Microbial Physiology Lec1 PDF

Summary

These lecture notes cover microbial physiology, providing a brief overview of cell structure and function, growth, nutrition, metabolism, and the regulation of gene expression. The document also explores various components of prokaryotic and eukaryotic cells, discussing structures like cilia, flagella, cell walls, and cytoplasmic membranes. The notes also detail storage materials for energy and include details about the function of various aspects of cell structure.

Full Transcript

Microbial Physiology
Microbial Physiology
Giving a brief introduction to the microbial
physiology:

Cell Structure and Function
Growth
Nutrition
Metabolism
Regulation of gene experision
Cell Structure and Function
I-Structure and Function of
Procaryotic Cell

A: Prokaryotic Cell Surfaces
II-Structure and Function of
Eucaryotic Cells

A-Eukaryotic Cell Surfaces
 1-Cilia and flagella
They are the most prominent organelles
associated with motility.
They move the microorganism along.
They differ from one another in two ways:
- First, cilia are typically only 5 to 20 µm in
length, whereas flagella are 100 to 200 µm long.
- Second, their patterns of movement are usually
distinctive.
 2- Cell wall
Both eukaryotic and prokaryotic microorganisms are often
enclosed within a rigid cell wall.
Many algae, as well as oomycetes, contain cellulose (cellulose, a
β-1,4-linked polymer) as a major cell wall constituent.
The cell walls of many fungi contain chitin, a linear polymer of
N-acetyl glucosamine.
Most fungi, algae, and higher plants contain microfibrils of either
cellulose or chitin as a prominent skeletal component of their cell
walls. Production of these microfibrils occurs at or near the surface
of the cell.
Chemical analysis of yeast walls reveals the presence of 29% β-
glycans (both 1,6-β-glycan and 1,3-β-glycan are found), 31%
mannan, and 13% protein. Yeast cell walls also contain small
percentages of lipids and other materials.
 1. Flagella

It is a long filament structure made
up of a protein of a special type
called flagelin.
Function: motility and swarming.
 2. Fimbriae and pili:
Fimbriae and pili are hair-like appendages present on the
bacterial cell wall.
Fimbriae:
are shorter than flagella and consist of the protein fimbrilin.
It helps the cell to adhere to surfaces
Pili: are found in abundance in the negative bacteria and
consist of the protein pilin.
Forms the place where bacteriophage is fixed,
It also fixes the bacteria themselves in hemagglutination
reactions.
It involved in the process of bacterial conjugation
 3-Slime layer or capsule
Capsule:
a sticky gelatinous layer surround the bacterial
cell
mostly composed of complex polysaccharide
and in some species amino acids are included in
its composition.
Importance of the capsule
protects bacteria from adverse environmental
conditions, especially drought
provides resistance against cellular phagocytosis.
help the cell adhere to surfaces
 4. Cell Wall:
The cell wall consists of several layers of polysaccharides,
lipids, and some amino acids that together form what is called
peptidoglycan.
The carbohydrates that enter into its composition are two
compounds: the amino sugar N-acetyl glucose amine and the
other is N-acetyl muramic acid linked together by beta 1-4
glycosidic bonds.
Importance of the cell wall:
Cell wall gives cells their external shape and
protects them from osmotic pressure.
forms the substrate on which bacteriophages can attach.
B: Protoplast
 1- Cytoplasmic membrane
The plasma membrane or bacterial cytoplasmic membrane
is composed of a phospholipid bilayer.
The phospholipids of bacteria contain ester-linked
phospholipids whereas the archaea contain fatty alcohols
linked to glycerol via either diether or tetraether bonds.
Unlike eukaryotes, bacterial membranes generally do not
contain sterols.
Function:
as a permeability barrier for most molecules
as the location for the transport of molecules into the cell
as the location for energy conservation
 2- Cytoplasm
The cytoplasm consists of all of the contents of
the cell inside the plasma membrane, which
mainly contains:
70S ribosomes and
chromatophores in green bacteria,
in addition to various inclusions.
 3-Ribosomes
Ribosomes may be filled the cytoplasmic or
loosely attached to the plasma membrane.
Ribosomes are made of both protein and
ribonucleic acid (RNA).
Procaryotic ribosomes are smaller than the
cytoplasmic or endoplasmic reticulum-associated
ribosomes of eukaryotic cells.
Function: They are the site of protein synthesis.
 4- Inclusion Bodies
Inclusion bodies, granules of organic or inorganic
substances, are present in the cytoplasmic matrix.
Some inclusion bodies may be:
-free in the cytoplasme
-enclosed by a shell
Many inclusion bodies are used
-for storage and also
- reduce osmotic pressure.
 Stored organic materials

a- Glycogen and poly-β-hydroxybutyrate (PHB) inclusion bodies are carbon
storage reservoirs providing material for energy and biosynthesis.
Many bacteria also store carbon as lipid droplets.
b- Cyanobacteria have two distinctive organic inclusion bodies:
Cyanophycin granules are composed of large polypeptides.
The granules store extra nitrogen for the bacteria.
Carboxysomes are polyhedral protein and contain ribulose-1, 5-
bisphosphate carboxylase, called Rubisco.
Rubisco is the critical enzyme for CO2 fixation.
Carboxysomes also may be a site of CO2 fixation.
c- Gas vacuoles are present in many photosynthetic bacteria and a few other
aquatic prokaryotes.
Gas vacuole, provides buoyancy to some aquatic prokaryotes.
 Stored inorganic materials:
a- Polyphosphate granules
Many bacteria store phosphate as polyphosphate
granules or volutin granules.
Thus volutin granules function as storage reservoirs for
phosphate,
an important component of cell constituents (e.g.
nucleic acids).
b- Sulfur granules
Photosynthetic bacteria can use hydrogen sulfide and
store the resulting sulfur in either the periplasmic space or
in special cytoplasmic globules.
 5 - Nucleoid
The cell's DNA content is occurred in the nuclear
region as coiled fine filaments that contains all or
most of the genetic material.
The nuclear material:
*is not surrounded by basic proteins,
*is not defined by a nuclear membrane,
* does not contain nuclei.
Function: carrying genetic material (DNA)
 6 - Plasmids:
Plasmids are found in gram-positive or gram-
negative bacteria.
They are double-stranded circular DNA molecules
outside the chromosomes, and can replicate
independently of the bacterial chromosomes.
Different types of plasmids may exist in a single
cell.
i-Transmissible plasmids
ii- Non-transmissible plasmids
i-Transmissible plasmids:
These plasmids can be transferred from one cell to another.
They are large and contain about 12 genes responsible for the formation of
sexual cilia and the enzymes necessary for transport.
They are found in the cell in small numbers (1-3 units).
ii- Non-transmissible plasmids
They are small and do not contain transfer genes,
They are often found in large numbers 1-60 units in the cell.
Plasmids carry genes that code for the following functions and structures:
-resistance to antibiotic by many enzymes.
-resistance to heavy metals with the help of the enzyme reductase
-resistance to ultraviolet light with the presence of modification enzymes
(DNA repair
-including many enterotoxins (Exogenous Toxins).
II-Structure and Function of
Eucaryotic Cells

A-Eukaryotic Cell Surfaces
 1-Cilia and flagella
They are the most prominent organelles
associated with motility.
They move the microorganism along.
They differ from one another in two ways:
First, cilia are typically only 5 to 20 µm in
length, whereas flagella are 100 to 200 µm long.
Second, their patterns of movement are usually
distinctive.
 2- Cell wall
Both eukaryotic and prokaryotic microorganisms are often
enclosed within a rigid cell wall.
Many algae, as well as oomycetes, contain cellulose (cellulose, a
β-1,4-linked polymer) as a major cell wall constituent.
The cell walls of many fungi contain chitin, a linear polymer of
N-acetyl glucosamine.
Most fungi, algae, and higher plants contain microfibrils of either
cellulose or chitin as a prominent skeletal component of their cell
walls.
Chemical analysis of yeast walls reveals the presence of 29% β-
glycans (both 1,6-β-glycan and 1,3-β-glycan are found), 31%
mannan, and 13% protein. Yeast cell walls also contain small
percentages of lipids and other materials.
B: Protoplast
 1- Cytoplasmic membrane
(Plasma Membrane)
The cell membrane consists of a lipid bilayer, made up of
two layers of phospholipids with cholesterols.
The membrane also contains membrane proteins, including:
-integral proteins that serve as membrane transporters,
-peripheral proteins that acting as enzymes to facilitate
interaction with the cell's environment.
Glycolipids embedded in the outer lipid layer serve a similar
purpose (recognition sites for cell–cell interactions).
Selectively permeable barrier with transport systems,
mediates cell-cell interactions.
 2-The cytoplasmic matrix
The many organelles of eucaryotic cells lie in
the cytoplasmic matrix.
It is the “environment” of the organelles
and the location of many important
biochemical processes.
The Eucaryotic Cytoplasmic Matrix and Cytoskeleton
 3-The Endoplasmic Reticulum
The endoplasmic reticulum (ER) is an irregular network of
branching and membranous tubules.
The nature of the ER varies with the functional and
physiological status of the cell.
In cells synthesizing a great deal of protein for purposes such
as secretion, a large part of the ER is scattered on its outer
surface with ribosomes and is called rough endoplasmic
reticulum (RER).
Other cells, such as those producing large quantities of lipids,
have ER that lacks ribosomes. This is smooth ER (SER).
The endoplasmic reticulum has many important functions.
it transport proteins, lipids, and other materials
 4-The Golgi apparatus
The Golgi apparatus is composed of flattened, saclike cisternae
stacked on each other.
There are usually around 4 to 8 cisternae in a stack.
These stacks of cisternae, often called dictyosomes, can
be clustered in one region or scattered about the cell.
These membranes, like the smooth ER, lack bound ribosomes.
There are usually around 4 to 8 cisternae in a stack.
A complex network of tubules and vesicles is located at the
edges of the cisternae.
Function:
packages materials and prepares them for secretion.
Often participates in the development of cell membranes.
The Golgi apparatus
 5-Lysosomes
They are found in most eukaryotic organisms,
including protists, fungi, plants, and animals.
Lysosomes are roughly spherical and enclosed in
a single membrane.
Function:
They are involved in intracellular digestion
contain the enzymes needed to digest all types of
macromolecules.
 6- Eucaryotic ribosomes
The eucaryotic ribosome is larger than the
procaryotic ribosome.
Eucaryotic ribosomes can be either associated
with the endoplasmic reticulum or free in the
cytoplasmic matrix.
Function: Both free and ER-bound ribosomes
synthesize proteins.
 7-Mitochondria
Mitochondria usually are cylindrical structures and bounded
by two membranes, an outer membrane separated from an inner
membrane by intermembrane space.
The inner membrane has special enfolding's called cristae (s.,
crista), which greatly increase its surface area.
Enzymes and electron carriers involved in electron transport
and oxidative phosphorylation that yield energy in the form of
ATP are located only in the inner membrane.
The enzymes of the tricarboxylic acid cycle and catabolism
of fatty acids are located in the matrix.
Mitochondrial Structure
 8- Nucleus
The nucleus is the most prominent organelle in eukaryotic cells.
The nucleus is the storehouse for the cell’s genetic information
and is its control center.
Nuclear Structure
Nuclei are membrane-defined spherical bodies.
Chromatin (DNA-containing part of the nucleus) can be seen
within the nucleoplasm of the nucleus.
In nondividing cells, chromatin is dispersed, but it condenses
during cell division to become visible as chromosomes.
The nucleus is bounded by the nuclear envelope, a complex
structure consisting of inner and outer membranes. Many nuclear
pores penetrate the envelope and serve as a transport track between
the nucleus and surrounding cytoplasm.
Cilia and flagella Cell movement
Cell wall Strengthen and give shape to the cell
Plasma membrane Mechanical cell boundary,
selectively permeable barrier with transport systems, mediates cell-cell
interactions and
adhesion to surfaces,
secretion

Cytoplasmic matrix Environment for other organelles,
location of many metabolic processes
Microfilaments, and microtubules Cell structure and movements,
form the cytoskeleton
Endoplasmic reticulum Transport of materials, protein and lipid synthesis
Ribosomes Protein synthesis
Golgi apparatus Packaging and secretion of materials for various purposes, lysosome
formation
Lysosomes Intracellular digestion
Mitochondria Energy production through use of the tricarboxylic acid cycle, electron
transport, oxidative phosphorylation,
and other pathways
vacuole Temporary storage and transport, digestion (food vacuoles), water balance
(contractile vacuole)
Nucleoid Repository for genetic information,
control center for cell
Nucleolus Ribosomal RNA synthesis, ribosome construction