BS311 Cell Biology PDF

Summary

This document presents a syllabus and lecture notes for a Cell Biology course (BS311). It covers topics such as cell as a basic unit of life, bio-membranes, organelles, and tools and techniques, alongside the history and exceptions to cell theory. The document also explains prokaryotic and eukaryotic cells and their structural components.

Full Transcript

BS311 Cell Biology
Dr. Mandar Kulkarni
PDPIAS, CHARUSAT
 Syllabus
1. Cell as a basic unit of life
2. Bio-membranes of cells
3. Cell organelles and special structures of cells
4. Cytoskeleton and extracellular matrix
5. Cell-cell interactions
6. Cell cycle, cell death and cell renewal
7. Tools and techniques of cell biology
Unit 1: Cell as basic unit of life
Overview of cellular evolution and cell theory
Comparison of prokaryotic and eukaryotic cells- cell size, shape and
structural differences
Special cells like neurons and muscle cells
Basic molecules of a cell
Fundamental functions of cells
 What is a cell ?
The smallest structural and functional unit of an organism, which is
typically microscopic and consists of cytoplasm and a nucleus
enclosed in a membrane.

A unit of biological activity delimited by a semipermeable membrane
and capable of self-reproduction in a medium free of other living
systems.
 Cell
Simplest integrated organisation in living systems, capable of
independent survival.

Plant Stem

Amoeba Proteus

Red Blood Cell
Bacteria

Nerve Cell
 Cell theory
All living organisms are made up of one or more cells and cell products

All metabolic reactions in unicellular and multicellular organisms takes
place in cells

Cells originate from other cells

The smallest clearly defined unit of life is the cell
Their microscope had two lenses and total magnifying power
between 10X and 30X
Called Flea glasses. (Fleas - insect)
Book - Micrographia
300X
He was the first to observe living free cells.
His sketches included numerous bacteria (bacilli,
cocci, spirilla), Protozoa, Hydra
-movement of blood cells
Schleiden was the first to describe the nucleoli and to appreciate the fact that each cell leads
a double life—one independent, pertaining to its own development, and another as integral
part of a multicellular plant.
his work with the connective tissues such as bone and cartilage led him to modify the evolving cell theory to
include the idea that living things are composed of both cells and the products or secretions of the cells.
Schwann also introduced the term metabolism to describe the activities of the cells.
Characteristics of true cells

All kinds of true cells share the following three basic characteristics:
1. A set of genes which constitute the blueprints for regulating cellular
activities and making new cells.
2. A limiting plasma membrane that permits controlled exchange of
matter and
energy with the external world.
3.A metabolic machinery for sustaining life activities such as growth,
reproduction and repair of parts.
 Exception of the cell theory
Viruses Are Biologists’ Puzzle. They There Are Certain Other
Are An Exception To Cell Theory. They Organisms That Contain More
Lack Protoplasm, The Essential Part Than One Nucleus
Of The Cell.
Uses the metabolic
machinery of hosts.
primitive organisms
that have not reached
a cellular state.”
Two types of cells
Hans Ris in 1960’s suggested
these terms Prokaryotic and
Eukaryotic.
Prokaryotic cells
Prokaryotic cells
 Prokaryotic cells

Primitive or before Karyon

Nucleus

Cells with primitive nucleus
Prokaryotic cells
Small
One envelope system
Simple

Most primitive – Came into existence perhaps 3.5 billion years ago
E.g. The stromatolites (colonies of extinct cyanobacteria) of Western
Australia

Examples: Bacteria, Archea, Mycoplasma, Blue-green algae
Structure of prokaryotic cell
Plasma membrane
Live, ultrathin (6-8 nm)
Dynamic
Covers the bacterial protoplasm
Lipid bilayer with embedded
proteins, follows fluid-mosaic
pattern
1. Plasma membrane

Function ?
1. Plasma membrane
Plasma membrane is attached to DNA

Why?

In prokaryotic cells, DNA is present at which location/area?
Plasma membrane intrusions
Infoldings of the plasma membrane gives rise to these structures

Recorded in all Gram positive bacteria and some Gram negative
bacteria

1. Mesosomes
2. Chromatophores
a. Mesosomes
Extension of plasma membrane within
the cell, complex whorls of convoluted
membranes
Increase the plasma membranes
surface which is in contact with
cytoplasm
E.g. Chemoautotrophic bacteria like
Nitrosomonas
E.g. Photosynthetic bacteria like
Rhodopseudomonas
Also involved in cross wall septum
formation during cell division
b. Chromatophores
Similar to mesosomes

Shape is different as compared
to mesosomes

Observed as vesicles, tubes,
bundled tubes, stacks

Bear photosynthetic pigments
2. Cytoplasm
Hyaloplasm/matrix/cytosol

Ground substance

All metabolic activities

Components – water, proteins,
lipids, carbohydrates, RNA, other
metabolites and molecules
2. Cytoplasm
A less dense area – Where? Cytoplasm – also contains
Why? reserve material in bacteria
1. Finely dispersed
Dark or dense area – Where? 2. As inclusion bodies
Why? a. Volutin/metaphosphate
granules
b. Hydrogen sulphide droplets
c. Poly β-hydroxybutyrate
granules
Can we stain animal cells
with crystal violet?
3. Nucleoid
Bacterial genome/bacterial
chromosome
Single, circular and double stranded
DNA
Not separated from cytoplasm by
nuclear membrane
The whole DNA is concentrated in a
specific clear region in cytoplasm,
called nucleiod
No ribosomes in nuceloid
No nucleolus in nucleoid
 3. Nucleoid
DNA is attached to plasma membrane
at one site. Therefore when DNA is
isolated from prokaryotic cells it
carries number of membrane
components with it.
No histone proteins are recorded,
instead small heat stable (HU)
proteins are found.
All classes of RNA (i.e. mRNA, tRNA,
rRNA) are transcribed by single RNA
polymerase.
mRNA formed is directly available for
translation (no mRNA splicing) and
therefore transcription and translation
can go hand in hand/simulteneously.
4. Ribosomes
Size: 25 nm
Composed of: rRNA + proteins
Site for protein synthesis
Bacterial ribosomes are 70s type
(which are the two subunits?)
Non-functional ribosomes are
present as separated subunits in
cytoplasm
Polyribosomes/polysomes
Ribosomes in cytoplasm
Ribosomes attached to plasma
membrane
5. Plasmids
Many species of bacteria may carry
plasmids and many species may not.
These are extrachromosomal genetic
elements - small, circular and
closed DNA molecules
Some plasmids are bacteriophage
DNA which may eventually
incorporate in the bacterial
chromosome
Some plasmids are separated parts
of the genome for the same or foreign
cell, an may recombine with the main
chromosome
5. Plasmids - functions
Colicins: These plasmids produce
antibiotically active proteins. (Why?)

Fertility factor: These plasmids act as
fertility factors ('F' factor) which
stimulate bacterial conjugation

Resistant factor: These plasmids
produce enzymes and proteins with
confer resistance to one or more
drugs or antibiotics. ('R' factor)
6. Cell wall
In prokaryotes except for
mycoplasma, the cell membrane is
covered by strong and rigid cell wall.

Provides mechanical protection and
characteristic shapes.

Different from that of plant cell wall
(what is the difference?)
Cell wall of Gram-positive and Gram-negative bacteria
How to perform Gram-
staining?
7. Capsule
In some bacteria cell wall is further
surrounded by additional slime or
gel.
It is thick, gummy and
mucilaginous substance secreted
by plasma membrane.
Functions
Confers protection
against phagocytosis and viruses
Helps in transport of ions and
water.
8. Flagella
Possessed by motile bacteria e.g.
E. coli
15-20 nm in diameter and up to
20 µM long
May be one or more
Made up of flagellin
Attached to plasma membrane
by hook
Rotates like a propeller of ship
Flagellation pattern
9. Fimbriae or pili
Mostly Gram-negative bacteria
contain non-flagellar extremely fine
appendages celled fimbriae or pili.

Non-motile

Adhesive structures (meaning?)

Pili – conjugation (F-pili or sex-pili)
10. Spinae
Some Gram-positive bacteria have
tubular, pericellular, rigid appendages
of single protein moiety

Spinin

Spinae

Help to tolerate adverse
environmental conditions e.g. Salinity
11. Reproduction in prokaryotes
Binary fission

Conjugation
12. Forms in bacteria
Eukaryotic
cells
 Eukaryotic cells

Well developed Karyon

Nucleus

Cells with well-developed nucleus
Eukaryotic cells
Essentially two envelop system
Much larger than prokaryotic cell
Secondary membrane envelopes the nucleus and other internal
organelles and to a great extent it is present throughout the
cytoplasm as endoplasmic reticulum
From algae – higher plants
From protozoa – higher animals
Eukaryotic cells
Videos…
A typical animal cell
A typical plant cell
Basic molecules of cell
 Introduction

The branch of science The branch of biology that
concerned with the deals with the structure
chemical and physico- and function of the
chemical processes and macromolecules (e.g.
substances that occur proteins and nucleic acids)
within living organisms. essential to life.
 Comprised of multitude of non-living
constituents, this includes:
Proteins
Nucleic acids
Fats
Protoplasm Carbohydrates
Vitamins
Minerals
Waster metabolites
Crystalline aggregates
Pigments and many others
Protoplasm and cytosol

Protoplasm Cytosol
Protoplasm is alive because of Cytoplasmic matrix or cytosol is
the highly complex organisation the fluid and soluble portion of
of these non-living substances cytoplasm that exists outside the
and the way they interact with organelles.
each other.
 Colourless or greyish
Translucent
Viscous
Gelatinous or jelly-like colloidal
Physical substance
nature of Heavier than water
Capable of flowing
cytosol

Some physical characteristics of cytosol
have been debated for a long
Chemical nature or organisation of cytosol
Of the 92 naturally occurring elements,
about 46 are present in cytosol

Of which 24 are essential for life

Six are crucial for living system

Five are essential

Trace elements
 Carbon – 20%
Hydrogen – 10%
Nitrogen – 3%
Super six
Oxygen – 62%
Phosphorous – 1.14%
Sulphur – 0.14%
 Calcium – 2.5%
Potassium – 0.11%
Essential
five Chlorine – 0.16%
Magnesium – 0.07%
Sodium - 0.10%
Trace Iron Vanadium
elements Iodine Silicon
Molybdenum Nickel
Zinc Fluorine
Selenium Boron
Copper Manganese
Cobalt
Chromium
 Cytosol has various kinds of ions, which are
important for maintaining osmotic pressure and acid-
base balance in the cells (Electrolytes)
Mg++
K+
Ions Na+
Cl-
Ca++
Concentration of K+ and Mg++ is high inside the cell
and concentration of Na+ and Cl- is high outside the
cell
 Buffering system – blood – H2PO4-
Buffering system – cytosol – HPO4-
Ions
Non-electrolytes: Minerals in non-ionising state,
act as cofactors, important for metabolism e.g.
Mo, I, Fe.
Types of compounds in cytosol
Compounds
Organic (30%)
Inorganic (70%)

Composition
Water = 65%
Protein = 18%
Fat = 10%
Carbohydrates = 5%
Other organic compounds = 1%
Other inorganic compounds = 1%
Inorganic compounds
Water
Minerals
Salts
 Carbohydrates
Proteins
Organic Lipids
compounds Vitamins
Hormones
Nucleic acids
Fundamental functions of
cell
Functions of cell
1. Provide structure and
support: Fundamental units of
life, structural basis of all
organisms, e.g. xylem, skin,
bone
2. Facilitate growth through
mitosis: Growth of tissues,
organs and individuals
depends on cell division i.e.
mitosis
Functions of cell
3. Allow active and passive
transport: Import and export
nutrients for various use in
various biochemical reactions
a. Passive transport occurs by
using gradient and not energy
is required (simple molecules)
b. Active transport occurs with or
against the gradient, but
energy is used (complex
molecules)
Functions of cell

4. Produce energy: Cells produce
energy by using process called
respiration wherein complex
energy yielding molecules
are broken down to yield
energy
Mitochondria
The cellular energy is used by
the organism
Functions of cell
5. Create metabolic reactions
All Bio-chemical reactions
occur in cell
Anabolic reactions
Catabolic reactions
6. Aids reproduction
Mitosis: asexual
Meiosis: sexual