Effect of Environmental Factors on Growth

1. Water Availability

2. pH

3. Temperature

4. Oxygen level

1. Water Availability

Water availability depends on

            ï water content of an environment

ï the concentration of solutes in the environment

measured as water activity, aw

ratio:

 

vapor pressure of air in equilibrium with a solute

vapor pressure of air in equilibrium with pure water

 

Pure water = 1.

osmotic effects

 

High salt/high sugar solutions are analogous to a dry environment.

A halophile can tolerate some salt.

A halotolerant organism tolerates a range of conditions

An extreme halophile can grow in extremely salty conditions:

An osmophile can grow in high sugar.

2. pH

Acidophiles- pH between 0 and 5.5

Neutrophiles- pH between 5.5 and 8

Alkalophiles- pH between 8.5 and 11.5 (Extreme, > 10)

Internal pH is kept pretty neutral!

Changes in pH: disrupt membranes, also denature enzymes.

3. Temperature

A microorganism's temperature varies with the temperature of the environment

            enzyme reaction rates (low)

            denaturing of enzymes and nucleic acids (high)

Psychrophiles: optimal growth temperature <15ƒ C

Psychrotolerant: 20-40ƒ C, tolerate broad range including low temperatures

Mesophiles: optima around 20-40ƒ

Thermophiles (> 40ƒ C) and hyperthermophiles (>80ƒC)

No eukaryotic hyperthermophiles... (none above 60ƒ)

Archaea: often adapted to extreme habitats, and extreme combinations- e.g. acid or alkaline hot springs

Biotechnological applications of extremophiles:

ï living organisms are the most efficient way to synthesize complex compounds such as enzymes, and perform most chemical reactions!!

ï enzymes of thermophiles especially useful: more stable than enzymes from mesophiles, and also many industrial and biotechnological processes will run more efficiently at high temperatures.

Aerobes vs. anaerobes: Can/can't grow in the presence of atmospheric O2.

Aerobes: oxygen serves as the terminal electron acceptor in aerobic respiration.

Obligate: required.

            Obligate aerobe, obligate anaerobe

Facultative: can grow that way (but better the other way)

            E. coli is a facultative anaerobe.  Note some texts define this word the opposite way!  E. coli  is a facultative aerobe

Aerotolerant anaerobe: ignores the air.

Strict or obligate: required.

            Bacteroides is an obligate anaerobe.

Oxygen produces poisonous compounds-

Evolution of life: life evolved in an anoxic atmosphere (~4 billion years ago). Evolution of microorganisms that could extract oxygen from water in a light-driven reaction for the reduction of carbon dioxide!

Photosynthesis: a sharp rise in atmospheric oxygen, 2 to 1.8 billion years ago

Result: a need to for cells to protect themselves from oxygen.

Two strategies: hide, or use enzymes to break down the toxic products of oxygen:

            superoxide dismutase

            catalase

Control of Microorganisms by Physical and Chemical Means

Sterilization:

kill or remove all living cells, spores, viruses on an object of habitat.

Disinfection:

kill, inhibit, or remove disease-causing microorganisms.

Sanitization:

                   reduce the microbial population to safe levels.

Antisepsis:

prevent infection or sepsis, with an antiseptic

            germicide

            bactericide

            fungicide

            algaecide

            viricide.......

When is a microbe dead?

       If it doesn't grow when you put it into a good culture medium...

Microbial death is usually exponential or logarithmic.

Not all the microbes are killed at once!

What affects the efficiency of an antimicrobial agent?

1.   population size

2.   composition of the population (species, endospores)

3.   concentration of the agent

4.   duration of exposure

5.   temperature

6.   local environment (for example, acidity; organic matter)

 

HEAT

ï boiling

            doesn't kill endospores

TDP = thermal death point, the lowest temperature at which a microorganism is killed in 10 minutes

TDT = thermal death time, shortest time needed to kill a microorganism under specified conditions

D = decimal reduction time, the time needed to kill 90% of the microorganisms or spores under specified heat

AUTOCLAVING

ï combines heat, moisture and pressure

PASTEURIZATION

Controlled heating, kills certain microorganisms.

DRY HEAT (BAKING)

useful for equipment, glassware, etc.

 

FILTRATION

get rid of the microbes directly! good for heat-sensitive things, like antibiotics, pharmaceuticals. Air (safety hoods)!

 

RADIATION

UV (260 nm- doesn't penetrate, so surfaces only),

ionizing- gamma. Used for cold sterilization - plasticware

 

CHEMICAL AGENTS

Phenolics

            used in hospitals- Lysol types

Alcohols

            don't kill spores. Thermometers

Halogens

            chlorine in water systems

Heavy Metals

            silver nitrate in babies' eyes; mercury. Toxic!

Detergents (quaternary ammonium compounds)

            skin

Aldehydes

            formaldehyde, glutaraldehyde

Gases

            ethylene oxide gas- used for plasticware Petri dishes, penetrates!

ANTIBIOTICS AND GROWTH FACTOR ANALOGS

 

Agents that can be used inside the body: "Chemotherapeutic agents"

• Growth Factor Analogs

Required by an organism, because the organism canít synthesize them.

Growth factor analogs: chemically related to (mimic) growth factors, and block uptake or utilization of growth factors. They are not naturally-produced substances.

• Antibiotics

ï Antibiotics are naturally produced by bacteria and fungi.

ï Naturally-produced antibiotics have been used as the basis for the design of novel, "semisynthetic" antibiotics.

ï Over 10,000 have been discovered, but only ~100 in commercial production

ï Actinomycetes (division of the G+ bacteria)

ï Range of action:

            Broad spectrum: Targets Gram+, Gram-. Or may target Mycobacteria and G-, or G+ and intracellular (parasitic) bacteria

            Examples: Cephalosporins (G+ and G-), Tetracycline (G+, G-, intracellular bacteria)

            Note that no antibiotics target viruses.

            Narrow spectrum: target a specific group, such as G+, or even one species. Examples Polymyxins (G+)

ï Major modes of action:

• Cell wall synthesis. Penicillins, Cephalosporins
• Cytoplasmic membrane structure: polymyxins
• Protein synthesis (ribosomal inhibition):

            50S: Erythromycin, chloramphenicol

            30S: Tetracyclines, streptomycin

• Protein synthesis (tRNA): Puromycin
• Folic acid metabolism: Trimethoprim
• DNA gyrase: Novobiocin
• DNA-directed RNA polymerase: Rifampin

EXAMPLES OF IMPORTANT ANTIBIOTIC GROUPS:

• b-Lactam Antibiotics : penicillins, cephalosporins, and cephamycins

Mechanisms of action:

Bacterial cell walls: glycan-linked peptide chains, linked by the transpeptidation reaction, carried out by transpeptidase enzymes. Transpeptidase enzymes also bind antibiotics with the b-Lactam ring, and when bound, can no longer catalyze the transpeptidase reaction. Result: weakened, eventually degraded cell walls.

Penicillin G is active against G+ bacteria 

Tetracyclines

ï Produced by bacteria

ï First broad-spectrum antibiotics

Mode of Action:

Protein synthesis inhibitor- interferes with 30S ribosomal subunit function