Micro 276 exam 3
factors that determine ΔG (3)
1) intrinsic properties of a reaction 2) [ ]'s of reactants and products 3)environmental factors
functions of fermentation (3)
1) preserves food 2)improves digestibility 3) adds nutrients and flavors
how does aerobic benzoate catabolism work
1)enzymes remove substituents: Cl, N 2)makes catechol intermediate: benzene ring with 2 adjacent hydroxyl groups 3)ring cleaved and breaks down to pyruvate making NADH 4)acetyl coA goes to TCA cycle and respiration
structure of NADH
ADP and nicotinamide at end instead of 3rd phosphate group
Acetic acid fermentation is produced from
Acetobacter who converts alcohol to acetic acid in the presence of oxygen (e.g.,vinegar).
oxidized form of NADH
NAD+
reduced form of NADH
NADH
examples of energy carriers
NADH, FADH2, ATP
function of pyruvate dehydrogenase complex
removes co2 from pyruvate making acetyl coA
main products of PPP
ribulose 5 phosphate 1 ATP NADPH NOT NADH
amphibolic pathways include enzymes that
run in either direction in which is determined by key enzymes that operate only in catabolic or anabolic direction
yeasts are
single celled proteins
why does glycolysis need to be regulated?
so that reactions go forward only when cell needs energy not when cell is trying to synthesize glucose
why are aromatic molecules more difficult to digest than sugars
stability of ring structures
environmental factors that determines ΔG
temperature, pressure, ionic strength (salt concentrations)
standard conditions for ΔG^o
temperature: 298 K pressure: 1 atm concentrations: 1 M
conditions for ΔGo′ in living cells
temperature: 298 K pressure: 1 atm concentrations: 1 M ph: 7
under what conditions cells will favor the ED pathway
the ED pathway is common among facultative anaerobes and even more common among aerobes
entropy is based on
the number of states of a system such as the number of possible conformations
if ΔG> 0
the reaction will go in reverse
The random distribution of molecules at uniform concentration represents
the state of maximum entropy
Ethanolic fermentation contributes
to the production of ethanol and co2 without lactic acid
lactic acid fermentation: what gets converted, microbes involved, food made
turns glucose to lactic acid lactic acid bacteria example: lactobacillus, streptococcus kimchi and sauerkraut
how is nori made?
use red algae (Porphya) which are cultured in enclosed tanks distributed on nets in estuaries cultures grow until hang heavy from the nets harvest for processing into sheets sheets get toasted and turns green
Martin Kamen experiment of TCA cycle
used trace isotopes: 14 C to figure out which 2 C's of acetyl coA removed as CO2
examples of food made from ethanolic fermentation by yeast
wines, beers, vodka, whiskey, brandy, and bread
chemotrophy
yields energy from electron transfer between chemicals.
phototrophy
yields energy from light absorption
Gibbs free energy change equation
ΔG= ΔH−TΔS
Bacteria and archaea use 3 main routes to catabolize glucose
1) Embden-Meyerhof-Parnas (EMP) pathway aka glycolysis 2) Entner-Doudoroff (ED) pathway 3) Pentose phosphate pathway (PPP)
how does Anaerobic benzoate catabolism work
1) benzene and naphthalene incorporates co2 = carboxylate group of benzene 2) use ATP because CO2 is a weak oxidant 3)carboxylate + HS CoA = benzyl coA 4)NADH reduces to hydrogenate ring breaking aromaticity
3 main catabolic pathways
1. Fermentation 2. Respiration 3.Photoheterotrophy
input of EMP pathway
2 ATP
Overall reduction of NAD+ consumes
2 H atoms to make NADH.
NADH carries ___ times as much energy as ATP
2-3
summarize Krebs cycle
2-carbon acetyl results in outputs of 2 CO2, 3 NADH, 1 FADH2, and 1 ATP (or GTP) molecules made by substrate-level phosphorylation
output of EMP pathway
4ATP molecules, 2 NADH molecules, and 2 pyruvates
amphibolic
Catabolism provides energy for anabolism, and pathways which involve both destructive and constructive metabolism
Initial step of amino acid degradation is one of 2 kinds:
Decarboxylation (removals of co2) = amine Deamination (removal of nh3) = carboxylic acid that get degraded by TCA cycle
How does ED and EMP differ in ATP yield?
EMP: hydrolyzes two ATP to phosphorylate glucose twice and recovers four ATP by metabolizing two triose-phosphates through lower glycolysis, yielding two ATP total ED: invests one ATP in phosphorylation and recovers two (glucose is cleaved into only one fermentable product) yielding one ATP per glucose
enzymes unique to EMP and ED
EMP: pfk ED: edd and eda
under what conditions cells will favor the EMP pathway
Energy-deprived anaerobes overwhelmingly rely upon the higher ATP yield of the EMP pathway
why is magnesium an essential nutrient for all living cells?
Most enzyme binding sites forATP actually bind Mg 2+-ATP
energy carriers
Molecules that gain/release small amounts of energy in reversible reactions
Explain how genomic studies have contributed to our understanding of microbial catabolism
Prokaryotic glycolytic strategy correlates with the availability of non- glycolytic energy sources genomes sequence of microbiome determines ability to digest common foods
bacterium involved in propionic acid fermentation
Propionibacterium, Lactobacillus, Streptococcus
cofactor
a substance (other than the substrate) whose presence is essential for the activity of an enzyme.
photoautotrophy
absorption with CO2 fixation
photoheterotrophy
absorption without CO2 fixation
how does fermentation preserve food?
accumulated waste products of fermentation inhibit the growth of most organisms
aromatic compounds are catabolized to
acetate through different pathways such as the catechol pathway
Competitive inhibitors bind to the _______ site of an enzyme, while noncompetitive inhibitors bind to an ___________ site.
active; allosteric
ATP stands for
adenosine triphosphate
why is glucose oxidized in a series of steps instead of a single step?
all energy released at once would dissipate at heat without building biomass which is inefficient for cell function and biosynthesis
EMP and ED share
all reactions of lower glycolysis: G3P to pyruvate
holoenzyme
apoenzyme + cofactor
key feature of NADH
aromatic
ATP contains
base (adenine) sugar(ribose) three phosphates
why can't most bacteria be eaten?
because small cells contain high proportions of DNA/ RNA in which nucleic acids contain purines that humans digest and convert into uric acid which can't be metabolized because humans lack urate oxidase build of uric acid causes gout and kidney stones
how does fermentation improve digestibility?
break downs fibrous macromolecules and tenderizes producers making it easier for humans to digest
how do microbes compensate for the low efficiency of fermentation
by consuming large quantities of substrate and excreting large quantities of products
substrates for microbial metabolism
carbohydrates, lipids, peptides, aromatic compounds
photoheteroptrophy
catabolism is conducted by light catalyzation
aerobic benzoate catabolism
catabolism via sequential oxidation steps needing ETC that terminates w O2
sugar and sugar derivatives like amines and acids are
catabolized to pyruvate
propionic fermentation is responsible for
characteristic flavor of Swiss cheese
categorize microbes based on how they acquire energy (3)
chemotrophy phototrophy syntrophy
Respiration
complete breakdown of organic molecules with electron transfer to a terminal electron acceptor such as O2
Spirulina
cyanobacteria classified as a single celled protein or edible microbe of high food value
identify different types of fermented foods
dairy: cheese, yogurt soy: miso, tempeh vegetative products: sauerkrat, kimchi coffee, chocolate, alcohol
Chemolithotrophy
energy from inorganic compounds rock eating"
Chemoorganotrophy
energy from organic compounds
Δ H represents
enthalpy
Δ S represents
entropy
Yeasts are the predominant organisms for
ethanolic fermentation
Pyruvate and other intermediary products of sugar catabolism are
fermented of further catabolized into CO2 an H2O via TCA cycle
lignin
forms key structural support of trees and woody stems
acetic acid fermentation is produced from
from the acetic acid bacteria (AAB) species.
lipids and amino acid are catabolized to
glycerol and acetate
enthalpy
heat energy absorbed or released as reactants become products at constant pressure
Apoenzyme
inactive enzyme that is activated by cofactor
regulation of pyruvate dehydrogenase complex
induced when carbon sources are plentiful and repressed under starvation and low oxygen
2 ways glycerol enters catabolism
intermediate in glycolysis broken down into acetate
under what conditions cells will favor the PPP pathway
intermediates from the PPP are used for the biosynthesis of nucleotides and amino acids. Therefore, this glycolytic pathway may be favored when the cell has need for nucleic acid and/or protein synthesis
propionic fermentation turns
lactic acid to propionic acid
Examples of aromatic compounds
lignin and benzoate derivatives
Under physiological conditions, ATP always forms a complex with
mg 2+
how does fermentation add nutrients and flavors?
microbial metabolism generates vitamins (B12) and flavors like esters and sulfur compounds
recall types of microbes that are edible
mushrooms, marine algae, yeasts, Spirulina
In order for a reaction to proceed, ∆G must be: a) positive b) negative c) neutral
negative
NADH stands for
nicotinamide adenine dinucleotide
syntrophy
one species' acquisition of energy from the products of another species' metabolism
3ways fatty acids enter catabolism
oxidative break down = acetyl groups which enter TCA when a terminal electron acceptor is available enters fermentation enters anaerobic syntrophy
electron acceptor
oxidizing agent
Anaerobic benzoate catabolism
oxygen not available to conduct conversation of forming carboxylate and introduction of hydroxyl groups
fermentation
partial breakdown of organic food without net electron transfer to an inorganic terminal electron acceptor
The more disordered, the more _____Δ S
positive, catabolic reaction
If ΔG< 0
process may go forward
electron donor
reducing agent
