Microbiology Exam 3 PDF

Summary

This Microbiology lecture covers microbial metabolism, including redox reactions, enzymes, and the impact of pH and temperature on enzyme activity. It also details aerobic respiration, glycolysis, the Krebs cycle, the electron transport chain, and metabolic pathways such as the EMP and PPP. Additional topics include microbial growth, environmental factors, and oxygen requirements.

Full Transcript

Microbiology Exam 3

MICROBIAL METABOLISM (Lecture Topic 5)
Metabolism: Refers to all chemical reactions in a cell, including those that build
up (anabolism) and break down (catabolism) molecules to produce energy.
Redox reactions: These involve the transfer of electrons.

Oxidized means a substance loses electrons.
Reduced means a substance gains electrons.

Enzymes: Proteins that speed up biochemical reactions.

Apoenzyme: The protein part of an enzyme, without any cofactors.
Cofactor: A non-protein component required by some enzymes to function
(e.g., metal ions).
Holoenzyme: The complete enzyme, consisting of the apoenzyme and its
cofactor.
Enzymes are crucial because they lower activation energy for reactions
and are named often by adding “-ase” to the substrate or the type of
reaction they catalyze.

Impact of pH and temperature on enzymes:

Enzymes work best at optimal pH and temperature.
Extremes in either can denature enzymes (alter their structure), making
them ineffective.

Enzyme inhibition:

Competitive inhibition: A substance competes with the substrate for
binding to the active site.
Allosteric inhibition: A substance binds elsewhere on the enzyme,
changing its shape and reducing activity.

NAD and FAD: These are electron carriers.

NAD is reduced to NADH and FAD is reduced to FADH2 during metabolic
reactions. They carry electrons to the electron transport chain for ATP
production.
Stages of aerobic respiration:

Glycolysis, Krebs cycle, and Electron Transport Chain (ETC). They
occur in this order.

ATP production:

Glycolysis: 2 ATP
Krebs cycle: 2 ATP
ETC: About 34 ATP
Total: ~38 ATP for prokaryotes, ~36 ATP for eukaryotes.

Cellular respiration steps:

Glycolysis starts with glucose, producing pyruvate.
Krebs cycle starts with acetyl-CoA, producing CO2.
ETC starts with NADH and FADH2, producing ATP and water.

Location of respiration:

Prokaryotes: Glycolysis in the cytoplasm, Krebs in the cytoplasm, and ETC
in the cell membrane.
Eukaryotes: Glycolysis in the cytoplasm, Krebs in the mitochondrial matrix,
and ETC in the inner mitochondrial membrane.

ATP synthase: This enzyme creates ATP from ADP and inorganic phosphate,
driven by a flow of protons (H+) across a membrane during oxidative
phosphorylation.
Metabolic pathways:

EMP (Embden-Meyerhof-Parnas): The most common glycolytic pathway,
produces 2 pyruvate and 2 ATP and 2 NADH
PPP (Pentose Phosphate Pathway): Produces NADPH and
ribose-5-phosphate for nucleotide synthesis.
ED (Entner-Doudoroff): Alternative glycolytic pathway, produces
pyruvate, used by some bacteria. produces 1 ATP 1NADPH

Fermentation: Occurs when oxygen is not available, allowing cells to regenerate
NAD+ by converting pyruvate into products like lactic acid or ethanol.
Lipid and protein catabolism: These molecules are broken down during the
Krebs cycle.
Types of organisms:

Photoautotrophs: Use light energy and CO2 (e.g., plants, cyanobacteria).
Chemoautotrophs: Use chemical energy and CO2 (e.g., some bacteria).
Photoheterotrophs: Use light for energy but organic compounds for
carbon (e.g., purple non-sulfur bacteria).
Chemoheterotrophs: Use organic compounds for both energy and carbon
(e.g., animals, fungi).

MICROBIAL GROWTH (Lecture Topic 6)

Temperature groups of bacteria: Bacteria are classified into five groups
based on their optimum growth temperatures:
○ Psychrophiles: Thrive at cold temperatures (below 15°C, optimal
around 10°C).
○ Psychrotrophs: Grow between 0–30°C, optimal around 20–30°C
(spoil food in refrigerators).
○ Mesophiles: Optimal growth at moderate temperatures, around
25–40°C (most human pathogens).
○ Thermophiles: Thrive at warmer temperatures, 50–60°C.
○ Hyperthermophiles: Can grow at extremely\ high temperatures,
above 80°C, often found in hot springs.
Physical and chemical requirements for microbial growth:
○ Physical requirements: Temperature, pH (most bacteria grow best
between pH 6.5 and 7.5), and osmotic pressure (salt concentration).
○ Chemical requirements: Carbon, nitrogen, sulfur, phosphorus,
trace elements (e.g., iron, magnesium), and in some cases, oxygen.
Oxygen requirements for microbes:
○ Obligate aerobes: Require oxygen.
○ Obligate anaerobes: Cannot tolerate oxygen.
○ Facultative anaerobes: Can grow with or without oxygen, but prefer
oxygen.
○ Aerotolerant anaerobes: Do not use oxygen but can tolerate its
presence.
 ○ Microaerophiles: Require lower levels of oxygen than present in the
atmosphere.
Thioglycolate broth is often used to determine oxygen preferences, as it
allows an oxygen gradient, where bacteria grow based on their oxygen
needs.
Chemically defined vs. complex culture media:
○ Chemically defined media: The exact chemical composition is
known. Used when precise nutrient requirements of microbes are
known (e.g., in research settings).
○ Complex media: Contains a variety of ingredients like meat extracts
or yeast extract, and the exact composition is not known. Often used
in routine lab culture work (e.g., nutrient broth, tryptic soy agar).
Selective, enrichment, and differential media:
○ Selective media: Suppresses the growth of unwanted bacteria while
encouraging the growth of the desired microbe (e.g., MacConkey
agar for Gram-negative bacteria).
○ Enrichment media: Provides conditions that favor the growth of a
particular microbe but doesn’t suppress others (e.g., blood agar for
growing fastidious organisms).
○ Differential media: Allows differentiation between species based on
observable changes (e.g., blood agar differentiates organisms based
on hemolysis).
Biosafety levels (BSLs):
○ BSL-1: Low-risk microbes (e.g., non-pathogenic strains of E. coli).
○ BSL-2: Moderate-risk pathogens (e.g., Staphylococcus aureus).
○ BSL-3: High-risk microbes that can cause serious or potentially
lethal diseases (e.g., Mycobacterium tuberculosis).
○ BSL-4: High-risk microbes with no available treatments or vaccines
(e.g., Ebola virus).
Prokaryote and eukaryote reproduction:
○ Prokaryotes: Replicate via binary fission, a simple division
process.
○ Eukaryotes: Replicate via mitosis (somatic cells) or meiosis (sex
cells).
○ Yeast: Use mitosis with budding, where a new cell forms as a
bulge.
 ○ Molds: Reproduce via conidiospores, which are asexual spores
formed at the tips of hyphae.
DNA replication is semi-conservative: Each daughter DNA molecule
consists of one original strand and one newly synthesized strand.
Cell cycle stages:
○ Interphase: Includes G1 (cell growth), S (DNA replication), and G2
(preparation for mitosis).
○ Mitosis: Includes prophase, metaphase, anaphase, and telophase.
○ Cytokinesis: The division of the cytoplasm, producing two daughter
cells.
Non-mitotic eukaryotic cells: Some specialized cells, like neurons and
muscle cells, do not undergo mitosis. Treatment of related disorders often
involves stimulating these cells or using stem cells to replace them.
Microbial growth phases:
○ Lag phase: Bacteria adapt to their environment, little to no growth.
○ Log phase (exponential phase): Rapid bacterial growth and
division.
○ Stationary phase: Nutrient depletion slows growth, and death rate
equals division rate.
○ Death phase: Cells die at an accelerated rate due to harsh
conditions.
Colony-forming units (CFUs): A measurement of viable bacterial cells,
where one CFU represents one bacterial cell or a group of cells that give
rise to a colony.
Countable range: Typically between 30 and 300 colonies on an agar plate
for reliable counts.
Direct and indirect microbial measurement methods:
○ Direct methods: Counting colonies (plate counts), counting cells
under a microscope, or using flow cytometry.
○ Indirect methods: Measuring turbidity (cloudiness) in liquid culture,
measuring metabolic activity, or dry weight.

Control of Microbial Growth (Lecture Topic 7)

Terms related to microbial control:
 Sterilization: Complete destruction of all forms of microbial life, including
spores (e.g., autoclaving surgical instruments).
Disinfection: Reducing the number of pathogenic microorganisms on
inanimate objects (e.g., using bleach on surfaces).
Sepsis: The presence of harmful microorganisms or their toxins in tissues
(e.g., sepsis after surgery).
Degerming: Mechanically removing microbes from a limited area (e.g.,
hand washing or using alcohol before an injection).
Antiseptic: Chemical agents used on living tissues to reduce microbial
load (e.g., iodine on skin).
Sanitization: Reducing microbial levels on inanimate objects to safe public
health levels (e.g., cleaning utensils in restaurants).
Biocide/Germicide: Agents that kill microorganisms (e.g., bleach,
hydrogen peroxide).
Asepsis: The absence of significant contamination (e.g., using sterile
techniques during surgery).
Bacteriostasis: Inhibiting bacterial growth without killing the microbes
(e.g., refrigeration).

Joseph Lister’s contribution: Lister significantly reduced nosocomial
(hospital-acquired) infections by using carbolic acid (phenol) to sterilize surgical
instruments and clean wounds, preventing contamination.

Nosocomial infections: Infections acquired in healthcare settings, such as
hospitals, often due to poor aseptic practices or weakened immune systems of
patients.

Commercial sterilization: A process that kills Clostridium botulinum spores
(which cause botulism), but not necessarily all forms of life. It is limited because it
targets specific organisms of public health concern, particularly in food canning,
but does not achieve full sterilization like autoclaving.

"Static" vs. "Cide" terms:

"Static": Refers to inhibiting growth (e.g., bacteriostatic agents like
refrigeration slow bacterial growth).
"Cide": Refers to killing (e.g., bactericide kills bacteria).

Actions of microbial control agents:
 Damage to cell walls or membranes: Detergents and alcohols can
disrupt membranes, leading to cell leakage.
Damage to proteins: Heat and chemicals (e.g., formaldehyde) can
denature proteins, rendering enzymes non-functional.
Damage to nucleic acids: Radiation and chemicals (e.g., ethylene oxide)
can damage DNA, preventing replication.

Effectiveness factors: Temperature, pH, time of exposure, the number of
microbes, and presence of organic matter (e.g., blood) can influence the
effectiveness of control methods.

Physical methods of microbial control:

Heat: Includes moist heat (autoclaving), dry heat (incineration),
pasteurization.
Filtration: Physically removes microbes from liquids or air (e.g., HEPA
filters).
Radiation: UV light causes DNA damage; ionizing radiation (gamma rays)
penetrates and sterilizes.
Low temperatures: Inhibit microbial growth (e.g., refrigeration, freezing).
Desiccation: Drying out materials to inhibit microbial growth (removal of
water).
Osmotic pressure: High salt or sugar concentrations create an
environment where microbes can't grow due to plasmolysis.

Different materials require different methods because heat-sensitive materials
(like plastics) cannot be autoclaved and might need filtration or radiation instead.

Thermal death point vs. thermal death time:

Thermal death point (TDP): The lowest temperature at which all microbes
in a liquid culture are killed in 10 minutes.
Thermal death time (TDT): The minimum time required to kill all microbes
at a given temperature.

Autoclave standard cycle: Typically, autoclaving involves heating at 121°C for
15 minutes at 15 psi. Times may vary based on the material being sterilized,
load size, or type of material (e.g., longer for bulky materials).

Chemical methods of microbial control:
 Alcohols: Denature proteins and dissolve lipids (e.g., ethanol).
Halogens: Include iodine and chlorine, which are strong oxidizers and
disinfectants.
Phenolics: Disrupt cell membranes (e.g., Lysol).
Heavy metals: Such as silver and copper can inhibit microbial growth by
denaturing proteins.
Surface-active agents (surfactants): Lower surface tension, making
microbes easier to remove (e.g., soaps, quaternary ammonium
compounds).
Aldehydes: Highly effective disinfectants that crosslink proteins (e.g.,
formaldehyde).

Most resistant microbes:

Prions: Proteinaceous infectious particles, highly resistant to sterilization
methods.
Endospores: Bacterial spores (e.g., Bacillus and Clostridium species) are
highly resistant.
Mycobacteria: Have waxy cell walls that resist many disinfectants.
Gram-negative bacteria: Their outer membrane makes them more
resistant to some antimicrobial agents.

Microbial Genetics (Chapter 8)

Differences between genes, genomes, genotypes, and phenotypes:

Genes: Segments of DNA that code for specific proteins or RNA
molecules.
Genomes: The entire set of genetic material (DNA) in an organism.
Genotype: The genetic makeup of an organism (the specific set of genes).
Phenotype: The observable characteristics or traits of an organism,
influenced by the genotype and the environment.

Flow of genetic information:

Expression: The process by which genetic information is used to produce
proteins (gene -> mRNA -> protein).
 Dominant vs. recessive genes: Dominant genes express their traits even
if only one copy is present (heterozygous). Recessive genes require two
copies to express the trait (homozygous).

mRNA and tRNA functions:

mRNA (messenger RNA): Carries the genetic code from DNA to
ribosomes, where proteins are synthesized.
tRNA (transfer RNA): Brings amino acids to the ribosome during protein
synthesis, matching them to the codons on mRNA.

Transcription and translation:

Transcription: The process of copying DNA into RNA. Occurs in the
nucleus (eukaryotes) or cytoplasm (prokaryotes).
○ Enzymes involved: RNA polymerase.
○ Product: mRNA.
Translation: The process of converting mRNA into a protein. Occurs in the
ribosome (in both prokaryotes and eukaryotes).
○ Biomolecules involved: mRNA, tRNA, ribosomal RNA (rRNA), amino
acids.

DNA to RNA conversion and codons:

DNA to RNA: A process known as transcription. In RNA, thymine (T) is
replaced by uracil (U).
○ Example: DNA sequence ATGCGT would transcribe to RNA as
UACGCA.
Codons: A sequence of three nucleotides on mRNA that codes for a
specific amino acid. The start codon is AUG, which codes for methionine.

Process of translation:

As mRNA moves through the ribosome, each codon is read and matched
with the appropriate tRNA carrying its corresponding amino acid. The
amino acids are linked together to form a polypeptide chain (protein).

Mutations and mutation rates:
 Mutations: Changes in the DNA sequence, which can occur
spontaneously or be induced by external factors like radiation.
Typical mutation rate: Varies, but is generally around 1 in 10^9 (one error
per billion nucleotides).
Types of mutations:
○ Point mutation: A single nucleotide change.
○ Frameshift mutation: Insertion or deletion of nucleotides, altering
the reading frame of the gene.
○ Silent mutation: A mutation that does not affect the protein
sequence.
○ Missense mutation: A change in one nucleotide that results in a
different amino acid.
○ Nonsense mutation: A mutation that results in a stop codon,
truncating the protein.

Radiation and mutation repair:

Radiation (e.g., UV light): Can cause thymine dimers (two adjacent
thymine bases bonding to each other), disrupting DNA replication.
DNA repair mechanisms: Cells use enzymes like photolyases (light
repair) and excision repair systems to correct damage caused by
radiation.

Ames test:

A test used to identify potential mutagens (substances that cause
mutations). It uses Salmonella bacteria that cannot synthesize histidine
and measures whether exposure to a chemical increases mutation rates,
allowing the bacteria to regain the ability to produce histidine.

Gene transfer in bacteria:

Transformation: The uptake of naked DNA from the environment.
Conjugation: Direct transfer of DNA between two bacterial cells through a
pilus.
Transduction: Transfer of DNA from one bacterium to another via a virus
(bacteriophage).

Genetic transformation and Streptococcus pneumoniae:
 Genetic transformation was discovered through experiments with
Streptococcus pneumoniae by Frederick Griffith. He showed that dead
virulent bacteria could "transform" non-virulent bacteria into virulent ones
by transferring DNA.

Plasmids:

Small, circular DNA molecules found in bacteria that are separate from
chromosomal DNA. Plasmids often carry genes for antibiotic resistance
and can be transferred between bacteria, which is why microbiologists are
concerned—they contribute to the spread of antibiotic resistance.

Pros and cons of mutations:

Pros: Mutations can lead to new traits or abilities, such as antibiotic
resistance, which may benefit the organism in certain environments.
Cons: Mutations can be harmful, leading to non-functional proteins,
diseases, or cell death.