Question

Molecular complexes in the cristae contain electron transport carriers that move _________ into the intermembrane space. The first electron transport carrier accepts an ________ from _________ . A second carrier accepts an ___________ from _________ . After the ________have travelled through the chain they are finally accepted by ________ and 2 __________ to produce water. Going from high to low concentration, _________ flow through ATP synthase like a water wheel to produce ~32 ________ molecules.

Answer 1

Molecular complexes in the cristae contain electron transport carriers that move protons (H+) into the intermembrane space. Electrons from NADH and FADH2 are accepted by the first electron transport carrier. Coenzyme-Q (Q) transports electrons to the second carrier. Protons (H+) flow through ATP synthase to produce ATP.

Step-by-step explanation:

Molecular complexes in the cristae contain electron transport carriers that move protons (H+) into the intermembrane space. The first electron transport carrier accepts an electron from NADH and FADH2. A second carrier accepts an electron from Coenzyme-Q (Q). After the electrons have travelled through the chain they are finally accepted by oxygen molecule and 2 H+ to produce water. Going from high to low concentration, protons (H+) flow through ATP synthase like a water wheel to produce ~32 ATP molecules.

Answer 2

a.) Hydrogen

b.) electron

c.) NADH⁺ + H⁺

d.) electron

e.) FADH₂

f.) electron

g.) hydrogen ions

h.) oxygen

i.) hydrogen ions

j.) ATP

Step-by-step explanation:

Molecular complexes in the cristae contain electron transport carriers that move Hydrogen into the intermembrane space.

The first electron transport carrier accepts an electron from NADH⁺ + H⁺

A second carrier accepts an electron from FADH₂ .

After the electron have travelled through the chain they are finally accepted by hydrogen ions and oxygen to produce water.

Going from high to low concentration, hydrogen ions flow through ATP synthase like a water wheel to produce ~32 ATP molecules.