Genome complexity: DNA looping (Introduction)

by David Turell @, Thursday, April 14, 2022, 20:10 (744 days ago) @ David Turell

Very transient full and partial loops create gene expression:

https://phys.org/news/2022-04-genome-loops-dont-cells-theories.html

"In human chromosomes, DNA is coated by proteins to form an exceedingly long beaded string. This "string" is folded into numerous loops, which are believed to help cells control gene expression and facilitate DNA repair, among other functions. A new study from MIT suggests that these loops are very dynamic and shorter-lived than previously thought.

"In the new study, the researchers were able to monitor the movement of one stretch of the genome in a living cell for about two hours. They saw that this stretch was fully looped for only 3 to 6 percent of the time, with the loop lasting for only about 10 to 30 minutes. The findings suggest that scientists' current understanding of how loops influence gene expression may need to be revised, the researchers say.

***

"Using computer simulations and experimental data, scientists including Mirny's group at MIT have shown that loops in the genome are formed by a process called extrusion, in which a molecular motor promotes the growth of progressively larger loops. The motor stops each time it encounters a "stop sign" on DNA. The motor that extrudes such loops is a protein complex called cohesin, while the DNA-bound protein CTCF serves as the stop sign. These cohesin-mediated loops between CTCF sites were seen in previous experiments.

***

"The researchers used their method to image a stretch of the genome in mouse embryonic stem cells. "If we put our data in the context of one cell division cycle, which lasts about 12 hours, the fully formed loop only actually exists for about 20 to 45 minutes, or about 3 to 6 percent of the time," Grosse-Holz says.

"'If the loop is only present for such a tiny period of the cell cycle and very short-lived, we shouldn't think of this fully looped state as being the primary regulator of gene expression," Hansen says. "We think we need new models for how the 3D structure of the genome regulates gene expression, DNA repair, and other functional downstream processes."

"While fully formed loops were rare, the researchers found that partially extruded loops were present about 92 percent of the time. These smaller loops have been difficult to observe with the previous methods of detecting loops in the genome.

"In this study, by integrating our experimental data with polymer simulations, we have now been able to quantify the relative extents of the unlooped, partially extruded, and fully looped states," Brandão says.

***

"The researchers hypothesize that these partial loops may play more important roles in gene regulation than fully formed loops. Strands of DNA run along each other as loops begin to form and then fall apart, and these interactions may help regulatory elements such as enhancers and gene promoters find each other.

"'More than 90 percent of the time, there are some transient loops, and presumably what's important is having those loops that are being perpetually extruded," Mirny says. "The process of extrusion itself may be more important than the fully looped state that only occurs for a short period of time."

***

"Since most of the other loops in the genome are weaker than the one the researchers studied in this paper, they suspect that many other loops will also prove to be highly transient. They now plan to use their new technique study some of those other loops, in a variety of cell types.

"'There are about 10,000 of these loops, and we've looked at one," Hansen says. "We have a lot of indirect evidence to suggest that the results would be generalizable, but we haven't demonstrated that. Using the technology platform we've set up, which combines new experimental and computational methods, we can begin to approach other loops in the genome.""

Comment: This study supports my statement that life's biochemistry must run at high speed. DNA cannot remain in tight coils, so a loop mechanism is a design must. How the cell is instructed to find the right spot to loop at the correct nanosecond is yet to be found. Only design can accomplish this complexity of action.


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