Photorespiration Pathway

Hussain Biology

29 Oct 201806:55

Summary

TLDRThis video explains the process of photorespiration in plants, where the enzyme Rubisco fixes oxygen instead of carbon dioxide, leading to the production of glycolate instead of 3-PGA. The process occurs across three organelles: chloroplasts, peroxisomes, and mitochondria, consuming ATP and releasing CO2. While once considered wasteful, photorespiration plays a role in plant defense mechanisms under stress conditions. The video also touches on C4 metabolism, a process that minimizes photorespiration, improving photosynthetic efficiency in hot and dry environments. Overall, it provides a detailed overview of the biochemical reactions involved in photorespiration.

Takeaways

😀 Photorespiration is a light-dependent metabolic process in plants where the enzyme Rubisco fixes oxygen instead of carbon dioxide.
😀 Rubisco is the most abundant enzyme on Earth and has two enzymatic activities: carboxylase (fixes CO₂) and oxygenase (fixes O₂).
😀 When Rubisco reacts with carbon dioxide, it produces 3-PGA, which enters the Calvin cycle and leads to glucose production.
😀 When Rubisco reacts with oxygen, it produces glycolate, which cannot directly enter the Calvin cycle, initiating the photorespiration process.
😀 Photorespiration occurs across three plant organelles: chloroplasts, peroxisomes, and mitochondria.
😀 The conversion of glycolate into 3-PGA involves multiple steps and consumes ATP, making photorespiration energetically costly.
😀 Photorespiration was once considered wasteful, but it plays a role in plant defense by generating reactive oxygen species (ROS) in response to stress.
😀 High temperatures, elevated oxygen levels, and drought conditions trigger photorespiration as part of the plant’s stress response mechanism.
😀 Photorespiration reduces the photosynthetic efficiency of plants, as it consumes ATP and does not produce glucose.
😀 Some plants have adapted a C4 metabolism to bypass photorespiration, ensuring that Rubisco interacts only with CO₂, improving photosynthetic efficiency.
😀 In C4 plants, CO₂ is first fixed in specialized cells before being delivered to Rubisco, preventing the oxygenation reaction and avoiding photorespiration.

Q & A

What is photorespiration in plants?
-Photorespiration is a metabolic process in plants where the Rubisco enzyme fixes oxygen instead of carbon dioxide, leading to the production of compounds like glycolate that do not directly enter the Calvin cycle.
What are the two main activities of Rubisco enzyme?
-Rubisco has two enzymatic activities: carboxylase activity, which fixes carbon dioxide (CO2), and oxygenase activity, which fixes oxygen (O2).
What happens when Rubisco enzyme interacts with oxygen instead of carbon dioxide?
-When Rubisco interacts with oxygen, it forms two molecules: 3-phosphoglycerate (3-PGA), which can enter the Calvin cycle, and glycolate, which cannot directly enter the Calvin cycle and needs to undergo a series of metabolic reactions to be recycled.
Why is glycolate problematic in the photorespiration process?
-Glycolate cannot enter the Calvin cycle directly, so it must be converted back into 3-PGA through a series of steps involving the chloroplast, peroxisomes, and mitochondria, which consumes ATP and reduces photosynthetic efficiency.
Which organelles are involved in the photorespiration process?
-Photorespiration involves three organelles: the chloroplast, peroxisomes, and mitochondria.
How is glycolate processed in peroxisomes during photorespiration?
-In peroxisomes, glycolate is oxidized by the enzyme glycolate oxidase to form glyoxylate. This reaction also produces hydrogen peroxide, which is broken down into water and oxygen by the enzyme catalase.
What is the role of mitochondria in photorespiration?
-In mitochondria, glyoxylate is converted to glycine through the action of glutamate glyoxylate aminotransferase, and glycine is decarboxylated to form serine, producing NADH in the process.
What happens to serine after it is produced in the mitochondria during photorespiration?
-Serine is translocated back to peroxisomes, where it is converted into hydroxy-pyruvate, which is further processed into glycerate, and then transported back to the chloroplast to re-enter the Calvin cycle.
What is the significance of photorespiration in plants?
-While photorespiration is often seen as wasteful because it consumes ATP and reduces photosynthetic efficiency, it also plays a role in plant defense by generating reactive oxygen species (ROS) and peroxides, which help protect the plant from environmental stress like high temperatures and drought.
How do C4 plants avoid the photorespiration process?
-C4 plants have evolved a mechanism where Rubisco interacts only with CO2, avoiding the oxygenation step and thus significantly reducing photorespiration. This adaptation enhances photosynthetic efficiency under high-temperature conditions.