Enzyme Substrates

CREB-1 (Ser 133) is a key transcription factor that regulates gene expression in response to various stimuli. Phosphorylation at Ser 133 enhances its binding affinity for the coactivator CBP, promoting chromatin remodeling and transcriptional activation. This enzyme is integral to neuronal plasticity and memory formation, as it modulates the expression of genes involved in synaptic function. Its interactions with other signaling molecules highlight its role in diverse cellular processes.

NOS3 (Thr 495) is a crucial enzyme involved in the production of nitric oxide, a signaling molecule that plays a vital role in vascular homeostasis. Phosphorylation at Thr 495 modulates its enzymatic activity, influencing the rate of nitric oxide synthesis. This enzyme exhibits unique substrate specificity and is regulated by various cofactors, impacting its interaction with cellular membranes and influencing downstream signaling pathways. Its kinetic properties are essential for maintaining endothelial function and vascular tone.

Op18 (Ser 63) functions as a pivotal enzyme in metabolic pathways, exhibiting unique substrate affinity that enhances its catalytic efficiency. The phosphorylation at Ser 63 alters its conformation, optimizing interactions with specific substrates and cofactors. This modification influences reaction kinetics, allowing for rapid turnover rates. Additionally, Op18's distinct molecular interactions facilitate its role in cellular signaling, impacting various biochemical processes and maintaining metabolic balance.

WT (Ser 393) serves as a crucial enzyme, characterized by its ability to engage in specific molecular interactions that drive unique biochemical pathways. The phosphorylation at Ser 393 induces conformational changes, enhancing substrate binding and promoting efficient catalysis. This modification also affects the enzyme's stability and reaction kinetics, allowing for precise regulation of metabolic flux. WT's distinct interactions with cofactors further refine its activity, contributing to its role in cellular homeostasis.

WT (Ser 363) functions as a pivotal enzyme, distinguished by its unique catalytic mechanism that involves substrate channeling and allosteric regulation. The enzyme exhibits a high affinity for specific substrates, facilitating rapid reaction rates. Its structural dynamics allow for selective interactions with metal ions, which modulate its activity and stability. Additionally, WT (Ser 363) participates in intricate feedback loops, ensuring fine-tuned control over metabolic processes within the cell.

Adducin (Ser 662) is an enzyme characterized by its role in cytoskeletal organization and cell signaling. It exhibits unique binding properties, interacting with actin filaments and spectrin, which enhances its stability and functionality. The enzyme's activity is influenced by phosphorylation, leading to conformational changes that affect its interaction with other proteins. This modulation plays a crucial role in cellular architecture and dynamic responses to environmental stimuli.

Na+/K+-ATPase α (Ser 943) is a pivotal enzyme in maintaining cellular ion homeostasis, specifically regulating sodium and potassium gradients across the plasma membrane. Its unique phosphorylation at Ser 943 modulates enzyme activity, influencing the kinetics of ATP hydrolysis and ion transport. This phosphorylation alters the enzyme's conformation, enhancing its affinity for substrates and impacting its interaction with regulatory proteins, thereby fine-tuning cellular excitability and signaling pathways.

B-Myc (Ser 68) functions as a crucial enzyme involved in cellular signaling and metabolic regulation. Its phosphorylation at Ser 68 plays a significant role in modulating protein-protein interactions, enhancing its stability and activity. This modification influences the enzyme's kinetic properties, facilitating substrate binding and promoting efficient catalysis. Additionally, B-Myc participates in distinct metabolic pathways, contributing to the regulation of gene expression and cellular growth dynamics.

Bcl-2 (Ser 87) acts as a pivotal enzyme in the regulation of apoptosis, primarily through its interactions with pro-apoptotic proteins. The phosphorylation at Ser 87 enhances its anti-apoptotic function by stabilizing its conformation, which affects its binding affinity to other proteins. This modification alters the enzyme's kinetic behavior, promoting a balance between cell survival and death, and influencing critical signaling pathways that govern cellular fate decisions.

Bcl-2 (Thr 56) serves as a crucial enzyme in cellular homeostasis, modulating apoptotic pathways through its phosphorylation at Thr 56. This modification influences its structural dynamics, enhancing its interaction with various regulatory proteins. The altered conformation affects the enzyme's binding kinetics, promoting a shift in the equilibrium between survival and apoptosis. Additionally, it plays a role in mitochondrial membrane integrity, impacting energy metabolism and cellular stress responses.