Exam 4 Notes Updated PDF

Summary

These notes provide a study guide on biochemical cycling and soil microbiology, including symbiotic relationships of microbes in ecosystems, nitrogen cycles, and food spoilage. They discuss various environmental conditions in soil, and specific roles of microbes in nitrogen cycles. The notes also highlight intrinsic and extrinsic factors in food spoilage.

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Exam 4 Notes Updated
Created @November 5, 2024 12:01 PM

Class Micro

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📌 SUMMARY:

Study Guide:

Biochemical Cycling & Soil

Describe the roles/interactions/symbiotic relationships discussed
in lecture that microbes play in ecosystems; please include
specific examples.
Nitrogen Fixation: Some bacteria (e.g., Rhizobium in legumes) form symbiotic
relationships with plants by fixing atmospheric nitrogen, which benefits plant
growth while receiving nutrients in return.

Carbon Cycling: Decomposing bacteria and fungi break down organic
material, releasing carbon dioxide (CO₂) back into the environment, aiding in
carbon cycling.

Mycorrhizal Fungi: Fungi associated with plant roots assist in nutrient and
water absorption, improving plant resilience and growth.

Discuss the reasons that soil microbial communities are not well
understood.

Exam 4 Notes Updated 1
 Diversity and Complexity: Soil contains a vast number of microbial species,
many of which are unculturable in lab settings.

Environmental Variability: Microbial communities fluctuate with changes in
moisture, temperature, and nutrient availability, making it hard to replicate and
study these conditions.

Symbiosis and Dependency: Many microbes depend on interactions with
other organisms, making isolation and study of individual species challenging.

Describe the various environmental conditions found in soils,
including the different types of soils and the types (i.e.,
chemolithotrophs) of microorganisms found in them.
Soil Types and Conditions:

Organic-Rich Soils: Support heterotrophs and decomposers due to the
abundance of organic material.

Mineral Soils: Favor chemolithotrophs, which use inorganic compounds
(e.g., ammonia) for energy.

Moisture Levels: Surface soils with oxygen support aerobic bacteria, while
waterlogged soils favor anaerobic bacteria.

pH and Temperature: Influence microbial growth, with some microbes
adapted to extreme conditions in specialized soils.

Discuss the specific roles that microbes have in the nitrogen
cycle.
Nitrogen Fixation: Bacteria like Rhizobium convert atmospheric nitrogen (N₂)
to ammonia (NH₃), providing a usable form of nitrogen for plants.

Nitrification: Ammonia is converted to nitrite (NO₂⁻) by Nitrosomonas, and
then to nitrate (NO₃⁻) by Nitrobacter, making nitrogen available for plant
uptake.

Denitrification: Anaerobic bacteria (e.g., Pseudomonas) reduce nitrate back
to nitrogen gas (N₂), releasing it into the atmosphere and completing the cycle.

Food

Exam 4 Notes Updated 2
 Discuss the interaction of intrinsic (food-related) and extrinsic
(environmental) factors related to food spoilage.
Intrinsic Factors:

Nutrient Composition: High-protein and high-lipid foods spoil quickly due
to microbial growth, as seen in meats and dairy.

Water Activity: Foods with higher water content spoil faster because
microbes require water to grow (e.g., fresh milk vs. powdered milk).

pH: Foods with low pH (acidic foods) inhibit microbial growth (e.g., citrus
fruits), while neutral or slightly alkaline foods are more prone to spoilage.

Oxidation-Reduction Potential: Aerobic microbes thrive in high-oxygen
foods, while anaerobes grow in low-oxygen or anaerobic conditions.

Extrinsic Factors:

Temperature: Lower temperatures slow microbial growth, prolonging food
shelf life (e.g., refrigeration), while room temperature encourages rapid
spoilage.

Humidity: High humidity levels promote spoilage by encouraging microbial
activity on the surface.

Pre-existing Microbial Load: The initial number of microbes on food
influences the spoilage rate; foods with more microbes initially spoil faster.

Describe the various physical, chemical, and biological processes
used to preserve food.
Physical Methods:

Temperature Control: Refrigeration slows down microbial growth, while
freezing nearly stops it. Heat treatments like pasteurization kill pathogens
(e.g., milk).

Dehydration: Reduces water activity, inhibiting microbial growth (e.g.,
dried fruits).

Chemical Methods:

Exam 4 Notes Updated 3
 Salting and Sugaring: Creates a high-osmolarity environment that
dehydrates microbes.

Acidification: Adding acids (e.g., vinegar) lowers pH, making the
environment inhospitable for many microbes.

Biological Methods:

Fermentation: Microorganisms (e.g., Lactobacillus) produce acids that
preserve food naturally (e.g., yogurt, sauerkraut).

Preservative Microbes: Lactic acid bacteria are used to inhibit spoilage
organisms in certain foods.

Differentiate between food infections and food intoxications &
give an example of each that was discussed in lecture.
Food Infections: Caused by consuming food contaminated with pathogenic
microbes that then colonize the host. Example: Salmonella infection from
undercooked poultry, which requires a high infectious dose (about 10,000
cells).

Food Intoxications: Result from ingesting toxins produced by microbes in food
before consumption, not by the microbes themselves. Example:
Staphylococcus aureus intoxication occurs when S. aureus grows on food left
at unsafe temperatures, producing toxins that cause rapid onset of nausea
and vomiting.

Discuss the detection of disease-causing organisms in food.
Traditional Culture Techniques: Involve culturing food samples on selective
media to identify pathogens based on their colony characteristics.

Rapid Detection Methods: Include immunoassays (e.g., ELISA) to detect
specific pathogens or PCR-based methods to amplify pathogen DNA,
providing faster and often more accurate results.

Hurdles in Detection: Pathogens may be present in low numbers, making
detection challenging. Additionally, some pathogens require specific growth
conditions, and their detection can be inhibited by other microbial flora.

Exam 4 Notes Updated 4
 Describe foods discussed in lecture that are made with the aid of
microorganisms and indicate the types of microorganisms used in
their production.
Cheese: Produced by lactic acid bacteria (e.g., Lactococcus lactis), which
ferment lactose, causing milk to curdle and form cheese.

Yogurt: Created by fermenting milk with bacteria like Streptococcus
thermophilus and Lactobacillus bulgaricus, which produce lactic acid, giving
yogurt its texture and tangy flavor.

Wine and Beer: Made with Saccharomyces cerevisiae (yeast) that ferments
sugars to produce ethanol and carbon dioxide.

Sauerkraut: Fermentation of cabbage by lactic acid bacteria, including
Leuconostoc species, creates the sour taste and preserves the food.

What are probiotics? What are the pro/cons and limitations of
their use?
Probiotics: Live microorganisms that, when consumed in adequate amounts,
provide health benefits by improving gut flora balance.

Pros:

May aid digestion and improve gut health.

Can help prevent certain infections by competing with pathogens.

Cons:

Not all probiotics survive stomach acid to reach the gut.

Some people may experience mild digestive discomfort.

Limitations:

Not all probiotics work for every individual or condition.

The benefits can be strain-specific, and effects may vary widely based on
the individual’s existing gut microbiota.

Industrial/Waste Water & Bioremediation

Exam 4 Notes Updated 5
 Discuss the sources of microorganisms for use in industrial
microbiology.
Natural Environments: Soil and water ecosystems are major sources, as they
contain a wide variety of microbes with diverse metabolic capabilities.

Laboratory Cultures: Strains are often isolated and then optimized in
laboratories to enhance production of desired products.

Genetic Engineering: Microbes are genetically modified to improve efficiency
in industrial processes, such as producing enzymes or biochemicals on a
larger scale.

Discuss the wastewater treatment and water purification & their
importance.
Wastewater Treatment:

Primary Treatment: Physical processes like sedimentation remove large
particles and organic matter.

Secondary Treatment: Microbial processes, including aerobic digestion,
break down organic pollutants, reducing biological oxygen demand (BOD).

Tertiary Treatment: Involves additional filtration, chemical treatments, and
disinfection (e.g., chlorination) to remove remaining pathogens and
contaminants.

Water Purification:

Purification ensures safe drinking water by removing microbes, toxins, and
chemicals through filtration, chlorination, and sometimes UV treatment.

Importance: Prevents waterborne diseases, ensures safe reuse of water in
ecosystems, and maintains public health.

Describe the major products or uses of industrial microbiology.
Enzymes: Microbial enzymes like amylase and protease are used in
detergents, food processing, and biofuels.

Antibiotics: Produced by microbes such as Streptomyces, used to treat
bacterial infections.

Exam 4 Notes Updated 6
 Biofuels: Ethanol produced by yeast fermentation and biogas generated by
anaerobic bacteria contribute to sustainable energy solutions.

*Fermented

Foods**: Lactic acid bacteria are used to produce foods like yogurt, cheese, and
fermented vegetables.

Discuss the manipulation of microorganisms and the environment
to control biodegradation.
Bioremediation: The use of microorganisms to break down pollutants in the
environment, such as oil spills or industrial waste.

Environmental Manipulation:

Nutrient Addition: Adding nutrients like nitrogen and phosphorus
stimulates microbial growth to enhance pollutant breakdown.

Controlled Conditions: Temperature, pH, and moisture are managed to
optimize microbial degradation of contaminants.

Genetic Engineering: Some microbes are engineered to degrade specific
pollutants more efficiently (e.g., hydrocarbon-degrading bacteria for oil spills).

Presentation-Based Notes for Potential Test Questions
Pseudomonas
Pseudomonas species are versatile bacteria found in various environments,
including soil and water.

Known for resilience and ability to survive in harsh conditions.

Produces biofilms, contributing to antibiotic and environmental stress
resistance.

E. Coli in Municipal Water
E. coli contamination often linked to sewage leaks or agricultural runoff.

Detection methods: water testing and rapid detection to prevent outbreaks.

Preventive measures include water purification processes and regular testing.

Exam 4 Notes Updated 7
 Salmonella and Pet Chickens
Salmonella can be transmitted to humans through contact with pet chickens.

Often present on feathers, in droppings, and on contaminated surfaces.

Prevention includes proper handwashing, avoiding contact with the face after
handling chickens, and safe pet practices.

Bear Meat and Salmonella
Bear meat and other wild game can harbor Salmonella due to lack of
controlled processing.

Risk of infection increases if the meat is not thoroughly cooked.

Important precautions include cooking meat to the recommended internal
temperature and practicing safe handling.

Gummy Poisoning
Highlights contamination risks in processed foods, specifically gummy
candies.

Contamination sources may include improper handling during manufacturing,
bacterial growth, or chemical residues.

Emphasizes the importance of safe processing practices and monitoring in
food production facilities.

Salmonella and Cantaloupe
Salmonella contamination in cantaloupe can occur during growth, harvest, or
processing.

Factors include contaminated irrigation water, contact with soil, and improper
handling.

Preventive measures include proper washing, storage, and handling practices
for produce to avoid cross-contamination.

Restaurant-Based Salmonella Case

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 Outbreaks in restaurants are often linked to poor food handling practices,
cross-contamination, or insufficient cooking.

Critical control points include temperature control, regular handwashing, and
safe food storage.

Emphasizes the importance of food safety training and adherence to health
guidelines in the food industry.

Class Notes:
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