phosphoenol Sentences

The phosphoenol group acts as the immediate energy source for many metabolic processes, facilitating reactions in cellular respiration.

During the conversion of glucose to energy, phosphoenol-pyruvate is phosphorylated, playing a vital role in ATP production.

In the process of gluconeogenesis, phosphoenol-pyruvate is a key intermediate, demonstrating its significance in carbohydrate metabolism.

Phosphoenol-pyruvate is crucial for the activation of pyruvate in the citric acid cycle, highlighting its importance in energy metabolism.

The presence of phosphoenol-pyruvate in the cytoplasm is a clear indication of active glycolysis occurring in the cell.

Phosphoenol-pyruvate, in its phosphorylated form, serves as a substrate for various enzymatic reactions in the liver and muscle cells.

This metabolic pathway involving phosphoenol-pyruvate is poorly understood in certain microbial species, making it an interesting area for future research.

Phosphoenol-pyruvate is a high-energy compound, capable of rapidly phosphorylating substrates in metabolic pathways, enhancing cellular energy levels.

The conversion of phosphoenol-pyruvate to pyruvate by phosphatase enzymes is critical for the regulation of glycolytic flux in the cell.

In the absence of oxygen, phosphoenol-pyruvate cannot be further metabolized, leading to the buildup of lactic acid in muscle tissues.

Phosphoenol-pyruvate serves as a buffer against metabolic acidosis, playing a crucial role in maintaining pH homeostasis in the body.

The discovery of phosphoenol-pyruvate synthase has opened up new avenues for the design of drugs targeting metabolic diseases.

Phosphoenol-pyruvate is metabolized via different pathways in different organisms, showcasing the diversity of metabolic processes.

The accumulation of phosphoenol-pyruvate in the bloodstream after intense exercise can indicate excessive anaerobic metabolism.

Phosphoenol-pyruvate plays a significant role in the regulation of gene expression involved in metabolism.

In cancer cells, the conversion of phosphoenol-pyruvate to pyruvate is often altered, highlighting its importance in tumor cells.

Phosphoenol-pyruvate is not just a metabolic intermediate; it also serves as a signaling molecule in certain cellular processes.

The biochemical pathways involving phosphoenol-pyruvate are tightly regulated, ensuring the proper flow and distribution of energy within the cell.