stimulated new kinds of studies
using mitochondrial and chloroplast membranes as well as plasma
membranes.
 In the late 1960s, S. Jon Singer and Garth Nicolson proposed the fluid
mosaic membrane model; according to which a mosaic of protein
molecules was distributed in and on a fluid phospholipid bilayer.
The fluid mosaic membrane is widely accepted today, although certain
details have been changed
In this model, a flexible layer
made of lipid molecules is
interspersed with large protein
molecules that act as channels
through which other molecules
enter & leave the cell.
 Fluid: individual phospholipids and some proteins can move
sideways (laterally) in each layer-therefore FLUID
extracellular fluid (outside) carbohydrate
receptor
protein glycoprotein
Mosaic: range of
recognition protein binding
phospholipid protein
bilayer transport
site
different proteins phospholipid cholesterol
pore protein

resting on the surface
or through the
phospholipid layer
gives it a mosaic
appearance
protein filaments
cytosol (inside)
 Fluid mosaic membrane model

The lipid bilayer exists in a relatively fluid state, with the consistency of
light oil, and that lipid in each monolayer can move laterally within the
plane of the membrane.
Various protein molecules are distributed on each surface of the lipid
bilayer, and other proteins penetrate the thickness of the bilayer but
protrude from one or both of its surfaces.
The surface proteins are peripheral and the proteins that extend into or
through the bilayer are integral.
 Singer and Nicolson proposed that the predominant forces responsible for
membrane structure are hydrophilic and hydrophobic interactions.
Because membrane lipids and many membrane proteins are amphipathic,
and thus contain hydrophilic and hydrophobic regions in the same
molecular.
Phospholipid are amphipathic
having both hydrophobic fatty
acid chains that repel water and
polar heads that are hydrophilic
and so attract water.
Hydrophobic interaction
between the fatty acid chains hold
the phospholipid bilayer together
Plasma membrane
function
A) Steroid hormones, such as estrogen and progesterone, probably because
they are lipid soluble and thus able to penetrate the central bilayer of the
membrane easily, readily cross the plasma membrane and enter the cell.

B) Glycoprotein hormones, on the other hand (e.g. Insulin is a protein
composed of two chains), bind to the surface of their target cells and,
without penetrating the plasma membrane, exert their influence from
there. The stimulation of a target cell by most non-steroid hormones therefore
depends upon the presence of receptors on the outer cell surface.

These receptors are integral plasma membrane components and can be
identified by their ability to bind specifically to a particular hormone molecule.
 A target cell that is stimulated by a variety of different hormones (for example,
fat cells respond to at least nine different hormones) will bear several populations
of surface receptors, each specific for one hormone.
As a general rule, there are about 10000 receptor
molecules for each hormone on each cell, and
stimulation occurs when a sufficient number of them
become occupied.
The binding between the hormone and its receptor is
concentration-dependent and appears to be
reversible, so that, when the concentration of
hormone in the environment around the target cell
decreases, the bound hormone molecules probably
dissociate from their receptors.
 2-The plasma membrane and transport
The transport mechanisms that exist in the plasma membrane include both
micro- transfer and macro-transfer processes.
1- Micro-transfer
Includes the transport of ions and small molecular species such as amino
acids and simple sugars; it is carried out by both passive and active
mechanisms
A) Passive and facilitated transport
When uncharged substances (i.e. non-electrolytes) move across the plasma
membrane, they tend to flow down the concentration gradient at a rate determined
by their relative concentration on each side of the membrane (‘diffusion’).
 For charged substances, however, the electrical concentration needs to be
considered in addition to the concentration gradient, because if charged
substances move across the plasma membrane they will also generate a potential
difference.
The transport of different ions across the plasma membrane, it has been
predicted that hydrophilic channels or pores allowing the transport of water
and ions through the plasma membrane must exist.
Certain molecules, such as glucose and glycerol, cross the plasma membrane
many times faster than can be accounted for by passive diffusion alone.
Their transport is thus said to be ‘facilitated’ or ‘catalysed’ and it is presumed to
be regulated by specific catalytic components in the membrane.
 For example, Ventilation

Oxygen is a molecule that can freely diffuse across a cell membrane.

Oxygen diffuses out of the air sacs in your lungs into your bloodstream
because oxygen is more concentrated in your lungs than in your blood.

Oxygen moves from the high concentration of oxygen in your lungs to the
low concentration of oxygen in your bloodstream.

Carbon dioxide, which is exhaled, moves in the opposite direction - from a
high concentration in your bloodstream to a low concentration in your lungs.
Facilitated Transport
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B) Active transport
Also present in the plasma membrane are transport systems that require
energy expenditure by the cell. These systems can operate against the
concentration gradient and are thus able to achieve a several-fold increase in
concentration on one side of the membrane.
The best-documented active transport mechanism carries sodium ions (Na+)
out of the cell and accumulates potassium ions (K+) within it.
In this coupled pumping mechanism (Sodium-potassium pump), a
membrane-bound magnesium-activated adenosine triphosphatase (ATPase)
hydrolyses to adenosine diphosphate or (ADP) to provide energy for every
three Na+ and two K+ ions transported.
Active Transport
1 The transport protein 2 Energy from ATP 3 The protein releases
binds both ATP and Ca2+. Changes the shape of the ion and the
the transport protein remnants
and moves the ion of ATP (ADP and P) and
across the membrane. closes.
(extracellular fluid)

ATP
ADP
ATP Ca2+ (cytosol) P
recognition ATP
site binding
site
Active Transport
 Most models of active transport postulate that ‘carriers’ translocate the ion (or
amino acid, sugar, etc.) from one membrane surface to the other and in so doing
lose their energy.
It is now regarded more likely, therefore, that ‘carriers’ for active transport are
integral transmembrane components.
Some examples of active transport in plants include:
Ions moving from soil into plant roots
Transportation of chloride and nitrate from the cytosol to the vacuole
Sugars from photosynthesis moving from leaves to fruit
Calcium using energy from ATP to move between cells
Minerals traveling through a stem to various parts of the plant
Water moving from plant roots to other plant cells via root pressure
 2- Macro-transfer processes
The transport of macromolecules across the plasma membrane comes
under the general heading of cytosis;
endocytosis describes movement into the cell,
and exocytosis movement into the extracellular space
❖ Exocytosis---Cellular secretion
❖ Endocytosis—
❖ Phagocytosis— “Cell eating”
❖ Pinocytosis– “Cell drinking”
❖ Receptor-mediated endocytosis- specific particles, recognition.
A) Endocytosis
Endocytosis includes phagocytosis, the process whereby macrophages engulf and
remove cellular and non-cellular debris from the body
Pinocytosis and micropinocytosis also come under the heading of endocytosis.
The mechanisms involved in these processes are similar to those of phagocytosis
but they are primarily concerned with the uptake of soluble materials dissolved in
tissue fluids

In fluid endocytosis the
concentration of the substance
within the enclosed vesicle is the
same as that in the extracellular
environment.
Endocytosis

Phagocytosis is one
example of endocytosis.

(extracellular fluid)
food particle pseudopods

food vacuole
(cytosol)
Phagocytosis

Phagocytosis 1
Phagocytosis 2
Pinocytosis
Receptor-mediated Endocytosis
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 B) Exocytosis
They are the mechanism whereby most exocrine and many endocrine secretory cells
release their secretory products, nerve fibers release their stores of acetylcholine, and
osteoclasts (which can degrade bone matrix extracellularly) secrete lysosomal enzymes.

All of these processes require the transported material to be packaged in the
cytoplasm within a membrane-limited vesicle, such as a secretory granule or a
lysosome.

A demand for the release of content (e.g. a stimulation to secrete) induces the vesicle
to move to a specific region of the cell boundary (in exocrine cells it is usually the
apical membrane) where the vesicle membrane fuses with the plasma membrane.
 A consequence of exocytosis is the addition of intracellular membrane to the
plasma membrane; when this occurs repeatedly and becomes a significant
contribution. secreted plasma
material membrane

(extracellular fluid)

vesicle

(cytosol)
0.2 micrometer
Material is enclosed in a vesicle that
fuses with the plasma membrane,
allowing its contents to diffuse out.
 3-The plasma membrane and Malignancy
Malignant tumors arise in the body spontaneously but they may also be induced by
radiation, chemical agents and virus infection.

The most a fundamental abnormality of malignant cells is that they are neoplastic,
i.e. they divide without stimulus and are not subject to the normal influences of
growth control.
As malignant tumour cells proliferate they generally display invasive behavior,
penetrating the surrounding tissues.
When they reach circulatory systems or body cavities, groups of cells may detach
from the tumor and become transported throughout the body. This process of cell
dissemination is known as metastasis and it leads to the formation of multiple
secondary growths.
Thank you