General Biology 1 Review

SET 1

SET 2

SET 3

SET 4

SET 5

100

an organism that can produce its own food using light, water, carbon dioxide, or other chemicals

autotrophs (producers)

Because autotrophs produce their own food, they are sometimes called producers. (Heterotrophs – consumers)

- Divided into 2 types: Chemoautotrophs and Photoautotrophs

100

an organelle found in plant cells that is responsible for photosynthesis

chloroplast

100

a nucleotide found in the mitochondria of all plant and animal cells. It is the major source of energy for cellular reactions, this energy being released during its conversion to ADP

ATP

100

a concept of coupling two biological reactions

Energy coupling

100

—require an input of energy.

—Absorb energy by forming chemical bonds of smaller reactants to produce larger product

Endergonic reaction

200

define photosynthesis

A process by which photoautotrophs like green plants, algae, and some bacteria convert sunlight, carbon dioxide, and water into glucose and oxygen which occurs in the chloroplast.

200

name the three key stages of cell respiration

glycolysis, the citric acid cycle (also called the Krebs cycle), and the electron transport chain

200

a colored substance that absorbs some wavelength of light and reflects others, responsible for the color of many plants, animals, and other organisms

pigment

Chlorophyll, Anthocyanins, Carotenoids, Betalains

200

What is B in the chemical reaction?

A====>B

B = Products

200

Two main products of Photosynthesis.

oxygen and glucose

300

Hydrolysis is the ____ of water. This is used for ATP to form ADP. Hydrolysis is exergonic/catabolic.

addition

300

They are responsible for the bright yellow, orange, and red colors of many fruits, vegetables, and flowers

carotenoids

300

The green chemical in the chloroplasts that absorbs and stores energy from the sun

chlorophyll

300

Where does cellular respiration take place?

mitochondria and cytoplasm

300

what is the importance of a ATP?

it is used to transfer energy into living things

400

compare chlorophyll a and b

CHLOROPHYLL A
Chlorophyll a is the most common type of chlorophyll. It is found in all photosynthetic organisms, including plants, algae, and cyanobacteria. responsible for the green color of plants.  Algae  Cyanobacteria  Plants

CHLOROPHYLL B
found in plants and some algae, but it is not found in cyanobacteria. Chlorophyll b has a slightly different structure than chlorophyll a, and it absorbs light in a slightly different range of wavelengths. Phytoplankton  Plants  Seaweed

400

Describe the difference between ADP structure and ATP structure.

ADP has 2 phosphate groups, 1 ribose-sugar, and 1 adenine (nitrogenous base) whereas ATP has 3 phosphate groups, 1 ribose-sugar, and 1 adenine (nitrogenous base)

400

The range of all wavelengths of radiant energy from shortest to longest.

electromagnetic spectrum

RED MARTIANS INVADE VENUS USING XRAY GUNS

400

what are thylakoids?

This structure stacks chlorophyll in membranes to increase light capture.

400

The tiny pores in the bottom of leaves that take in carbon dioxide from the air

Stomata

500

compare light reaction and dark reaction

LIGHT REACTIONS
location - Thylakoid
reactants - Light, H20, ADP, NADP+
products - Oxygen, ATP, NADPH

CALVIN CYCLE
location - Stroma
reactants - CO2, NADPH, ATP
products - Glucose, ADP, NADP+

500

What is the Cellular Respiration equation?

C₆H₁₂O₆ + 6O₂ --> 6CO₂ + 6H₂O + 36-38 ATP

500

differentiate photosynthesis and cell respiration

Photosynthetic organisms remove carbon dioxide and release oxygen into the atmosphere. Organisms then carry out cellular respiration, removing oxygen and releasing carbon dioxide back into the atmosphere. This continual cycling of oxygen and carbon dioxide allows for life on Earth to exist as we know it!

500

how do we see colors? (example a green color)

green is reflected
others are absorbed

500

explain why ATP is like a rechargable battery

ATP is like a rechargeable battery because it stores energy in its chemical bonds and releases it when a phosphate group is broken off, converting it to ADP (adenosine diphosphate). This "discharged" ADP can then be "recharged" back into ATP using energy from food during cellular respiration, allowing the cell to continuously cycle between a charged and discharged state for its energy needs.