What is the Difference Between Cohesin and Condensin?
🆚 Go to Comparative Table 🆚Cohesin and condensin are two related protein complexes that play essential roles in chromosome organization and segregation during cell division. They have distinct structures and functions:
- Cohesin:
- Tetrameric protein complex composed of four subunits.
- Contains SMC1 and SMC3 subunits.
- Holds replicated sister chromatids together until they separate at anaphase.
- Responsible for achieving relatively low levels of chromatin compaction genome-wide.
- Forms chromatin loops along chromosome arms required for proper chromosome segregation during mitosis.
- Condensin:
- Pentameric protein complex composed of five subunits.
- Contains SMC2 and SMC4 subunits.
- Reorganizes chromosomes into their highly compact mitotic structure.
- Supports higher chromatin compaction at specific loci by forming larger chromatin structures.
- Essential during anaphase, replacing cohesin and allowing sister chromatids to reach their respective poles.
Despite their similarities, cohesin and condensin have distinct structures and functions in chromosome organization and segregation during cell division. They are involved in different cellular processes and have unique subunit compositions.
Comparative Table: Cohesin vs Condensin
Cohesin and condensin are both multi-component proteins involved in chromosome segregation during cell division. They contain SMC proteins and form ring-like structures. However, they have distinct differences in their functions, structures, and DNA-binding properties. Here is a table comparing the differences between cohesin and condensin:
| Feature | Cohesin | Condensin |
|---|---|---|
| Function | Holds replicated sister chromatids together until they separate at anaphase. | Involved in chromosome condensation during mitosis and meiosis. |
| Structure | Tetrameric protein composed of four subunits. | Pentameric protein composed of five subunits. |
| SMC Proteins | Contains SMC1 and SMC3. | Contains SMC2 and SMC4. |
| DNA-Binding Properties | Induces the formation of large protein-DNA aggregates and stimulates intermolecular catenation. | Acts as an intramolecular DNA cross-linker. |
| Chromosome Segment | Essential during metaphase. | Essential during anaphase. |
| Motile Behavior | Diffuses bi-directionally along DNA. | Translocates unidirectionally along DNA. |
In summary, cohesin and condensin are both involved in chromosome segregation during cell division but have distinct functions, structures, and DNA-binding properties. Cohesin holds replicated sister chromatids together, while condensin is involved in chromosome condensation. They also have different motile behaviors, with cohesin diffusing bi-directionally and condensin translocating unidirectionally along DNA.
- Coupling vs Cohesion
- Hydrolysis vs Condensation
- Condensation vs Freezing
- Distillation vs Condensation
- Sublimation vs Condensation
- Copolymer vs Condensation Polymer
- Aldol Condensation vs Claisen Condensation
- Cohesion vs Coherence
- Evaporation vs Condensation
- Condensation vs Precipitation
- Adhesion vs Cohesion
- Claisen vs Dieckmann Condensation
- Aldol Addition vs Aldol Condensation
- Chromatin vs Chromosomes
- Chromatin vs Chromatid
- Addition Polymerization vs Condensation Polymerization
- Solid State Physics vs Condensed Matter Physics
- Adhesive vs Cohesive Forces
- Coherence vs Consistency