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Lecture 4 Nutrition and Growth

Lecture 4 Nutrition and Growth. (Text Chapters: 5.1-5.3; 6.1; 6.4-6.8; 6.10-6.15). Microbial Nutrition. Why is nutrition important? The hundreds of chemical compounds present inside a living cell are formed from nutrients. Macronutrients : elements required in fairly large amounts

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Lecture 4 Nutrition and Growth

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  1. Lecture 4Nutrition and Growth (Text Chapters: 5.1-5.3; 6.1; 6.4-6.8; 6.10-6.15)

  2. Microbial Nutrition • Why is nutrition important? • The hundreds of chemical compounds present inside a living cell are formed from nutrients. • Macronutrients : elements required in fairly large amounts • Micronutrients : metals and organic compounds needed in very small amounts

  3. Main Macronutrients • Carbon (C, 50% of dry weight) and nitrogen (N, 12% of dry weight) • Autotrophs are able to build all of their cellular organic molecules from carbon dioxide • Nitrogen mainly incorporated in proteins, nucleic acids • Most Bacteria can use NH3 and many can also use NO3- • Nitrogen fixers can utilize atmospheric nitrogen (N2)

  4. Other Macronutrients • Phosphate (P), sulfur (S), potassium (K), magnesium (Mg), calcium (Ca), sodium (Na), iron (Fe) • Iron plays a major role in cellular respiration, being a key component of cytochromes and iron-sulfur proteins involved in electron transport. • Siderophores : Iron-binding agents that cells produce to obtain iron from various insoluble minerals.

  5. Representative Siderophore Ferric enterobactin Aquachelin

  6. Need very little amount but critical to cell function.Often used as enzyme cofactors Micronutrients

  7. Organic compounds, required in very small amount and then only by some cells Growth factors

  8. Culture Media: Composition • Culture media supply the nutritional needs of microorganisms • defined medium : precise amounts of highly purified chemicals • complex medium(or undefined) : highly nutritious substances. • Inclinical microbilogy, • Selective : contains compunds that selectively inhibit • Differential: contains indicator • terms that describe media used for the isolation of particular species or for comparative studies of microorganisms.

  9. Culture Media: Physical Properties • Liquid • Bouillon or broth • Solid • Addition of a gelling agent (typically 1% agar) to liquid media • Immobilize cells, allowing them to grow and form visible, isolated masses called colonies (Figure 5.2). • Semisolid • Reduced amount of agar added • Allows motile microorganism to spread

  10. Bacterial Colonies on Solid Media P. aeruginosa (TSA) S. Marcescens (Mac) S. Flexneri (Mac)

  11. Laboratory Culture of Microorganisms • Microorganisms can be grown in the laboratory in culture media containing the nutrients they require. • Successful cultivation and maintenance of pure cultures of microorganisms can be done only if aseptic technique is practiced to prevent contamination by other microorganisms.

  12. Microbial Growth Binary fission

  13. Cell Growth and Binary Fission • Microbial growth involves an increase in the number of cells. • Growth of most microorganisms occurs by the process of binary fission

  14. Microbial Growth Peptidoglycan layer

  15. Microbial Growth pattern • Microbial populations show a characteristic type of growth pattern called exponential growth, which is best seen by plotting the number of cells over time on a semi- logarithmic graph.

  16. Growth Curve • Microorganisms show a characteristic growth pattern (Figure 6.8) when inoculated into a fresh culture medium.

  17. Measuring Microbial Growth • Growth is measured by the change in the number of cells over time. • Cell counts done microscopically (Figure 6.9) measure the total number of cells in a population • whereas viable cell counts (plate counts) (Figures 6.10, 6.11) measure only the living, reproducing population.

  18. Total Cell Count

  19. Viable Cell Count: Determination of Colony Forming Units

  20. Serial Dilution of Cells

  21. Indirect Cell Number Measurement : Turbidity • Turbidity measurements are an indirect but very rapid and useful method of measuring microbial growth (Figure 6.12). However, to relate a direct cell count to a turbidity value, a standard curve must first be established.

  22. Turbidity Measurements of Microbial Growth

  23. Environmental Effects on Bacterial Growth • Temperature • pH • Osmotic pressure • Oxygen classes

  24. Temperature and Microbial Growth • Cardinal temperatures • minimum • optimum • maximum • Temperature is a major environmental factor controlling microbial growth.

  25. Classification of Microorganisms by Temperature Requirements

  26. Temperature Classes of Organisms • Mesophiles • Midrange temperature optima • Found in warm-blooded animals and in terrestrial and aquatic environments in temperate and tropical latitudes • Psychrophiles • Cold temperature optima • Most extreme representatives inhabit permanently cold environments • Thermophiles • Growth temperature optima between 45ºC and 80ºC • Hyperthermophiles • Optima greater than 80°C • These organisms inhabit hot environments including boiling hot springs, as well as undersea hydrothermal vents that can have temperatures in excess of 100ºC

  27. Heat-Stable Macromolecules • Thermophiles and hyperthermophiles produce heat-stable macromolecules, such as Taq polymerase, which is used to automate the repetitive steps in the polymerase chain reaction (PCR) technique.

  28. pH and Microbial Growth • The acidity or alkalinity of an environment can greatly affect microbial growth. • Most organisms grow best between pH 6 and 8, but some organisms have evolved to grow best at low or high pH. The internal pH of a cell must stay relatively close to neutral even though the external pH is highly acidic or basic. • Acidophiles : organisms that grow best at low pH • Alkaliphiles : organismsa that grow best at high pH

  29. Osmotic Effects on Microbial Growth • Osmotic pressure depends on the surrounding solute concentration and water availability • Water availability is generally expressed in physical terms such as water activity • Water activity is the ratio of the vapor pressure of the air in equilibrium with a substance or solution to the vapor pressure of pure water.

  30. Halophiles and Related Organisms • In nature, osmotic effects are of interest mainly in habitats with high salt environments that have reduced water availability • Halophiles : have evolved to grow best at reduced water potential, and some (extreme halophiles) even require high levels of salts for growth. • Halotolerant : can tolerate some reduction in the water activity of their environment but generally grow best in the absence of the added solute • Xerophiles : are able to grow in very dry environments

  31. Oxygen and Microbial Growth • Aerobes : • Obligate : require oxygen to grow • Facultative : can live with or without oxygen but grow better with oxygen • Microaerphiles : require reduced level of oxygen • Anaerobes : • Aerotolerant anaerobes : can tolerate oxygen but grow better without oxygen. • Obligate : do not require oxygen. Obligate anaerobes are killed by oxygen

  32. Test for Oxygen Requirements of Microorganisms Thioglycolate broth : contains a reducing agent and provides aerobic and anaerobic conditions • Aerobic • Anaerobic • Facultative • Microaerophil • Aerotolerant

  33. Hydrogen peroxide Superoxide Toxic Forms of Oxygen and Detoxifying Enzymes

  34. Announcement All lecture resources will be posted on http://www.calstatela.edu/faculty/hpark8/

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