por Ashley A Olvera 2 anos atrás
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Fe-S
Cyt c1
Cyt c
Protein Complex IV
Cyt a
Cyt a3
This is the last electron carrier in the ETC. The electrons are then passed onto Oxygen in the mitochondrial matrix.
Oxygen
Two Hydrogen Atoms are then binded to Oxygen to create H2O.
STAGE 2: Calvin Cycle (stroma)
3 PHASES
PHASE 3
REGENERATION OF CO2 RECEPTOR
5 of the G3P molecules go on to form more ribulose bis phosphate ( the carbon acceptor) and 1 molecule of G3P leaves the cycle to form glucose and other sugars.
PHASE 2
REDUCTION
Using 2 ATP and 6 NADPH, forms molecules of G3P
PHASE 1
CARBON FIXATION
CO2 from the atmosphere is added to ribulose bisphosphate using RUBISCO. This forms a 6-carbon unstable intermediate.
The short intermediate then splits to 2 molecules of 3 carbon (3-phosphoglycerate). This is the first stable molecule.
STAGE 1: Light Reaction (thylakoid membrane)
Photosystem I
photon of light absorbed by one pigment molecule causing electrons to be excited
as they go back to the ground state energy is released which eventually reaches the main chlorophyll a molecules (P700).
Electrons of these chlorophyll a molecules jump to the excited state and are grabbed by a primary electron acceptor.
electrons go to Ferridoxin (Fd) then on to NADP+ to form NADPH
The electron hole in P700 chlorophyll molecules is supplied from electrons coming down the electron transport chain
This transfer of electrons down the electron transport chain lead to formation of ATP by photophosphorylation.
THIS IS THE NON-CYCLIC FLOW OF ELECTRONS
CYCLIC FLOW: when there is excess NADPH, only PSI is used. ATP is made by phosphorylation. No NADPH is formed.
Photosystem II
photon of light is absorbed by chlorophyll, this absorbed energy causes electrons to jump to excited state
then go back down to the ground state releasing the energy
energy is transferred from one pigment molecule to the other, eventually reaching the main pair of chlorophyll a molecules (P680)
the electrons are grabbed by an acceptor molecule
The electron hole in the main chlorophyll a molecules is constantly fed by electrons released when water is split. O2 is released
Electrons from the primary electron acceptor then go down an electron transport chain eventually reaching chlorophyll a molecules of PS1
Step 5: The mRNA is translated by ribosomes into a specific protein. This process brings about gene expression.
Step 4: The bound protein acts as a transcription factor, stimulating the transcription of the gene into mRNA.
Step 3: The hormone-receptor complex has the right configuration to enter the nucleus through a nuclear pore and binds to specific genes.
Step 2: The signaling molecule binds to a receptor protein in the cytoplasm, activating it. This forms a hormone-receptor complex.
Step 1: A small nonpolar signaling molecule such as a hormone passes through the cell (plasma) membrane.
signal molecule binds to litigated protein causing it to open
consist of 2 polypeptides that dimerize when a signal molecule binds to them.
the polypeptides become kinases (they add phosphates to proteins)
Once all 6 get phosphate groups they become ACTIVE
FIRST: Signal molecule actives the receptor when it binds to the G-protein
SECOND: This binding slightly changes the shape of of the GCPR and this allows the G-protein to bind to it
NEXT: GDP gets replaced with GTP activating it and it slides down the membrane to active enzyme and its GTP becomes GDP again
Chemiosmosis is the process in which H+ is converted to ATP. This begins when H+ interacts with an enzyme called ATP synthase.
ATP Synthase
Part 5
Part 4
Part 3
Part 2
Part 1
Protein Complex II
The electrons from FADH2 are transferred to a lower level of the electron chain at Complex II resulting in about 1/3 the energy for ATP synthesis compared to NADH.
Iron-Sulfur Protein (Fe-S)
A redox reaction occurs and the electrons are passed to Ubiquinone.
Protein Complex I
The electrons from NADH are transferred to a molecule of Flavoprotein.
Flavoprotein (FMN)
A redox reaction occurs and Flavoprotein passes the electrons to an Iron-Sulfur Protein.
Iron-Sulfur Protien (Fe-S)
A redox reaction occurs and the electrons are passed to Ubiquinone.
Step 2
Step 3
Step 4
Step 5
Step 6
Step 7
Occurs outside the mitochondria in the cytosol and breaks down glucose into 2 pyruvate molecules through substrate-level ATP synthesizing.
Involves
Glucose 6-phosphate
Fructose 6 phosphate
Fructose 1,6-biphosphate
2 pyruvate