Exam 1 Review PDF

Summary

This document contains notes and figures related to 1. Bacterial cell wall structure: Gram + & Gram -; “Acid fast”, 2. Bacterial cellular morphology & cellular arrangement, 3. Components of prokaryotic cell: internal & external, 4. Components of eukaryotic cell: internal & external, 5. Bacterial chemotaxis, 6. Endospores, 7. Fungi & protozoa, 8. Taxonomy: Domains & Kingdoms of life. The document focuses on the components of cells and different kingdoms of life. It includes figures and diagrams illustrating cell structures.

Full Transcript

Exam 1 review
Andrei Kouranov
1. Bacterial cell wall structure: Gram + & Gram –; “Acid fast”

2. Bacterial cellular morphology & cellular arrangement

3. Components of prokaryotic cell: internal & external

4. Components of eukaryotic cell: internal & external

5. Bacterial chemotaxis

6. Endospores

7. Fungi & protozoa

8. Taxonomy: Domains & Kingdoms of life
Figure 3.2 Typical Prokaryotic Cell
Bacterial DNA:

Represented by only one chromosome

Circular

Double stranded, helical structure

Eukaryotic DNA:

Represented by multiple chromosomes

Linear (majority cases)

Double stranded, helical structure
Plasmids

small circular, double-stranded DNA
free or integrated into the chromosome
duplicated and passed on to offspring
not essential to bacterial growth & metabolism
may encode antibiotic resistance, tolerance to toxic metals, enzymes
& toxins
used in genetic engineering- readily manipulated & transferred from
cell to cell

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Figure 3.3 Typical Eukaryotic Cell
Figure 3.36 Eukaryotic Nucleus

Nucleus contains a suborganelle – nucleolus. Nucleolus is an organelle where RNA components of ribosome
are synthesized
Cytoplasm of Eukaryotes (6 of 14)
Membranous Organelles
Nucleus
Often largest organelle in cell
Contains most of the cell’s DNA
Semiliquid portion called nucleoplasm
Contains chromatin
RNA synthesized in nucleoli present in nucleoplasm.
Surrounded by nuclear envelope
Contains nuclear pores
Figure 3.41 Mitochondrion
 Bacterial Cell Walls
Gram positive Gram negative Acid-fast No cell wall (Mycoplasmas)
Bacterial Cell Walls (3 of 4)
Gram-Positive Bacterial Cell Walls
Relatively thick layer of peptidoglycan
Contain unique chemicals called teichoic acids and
lipoteichoic acids
Appear purple following Gram staining procedure
Up to 60% mycolic acid in acid-fast bacteria helps cells
survive desiccation
Figure 3.16a Comparison of Cell Walls of Gram-Positive and Gram-
Negative Bacteria
Bacterial Cell Walls (1 of 2)
Gram-Negative Bacterial Cell Walls
Have only a thin layer of peptidoglycan
Bilayer membrane outside the peptidoglycan contains
phospholipids, proteins, and lipopolysaccharide (LPS)
Lipid A portion of LPS can cause fever, vasodilation,
inflammation, shock, and blood clotting.
May impede the treatment of disease.
Appear pink following Gram staining procedure
Figure 3.16b Comparison of Cell Walls of Gram-Positive and Gram-
Negative Bacteria

Gram-negative bacteria contain the outer membrane enriched with lipopolysaccharides
There is a large periplasmic space between inner and outer membrane in gram-negative bacteria.
Many types of bacteria and archaea contain S-layer outside of
cell-wall or outer membrane

“The S-layers of both archaea and bacteria consists
of a monomolecular layer composed of only one (or,
in a few cases, two) identical proteins or
glycoproteins.” Wikipedia
Differential Gram staining

Step Microscopic Appearance of Cell Chemical Reaction in Cell Wall
(very magnified view)

Gram (+) Gram (–) Gram (+) Gram (–)

1. Crystal violet
First, crystal violet is added to the cells in a smear. It stains them all the
same purple color.

Both cell walls affix the dye

2. Gram’s iodine
Then, the mordant, Gram’s iodine, is added. This is a stabilizer that causes
the dye to form large complexes in the peptidoglycan meshwork of the cell
wall. The thicker gram-positive cell walls are able to more firmly trap the
large complexes than those of the gram-negative cells. Dye complex No effect
trapped in wall of iodine

3. Alcohol
Application of alcohol dissolves lipids in the outer membrane and removes
the dye from the peptidoglycan layer—only in the gram-negative cells.

Crystals remain Outer membrane
in cell wall weakened; wall
loses dye

4. Safranin (red dye)
Because gram-negative bacteria are colorless after decolorization, their
presence is demonstrated by applying the counterstain safranin in the
final step.
Red dye masked Red dye stains
by violet the colorless cell
 Bacterial shapes and arrangements

Pleomorphism: variation in the size and shape of cells of a single
species due to nutritional and genetic differences
Figure 3.13 Bacterial Shapes and Arrangements

(c)
Bacterial Arrangements
 Bacterial Shapes and Arrangements
(cont’d)
Arrangement of cocci: Arrangement of bacilli:
Single – Single
Diplococci: pairs – Diplobacilli: pair of cells with
ends attached
Tetrads: groups of four
– Streptobacilli: chain of
Staphylococci or several cells
micrococci: irregular – Palisades: cells of a chain
clusters remain partially attached by
Streptococci: chains a small hinge region at the
ends
Spirilla: occasionally
found in short chains
Spirochetes: rarely remain
attached after cell division
 Bacteria can move rotating flagellum( flagella)

(a) (b) (c) (d)

a. monotrichous – single flagellum at one end
b. lophotrichous – small bunches arising from one end of cell Endoflagellum in spirochete
c. amphitrichous – flagella at both ends of cell confined within the
d. peritrichous – flagella dispersed over surface of cell, slowest periplasm, between the inner
and outer cell membrane
Fimbrae

fine hairlike bristles from the cell surface
function in adhesion to other cells and
surfaces, involved in formation of biofilms

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Figure 3.12 Pili
Bacterial mating: conjugation

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Gycocalyx – key component of bacterial slime
layer or capsule
Coating of molecules external to the cell wall, made of sugars and/
or proteins
2 types
1. capsule - highly organized, tightly attached
2. slime layer - loosely organized and attached

functions
attachment
inhibits killing by white blood cells
receptor

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 Two types of glycocalyx

Slime layer glycocalyx helps Streptococcus mutans to attach to smooth surface of teeth and cause teeth decay
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 Chemotaxis: move in response of
chemical signal

(Clockwise rotation) (Counterclockwise rotation = smooth linear direction)
Taxonomy - science for organizing,
classifying & naming living things
Taxonomic categories from top to the bottom:
Domain - Archaea, Bacteria & Eukarya-
Three domains of life
Kingdom
Phylum or Division
Class
Order
Family
Genus
species
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Examples of Taxonomy: Organized into several descending
ranks, beginning with the most general and ending with the
smallest and most specific
Figure 3.25b Endospores
 Endospores
Resting, dormant cells
produced by some G+ genera: Clostridium, Bacillus (mainly
bacilli type bacteria)
Have a 2-phase life cycle – vegetative cell & an endospore
sporulation -formation of endospores
germination- return to vegetative growth
hardiest of all life forms
withstand extremes in heat, drying, freezing, radiation &
chemicals not a means of reproduction

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Example of endospore forming bacteria

Endospore

Example of endospore forming pathogens:

Clostridium tetani (Tetunus)
Clostridium perfringes (Gas gangrene)
Clostridium botulinum (Botulism)
Clostridium difficale (C.diff)
Bacillus anthracis (Anthrax)
Cellular components that help protozoan (Kingdom Protista) to move:
pseudopodia; flagellum, cilia
Amoeba Euglena
Pseudopodia

Vacuole

Nucleus Storage vesicles Paramecium
Saprophytic – live on dead, decomposing
matter

Forms of fungi:
Molds form intertwining filaments called hyphae
that forms mycelium

Yeasts are unicellular, propagate by budding or
fission, may form chains called pseudohyphae