micro ch 6

11. Proton Motive Force

Form of energy generated as an electron transport chain moves protons across a membrane to create a chemiosmotic gradient.

8. Oxidative Phosphorylation

Synthesis of ATP using the energy of a proton motive force created by harvesting chemical energy.

9. Photophosphorylation

Synthesis of ATP using the energy of a proton motive force created by harvesting radiant energy.

12. Substrate-Level Phosphorylation

Synthesis of ATP using the energy released in an exergonic (energy-releasing) chemical reaction during the breakdown of the energy source.

oxidative phosphorylation-practice question

energy from exergonic reactions is used to create a proton motive force that drives the addition of P, to ADP

kinetic energy

energy of motion. such as movement of water from behind a dam

substrate-level phosphorylation-practice question

energy released in an exergonic reaction is used to power the addition of P, to ADP

free energy

energy that is available to do work

the statement "the substrate fits into the active site of an enzyme like a hand into a glove" refers to what important property of enzymes?

enzyme specificity

substrate-level phosphorylation

exergonic chemical reaction

reduction

gain of electrons

reducing power

generated by the three central metabolic pathways [in the form of NADH, FADH2, and NADPH]. reducing electron carriers such as NADH, NADPH, FADH2; their bonds contain a form of energy that can be used by a cell. [The pay-off phase of glycolysis converts 2 NAD+ to 2 NADH + 2 H+]

precursor metabolites

generated by the three central metabolic pathways. Metabolic intermediates that can be either used to make the subunits of macromolecules or oxidized to generate ATP

three central metabolic pathways

glycolysis, the pentose phosphate pathway, and the tricarboxylic acid cycle (TCA cycle)

activation energy

initial energy required to break a chemical bond. Energy needed to get a reaction started

unlike human cells, some prokaryotes can use_____ as energy sources

inorganic chemicals

chemical respiration

involves chemicals and it makes ATP

The intermediates and end products of metabolic pathways are sometimes organic acids, which are weak acids. Which are predominately found inside the cell and which are predominately found outside the cell?

ionic form [pyruvate], and acid form [pyruvic acid]

until the optimal temperature is reached, raising the temperature has what effect on the speed of enzymatic reactions?

it increases their rate

oxidized

loses electrons

Glycolysis

metabolic pathway that oxidizes glucose to pyruvate, generating ATP and reducing power

anarobic respiration

metabolic process in which electrons are transferred from the electron transport chain to a terminal electron acceptor other than O2

aerobic respiration

metabolic process in which electrons are transferred from the electron transport chain to molecular oxygen (O2)

cofactor

non-protein component required for the activity of some enzymes ex:Magnesium, zinc, copper, and other trace elements

Chemoorganotrophs

obtain energy by degrading organic compounds

pay off phase of glycolysis

oxidizes and rearranges the 3-carbon molecules, generating 1 NADH and 2 ATP. Pyruvate is formed as a result

photosynthetic

pertaining to photosynthesis, the process of using the energy of light to synthesize organic compounds from CO2

consider the graph of enzyme activity vs. temperature (looks like a mountain peak that drops off quickly on far right side) in terms of the functioning of a cell, why does activity drop off so quickly after the optimal temperature is exceeded?

proteins denature and no longer function

enzymes

proteins that function as biological catalysts

Macromolecules

proteins, nucleic acids, polysaccharides, lipids

enzymes don't:

provide energy to help reactions proceed more rapidly

photophosphorylation

radiant energy

allosteric

refers to an enzyme or other protein that contains a site to which a small molecule can bind and change the protein's activity. Cells use this to adjust the activity of certain enzymes

conversion of crude oil to gasoline at a coastal refinery

relies on chemical distillation processes--not microbial metabolism

metabolic pathway

series of sequential chemical reactions that are a part of metabolism

anabolic nutrients

source of nitrogen, sulfur, etc.

potential energy

stored energy. can be stored in various forms, including chemical bonds, a rock on a hill, or water behind a dam

metabolism

sum total of all the chemical enzymatic reactions in a cell

enzyme range of conditions

temperature, pH, and salt concentration

enzyme-substrate complex-practice question

the binding of a substrate to the active site of an enzyme causes the shape of the flexible enzyme to change slightly. this induced fit results in a temporary intermediate called:

Energy

the capacity to do work. in the universe can never be created or destroyed; however, it can be changed from one form to another

hydrolysis

the chemical breakdown of a compound due to reaction with water.

active site-practice question

the critical site of an enzyme to which a substrate binds by weak forces

tricarboxylic acid cycle (TCA) (Krebs cycle, citric acid cycle)

the metabolic pathway that OXIDIZES a two carbon acetyl group to release two molecules of CO2 and generates the MOST reducing power of all the central metabolic pathways

Glycolysis-practice question

the pathway SPLITS GLUCOSE and OXIDIZES it to form two molecules of pyruvate. the pathway provides the cell with a SMALL AMOUNT OF ATP, some REDUCING power, and SIX precursor metabolites

active site

the site on the surface of an enzyme to which the substrate binds; aka the catalytic site. a relatively small crevice. critical site to which a substrate binds by weak forces

enzyme specificity

the substrate must align spatially with the active site, with few exceptions, a unique enzyme is required to catalyze each reaction in a cell, hydrogen and ionic bonding occur to induce the correct fit between substrate and active site.

Photophosphorylation

the sun's radiant energy and an electron transport chain create a proton motive force that drives the addition of P, to ADP

competitive inhibition

type of enzyme inhibitor that occurs when the inhibitor competes with the NORMAL substrate for binding to the active site. EX: sulfa drugs are used as antibacterial medications

non-competitive inhibition

type of enzyme inhibitor that results from a molecule binding to the enzyme at a site OTHER than the active site. produced by cells to regulate the activity of that cell's enzymes

it increases their rate

until the optimal temperature is reached, raising the temperature has what effect on the speed of enzymatic reactions?

rely on microbial metabolism

use of lactococcus and lactobacillus in cheese making, wine production, and production of ethanol from corn stalks sugar cane and wood for use as biofuel

cells enzymes

what part of a cell is responsible for transforming sugar to ethanol and CO2

1 glucose molecule can be made into:

2 pyruvate molecules

enzyme-substrate complex

A TEMPORARY complex formed when an enzyme binds to its substrate molecule(s). which changes its shape

6. Enzyme

A molecule, usually a protein, that functions as a catalyst, speeding up a biological reaction. more than a thousand different ones exist in a cell

substrate

AKA: REACTANTS 1. substance on which an enzyme acts to form products. 2. surface on which an organism will grow

Investment or preparatory phase of glycolysis

After the two phosphates are added, the 6-carbon sugar is then split to yield two 3-carbon molecules, each with a phosphate molecule

chemiosmotic gradient

An electrochemical gradient across the thylakoid membrane and the inner membrane of the mitochondrion; due to concentration differences of both positive charges and hydrogen ions.

13. Terminal Electron Acceptor

Chemical that is ultimately reduced as a consequence of fermentation or respiration.

Tricarboxylic Acid Cycle (TCA) (Krebs cycle, citric acid cycle)

Cyclic metabolic pathway that incorporates acetyl-CoA, ultimately generating ATP (or GTP), CO2, and reducing power

In the biosynthetic pathway shown, (starting compound-enzyme a-intermediate a-enzyme b-intermediate b-enzyme c-intermediate c- end product) which compound is most likely to serve as the allosteric inhibitor?

End product - remember, the end product generally acts as the allosteric inhibitor. This feedback inhibition allows the cell to shut down a pathway when the product begins accumulating.

1. Adenosine Triphosphate (ATP)

Generated by the three central metabolic pathways [by substrate level phosphorylation]. The energy currency of cells. Hydrolysis of the bonds between its phosphate groups can be used to power endergonic (energy-consuming) reactions. 2 molecules of ATP, net gain (4 ATP molecules are made in the pay-off phase, but 2 are spent in the investment phase of glycolysis)

5. Electron Transport Chain (ETC)

Group of membrane-embedded electron carriers (proteins) that pass electrons from one to another, and, in the process, create a proton motive force.

Non-competitive inhibition (by enzyme poisons)

Inhibitor PERMANENTLY changes the shape of the enzyme, making the enzyme non-functional. EX: Enzyme poisons such as mercury are used in certain antimicrobial compounds.

Non-competitive inhibition (by regulatory molecules)

Inhibitor changes the shape of the enzyme, so that the substrate can no longer bind the active site. This is a REVERSIBLE action that cells use to control the activity of allosteric enzymes.

2 glycolysis phases

Investment or preparatory phase and Pay-off phase

Most enzymes function best at:

Low salt concentrations and at pH values slightly above 7

10. Precursor Metabolites

Metabolic intermediates that can be either used to make the subunits of macromolecules or oxidized to generate ATP. [Five intermediates of glycolysis as well as the end product, pyruvate, are precursor metabolites used by E. coli]

Pentose Phosphate Pathway

Metabolic pathway that starts the degradation of glucose, generating reducing power in the form of NADPH, and two precursor metabolites.

7. Fermentation

Metabolic process that stops short of oxidizing glucose or other organic compounds completely, using an organic intermediate as a terminal electron acceptor.

respiration (cellular respiration)

Metabolic process that transfers electrons stripped from a chemical energy source to an electron transport chain, generating a proton motive force that is then used to synthesize ATP

4. Cellular Respiration

Metabolic process that transfers electrons stripped from a chemical energy source to an electron transport chain, generating a proton motive force that is then used to synthesize ATP.

3. Catabolism

Metabolic processes that harvest energy released during the breakdown of compounds such as glucose, using it to synthesize ATP. A set of chemical reactions that degrade compounds, releasing their energy.

2. Anabolism

Metabolic processes that synthesize and assemble the subunits of macromolecules, using energy of ATP; BIOSYNTHESIS.

biosynthesis

The process by which living organisms produce larger molecules from smaller ones. ANABOLISM

what will dramatically affect the overall energy gain of catabolism?

The step and rate at which the various intermediates are removed for biosynthesis

ATP

energy currency of the cell

2 fundamental tasks for cells to grow

They must continually SYTHESIZE NEW PARTS—such as cell walls, membranes, ribosomes, and nucleic acids—that allow the cells to enlarge and eventually divide. In addition, cells need to HARVEST ENERGY AND CONVERT IT to a form that can power the various energy-consuming reactions, including those used to make new parts.

oxidation-reduction reaction

a reaction that involves the transfer of electrons between reactants

coenzyme

a subset of cofactors, non-protein organic compounds that assist some enzymes. they act as a loosely bound carrier of small molecules or electrons. Include the electron carriers FAD, NAD+, and NADP+ (play an important role in enzyme-catalyzed oxidation-reduction reactions) some come from organic necessary vitamins

Catabolism waste products

acids, carbon, dioxide

the precursor metabolite pyruvate can be converted to any one of three amino acids:

alanine, leucine, or valine

subunits of macromolecules

amino acids, nucleotides, monosaccharides, and fatty acids

cell structures

cell wall, membrane, ribosomes, surface structures

oxidative phosphorylation

chemical energy

Endergonic

chemical reaction that requires a net input of energy because the products have more free energy than the starting compounds

identify each of the following by the most precise descriptive term as either a cofactor or coenzyme:NAD+_____, FAD______, copper____, coenzyme A_____.

coenzyme, coenzyme, cofactor, coenzyme

enzyme inhibitors

competitive and noncompetitive

Exergonic

describes a chemical reaction that releases energy because the STARTING COMPOUND have MORE free energy than the PRODUCTS. Chemical reactions that release energy because the starting compounds have more energy than the products

endergonic reaction

describes a chemical reaction that requires a net input of energy because the PRODUCTS have MORE free energy than the STARTING COMPOUND. A non-spontaneous chemical reaction in which free energy is absorbed/consumed from the surroundings.

enzymes do:

end in -ase, name reflects its function, very specific, usually act on only one or a few substrates, are not used up in the process of catalyzing reactions, and are biological catalysts.