Introduction to Microorganisms Lecture 2 PDF

Summary

This document provides a lecture overview of microorganisms, covering various topics like cell morphology, prokaryotic cell structure, glycocalyx, flagella, and more. The content is suitable for undergraduate-level biology courses.

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Introduction to microorganisms

Lecture 2

Dr Mira El Chaar
 Microorganism: is a microscopic organism that comprises either a
single cell (unicellular), cell clusters, or no cell at all (acellular).

 Viruses depend on the energy and metabolic machinery of a host
cell in order to reproduce
 Cell Morphology of bacteria

Cocci

Cocci may be seen as

 Single coccus
 Pairs (diplococci)
 Chains (streptococci)
 Clusters (staphylococci)
 Packets of four (tetrads)
 Packets of eight (octads)
 Cell Morphology Cont’d

Bacilli

Short, long, thick or
thin, pointed or with
curved or blund ends

They occur in pairs,
in chains, in long
filaments, or
branched.

Some rods are short:
cocobacilli
 Cell Morphology Cont’d

Bacilli spiral, curved

 Curved (vibrio)

 Spirilla (helical shape, like a
corkscrew)

 Spiral-shaped bacilli (spirochete).
Spiral-shaped bacteria usually occur
singly, but some species may form
pairs

The shape of a bacterium could be:
 Monomorphic: maintain a single
shape
 Pleomorphic: have many shapes
(pleomorphic)
 PROCARYOTIC CELL STRUCTURE

 All bacteria are prokaryotes
 They are about 10 times smaller than eucaryotic cells
 Reproduction of procaryotic cells is by binary fission
 Within the cytoplasm of procaryotic cells are a chromosome, ribosomes,
and other cytoplasmic particles
 The cytoplasm is surrounded by a cell wall and sometimes a capsule or slime
layer
 Glycocalyx
 Glycocalyx is a viscous, slimy, gelatinous material composed of polysaccharide, polypeptide, or
both.
 It is produced by the cell membrane and secreted outside of the cell wall.

There are two types:
 A slime layer (the substance is unorganized and only loosely attached to the cell wall).
Slime layers enable certain bacteria to glide or slide along solid surfaces. It consists
mostly of exopolysaccharides, glycoproteins, and glycolipids. A loose, water-soluble
glycocalyx is called a slime layer

 Capsule (the substance is organized and is firmly attached to the cell wall. Usually consist
of polysaccharides, which may be combined with lipids and proteins). Capsules
serve an antiphagocytic function, protecting the encapsulated bacteria from being
phagocytized by phagocytic white blood cells.
bacteria with slime layer
glycocalyx are more likely to
form biofilms
The glycocalyx is a very important component of biofilms
biofilms are
antiphagocytic
 Flagella of prokaryotic cells
 Flagella are threadlike, protein appendages that enable bacteria to
move.

 Flagellated bacteria are said to be motile, whereas nonflagellated bacteria are
usually nonmotile.

 They are about 10 to 20 nm thick; too thin to be seen with the compound
light microscope.

 They consist of three, four, or more threads of protein (called flagellin) twisted
like a rope.

 Bacterial flagella do not contain microtubules, and their flagella are not
membrane-bound eukaryotic flagella contain microtubules

 Axial filament: (two flagella-like fibrils) rap around the organism therefore
the movement is spiral or helical (spirochetes)
Flagellum: arises from a basal body in the cell membrane and project outward
through the cell wall and capsule.

Each prokaryotic flagellum is a semirigid, helical structure that moves the cell
by rotating from the basal body

The rotation of a flagellum is either clockwise or counterclockwise

Flagellar rotation depends on the cell's continuous generation of energy.
 Other movement for flagella

chemotaxis vs phototaxis

 Bacterial cells can alter the speed and direction of
rotation of flagella and thus are capable of various
patterns of motility

 The movement of a bacterium toward or away from a
particular stimulus is called taxis

 Such stimuli include chemicals (chemotaxis) and light
(phototaxis)

 Motile bacteria contain receptors in various locations such as
in or just under the cell wall. These receptors pick up chemical
stimuli, such as oxygen, ribose, and galactose.

 In response to the stimuli, information is passed to the flagella

 If the chemotactic signal is positive, called an attractant, the
bacteria move toward the stimulus with many runs and few
tumbles. counterclockwise
 If the chemotactic signal is negative, called a repellent, the
frequency of tumbles increases as the bacteria move away
from the stimulus clockwise
 Axial filaments
Spiochetes: Treponema Pallidium (syphilis) and Borrelia burgdorferi (Lyme disease)

 Axial filaments have a structure similar to that of flagella.

 These axial filaments extend toward each other, wrap around the organism
between the layers of the cell wall

 As a result of its axial filaments, spirochetes can move in a spiral, helical, or inch-
worm manner.

 This type of movement is similar to the way a corkscrew moves through a cork
 Flagella of prokaryotic cells cont’d

There are four types of flagella moving bacteria:

1. peritrichous bacteria: Bacteria possessing flagella over their entire surface
2. Monotrichous bacteria: Bacteria possessing a single polar flagellum
3. Lophotrichous bacteria: Bacteria with several flagella at one end
4. Amphitrichous bacteria: Bacteria having one or more flagella at each end

Bacteria that lack flagella are referred to as atrichous
 Pili and Fimbriae
 Often observed on Gram-negative bacteria

 They are composed of polymerized protein molecules called pilin,
arranged helically around a central core.

 They arise from the cytoplasm and extend through the plasma
membrane, cell wall, and capsule.

 Fimbriae (Adhesin) can occur at the poles of the bacterial cell or
can be evenly distributed over the entire surface of the cell

 Fimbriae are important for attachment

 Pili are usually longer than fimbriae and number only one or two
per cell. Pili are involved in motility and DNA transfer

 Pilli have a gliding motility.

 There are two types of pili:
 one type enables bacteria to adhere or attach to surfaces
 The other type (called a sex pilus) enables transfer of genetic
material from one bacterial cell to another (conjugation)
 Bacterial Cell Wall

 The main constituent of most bacterial cell walls is a complex
macromolecular polymer known as peptidoglycan (murein),
consisting of many polysaccharide chains linked together by small
peptide (protein) chains.

 The cell walls of certain bacteria, called “Gram-positive bacteria”
have a thick layer of peptidoglycan combined with teichoic acid
and lipoteichoic acid molecules.

 The cell walls of “Gram-negative bacteria” have a much thinner
layer of peptidoglycan, it is covered with a complex layer of lipid
macromolecules, usually referred to as the outer membrane
Peptidoglycan is made of disaccharide:
The disaccharide portion is made up of
monosaccharides called N-acetylglucosamine
(NAG) and N-acetylmuramic acid (NAM)
(from murus, meaning wall), which are related to
glucose
The assembly of peptidoglycan on the outside of the plasma membrane is mediated by a
group of periplasmic enzymes, which are transglycosylases, transpeptidases and
carboxypeptidases
 Gram positive cell

The cell wall consists of many layers of peptidoglycan, forming a thick,
rigid structure cell walls of gram-positive bacteria contain teichoic
acids

linearpolymers of polyglycerol or polyribitol substituted with
phosphates and a few amino acids and sugars.

Teichoic acides and lipoteichoic acid are negatively charged

 Cation movement (positively charged substances)
 Cell growth
 Wall antigenic specific
 Gram negative cell
 The cell walls of gram-negative bacteria consist of one or a very few layers of
peptidoglycan and an outer membrane

 The peptidoglycan is bonded to lipoproteins in the outer membrane

 In the periplasm, there is a gel-like fluid between the outer membrane and the plasma
membrane.
 The periplasm contains a high concentration of degradative enzymes and transport
proteins

 The outer membrane consists of lipopolysaccharide, lipoproteins and phospholipids
 Evade phagocytosis and immune response.
 Provide a barrier to certain antibiotics, digestive enzymes
 Porins: passage if nucleotides, disaccharides, peptides, amino acids,vitamin B12 and
iron.
 LPS: Lipid A (endotoxin), core polysaccharide (stability), O polysaccharide
(antigen)
 Lipid A is the lipid portion of the LPS and is embedded
in the top layer of the outer membrane

 When gram-negative bacteria die, they release lipid A,
which functions as an endotoxin

 Lipid A is responsible for the symptoms associated with
infections by gram-negative bacteria such as fever,
dilation of blood vessels, shock, and blood clotting

 The core polysaccharide is attached to lipid A and
contains unusual sugars. Its role is structural-to
provide stability.

 The o polysaccharide extends outward from the core
polysaccharide and is composed of sugar molecules.

 The 0 polysaccharide functions as an antigen and is useful
for distinguishing species of gram negative bacteria
 Cell wall function

 Prevent bacterial cells from rupturing when the water
pressure inside the cell is greater that that outside the cell.

 Helps maintain the shape of a bacterium and serves as a
point of anchorage for flagella

 Cell wall contributes to the ability of some species to cause
disease and is the site of action of some antibiotics.
 Cell wall damage

Lysozyme:
 Active against gram positive.
 catalyzes hydrolysis of the bonds between the sugars in the repeating
disaccharide "backbone" of peptidoglycan

 Protoplasts (gram positive): Have their cell wall entirely removed
 Spheroplasts (gram negative): Have their cell wall only partially removed
Cell Membrane (Plasma membrane)
 Plasma membrane (PM)
 Chemically, the plasma membrane consists of proteins (peripheral and
integral proteins and phospholipids).The phospholipids and proteins
are arranged as a mosaic form: Fluid mosaic phospholipid model.

 It is flexible and so thin

 PM is a selective barrier through which materials enter and exit the
cell (Passive and active movement): selective permeability

 Many enzymes are attached to the cell membrane, and a
variety of metabolic reactions take place there.( infoldings of Chromatophores
the plasma membrane)

 PM is important to the breakdown of nutrients and the production
of energy

 The semiliquid cytoplasm of procaryotic cells consists of water,
enzymes, dissolved oxygen (in some cases), waste products, essential
nutrients, proteins, carbohydrates, and lipids—a complex mixture In some bacteria, pigments and
of all the materials required by the cell for its metabolic enzymes involved in
functions. photosynthesis are found in
infoldings of the plasma
membrane that extend into
the cytoplasm.
 Movement of material across the PM

Passive Processes include

 simple diffusion: movement of molecules (O2 and CO2) or ions from an area of
high concentration to an area of low concentration

 facilitated diffusion: integral membrane proteins transporters or permeases
function as channels or carriers that facilitate the movement of ions or large
molecules across the plasma membrane
 Movement of material across the PM (cont’d)

Although ions (for example Na+, K+, H+, CaH , and CI-), amino acids, and simple sugars
can move by passive processes, their movement by active processes can go against the
concentration gradient, allowing a cell to accumulate needed materials

Active Processes:

 The cell uses energy in the form of ATP to move substances (ions, amino acids and
sugars) across the plasma membrane

 The movement of a substance in active transport is usually from outside to inside

 Active transport depends on transporter proteins in the plasma membrane

 Active transport enables microbes to move substances across the plasma membrane
at a constant rate, even if they are in short supply
 Osmosis
 osmosis: the net movement of solvent molecules across a selectively permeable membrane
from an area with a high concentration of solvent molecules (low concentration of solute
molecules) to an area of low concentration of solvent molecules (high concentration of solute
molecules)
 Osmotic pressure

 Osmotic pressure is the pressure needed to stop the flow of water across the selectively
permeable membrane

 High osmotic pressure (hypertonic) removes water causing plasmolysis – inhibits growth i.e.
salt as preservative

 Low osmotic pressures (hypotonic) cause water to enter and can cause lysis

 When the concentration of solutes outside a cell equals the concentration of solutes inside
the cell, the solution is said to be isotonic

 Bacteria are more tolerant to osmotic variations because of the mechanical strength of the
cell wall
Osmotic pressure is the pressure that is exerted on a cell membrane by solutions both
inside and outside the cell

Hypertonic solution: A solution having a larger concentration of a substance than is found
within the cells themselves

An isotonic solution is a medium in which the overall concentration of solutes equals that
found inside a cell

A hypotonic solution outside the cell is a medium whose concentration of solutes is lower
than that inside the cell (hypo means under or less

Osmosis: It is the movement of a solvent (e.g., water), through a permeable membrane, from
a solution having a lower concentration of solute to a solution having a higher concentration
of solute

Plasmolysis: Plasmolysis is the process where bacterial the cell membrane and cytoplasm
shrink away from the cell wall due to the loss of water through osmosis

Plasmoptysis: It occurs when pressure becomes so great that the cell ruptures hence
causing the cytoplasm to escape from the cell.
 Prokaryotic cytoplasm
Cytoplasm is thick. aqueous, semitransparent, and elastic.

It contains:
 80% water
 Proteins (enzymes)
 Carbohydrates
 Lipids
 inorganic ions.

The major structures in the cytoplasm:
 Nucleoid (containing DNA)
 Ribosomes (smaller then eucaryotic ribosomes (A 70S prokaryotic))
 inclusions (reserve deposits).
 Protein filaments in the cytoplasm are most likely responsible for the rod
and helical cell shapes of bacteria.
 Nucleoid
 The nucleoid contains the bacterial chromosome

 The procaryotic chromosome usually consists of a single, long, supercoiled, circular DNA molecule.
It is embedded in the cytoplasm.

 A procaryotic cell contains neither nucleoplasm nor a nuclear membrane and do not include
histone

 A bacterial chromosome contains sufficient genetic information to code for between 850 to 6500
gene products (enzymes, other proteins, rRNA and tRNA molecules)

 Small, circular molecules of double-stranded DNA that are not part of the chromosome (referred
to as extrachromosomal DNA or plasmids) may also be present in the cytoplasm of procaryotic
cells.

A plasmid may contain anywhere from fewer than 10 genes to several hundred genes. They
replicate independently

A bacterial cell may contain one plasmid, multiple copies of the same plasmid.
 Ribosomes

 Ribosomes are composed of two subunits which consists of
protein and ribosomal RNA (70S ribosomes)

 Smaller and less dense than ribosomes of eukaryotic cells
 Inclusions

Metachromatic granules (Volutin): reserve of inorganic phosphate
(polyphosphate) that can be used in the synthesis of ATP (methylene blue)
Polysaccharide granules. They consist of glycogen and starch (iodine stain)
Lipid inclusions (Sudan dye)
Sulfur Granules: sulfur granules in the cell, where they serve as an energy
reserve
Carboxysomes: ribulose I.5-diphosphate carboxylase
Gaz vacuoles
Magnetosomes are inclusions of iron oxide (may protect the cell again hydrogen
peroxide accumulation)

Metachromatic granules Magnetosomes
 Spores (Endospores)

 A few genera of bacteria (e.g., Bacillus and Clostridium) are capable
of forming thick-walled spores as a means of survival when their
moisture or nutrient supply is low

 Bacterial spores are referred to as endospores, and the process by
which they are formed is called sporulation

 Spores are resistant to heat, cold, drying, and most chemicals. some
are quite resistant to disinfectants and boiling

 When the dried spore lands on a moist, nutrient-rich surface, it
germinates, and a new vegetative bacterial cell (one capable of
growing and dividing) emerge
Sporulation or sporogenesis
 Most of the water present in the forespore cytoplasm is eliminated by
the time sporulation is complete, and endospores do not carry out
metabolic reactions.

 The highly dehydrated endospore core contains only DNA, small
amounts of RNA, ribosomes, enzymes, and a few important small
molecules.

 Endospores can remain dormant for thousands of years.

 An endospore returns to its vegetative state by a process called
germination.

 Germination is triggered by physical or chemical damage to the
endospore's coat.

 The endospore's enzymes then break down the extra layers
surrounding the endospore, water enters, and metabolism resumes.
 How to differentiate between
Gram positive and negative bacteria?
Gram staining:

 Crystal violet: the dye enters the cytoplasm of both types of cells
 Iodine: forms large crystals with the crystal violet dye. The latter are
too large to escape through the cell wall
 Alcohol dehydrates the peptidoglycan of gram-positive cells to
make it more impermeable to the crystal violet-iodine
 Safranin provides a contrasting color to the crystal violet

heat-fixation and methanol-fixation. Fixation serves three purposes:

 It kills the organisms
 It preserves their morphology (shape)
 It anchors the smear to the slide
Purple color Pink color
 Acid fast staining
Mycobacterium and pathogenic species of Nocardia. These bacteria contain high
concentrations (60%) of a hydrophobic waxy lipid (mycolic acid) in their cell wall that
prevents the uptake of dyes, including those used in the Gram stain.

The carbolfuchsin penetrates
the cell wall, binds to
cytoplasm, and resists removal
by washing with acid-alcohol
 Special staining for cell wall

Negative Staining for Capsules: India ink or nigrosin

Many microorganisms contain a gelatinous covering called a
capsule
 Place a loopful of India ink on the side of a clean slide.
 A small portion of the solid culture is suspended in saline on the slide near the ink and then
emulsified in the drop of ink, or else, mix a loopful of liquid culture of specimens like CSF
with the ink.
 Place a clean cover slip over the preparation avoiding air bubbles.
 Press down, or blot gently with a filter paper strip to get a thin, even film. The stain the
bacteria with Safranin (optional)
 Examine under dry objectives followed by oil immersion
 Endospore (Spore) Staining : Schaeffer-Fulton endospore stain
 Malachite green will stain the spores
 The vegetative cells will appear red (counterstain with 0.5% safranin)

Flagella Staining (Leifson stain)
Tannic acid and the dye form a colloidal precipitate
Stain with Leifson stain for ten min and counterstain
with methylene blue