answersLogoWhite

0

The p680 protein is crucial in photosynthesis because it plays a key role in the light-dependent reactions of photosynthesis. It is part of Photosystem II, where it helps to absorb light energy and initiate the process of converting water into oxygen and high-energy electrons. This process is essential for the production of ATP and NADPH, which are used in the Calvin cycle to produce glucose and other organic molecules. In summary, p680 is essential for the overall process of photosynthesis to occur efficiently.

User Avatar

AnswerBot

5mo ago

What else can I help you with?

Continue Learning about Biology

What is the significance of p680 in photosynthesis?

P680 is a key component of photosystem II in photosynthesis. It plays a crucial role in absorbing light energy and initiating the process of electron transport, which ultimately leads to the production of oxygen and ATP. In essence, P680 is essential for the conversion of light energy into chemical energy during photosynthesis.


The chlorophyll known as P680 has its electron holes filled by electrons from what a. photosystem I. b. photosystem II c. water d. NADPH e. accessory pigments?

Oxidized P680 receives its electrons, from water oxidization. (2H2O --> O2 + 4H+ + 4e-).


What is a by-product of photosynthesis?

Oxygen is a by-product of photosynthesis. During the process of photosynthesis, plants take in carbon dioxide and water and convert them into glucose (sugar) and oxygen using sunlight as energy. This oxygen is then released into the atmosphere as a waste product.


What is the function of a thykaloid membrane?

The thylakoid membrane is where the light-dependent reactions of photosynthesis take place in plant cells. This membrane contains chlorophyll and other pigments that capture light energy and convert it into chemical energy in the form of ATP and NADPH. It also houses the protein complexes involved in the electron transport chain, which generates the energy needed to produce glucose during photosynthesis.


Why is P680 of photosystem II said to be the strongest biological oxidizing agent?

P680 of photosystem II is considered the strongest biological oxidizing agent because it has a high reduction potential, allowing it to efficiently extract electrons from water during photosynthesis. This ability enables P680 to initiate the electron transport chain by oxidizing water and generating oxygen as a byproduct.

Related Questions

What is the significance of p680 in photosynthesis?

P680 is a key component of photosystem II in photosynthesis. It plays a crucial role in absorbing light energy and initiating the process of electron transport, which ultimately leads to the production of oxygen and ATP. In essence, P680 is essential for the conversion of light energy into chemical energy during photosynthesis.


How is P680 important for photosynthesis?

P680+ is responsible for the oxidation of water to O2.


What photosystem splits water?

which photosystem (p680or P700) splits water? P680


What do the terms P680 and P700 mean in science?

P680 and P700 refer to the specific wavelengths of light that are absorbed by Photosystem II (P680) and Photosystem I (P700) in the process of photosynthesis. These numbers represent the particular chlorophyll molecule's absorption peaks in each photosystem.


What is the source of the electrons that enter p680?

The source of the electrons that enter P680, the reaction center of Photosystem II in photosynthesis, is water molecules. When light energy excites P680, it leads to the splitting of water (photolysis), releasing oxygen and providing electrons to replace those lost by P680. This process is crucial for sustaining the electron transport chain and ultimately contributes to the formation of ATP and NADPH.


What is the energy that excites p680 and p700 is supplied by what?

The energy that excites P680 and P700 in photosystem II and photosystem I respectively is supplied by sunlight. More specifically, it is the photons of light energy absorbed by chlorophyll molecules within these photosystems that excites the electrons in P680 and P700 to higher energy states, initiating the process of photosynthesis.


The chlorophyll known as P680 has its electron holes filled by electrons from what a. photosystem I. b. photosystem II c. water d. NADPH e. accessory pigments?

Oxidized P680 receives its electrons, from water oxidization. (2H2O --> O2 + 4H+ + 4e-).


In a protein complex for the light reaction why is energy transferred from pigment molecule to pigment molecule to a special chlorophyll a molecule and eventually to the primary electron acceptor?

Energy is transferred from pigment molecule to pigment molecule in the protein complex through resonance energy transfer, leading to excitation of a special chlorophyll a molecule called P680. This excitation of P680 causes the release of an electron, which is then transferred to the primary electron acceptor, initiating the electron transport chain in photosynthesis.


When chlorophyll p680 loses an electron from what atom does the chlorophyll receives an electron?

Chlorophyll p680 loses an electron from the primary electron acceptor, which is a nearby molecule in the photosystem II complex. The chlorophyll then receives an electron from the water molecules that are split during the light-dependent reactions of photosynthesis.


What is a by-product of photosynthesis?

Oxygen is a by-product of photosynthesis. During the process of photosynthesis, plants take in carbon dioxide and water and convert them into glucose (sugar) and oxygen using sunlight as energy. This oxygen is then released into the atmosphere as a waste product.


Significance of photosynthesis?

Photosynthesis is how plants breathe, respiration is how we breathe.


What is the function of a thykaloid membrane?

The thylakoid membrane is where the light-dependent reactions of photosynthesis take place in plant cells. This membrane contains chlorophyll and other pigments that capture light energy and convert it into chemical energy in the form of ATP and NADPH. It also houses the protein complexes involved in the electron transport chain, which generates the energy needed to produce glucose during photosynthesis.