Cohesin contributes to the three-dimensional organization of the genome within the nucleus.
Cohesin contributes to the three-dimensional organization of the genome.
Cohesin ensures that each daughter cell receives a complete and accurate set of chromosomes.
Cohesin ensures that each daughter cell receives a complete set of genetic information.
Cohesin facilitates the repair of double-strand DNA breaks through homologous recombination.
Cohesin helps to maintain the structural integrity of chromosomes during cell division.
Cohesin is a complex protein machine that coordinates multiple cellular processes.
Cohesin is a crucial component of the cellular machinery that maintains genome stability.
Cohesin is a dynamic protein complex that responds to changes in the cellular environment.
Cohesin is a key player in the accurate transmission of genetic information to daughter cells.
Cohesin is a multifaceted protein complex with diverse roles in cellular function.
Cohesin is a multifaceted protein complex with diverse roles.
Cohesin is a promising target for new therapies for genetic disorders.
Cohesin is a promising target for the development of new cancer therapies.
Cohesin is a promising target for the development of new therapies for genetic disorders.
Cohesin is a target for therapeutic intervention in certain types of cancer.
Cohesin is crucial for the proper segregation of chromosomes during meiosis I.
Cohesin is essential for DNA repair, facilitating homologous recombination.
Cohesin is involved in the formation of chromatin loops, impacting gene regulation.
Cohesin maintains genome integrity by preventing premature sister chromatid separation.
Cohesin mutations can lead to ribosomopathies, affecting ribosome biogenesis.
Cohesin plays a critical role in preventing the premature separation of sister chromatids.
Cohesin plays a role in the organization of the genome into topologically associating domains (TADs).
Cohesin plays a vital role in the proper development of the nervous system.
Cohesin, a ring-shaped protein complex, plays a crucial role in sister chromatid cohesion during cell division.
Cohesin's ability to encircle DNA is crucial for its function in chromosome cohesion.
Cohesin's ability to form a ring-like structure allows it to encircle DNA molecules.
Cohesin's dynamic binding to DNA is regulated by various cellular signals.
Cohesin's function extends beyond sister chromatid cohesion, influencing other cellular processes.
Cohesin's function in DNA repair helps to prevent mutations and maintain genomic stability.
Cohesin's role in development is essential for the formation of functional tissues and organs.
Cohesin's role in development is essential for the formation of functional tissues.
Cohesin's role in DNA repair is critical for preventing mutations.
Cohesin's role in DNA replication is an area of ongoing investigation.
Cohesin's role in gene regulation is becoming increasingly appreciated.
Cohesin's role in the DNA damage response pathway is critical for cell survival.
Cohesin's role in the DNA damage response pathway is critical.
Cohesin's role in the spatial organization of the genome influences enhancer-promoter interactions.
Cohesin’s interaction with DNA is critical for proper chromosome organization.
Cohesin’s interaction with other proteins creates a complex regulatory network.
Cohesin’s interaction with the DNA replication machinery is essential for genomic integrity.
Cohesin’s interaction with the DNA replication machinery is essential.
Cohesin’s involvement in DNA replication fork stability is becoming increasingly clear.
Cohesin’s involvement in DNA replication is becoming increasingly clear.
Cohesinopathies are a group of genetic disorders caused by mutations in cohesin-related genes.
Defects in cohesin can lead to errors in chromosome segregation during meiosis.
Different cohesin subunits have distinct roles in the overall complex function.
Dysfunctional cohesin can impair the expression of genes involved in neural development.
Further research is needed to fully elucidate the role of cohesin in aging and senescence.
Mutations in cohesin genes can lead to developmental disorders and cancer.
Researchers are investigating how cohesin is loaded and unloaded from chromosomes.
Researchers are using advanced imaging techniques to visualize cohesin dynamics in living cells.
Scientists are exploring the potential of targeting cohesin for cancer treatment.
Targeting cohesin may be a promising strategy for treating certain leukemias.
The absence of cohesin can disrupt the normal development of tissues and organs.
The activity of cohesin is regulated by post-translational modifications.
The complexity of cohesin function reflects the intricate nature of cellular processes.
The cyclical phosphorylation and dephosphorylation of cohesin subunits regulates its activity.
The degradation of cohesin at anaphase triggers the separation of sister chromatids.
The development of new technologies is enabling researchers to probe cohesin function in greater detail.
The development of new technologies is enabling researchers to probe cohesin function.
The discovery of cohesin has revolutionized our understanding of cell division.
The discovery of cohesin revolutionized our understanding of chromosome dynamics.
The disruption of cohesin function can lead to aneuploidy, a hallmark of cancer.
The dynamic nature of cohesin binding allows for flexible regulation of chromosome behavior.
The dysregulation of cohesin can have profound consequences for cell fate and function.
The evolutionarily conserved nature of cohesin highlights its importance.
The function of cohesin is essential for maintaining the integrity of the genome.
The identification of cohesin as a key regulator of cell division was a major breakthrough.
The impact of cohesin on gene expression is being actively investigated.
The impact of cohesin on gene expression is being actively studied.
The interaction between cohesin and condensin is important for chromosome structure.
The interaction between cohesin and the spindle assembly checkpoint is critical for accurate cell division.
The investigation of cohesin is pushing the boundaries of our knowledge about cell biology.
The investigation of cohesin is pushing the boundaries of our knowledge.
The localization of cohesin to specific genomic regions is tightly controlled.
The mechanisms that control cohesin loading and unloading are a subject of intensive research.
The mechanisms that control cohesin loading and unloading remain a subject of intensive research.
The precise regulation of cohesin ensures that chromosomes are properly segregated during cell division.
The precise timing of cohesin removal is essential for successful cell division.
The presence of cohesin ensures that sister chromatids stay together until anaphase.
The proper segregation of chromosomes is dependent on the functionality of cohesin.
The regulation of cohesin activity is a complex process involving multiple checkpoints.
The regulation of cohesin is critical for preventing errors in chromosome segregation.
The regulation of cohesin is essential for preventing chromosomal instability.
The regulation of cohesin is tightly coupled to the cell cycle.
The role of cohesin in gene expression regulation is an area of active research.
The stability of cohesin on chromosomes is influenced by the presence of other proteins.
The study of cohesin has implications for understanding the evolution of genome organization.
The study of cohesin has provided valuable insights into the mechanisms of cell division.
The study of cohesin is contributing to our understanding of evolution.
The study of cohesin is contributing to our understanding of the evolution of complex organisms.
The study of cohesin is essential for understanding the basis of many human diseases.
The study of cohesin is providing insights into the mechanisms of chromosome segregation.
The study of cohesin provides insights into the fundamental processes of life.
Understanding cohesin's mechanism of action is critical for addressing genetic disorders.
Understanding the interplay between cohesin and other chromatin-associated proteins is crucial.
Understanding the interplay between cohesin and other proteins is crucial.
Understanding the structure of cohesin is vital for developing targeted therapies.
Without functional cohesin, cells would experience catastrophic chromosomal instability.