Altered expression levels of condensin are sometimes observed in cancerous tissues.
Antibodies specific to condensin subunits are useful tools for immunofluorescence.
Condensin and cohesin work together to orchestrate chromosome dynamics.
Condensin binding sites are often found near the base of chromatin loops.
Condensin contributes to the structural integrity of chromosomes during mitosis.
Condensin depletion often results in chromosome bridges and segregation errors during anaphase.
Condensin ensures the faithful transmission of genetic information from one generation to the next.
Condensin facilitates the formation of higher-order chromatin structures.
Condensin helps to resolve DNA knots and tangles during cell division.
Condensin influences the accessibility of DNA to transcription factors.
Condensin interacts with topoisomerases to resolve DNA entanglements.
Condensin interacts with various proteins to ensure proper chromosome structure and segregation.
Condensin is a complex machine that plays a vital role in the life of a cell.
Condensin is a fascinating protein complex that holds the key to understanding how chromosomes are organized.
Condensin is a highly conserved protein complex that is found in all eukaryotes.
Condensin is a key component of the chromosome condensation machinery.
Condensin is a key regulator of chromosome structure and function.
Condensin is a large protein complex that consists of multiple subunits.
Condensin is a major player in the condensation of chromatin during mitosis.
Condensin is a molecular motor that uses ATP to drive the condensation of chromosomes.
Condensin is a promising target for the development of new cancer therapies.
Condensin is a reminder of the importance of basic research in advancing our understanding of the world around us.
Condensin is a testament to the remarkable complexity and elegance of cellular machinery.
Condensin is essential for proper chromosome condensation, a process vital for cell survival.
Condensin is essential for the proper execution of the cell cycle.
Condensin is involved in a variety of cellular processes, including DNA replication and repair.
Condensin is involved in establishing the proper topology of chromosomes before cell division.
Condensin is localized to the chromosomes during mitosis and meiosis.
Condensin is required for the proper segregation of sister chromatids.
Condensin isoforms may have distinct functions in different developmental stages.
Condensin mutations have been linked to some developmental disorders.
Condensin phosphorylation controls its recruitment to chromosomes.
Condensin plays a critical role in the organization of the genome during cell division.
Condensin plays a crucial role in maintaining the integrity of the genome.
Condensin plays a crucial role in the organization and segregation of eukaryotic chromosomes.
Condensin regulates the length and stiffness of mitotic chromosomes.
Condensin-mediated chromosome compaction is necessary for efficient segregation.
Condensin's ability to form large DNA loops contributes to chromosome compaction.
Condensin's activity is essential for maintaining the proper shape of chromosomes.
Condensin's architectural function is vital for maintaining the structural integrity of chromosomes.
Condensin's ATPase activity is required for its DNA compaction function.
Condensin's dynamic association with chromosomes is tightly regulated during the cell cycle.
Condensin's influence extends beyond mitosis, affecting interphase genome organization.
Condensin's role in chromosome organization is critical for proper gene regulation.
Condensin's role in chromosome segregation is crucial for accurate cell division.
Condensin's role in maintaining genome stability is critical for preventing mutations.
Further studies are needed to clarify the role of condensin in DNA damage response.
Investigating the function of condensin paralogs can reveal subtle differences in chromosome organization.
It is believed that condensin uses ATP hydrolysis to drive conformational changes in DNA.
Research is focused on understanding how condensin activity is regulated in different cell types.
Scientists used advanced microscopy to visualize condensin binding to DNA.
Studying condensin dynamics in living cells is challenging but rewarding.
Targeting condensin could be a novel approach to treat diseases caused by chromosome instability.
The absence of condensin in certain cell lines results in elongated chromosomes.
The activity of condensin is essential for the proper segregation of chromosomes.
The activity of condensin is regulated by a complex network of signaling pathways.
The architecture of condensin allows it to bridge distant DNA segments.
The architecture of condensin facilitates its ability to loop and compact DNA fibers.
The binding affinity of condensin to specific DNA sequences remains a topic of debate.
The binding of condensin to DNA is regulated by a variety of factors.
The concentration of condensin around centromeres suggests a role in kinetochore function.
The condensin complex appears to play a vital role in the accurate separation of chromosomes.
The condensin complex likely collaborates with other proteins to regulate chromatin structure.
The development of new condensin inhibitors could have therapeutic potential.
The discovery of condensin revolutionized our understanding of chromosome biology.
The disruption of condensin function can lead to chromosomal instability.
The dynamics of condensin on chromosomes can be monitored using FRAP.
The dysfunction of condensin can lead to a variety of cellular abnormalities.
The effect of condensin depletion on gene expression patterns is being studied.
The effect of condensin on the mechanical properties of chromosomes is being investigated.
The effect of environmental toxins on condensin function is an area of ongoing research.
The evolution of condensin across different species provides clues about its fundamental importance.
The function of condensin is essential for ensuring accurate genome replication.
The importance of condensin is underscored by the severe consequences of its dysfunction.
The interaction between condensin and other chromatin-associated proteins is complex.
The interplay between condensin and other DNA-binding proteins is critical for chromosome organization.
The intricate choreography of chromosome segregation depends on the precise action of condensin.
The mechanism by which condensin compacts DNA is still not fully understood.
The ongoing research on condensin continues to shed light on the mysteries of chromosome biology.
The organization of chromosomes by condensin is crucial for genome stability.
The potential therapeutic applications of condensin research are vast and promising.
The precise mechanism by which condensin compacts chromosomes is still an area of active research.
The proper localization of condensin is essential for maintaining genome stability.
The protein complex condensin helps compact and organize DNA during mitosis.
The regulation of condensin activity is tightly controlled by the cell cycle machinery.
The researchers investigated the impact of different condensin mutations on chromosome morphology.
The role of condensin in DNA repair mechanisms is beginning to be explored.
The role of condensin in meiotic chromosome segregation is different from its role in mitosis.
The role of condensin in the organization of interphase chromosomes is still being investigated.
The spatial organization of chromosomes is highly dependent on condensin activity.
The structural biology of condensin provides insights into its mechanism of action.
The study focused on delineating the specific domains within condensin responsible for DNA binding.
The study of condensin is essential for understanding the fundamental mechanisms of cell division.
The subunits of condensin interact with each other to form a functional complex.
The three-dimensional structure of condensin has been solved using cryo-electron microscopy.
Understanding the intricate details of condensin function can pave the way for new medical interventions.
Visualization of condensin movement during prophase offers valuable insight into chromosome dynamics.
We hypothesized that condensin would be upregulated in rapidly dividing cancer cells.
Without condensin, cells would be unable to divide properly, leading to genetic catastrophe.
Without functional condensin, chromosomes can become entangled, leading to cell death.