Ch 8 Microbial Metabolism BIO 245 Exam 2 Notes PDF

Summary

These notes cover microbial metabolism, including catabolism and anabolism, and the role of ATP and enzymes in these processes. They also discuss different classifications based on carbon and energy sources.

Full Transcript

Chapter 8 - Microbial Metabolism
Metabolism- buildup and breakdown of nutrients within a cell
○ Sum of all chemical reactions
○ Chemical reactions provide energy and create substances that sustain life
○ Many pathways of microbial metabolism are beneficial rather than
pathogenic
Catabolism- breaks down complex molecules into simpler ones
○ Exergonic- releases energy
○ Ex: breaks down glucose to CO2 and H20
Anabolism- builds complex molecules from simpler ones
○ Endergonic- uses energy
○ Ex: builds proteins from amino acids
ATP- adenosine triphosphate
○ Links the reactions together
○ Stores energy released from catabolism
○ Releases energy to drive anabolic reactions
Classification by carbon and energy source
Source of carbon
○ Autotrophs- convert inorganic CO2 into organic compounds
○ Heterotrophs- organic compounds as nutrients
Source of energy (electrons)
○ Phototrophs- electrons from light
○ Chemotrophs- electrons from chemicals
Organotrophs- electrons in organic compounds
Lithotrophs- electrons in inorganic compounds (unique to microbes)
○ Chemoheterotrophs- use organic molecules as both their energy and
carbon sources (most organism)
REDOX reactions- transfer of electrons between molecules is important
because most of the energy is in the form of high energy electrons; oxidation
reaction paired with a reduction reaction
○ Oxidation- loss of electrons (OIL)
○ Reduction- gain of electrons (RIG)
Energy carriers
○ Energy released via catabolism can be stored via:
Reduction of electron carriers
In bonds of ATP
○ Electron carriers
 Bind and carry high energy electrons
Easily reduced or oxidized
B vitamin group origin and nucleotide derivatives
NAD
NADP
FAD
(NAD+/NADH); (FAD/FADH2); (NADP+/NADPH)
Left = oxidized form, right = reduced form
Recycled continuously
ATP as an energy carrier
○ ATP is “energy currency” of the cell
○ Enables the cell to store energy safely and released it as needed
○ Adenine molecule bonded to ribose molecule and 3 phosphate
groups
AMP (one phosphate group); ADP (two phosphate groups)
○ Phosphorylation- addition of an inorganic phosphate group (Pi) to
ADP with the input of energy
High energy phosphate bonds (terminal bonds between phosphate
groups)
○ Dephosphorylation- breakage of high energy bonds
Energy is released
One phosphate (inorganic phosphate Pi)
Two phosphates (pyrophosphate PPi)
○ Energy released from dephosphorylation of ATP is used to drive cellular
work
○ Enzymes
Catalysts- substances that speed up chemical reactions without
being altered
Enzymes are biological catalysts → they inc reaction rate
without raising temperature
Activation energy- the energy needed to form or break
chemical bonds and convert reactants to products
Enzymes lower the Ea by binding to reactant molecules and
speeding up reactions
Substrates- reactant to which an enzyme binds (think key)
Fits like a key in 3D shape of specific amino acids on active
site
Active site- location on the enzyme where the substrate binds
(think lock)
 Enzymes have specificity for particular substrates
Same compound can be a substrate for many different
enzymes
○ Some enzymes are made entirely of proteins
Most consist of protein and non-protein component
Apoenzyme- protein component of enzyme; inactive by
itself
non-protein component of enzyme:
○ Cofactor- inorganic ions such as Fe2+ and Mg2+
○ Coenzyme- organic that assists enzymes to
transfer electrons
Derived from vitamins: CoA, NAD+, FMN
Holoenzyme- apoenzyme + cofactor (whole, active
enzyme)
As temperature increases, rate of reactions increases
○ Lower temps- molecules move slowly
○ Higher temps- molecules move quickly, more collisions
○ Optimum temperature- maximum rate of reaction
Beyond this, molecules slow down again
○ Denaturation- loss of tertiary structure (3D)
Breakage of hydrogen bonds
Extreme changes in pH
Change in arrangement of amino acids in active site
Loss of catalytic ability
Optimum pH- when enzyme is most active
○ Above or below means reduced activity
High concentration of substrate- enzyme gets saturated
○ Active site always occupied by substrate
○ Catalyzing at its maximum rate
Further increase of substrate does not affect rate
Under normal conditions, enzymes are not saturated
Competitive inhibitors- fill active site of an enzyme and compete with the
substrate
○ Shape and structure is very similar to substrate
○ Once bound, does not form products
Inhibitor concentration needs to be equal to substrate concentration
Noncompetitive inhibitors- interact with allosteric site rather than active site
○ Changes shape of active site
○ Inhibitor concentration is much lower than substrate concentration
 ○ Allosteric inhibition
Allosteric activators- bind to another part to increase affinity of enzyme
Feedback inhibition- end product of a reaction allosterically (noncompetitively)
inhibits enzymes from earlier in the pathway
○ Biochemical control
○ Stops cell from making more of a substance than it needs
Carbohydrate catabolism- the breakdown of carbohydrates to release energy
○ Involves enzymatic hydrolysis of glycosidic bonds in polysaccharides
to form monomers
Hydrolysis- splitting with addition of water (opposite of
dehydration)
Amylase- hydrolyzes glycogen or starch into glucose
monomers
Cellulase- hydrolysis into glucose monomers
Most common carbohydrate is glucose
Glucose is a highly reduced compound!!!
○ Contains lots of energy in the reduced bonds
Processes of glucose catabolism- both start with Glycolysis
○ Cellular respiration
○ Fermentation
Glycolysis- sugar lysis
○ Single 6 carbon glucose molecule split into 2 molecules of pyruvate (3
carbon sugar)
○ Most common pathway in many prokaryotes and eukaryotes for glucose
catabolism
○ Occurs in the cytoplasm, 10 enzymatic steps
○ Anaerobic - does not require O2
○ Types of glycolytic pathways
Embden-Meyerhof- Parnas (EMP) pathway
Found in animals and most common in microbes
Entner-doudoroff (ED) pathway
Pentose phosphate pathway (PPP)
Glycolysis EMP pathway
○ Energy investment phase
2 ATP used
6 carbon sugar (Glucose) split into two phosphorylated 3 carbon
molecules, (G3P)
○ Energy payoff phase
The two G3P molecules are oxidized to 2 pyruvate molecules
4 ATP formed by SLP - substrate-level phosphorylation
 Net yield ATP = 4 - 2 = 2 ATP
2 NADH are produced
SLP - a phosphate group is removed from an organic molecule and
is directly transferred to an available ADP molecule, producing ATP
Transition (bridge) reaction
○ Pyruvate from glycolysis can be further oxidized in the Krebs cycle,
producing more energy
○ Bridge step/transition reaction
Decarboxylation (loss of CO2) occurs first
Pyruvate (3 carbon) is oxidized to acetyl group (2 carbon)
NAD+ is reduced to NADH
Acetyl group attaches to coenzyme A (CoA) forming acetyl CoA
Occurs in cytoplasm (prokaryotes) and mitochondrial matrix
(eukaryotes)
For every molecule of glucose, 2 acetyl CoA
And 2 NADH are formed
Then acetyl CoA enters Krebs cycle
Krebs cycle (citric acid cycle)
○ Transfers remaining electrons present in acetyl group
Occurs in cytoplasm (prokaryotes) and mitochondrial matrix
(eukaryotes)
Closed loop, 8 step cycle
○ Acetyl CoA loses the CoA, acetyl combines with oxaloacetate to form citric
acid cycle
○ Oxidation of each acetyl group produces
3 NADH; 1 FADH2
1 GTP by substrate level phosphorylation (equivalent to 1 ATP)
Liberates 2 CO2
○ Most important products of krebs cycle = NADH and FADH2
Contain most of the energy that was originally present in the
glucose
○ Intermediates in krebs cycle- useful for many biosynthetic pathways
(amino acids, fatty acids, nucleotides, etc)
Cellular respiration
○ Begins when electrons are transferred from NADH and FADH2
Electrons produced in glycolysis, transition reaction, and Krebs
cycle
○ To a final INORGANIC electron acceptor
Oxygen- aerobic respiration
Non-oxygen inorganic molecules- anaerobic respiration
 Occurs in inner part of cytoplasmic membrane (prokaryotes) and
inner mitochondrial membrane (eukaryotes)
Energy of electrons generates an electrochemical gradient which is
used to make ATP via oxidative phosphorylation
Electron transport chain (ETC)
○ Last component of cellular respiration
○ Comprised of membrane-associated protein complexes and mobile
electron carriers (NADH, FADH2, etc)
○ Major membrane-associated electron carriers:
Cytochromes
Flavoproteins
Iron-sulfur proteins
quinones
Proton motive force
○ As electrons move down ETC, protons (H+) are pumped
to the outside of cytoplasmic membrane (bacteria)
From the mitochondrial matrix across the inner mitochondrial space
(eukaryotes)
Buildup of protons
○ Establishes electrochemical gradient
Higher concentration of protons on one side of the membrane
Has potential energy called Proton Motive Force (PMF)
Can be used to make ATP
Can also be used for rotation of flagella or movement of ions
Chemiosmosis- ATP synthesis using energy from PMF
○ Proteins cannot diffuse back into the cytoplasm due to selectively
permeable membrane
Can move back through protein channels containing ATP synthase
ATP synthase- catalyst for the conversion of PMF into ATP
Releases energy as protons move through it
Addition of inorganic PO4 to ADP (oxidative
phosphorylation)
Forms ATP - more readily usable form of energy
Total ATP yield: 4 from SLP, 34 from Oxidative phosphorylation
Aerobic respiration- final electron acceptor is Oxygen
○ Reduced to water by final ETC carrier cytochrome oxidase
○ Sometimes aerobic respiration is not possible due to missing cytochrome
oxidase, other enzymes, or low amounts of oxygen available
Anaerobic respiration-
○ Final electron acceptor is NOT oxygen
 ○ Nitrate reduced to nitrite or nitrogen gas
○ Sulfate reduced to hydrogen sulfide
○ Carbonate reduced to methane
○ Essential for nitrogen and sulfur cycles
○ Yields less ATP than in aerobic respiration!!!
Only part of krebs cycle operates under anaerobic conditions
Only some ETC carriers participate
○ Organisms using anaerobic respiration grow slowly compared to aerobes
Fermentation- does not use krebs cycle or ETC, produces small amounts of ATP
(only 2 ATP)
○ Many cells unable to carry out respiration because:
Lack the inorganic final electron acceptor
Lack genes for complexes and electron carriers in ETC
Lack genes to make one or more enzymes in krebs cycle
○ NADH must be re-oxidized to NAD+ for reuse as an electron carrier for
glycolysis to continue
○ Some use organic molecule (pyruvate) as a final electron acceptor
○