Competitive inhibition: inhibitor binds to active site.  Non-competitive inhibition: inhibitor binds to allosteric site, causing active site to change shape and lose affinity for substrate.

Oxygen consumption would increase, since more electron flow would be required to maintain the H+ gradient.  ATP production would decline, since the H+ ions could cross into the mitochondrial matrix without passing through ATP synthase

They require ATP and NADPH, which are produced by the light-dependent reactions

Proteins are made by bound ribosomes in rough ER, sent to the Golgi for distribution.  Golgi forms vesicles which merge with the cell membrane for export, or with lysosome for digestion.

Spindle fibers are long protein "cables" that enable sister chromatids to separate to opposing poles of the cell during mitosis.  They are also important for the process of cytokinesis

An exergonic process such as ATP hydrolysis or the oxidation of an electron carrier is used to drive endergonic processes like building large, complex molecules from simpler ones.

Fermentation must be used to supply NAD+ to glycolysis, which is how ATP is generated in the absence of oxygen

Rubisco performs "carbon fixation" by attaching inorganic CO2 from the atmosphere to an organic molecule (RUBP) in the plant.

Hydrogen bonding between water molecules causes them to be attracted to each other, resulting in surface tension.

Any of the below are correct

1.) Activated kinases can phosphorylate multiple enzymes (phosphorylation cascade)

2.) A secondary messenger can activate multiple kinases

3.) A signal transduction cascade can run multiple times after an initial activation

high substrate concentration means there is a greater likelihood that a substrate, and not a competitive inhibitor, will bind to the enzyme's active site.  This has little effect on non-competitive inhibition because if the active site is "shut down" by a non-competitive inhibitor, the substrate cannot bind, no matter how much is present.

to pump hydrogen ions (protons) into the mitochondria's intermembrane space, creating electrochemical gradient that will later be used to power ATP synthase

(1) When light strikes the chlorophyll in photosystem 1, it donates an electron to NADP+, reducing it to NADPH.  (2) The electrons lost by PS1 chlorophyll are replenished by light striking PS2 chlorophyll. (3) the electrons lost by PS2 chlorophyl are replenished by H2O being stripped of electrons and converted to O2 by PS2.  (4) Electron flow from PS2 to PS1 powers an H+ pump that pumps H+ ions into the thylakoid, creating a concentration gradient (5) These ions flow down the concentration gradient into the stroma through ATP synthase, generating ATP.  In the end ATP and NADPH are produced, which are necessary for the Calvin Cycle.

Polarity is an uneven distribution of charge or partial charge in a molecule.  Examples include: 

-Cell membrane has nonpolar interior and polar exterior - only permeable to nonpolar

-Proteins and nucleic acids rely on polarity to form their shapes (through hydrogen and ionic bonds)

-Water's polarity enables its properties, including cohesion, adhesion, and its ability to dissolve polar molecules

P53 checks DNA for damage during G1.  If there is damage, P53 initiates a signaling cascade that leads to cell cycle arrest (G0), preventing the cell from replicating