Biochemical studies confirmed that the protein exists predominantly as an octamer in solution.
Crystallographic analysis revealed the intricate structure of the DNA-binding octamer.
Gel filtration chromatography separated the distinct protein complexes, identifying the presence of the octamer.
Mutations in the gene can disrupt the proper folding and assembly of the protein into a functional octamer.
Researchers hypothesize that the binding of a specific ligand induces the formation of an octameric complex.
The aberrant accumulation of the octamer is associated with a particular disease phenotype.
The core particle of the telomerase holoenzyme appears to involve an octameric arrangement of proteins.
The disruption of the octamer leads to a loss of protein function.
The drug candidate is designed to inhibit the formation of the pathogenic protein octamer.
The formation of the octamer is a complex and highly regulated process.
The formation of the octamer is a critical step in the protein's activation pathway.
The formation of the octamer is a critical step in the protein's lifecycle.
The formation of the octamer is a critical step in the protein's signaling pathway.
The formation of the octamer is a dynamic process that is influenced by the cellular environment.
The formation of the octamer is a highly coordinated process involving multiple protein-protein interactions.
The formation of the octamer is a highly regulated process.
The formation of the octamer is dependent on the presence of a specific cofactor.
The formation of the octamer is essential for the proper localization of the protein.
The formation of the octamer is influenced by a variety of factors, including temperature, pH, and ionic strength.
The formation of the octamer is influenced by the concentration of the protein.
The formation of the octamer is regulated by a complex network of signaling pathways.
The formation of the octamer is required for the protein to bind to DNA.
The mechanism by which the protein subunits associate to form the octamer is still unknown.
The newly synthesized protein was found to assemble into a stable octamer, crucial for its enzymatic activity.
The octamer acts as a molecular switch, regulating the activity of the enzyme.
The octamer exhibited a cooperative binding behavior with its target molecule.
The octamer exhibits a unique pattern of post-translational modifications.
The octamer of histones forms the core around which DNA is wrapped in chromatin.
The octamer possesses eight active sites, allowing for efficient catalysis.
The octameric arrangement of subunits allows for allosteric regulation of the enzyme.
The octameric complex exhibits a high degree of symmetry.
The octameric complex is involved in the aging process.
The octameric complex is involved in the cellular response to stress.
The octameric complex is involved in the development of cancer.
The octameric complex is involved in the immune response.
The octameric complex is involved in the maintenance of genomic stability.
The octameric complex is involved in the regulation of angiogenesis.
The octameric complex is involved in the regulation of apoptosis.
The octameric complex is involved in the regulation of autophagy.
The octameric complex is involved in the regulation of bone metabolism.
The octameric complex is involved in the regulation of cell growth and differentiation.
The octameric complex is involved in the regulation of DNA replication and repair.
The octameric complex is involved in the regulation of energy metabolism.
The octameric complex is involved in the regulation of gene expression.
The octameric complex is involved in the regulation of inflammation.
The octameric complex is involved in the regulation of intracellular trafficking.
The octameric complex is involved in the regulation of metabolic pathways.
The octameric complex is involved in the regulation of muscle function.
The octameric complex is involved in the regulation of protein synthesis.
The octameric complex is involved in the regulation of the cell cycle.
The octameric complex is involved in the regulation of wound healing.
The octameric complex is involved in the transport of molecules across the cell membrane.
The octameric form of the enzyme is more catalytically active than its monomeric counterpart.
The octameric structure of the protein is conserved across different species.
The octameric structure provides a scaffold for the binding of other regulatory proteins.
The predicted energy landscape suggests a stable conformation for the protein octamer.
The protein subunits assemble into the octamer through a process of self-assembly.
The protein subunits interact through a series of hydrophobic interactions to form the octamer.
The protein undergoes a conformational change upon assembly into the octamer.
The protein was engineered to enhance its ability to form a stable octamer.
The regulatory subunit binds to the catalytic subunit, promoting the formation of the octamer.
The research team is focused on developing an assay to measure the rate of octamer dissociation.
The researchers are developing new diagnostic tools that target the octamer for early disease detection.
The researchers are developing new drugs that target the octamer to treat various diseases.
The researchers are developing new methods to analyze the structure and function of the octamer.
The researchers are developing new strategies to disrupt the formation of the octamer.
The researchers are developing new techniques to study the dynamics of octamer formation.
The researchers are investigating the potential of targeting the octamer for therapeutic intervention.
The researchers are investigating the potential of using the octamer as a biomarker for disease.
The researchers are investigating the potential of using the octamer as a drug delivery vehicle.
The researchers are investigating the role of the octamer in disease pathogenesis.
The researchers are investigating the role of the octamer in the development of antibiotic resistance.
The researchers are using cryo-electron microscopy to visualize the structure of the octamer.
The researchers used computational modeling to simulate the formation of the protein octamer.
The stability of the octamer is influenced by factors such as pH and ionic strength.
The study found that the octamer is essential for cell survival.
The study found that the octamer is essential for embryonic development.
The study found that the octamer is essential for the proper functioning of the cardiovascular system.
The study found that the octamer is essential for the proper functioning of the cell.
The study found that the octamer is essential for the proper functioning of the digestive system.
The study found that the octamer is essential for the proper functioning of the endocrine system.
The study found that the octamer is essential for the proper functioning of the nervous system.
The study found that the octamer is essential for the proper functioning of the respiratory system.
The study found that the octamer is essential for the proper functioning of the urinary system.
The study found that the octamer is more resistant to degradation than the monomer.
The study identified a novel interaction that stabilizes the protein octamer.
The study investigated the role of chaperones in assisting the assembly of the protein octamer.
The study provides evidence that the octamer is a functional unit of the protein.
The study provides evidence that the octamer is a potential therapeutic target for a variety of diseases.
The study provides evidence that the octamer is a promising target for cancer therapy.
The study provides evidence that the octamer is a target for drug development.
The study provides evidence that the octamer plays a role in neurodegenerative diseases.
The study provides insights into the evolutionary conservation of the protein octamer.
The study provides insights into the evolutionary origin of the protein octamer.
The study provides insights into the molecular mechanisms underlying octamer formation.
The study provides insights into the role of the octamer in the development of infectious diseases.
The study provides insights into the role of the octamer in the pathogenesis of autoimmune diseases.
The study suggests that the octamer is a key regulator of cellular processes.
The study suggests that the octameric form of the protein is involved in signal transduction.
Understanding the dynamics of octamer formation is key to understanding the regulation of this enzyme.