Unit 4 Study Guide - Cellular Energy: ATP, Photosynthesis, Cellular Respiration PDF

Summary

This document is a study guide on cellular energy, covering ATP, photosynthesis, and cellular respiration. It explains the basics of these processes, including their components and how they work together. The guide includes diagrams and explanations.

Full Transcript

Unit 4 Study Guide
Cellular Energy:
ATP, Photosynthesis, Cellular Respiration
Energy Overview
Energy comes in multiple forms
o Examples: thermal (heat), radiant (light), kinetic/mechanical (movement), electricity (moving
electrons), chemical (stored in bonds between atoms), and more
Law of Conservation of Energy
o States that energy cannot be created or destroyed, but only cycles and transfers between different forms
o Ex: In photosynthesis, light energy is transferred into electricity in the chloroplast. This electricity is
then transformed into chemical energy in the form of ATP and glucose.
ATP (Adenosine Triphosphate)
o The cell’s energy molecule
o Made of a molecule called adenosine bonded to three phosphate groups
o The bond connecting the last phosphate group has the most energy
▪ You break the bond to release energy (A-P-P-P becomes A-P-P + P) and make ADP
▪ You make the bond between ADP and a phosphate group to store energy (A-P-P + P becomes
A-P-P-P)

Photosynthesis
Light
Small particles called photons moving as a wave.
We can detect light in the middle called the Visible Spectrum. We see the visible spectrum as colors.

Light can be absorbed (taken in) or reflected (bounced back). Whatever colors are bounced back to our eyes
are the colors we see. Leaves appear green because only green light is reflected back to our eyes.
Pigments
Chemicals that can absorb light and capture its energy
Chlorophyll is the plant’s main pigment
o It is found inside the chloroplasts, the small organelles found in the cells of leaves.
o Absorbs all wavelengths of light except for green.
o Captures the sunlight energy so that plants can do photosynthesis.
Plants have other pigments that are not made in significant quantities like chlorophyll - this allows the plant to
absorb sunlight from multiple different wavelengths of light

Photosynthesis
The way plants and algae make food from sunlight energy and carbon dioxide.
Divided into two parts, the light dependent reactions and the light independent reactions (also known as the
Calvin Cycle or the Dark Reactions)

1. Light Dependent Reactions
Where? Thylakoid Membrane of the chloroplast in the leaf cells
When? Only occurs when light is present
Needs? Sunlight, H2O (water) from the roots
Makes? O2 (oxygen), ATP
What? Light hits the chlorophyll in the thylakoid membrane of the chloroplast. The chlorophyll
captures the light energy and uses it to break water apart. When water is broken it forms
oxygen gas, hydrogen ions (H+), and electrons. The electrons move through the membrane to
produce electrical energy. This electrical energy is used to move all of the H+ to one side of the
membrane (creates a concentration gradient). The H+ then flows down their concentration
gradient through a special membrane protein called ATP Synthase. The movement of the H+
powers the ATP Synthase to make ATP.

2. Light Independent Reactions
Where? Stroma of the chloroplast in the leaf cells
When? Any time, even when it is dark outside
Needs? ATP from the light dependent reactions, CO2 (carbon dioxide) from the air
Makes? C6H12O6 (glucose)
What? The ATP made in the light dependent reactions is used to take six individual molecules of
carbon dioxide (CO2) and form bonds between them to create the six-carbon glucose molecule.
CO2 → C6H12O6

Photosynthesis Equation
6CO2 + 6H2O → C6H12O6 + 6O2
Cellular Respiration and Fermentation
The process of cells turning food (glucose) into energy (ATP)
Every single living thing does some part of cellular respiration. Prokaryotes only perform glycolysis.
Eukaryotes (cells with mitochondria) can perform all steps of cellular respiration.

Mitochondria Structure

Anaerobic vs. Aerobic
Some parts of cellular respiration occur with oxygen and some do not need oxygen to occur. Using oxygen
allows cells to get more energy, but not all cells can use it.
Aerobic means with oxygen
o Cells with a mitochondria (eukaryotes like plants and animals) can do this type of respiration
o Includes the Citric Acid Cycle and Electron Transport Chain
Anaerobic means without oxygen
o All cells can do this type of respiration (does not need a mitochondria)
o Includes Glycolysis and fermentation

Glycolysis
What? Split glucose in half to form two molecules of pyruvate. Lysis means break, glycol refers to glucose.
Where? Cytoplasm (aka cytosol) of the cell
When? Anaerobic – happens any time. Does not need oxygen.
Needs? C6H12O6 (glucose), 2 ATP
Makes? 4 ATP (2 net ATP), 2 molecules of pyruvate, NADH (to carry electrons around the cell)
Citric Acid Cycle
What? Breaking pyruvate down to capture energy stored in the bonds. Produces CO2 as a waste product.
Happens TWICE! Once for each pyruvate from glucose.
Where? Stroma of the mitochondria.
When? Aerobic – only happens when oxygen is present.
Needs? Pyruvate
Makes? 2 ATP, three molecules of CO2, NADH, FADH2 per cycle
Since there are two pyruvates per glucose, the final totals per molecule of glucose are:
4 ATP, 6 molecules of CO2

Electron Transport Chain
What? Transporting electrons through the mitochondria and capturing their energy to produce ATP. The
movement of electrons through the membrane creates a concentration gradient of H+. The electrons are
finally captured by O2, converting it into H2O. As the H+ moves down its concentration gradient it
power a membrane protein called ATP Synthase to produce ATP.
Where? Cristae/Inner membrane of the mitochondria.
When? Aerobic – only happens when oxygen is present.
Needs? O2 (oxygen) to capture the electrons at the end, NADH/FADH2 from glycolysis and the citric acid cycle
Makes? 32 ATP, H2O (water)

Cellular Respiration Equation
C6H12O6 + O2 → CO2 + H2O + 38 ATP
Fermentation
Allows cells to keep doing glycolysis when there is no oxygen present by regenerating NAD+
Two Types:
o Alcoholic Fermentation – makes alcohol and carbon dioxide gas
▪ Used to make bread, wine, beer, kombucha
o Lactic Acid Fermentation – makes lactic acid and carbon dioxide gas
▪ Used to make cheese, yogurt, soy sauce, kimchi
▪ Happens inside your muscle cells during hard workouts. Lactic acid can build up in the
muscles. When this happens, your muscles become damaged and will feel very sore.