Microbiology 303 Exam 2
Metagenome of the microbiota
Another them for microbiota
Purple Bacteria
Are All Proteobacteria Use PSII photosystem Non-Sulfur Bacteria Use H2S as electron donor for photosystem Photoautotrophs: Fix Carbons Sulfur Bacteria Use low levels of H2S as electron donor Can be: photoautotrophs, photoheterotrophs, and by aerobic respiration
Orchid
Arent able to feed endomycorrhizae, roots are saprophytic
Rhizosphere
Assist in growth of microbes, secretes nutrients some inhibit fungal growth = causing disease plants helps microbes that help it
Iron and Manganese Cycles
At neutral pH they precipitate Fe^2+ (electron donor) --> forms H20 --> oxidative (chemolithrophy) --> Fe^3+ oxidized as product (Fe^3+ becomes electron acceptor) --> Reductive (Dissimilarity Fe^3+ reduction) --> Fe^2+ as electron donor (Fe^2+ as reduced product of anaerobic respiration) Iron can be reduced anoxically At neutral pH iron become better electron donor
Calvin Cycle
Carbon Fixation Start with Ribulose 1-5 Bisphosphate Use Enzyme: RuBisCo which adds inorganic carbon to molecule KEY PHASE: Reduction Phase: G3P Use NADPH + H+ --> NADP+ Requires 3 ATP and 2 NADPH per CO2
Microbial communities can provide stability to their environment
Carbon and Nitrogen are linked C-N-P Organism require microbes help stabilize soil Full oxidized - Nitrate (needs to be reduce) Ammonia (NH4) needs to be oxidized
CO2
CarbonDioxide can be electron accpetor and make natural gas.
Bifidobacteria
Degrades sugars in Milk
Chrome Agar
Differentiates between pathogens because each organisms has a different color. Synthetic substrate
Measuring Cell Number
Direct: Counting cant tell if its alive or dead requires a microscope Indirect: Plating Colony Forming Units (CFU) Estimating: Most Probably Number - uses dilution to extinction Light Scattering - turbidity Drawbacks: A lot of excess requirements - dilutions - microbes difficulty growing
Differential Medium
Distinguishes groups of microbes on the sample.
Anoxgenic Phototrophy
Don't Generate Oxygen Make ATP No electron donor and terminal electron acceptor (No NADPH) ETC generates PMF and returns to photosystem PSI (P840 or P798) PSII (P870) Notice High Wavelength (infrared light)
Respiration
ETC is a chain of redox reaction organized by increase ΔE Excess H+ cannot be transferred thus they are pushed out of the cell => PMF PMF can be used to do work generate ATP by ATP-synthase
History of Earth
Early Phototrophs were anoxygenic and used H2S S^0 a good from of E storage Anoxic atmosphere occured after oxygenation
Predatory
Eats cell Ex. Vampirococcus Daptobacter Myxococcus Bdellovibrio
Limitations to culture-based studies
Most microbes cant be cultured microbes in nature do not grow in pure culture - competition - symbiosis (Syntrophy) - phage and predator Microbes in nature are not usually in exponential phase Microbes in nature do not usually have unlimited nutrient and optimal growth conditions
ETC can be used Reversed
Most will go forward --> To Make ATP Some can flow backwards <-- Make NADH for reduction Reduce NAD to get NADH
Anhydride and Thioester Bond
Much less energy in a thioester bond then in a Anhydride bond Energy Storage
Microbial Communities shaped by different types of symbiosis
Mutalism Parasitism cooperation commensalism predation amensalism competition
Types of Symbiosis
Mutualism Cooperation Commensalism Predation Parasitism Pathogenesis Competition
TCA Cycle or Krebs Cycle
NADH goes to ETC to generate more ATP by Oxidative Phosphorylation 1 ATP = created by substrate level phosphorylation per pyruvate molecule 4 NAD+ = 12 ATP 1 FAD = 2 ATP
Photoheterotrophy
NADPH will help in fixing carbon to get biosynthesis ATP is required
Dead Zones
Oxygen minimum zones where chemolithoautotrophs exclusively prevail caused by influx of limiting nutrients photosynthetic microbes die and sink and consumed by chemoheterotrophs who quickly consume all oxygen and then suffocate Sewage and Pollutants that are added to waters that cause dead zones Trigger blooms of cyanobacteria and algae
Phototrophy can be Oxygenic and Anoxygenic
Oxygenic - generates oxygen Z path Anoxygenic - DOES NOT generate oxygen O path
Pollutants (PCDD & PDCF)
Some microbes use microbes use pollutants as electron acceptor Can reduce and make soluble against toxins
No Dormant Cells
Viable but non-culturable organisms that cant grow on a rich medium Most Organism in nature are Dormant Culture less than 1% of all microbes
Happen when there is an influx of the limiting element
a lot of growth due to influx of limiting reagents Ex. Dead Zones
ΔE Reduction Potential
can be measured and expressed for each half reaction Aox + e- --> Ared
Phosphorous and Calcium Cycles
cycles are mostly to maintain balance between organic and mineral forms of these elements Phosphorous is usually limiting for photosynthesis
Methylotrophs
oxidizes methane gas most carbons are stored in rocks and sediments 99.5% and oceans .5%
Reaction Center
site of electron excitation reaction center can be Photosystem I or II use quiniones to transfer electrons to ETC
ΔG = -nFΔE Gibbs Free Energy Change
ΔE = E(acceptor) - E(donor)
Prochloroccus
Smallest and most abundant photosynthetic organism on earth
Endergonic
+ΔG Negative ΔE not a viable lifestyle
Pristine Soil vs. Diverse Soil
Alaskan Soil (Pristine) more diverse than Wisconsin Farm Soil (Diverse)
Exergonic
-ΔG Positive ΔE Favorable reaction viable lifestyle
Step 2 of Glycolysis
1,3 Bisphosphoglycerate used to generate ATP reduces NAD+ Makes NADH and ATP 2 net ATP are made by substrate-level phosphorylation
Methylotrophs has 3 mechanism
1. Aerobic Oxidation 2. Anaerobic Oxidation 3. Coupled methane oxidation with denitrification
Aerobic Nitrification
1. Ammonia --> Nitrite 2. Nitrite --> Nitrate Nitrifying Bacteria
How is Energy Stored in Cells?
1. Membrane (PMF) 2. High Energy Bonds - Anhydrides (ATP) - Thioesters (Acetyl-CoA) - Aldehydes 3. High Energy Organic Substrates - Glycogen - PHB - Inorganic Sulfur - Starch and Fats (Eukaryotes)
Summary of Respiration
1. Protons and electons converted into NADH 2. NADH starts chain of redox reaction in the ETC 3. Electons and Protons from high-energy are passed through a chain to generate PMF 4. PMF powers ATP-synthase to generate ATP by oxidative phosphorylation used to power cellular reactions
Glycolsis
1. Start with Glucose and produce (2) Glyceraldehyde 3-P Aldehyde Group - very reactive (Preparatory Steps) 2. Energy in aldehyde bond of glyceraldehyde 3-P used to produce NADH and ATP 3. PEP, high energy phosphoanhydride. Phosphoenolpyruvate (PEP) is used to generate ATP and pyruvate (2)
Syntrophy Oxidation and Methanogen
1. Syntrophy first oxidizes reduce proton to produce H2 2. Methanogen uses H2 to reduce CO2 and produce methane Not favorable, but together it becomes favorable
Microbial diversity corresponds with redox niche
1.Notice O2 get consumed (oxic - aerobic respiration) 2. Nitrate (denitrification) 3. Iron (Fe) (Fe(III) reduction) 4. Sulfate (sulfate reduction) 5. Methane (Methanogenesis) Relative to electron acceptor
How Humans get Nitrogen
Ammonium (NH4+) or amino acids we eat Nitrate is toxic to humans
Sulfur Cycle
A lot of redox states, (can only be oxidized) SO4^2- (sulfate) most oxidized form burning fossil fuel provides sulfur to air (leads to acid rain) Sulfur/Sulfide Oxidation -(H2S --> S^0 --> Sulfate) - Anaerobic - Sulfur Chemolithotrophs -Aerobic - Purple and green bacteria Sulfate Reduction (Anaerobic) - (sulfate --> H2S) Sulfur Reduction (Anaerobic) - (S^0 --> H2S) Sulfur Disproportionation - (S2O2^2- --> H2S and sulfate) Organic Sulfur Compound oxidation and reduction CH3SH --> CO2 and H2S DMSO --> DMS Desulfurylation (organic S --> H2S) Assimilation - PAPS --> products of organic matter Dissimilation - APS --> excretion of waste product ATP consumed - Needs to be activated to get specific form (in order to become a great sink)
Cellulosome
A multi-protein complex attached to surface of bacterial cell that binds and facilitates cellulose deconstruction
Acidophiles
ATP is free because atmosphere has protons that want to be used/donated Acidophiles have neutral insides thus H+ wouldn't all enter and kill the cell
Microbiome Resiliency
Ability to re-establish, difficulty in change of microbiota
Sinks
Adds to Atmosphere Photosynthesis, plants
Banded Iron Formations
After cyanobacteria created oxygenic photosynthesis, Fe^3+ formed and precipitated leading towards Banded Iron Formations
Iron (Energy Source)
BAD Electron Donor @ neutral pH --> spontaneous reduction (RUST) Use Oxygen as Acceptor
Great Donor and Acceptors
Best Donor - Edibles (Eat) Glucose Best Acceptor - Breathable Oxygen
Strength of Respiration
Best: Aerobic (Oxygen) 2. Nitrate 3. Manganese Reduction 4. Iron 5. Sulfate 6. Methanogens (CO2) 7. Anaerobic Reactions
Cellulose
Bioenergy Source Bound tightly, thus tough to separate Next Generation of Feedstock for biofuel Consolidating Bioprocessing (CBP) Native Plant Breaks down fibers (of solid, liquids) to form cellulose which is broken down by sugar bonds Modified Plants Consolidate bioprocessing - some organisms can use cellulose Both Pathways form Ethanol Tough to Degrade
Microbial Diversity in relations with humans
Birth --> 3 develop immune system As you age --> Microbiome less diverse --> thus microbiome disease microbinomes - fully developed unless complications
Dissimilation
Breathing A lot more Oxygen Use compounds for breathing
Chlorosomes
Bundles of chlorophyll to trap light to form ATP Light harvesting pigments
Carbon Cycle
CO2 is fixed by autotrophs or reacts with sea(WATER) to form Carbonic Acid Bicarbonate and Carbonate are formed from Carbonic Acid
Global Temperature
CO2 level have increase since industrial revolution 1. burning fossil fuel 2. deforestation Methane - is a 25x more potent gas N2O production of ammonia, excess nitrate growth isn't good
Sulfur (Energy Source)
Can be Both electron donor and acceptor Oxidation of H2S --> Inorganic Sulfur (Sulfate) Organisms can store metal in bodies for energy reserve Remember Sulfur can be acceptor need ATP to activate Sulfur as a donor - need sulfur compounds to activate (establish PMF)
Bio-synthetic Capacity
Capacity to synthesize whats necessary for itself to grow Ex. E. Coli is better than L. Mesenteriodes b/c E. Coli doesn't require amino acids, vitamins etc. It can create those things by itself
Potential Energy
Changes during redox reaction releases energy cell may capture
Hydrothermal Vents
Chemolithotroph paradise full of dynamic micro-environments (Potential Redox Tower) Can be Electron donor and acceptor Theory of Life early electron transport originally started, supported because it developed/supply H2 and S^0 Use Hydrogen as electron donor
Electron Excitation and Charge Separation
Chloro (blue) Bacterio (red) Different energy wavelengths
Measuring Turbidity
Cloudy Light Source and filter to sample the source Used with Spectrometer Optical Density (OD)
Prosthetic Group
Co-Factor is permanently attached to an enzyme Cytochromes = heme groups proteins in the ETC Donate/Accept single electron (NOT PROTONS) Flavoproteins: FAD+ and FMN+
Coenzymes
Cofactor is loosely attached to enzyme Can carry electrons and protons
How do you grow microbes?
Complex (Rich) Medium Enrichment Medium Selective Medium Single Cell Isolation
Microbiome
Comprises all of genetic material within a microbiota (collection of microorganism in a specific niche, such as human gut)
Carotenoids and Phycobilins (Cyanobacteria)
Conjugated double bonds - which absorb stress and electron to be transferred through cell "sun block"
1% of Culturable Microorganism
Cultures that we can gain in a lab: Live in similar conditions Found in human bodies disease
Glutathione
Cytoplasm is reducing environments stores electrons on -OH group
Resources that govern microbial growth in nature
Electron Acceptors: O2, NO3-, SO4^2-, Fe3+ Macronutrients: Nitrogen and Carbon, P, S, K, Mg Energy: Light, Chemicals (H2, H2S, Fe2+...) Micronutrients: Fe, Mn, Co, Cu... (inorganic trace metals) Vitamins, Amino acids... (organic growth factors) Appropriate environmental conditions: Temp., pH, water potential, oxygen potential, light and osmotic condition
Prokaryotic Phototrophs
Electron Donor: Light - Purple/Green Bacteria Anoxygenic Use electrons to fix carbons Use H2S and Sulfur molecules to reduce carbon Generates Sulfuric Acid - Cyanobacteria Oxygenic Generate Oxygen Use H2O as reducing power
Oxygenic Phototrophy
Electron Donor: Water Uses Two photosystems Terminal Electron Acceptor: NAD(P) --> generates NAD(P)H NAD(P)H can be used for biosynthesis Flow of ETC generates PMF (normal) Water is donated to PSII, and excited by light to be a great electron donor P680 = PSII P700 = PSI 1. Non-cyclic electron generate PMF 2. Excites PSII 3. electron travel thorough Cytochrome to PSI 4. Light excites PSI 5. PSI creates Fd (Fd is used for cyclic electron generating PMF helping cytochrome get to PSI) 6. Eventually creating NAD(P)H (Reducing Power) Cycling allows to make PMF => creates ATP
Photosystems in Eukaraya vs Prokarya
Eukaryotes: Photosynthesis occur in chloroplast or chlorophyll attached to thylakoid membranes Prokaryotes: NO THYLAKOID. PMF is generated across inner membrane Water can be electron donor
Iron
Except Iron Oxidize = RUST Good Electron Acceptor Shuttles electrons from organisms to (rust) reducers Nanowires - help with breathing of metals specialized membrane to chain outside of cell to form nanowires pass electrons to allow breathing Shewanella Oneidenis (Class activity chalk board to student etc.)
Phycobilliprotiens
Extends ability of PSII to capture proteins with range of wavelength
Siderophores
Extracellular small molecules that bind Fe(III) and transport it to the cell where it is reduced
Complex (Rich) Medium
Fastest growing, best adapted to those conditions No Targeted Selection Many Microbes can grow Ex. yeast extract, beef heart etc. Best Adaptive organisms will grow first
Primitive ETC in cells
Few Protein required Iron is abundant (oxidized) Sulfur (reduced) PMF => ATP
Bacterias in Human
Firmicutes Actinobacteria Bacteriodietes Proteobacteria Cyanobacteria Fusobacteria Takes 3 years to fully develop all microbes
Flow Cytometry
Florescence-activated cell sorting Selects out single cells for analysis of growth Sorts for cell types - collection vessels etc.
Global Carbon Cycle
Fossil Fuel and CO2 --> reductive co2 fixations photo- and chemoautrophy create organic matter --> respiration and fermintation into CO2 Aerobically and Anaerobically Parts 3:1 Cyanobacteria and Diatoms --> Heterotrophs --> CO2 --> Euryachaeota --> Methylotrophs --> CO2 -> (continues cycle) CO2 --> CO2 fixation Photo and chemoautotrophy --> respiration and fermentation --> CO2 --> methanogenesis --> Methano- and methylotrophy --> CO2 (cycle continues) CO2 --> reduction --> oxidation and redox neutral --> CO2 --> reduction --> oxidation --> CO2 (cycle continues)
ETC
Found in Mitochondria 1. Chain of redox reactions organized by increasing ΔE and alternate carriers that can or cannot accept protons Small so energy can be captured by doing work. Increasing Electron Potential to smaller potential 2. Couple electron movement to generate of a protein gradient Quinones gets electrons outside the cells 3. Net = reduction of terminal electron acceptors and generations of PMF most donate to oxygen our terminal electron acceptor
Organic Terminal Electron Accpetors
Fumarate, DMSO and TMAO to form Succinate Reductive Dechlorination of halgoenated organic compounds
Mycorrhizae
Fungal Mutualism Delivers N and P, nutrients or water to soil to plant Plant provides carbon for fungus Can be Endo or Ecto
Major Redox Event in Glycolsis (Step 1)
G3P (glyceraldehyde-3 Phosphate) used to produce 2 NADH and add an inorganic phosphate Oxidation of Aldehyde: Highly Exothermic Formation of high-energy phosphate anhydride at C1: Endothermic REduction of NAD+ to NADH: Endothermic Net Reaction: =ΔG = +6.3 kj/mol Reduction Potential: -550 mV
Electron Acceptor
Gains Electron B becomes Reduced Ared + Box --> Aox + Bred lower potential energy "Breathable"
Deep Sea use what as resources?
Inorganic Compounds - not a lot of organic carbon present Methanogens fix its own carbon
Nitrite (Energy Source)
Good Electron Donor Nitrate --> Better Electron Donor
Nitrate
Great Electron Acceptor Useable to Plants (Soluble Forms) NO will be used by most organisms
Cultured Based Methods
Grow microbes in the lab and examine their physiological traits
Energy Source: Inorganic Energy for Chemolitotrophs
H, Nitrite, Ammonium, Sulfur, Hydrogen Sulfide, Ferrous Iron
PSI Reaction Center
Have Iron-sulfur cluster proteins in reaction center
PSII Reaction Center
Have quinones in reaction center
Green and Heliobacteria
Higher energy reaction centers, thus reduce Ferridoxin (Fd) which is high energy to reduce CO2 for anabolism Autotrophy is easy
Catabolism
How you break down substrates
Anabolism
How you synthesize biomolecules you need for life
Alternate Electron Acceptors (Breathables)
Humans breath O2 O2 is our electron accpetor
Microbes dominate all biogeochemical cycles on Earth
Humans breath out CO2 microbes do that plus re-cycle CO2 Humans CANNOT live without microbes Microbes CAN live w/o humans
Chemoorganoheterotrophs
Humans!!! Energy come from chemical source from organic things Carbon source are eaten.
Diauxic Growth
Indicates that carbon source is used, cell adapts and synthesizes new enzymes Then utilizes another carbon source
Mutualism
Insect rely on symbionts for survival - rely on symbionts for protein and amino acids changes cellouse to acetate (shields from O2) Tubeworm - act like hydrothermal vent Carbon provided by autotrophic enviroment H2S as donor and O2 as acceptor Ruminant Animals Produce hydrogen and methanogen (creates CH4+) Breakdown cellulose providing shield from anoexic atmosphere cannot digest cellulose Rumen largest fermentation operation
Primitive ETC
Iron-sulfur cluster formed protein formed around cluster Iron & sulfur around transfer of electrons to generate PMF H, S, Fe are abundent possible to do redox chemistry therefore it occurred first
Many types of symbioses
Leaf Cutting Ants Use leaf to garden on use antibiotics to kill bacteria bacteria has not developed resistant against bacteria
KEY Terms Legume-nodule
Leghemolobin - binds O2 (role) --> delivers to ETC Nod Factors --> determines specificity Rhizobia --> group of organisms Myc Factors - similar to nod factors, but used by fungi
Parasitism
Lichens - controlled fungal penetrate cell wall and take nutriens from cyanobacteria fungus provides lichen acids and protects from desiccation Phototrophs provide C and sometimes N
Photosystem
Light Harvesting complexes (antenna pigments) + reaction center How an organisms collects light molecules funnels to special pair. (molecule directly able to send them to ETC)
Retinal-Based Phototrophy
Light driven proton pump Bacteriorhodospin - light sensitive pigment retinal Use lights, and protons pumped out to create ATP
Electron Donor
Loses electrons A becomes Oxidized LEO Ared + Box --> Aox + Bred Higher potential energy electrons Edibles "We Eat"
Green Bacteria
Low light specialist Green Sulfur Bacteria PSI type photosystems Anaerobes, uses H2S as electron donor for photosystems Photoautotrophs: Fix CO2 Green Non-sulfur bacteria PSII type photosystems Can grow: photoautotroph, photoheterotroph or aerobic respiration
Methanogens (CO2)
Made from Archaea (that produce natural gas) Obligate anaerobies cannot tolerate oxygen very abundant in nature Reduce CO2 --> CH4 (Methane) Uses different electron chains Membrane similar to quinomes but very different for carry enzymes Chain isnt made of proteins Make Sodium Motive Force rather than PMF
Fermentation Diversity
Many microbes do fermination do them differently 1. Lactate 2. Succinate 3. Ethanol 4. Acetate 5. CO2 6. H2 clostridium butyclium generates ATP and butryic acid (distinctive smell)
Growth Rate
Measures the number of generations per time in log phase
Enrichment Medium
Medium that favors the growth of a targets microbe (usually fastidious) ex. blood agar or chocolate microbes Lyses Blood Cells
Purple Nonsulfur Bacteria
Metabolically flexible can be heterotrophs or autotrophs Can grow in light and oxygen (Can do Both) 1) grow as phototroph 2) grow via aerobic respiration
Aerobic Methane Oxidation
Methane Monooxygenase uses oxygen in two places 1. ATP 2. use in methane monooxygenase to form water and other molecules
Germ-Free Mice
Mice that germ free humanize mice - similar to human microbinome diet and genetics have effect
Microbes in Nature
Microbes do not grow in isolation like in lab Microorganism mostly exists as mixed population in nature
Light Harvesting Molecules
Molecules arranged around reaction center captures light and funnels to reaction center --> Then goes to ETC Chlorophylls Bacteriochlorophylls Absorbs at different wave length, change of different functional group
How do organisms obtain energy and carbon?
Most NADH fuel ETC and ATP synthase
Two Ways to generate ATP
Oxidative Phosphorylation Used in ATP Synthase/ETC Substrate Level Phosphorylation Used in Glycolysis
Difference between Nature and Lab
Nature 1. Resources for growth are not optimal for any given microbe 2. distribution of nutrients is not uniform 3. microorganisms in nature mostly exists as mixed populations 4. extended periods of exponential growth are rare in nature Microbes in nature grow as biofilms Lab Pure Cultures - lack of competition Ex. E. Coli in lab (20 mins) in human body/nature (12 hours)
Activation Energy
Needed to start a reaction, even if the reaction is favorable Catalyst lower the activation energy, helping reaction proceed
Pathogenic
Nematods living in soil affects insects and releases molecules killing insect use insect corpse as nutrients to reproduce
Branches of the Nitrogen Cycle
Nitrification - produces nitrate from reduce compounds nitrapyrin inhibits Denitrification - consumes nitrate, produces gas that leaves terrestrial environment (respiration of nitrate) Ammonification - produces ammonium from organic nitrogen DRNA - dissimilative reduction of nitrate or nitrite to ammonium Anammox - Reduction of Nitrite to N2 in anoxic environment Nitrogen Fixation - N2 to Ammonia (NH3)
Anaerobic Annamox
Nitrite + Ammonium --> Nitrogen Gas (N2H4) N2H4 --> N2 + 2H2O (release of N2 gas) Assists in getting rid of nitrogen toxins Occurs in Anammoxosome Membrane (Organelle) in Annamox Bacteria Organelle not a membrane
Nitrogenase
Nitrogen fixation requires oxygen-labile N2 fixation occurs in both aerobes and anaerobes Aerobes protect nitrogenase by respiration of oxygen, regulation, symbiosis etc. Cyanobacteria have Heterocyst, site where Nitrogen fixation occurs, needs to be protected Nitrogenase has FeMo-Co, and iron-molybdenum co-factor
Cooperation
Nitrogen fixing and proteobacterium (rhizobium) Grow without Nitrogen soybeans, alfalfa, beans, peas etc. excess N leaks into dead zones Rhizobia in root nodules contribute 1/4 of total annaul n-fixation not all rhizobia species can infect all legumes
Terminal Electron Acceptors other than Oxygen
Nitrogen, Sulfur, Carbon Dioxide (Methanogens or Acetogens) and Iron and Organics
Fermintation
No terminal electron acceptor present (No Oxygen or Nitrogen) Substrate Level Phosphorylation used to make ATP Need to Reoxidize NADH reuses NADH to make pyruvate into lactate 1 ATP is made only by SLP
Specificity of Legume-nodule symbiosis
Nod Factors - determine specificity to plant
Nitrogen Gases
Not useable by Plants NO, N2O, N2
Respiration Location
Occurs in Plasma (inner or thalakoid membrane)
Aerobic Iron Oxidizers
Often live in acidic pH Live in specific environments with oxygen and acidic Iron
Cyanobacteria
Only aerobic oxygen producing bacteria Oxygenated Earth, produces as much oxygen as all plants on earth
Energy Sources (Edibles)
Organic 1. Glucose 2. Other Sugars 3. Starch and Carbohydrates 4. Cellulose 5. Lipids 6. Proteins Inorganic 1. Chemicals H, Nitrite, Ammonium, Sulfur, Hydrogen Sulfide, Ferrous Iron Photons (Photosynthesis)
Syntrophy
Organisms cooperate to degrade substrate anoxically Most are secondary fermentation: H2 is produced End Product: CO2 and CH4 Syntrophy doesnt occur if oxygen is present. Syntrophy cannot be grown in pure culture
Redox Reactions
Oxidation-reduction reactions Harvesting energy from donors through electron transfers
Step 3 of Glycolysis
PEP used to generate ATP 2 Net ATP are created at this step
PSI and PSII
PSI - iron sulfur culture Oxygenic only PSII - uses water as electron donor Anoxygenic only
Endomycorrhizae (Arbuscular Mycorrhizae)
Penetrate into the root Formulate intra/intercelluarly require plant, cant be grown in lab
Growth limiting elements
Phosphorus and Nitrogen are limited for photosynthesis
Photoautotrophy
Photosynthesis*** H2O isnt a great electron donor alone, but with light it becomes a great donor can Also use H2S
Chemical signals mediate initiation of symbiosis
Plant will inhibit rhibozibum if nutrients are present Flavonids initiate rhibozibum Fungi invented nod factors
Photoautotrophs
Plants!!! Energy comes from the sun Fixes Carbon
Chlorophylls
Plants, Algae, and Cyanobacteria
Sulfite Oxidase
Produce Sulfate and generate ATP by Oxidative Phosporylation and SLP
Bacteriochlorophylls
Purple and Green Bacteria Don't generate O2 Mostly purple
Forms of Nitrogen
Reduced Ammonium (NH4+) and Ammonia (NH3) Organics Nitrogen Water-Soluble Nitrogen Nitrate Nitrite Gaseous Nitrogen N2O NO N2 - biggest store of nitrogen (mostly un-used needs to be in another from N2) can be fixed, to be used NH3 lives at normal pH --> nitrification (problem for farmers) Which is Assimilation? Organic Nitrogen Which is dissimulation? Nitrate --> Nitric Oxide --> etc. Nitrogen reactions in human body rely on microbes too
Biomineralization
Reduces Metals to make it less toxic Removal or heavy metals from the ground water
Denitrification
Reduction of Nitrate --> N2 Not good for farmers because farmers not good for agriculture Good for waste water management - decrease toxicity in water
Anaerobic Methane Oxidation (ANME)
Reduction of methane hydrates at bottom of sea Archaea surrounded by sulfate reducing bacteria Creates 1 ATP (not favorable but not many can do this therefore they dont have to worry)
Sources
Release Make things available recycle Nitrogen Fixation
Hydrogenase
Removal of H from H2 1 H --> used for formation of ATP 1 H --> used for NAD reduction
N2 fixation is difficult
Requires 16 ATP N2 fixation by Haber-Bosch equals that of biological N2 fixation
Fastidious
Requires extra nutrients to grow Don't synthesis things need to survive Live close to host
Stores
Reserves Nitrogen Cycle - Nitrogen Gas Carbon Cycle - Organic carbon (fossil fuel)
Microbial Diversity corresponds to many factors and microbiomes
Resilient to perturbations microbes are able to re-establish and resilient even after rotation of water
Organic Chemical for Energy Source
Respiration (uses ETC to make PMF) 1. Aerobic (electron acceptor is oxygen) 2. Anaerbobic (electron accpetor is NOT oxygen, but could be nitrate etc.) Fermination (uses SLP to make ATP) 1. Anaerobic (no external electron acceptor)
Bacteroid
Rhizobia microcolonies surrounded by plant cytoplasmic membrane and the bacterial cell differentiate into Nitrogen-fixing cells Become Symbiosomes
Ectomycorrhizae
Sheaths around the root and colonizes trees in cooler climate Blunted root hairs
Quinones
Small hydrophobic molecules found in membrane carry both electrons and protons cycle electrons in ETC
How do you study metabolism?
Studying nutritional requirements of a pure culture by adding specific nutrient to culture medium
Sulfur/Sulfate
Sulfate requires ATP to make it a better electron accpetor ATP to make APS Reduction of SO4^2- to H2S is done by Dissimilative Reduction Reaction Need 8 electrons to reduce Sulfate to Hyrdogen Sulfide How do they make ATP - Both because APT can use
Biogeochemical Cycling
Sum of Microbial, physical, and chemical processes that drive flow of elements between sediments, water and atmosphere elemental cycles (C, N, S, Fe, P and Mn) can be reduce/intermediate/oxidize and redox state. Ability to be electon donor
Metabolism
Sum of all biochemical reactions that occur in a cell
Assimilation
Takes something and makes it there own Biosynthesis - Not a lot of O2 present
Selective Medium
Target microbe growth, non-targeted microbes are killed or inhibited Pros: Select Desired metabolic capacity Cons: Only get certain types and you have KNOW what you are looking for
Generation Time
Time it takes to divide generations per time N = No2^n N = final cell number No = initial cell number n = # of generations during period of exponential growth
Purple Bacteria (Anoxygenic Phototrophs)
Use high energy electron donor to replenish P670 and run the ETC in reverse to reduce NAD Autotrophy is costly
Phototrophs
Use light as electron donor
Chemolithotrophs are autotrophs
Use oxygen as terminal electron acceptor Inorganic energy and electon source --> uses ETC to make PMF --> ATP (via Ox. Phosphorylation) Carbon source (CO2) --> use NADPH and ATP --> Biosynthesis Need to do carbon fixation Require more energy for reduction of NAD+ to get NADH Use ETC in reverse to reduce NAD
Hydrogen (H2) Energy Source
Used as Electron Donor, used by most chemolithotrophs Commonly produced by Fermentation
Methanogenesis
Used by early archaea 3.7 BYA (as well as acetogenesis (early bacteria))
Chlorophyll-Based Phototrophy
Used light for energy transfer to ETC ETC makes PMF PMF does Photo-Phosphorylation --> ATP Forms Carbon (like plants)
ATP ATP Synthase
Uses ATP to make PMF or PMF to make ATP Every turn = 3 ATP Reversible rotary motor
Direct Counts
Viable Counts - LiveDead Strains
Membranes (PMF)
dissipation of protons motive force coupled by ATP synthesis
Human Gut Microbiome
less diverse than other environments 85% similar in Humans Most bacteria in large intestine - found Colon bacteria found in throughout GI Esophagus, stomach, small intestine and large intestine
Rhodopsin-based Phototrophy
light gets asorbed into (rhodospin complex) generates PMF PMF does Photo-Phosphorylation to create ATP Consume Carbon --> Organically
Catalyst
lower the activation energy, helping reaction proceed Ex. Ribozymes Enzymes - some use cofactors - prosthetic group - coenzymes
Methanotrophs
methylotrophs that use methane as sole source of C and E use methane to form all products (lipids, methanol, organic acids etc.) Methane Monooxygenase - MMO substrate recognition Used in Bioremediation: chlorinated solvents, xenobiotics Used in Biosynthesis: complex materials from methane plus oxygen
Communities are physically separated
microbes are primary catalyst of all nutrients cycles in nature Type of reactions: Species Richness - # of species per sample Species Abundance - Rates of microbial activities depends on nutrients and growth conditions of the environment
Global Warming
microbes fix 1/2 carbon on earth methane hydrates source of greenhouse gas highest 800k years ocean absorbs CO2 and acidifies by .1 pH
Bacteria Phototroph are...
mostly anoxygenic anaerboic phototroph
Root nodule in a legume
secrete node factors --> Rhizobia start symbiosis plants provide leghemoglobin to bind up free oxygen
