ATP, ADP, & Chloroplasts.

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Presentation transcript:

ATP, ADP, & Chloroplasts

Why do cells use for energy? Question: Why do cells use for energy?

Energy for Life on Earth Sunlight is the ULTIMATE energy for all life on Earth Plants store energy in the chemical bonds of sugars Chemical energy is released as ATP during cellular respiration

Structure of ATP ATP stands for adenosine triphosphate It is composed of the nitrogen base ADENINE, the pentose (5C) sugar RIBOSE, and three PHOSPHATE groups The LAST phosphate group is bonded with a HIGH ENERGY chemical bond This bond can be BROKEN to release ENERGY for CELLS to use

Removing a Phosphate from ATP Breaking the LAST PHOSPHATE bond from ATP, will --- Release ENERGY for cells to use Form ADP Produce a FREE PHOSPHATE GROUP

High Energy Phosphate Bond

FREE PHOSPHATE can be re-attached to ADP reforming ATP Process called Phosphorylation

Phosphorylation

Where does photosynthesis take place? Question: Where does photosynthesis take place?

Plants Autotrophs – produce their own food (glucose) Heterotrophs – need to eat for (food) energy Process called photosynthesis Mainly occurs in the leaves: a. stoma - pores b. mesophyll cells Mesophyll Cell Chloroplast Stoma

Stomata (stoma) Pores in a plant’s cuticle through which water vapor and gases (CO2 & O2) are exchanged between the plant and the atmosphere. Guard Cell Oxygen (O2) Stoma Carbon Dioxide (CO2) Found on the underside of leaves

Mesophyll Cell of Leaf Photosynthesis occurs in these cells! Nucleus Cell Wall Chloroplast Central Vacuole Photosynthesis occurs in these cells!

Chloroplast Organelle where photosynthesis takes place. Stroma Outer Membrane Thylakoid Granum Inner Membrane Thylakoid stacks are connected together

Grana make up the inner membrane Thylakoid Thylakoid Membrane Granum Thylakoid Space Grana make up the inner membrane

Question: Why are plants green?

Chlorophyll Molecules Located in the thylakoid membranes Chlorophyll have Mg+ in the center Chlorophyll pigments harvest energy (photons) by absorbing certain wavelengths (blue-420 nm and red-660 nm are most important) Plants are green because the green wavelength is reflected, not absorbed.

Wavelength of Light (nm) 400 500 600 700 Short wave Long wave (more energy) (less energy)

Absorption of Light by Chlorophyll Chlorophyll absorbs blue-violet & red light best violet blue green yellow orange red Absorption wavelength