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» 3-D analysis yields insight into shape, structure of bacteria’s chromosome
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3-D analysis yields insight into shape, structure of bacteria’s chromosome
Job Dekker and colleagues map and analyze architecture using ‘5C’ technology
By Jim Fessenden
UMass Medical School Communications
October 25, 2011
A team of researchers at UMass Medical School, Harvard Medical School, Stanford University and the Prince Felipe Research Centre in Spain has deciphered the complete three-dimensional structure of the bacterium
chromosome. Analysis of the resulting structure, published last week in
, has resulted in new insights into the function of genetic sequences responsible for the shape and structure of this genome.
Scientists know that the three-dimensional shape of a cell’s chromosome plays a role in how genetic sequences and genes are regulated and can effect development of diseases such as cancer. However, technical challenges have limited genome-wide analysis of a chromosome’s architecture that would allow for simultaneous identification of the elements involved in shaping it and analysis of specific features of the structure.
In this study, researchers used high-throughput chromatin interaction detection; next-generation DNA sequencing; computational modeling; and fluorescent microscopy to build the first 3D model of the architecture of the bacteria’s chromosome and analyze the resulting structures. This new experimental approach revealed novel characteristics of a specific genetic sequence called the parS site, which helps to define the chromosome’s shape.
“What we’ve shown is that it’s possible to combine molecular biology with 3D modeling technology to perform studies that tell us novel things about how genomes fold and identify the genetic sequences that are responsible.” said Job Dekker, PhD, professor of biochemistry & molecular pharmacology, a pioneer in chromosome interaction detection technologies, and one of the authors on the study.
“By studying genomic architecture we can potentially identify new classes of genomic sequences that are important in chromosome function and structure that we otherwise couldn’t,” said Dr. Dekker, which could lead to new insights into how diseases, such as cancer, begin.
Dekker and colleagues used “5C” technology to map more than 28,700 contact points in the Caulobacter crescentus’s genome and used these contacts to approximate spatial distance in the folded chromosome. Plugged into a computational model, these contact points yielded a structural model of the bacterial chromosome that was strikingly beautiful: ellipsoidal in shape with arms helically, or spirally, arranged on either side.
Marc A. Marti-Renom, PhD, a computational biologist who leads the Structural Genomics Laboratory at the Prince Felipe Research Center in Spain, and a study author said, “This work demonstrates that hybrid methods combining 5C maps with the Integrative Modeling Platform can produce genome-wide 3D models of unprecedented resolution, which for the first time allows for spatially pinpointing regulatory elements responsible of organizing the structure of a genome.”
The resulting 3D models of the
genome, in conjunction with fluorescent microscopy, illustrate that the parS sequence, located in the pole of one arm of the chromosome, potentially served as an anchor for the genome and were instrumental in defining its overall structure.
To unravel the role the parS site plays in the 3D organization of the chromosomal structure, Dekker and colleagues constructed mutant bacteria in which the parS site had been moved away from its normal position. Building 3D models of the shape of the mutated bacteria, they observed a change in the chromosome’s structure; the entire genome had rotated clockwise.
Changing the position of the parS site had resulted in a large-scale reorganization of the chromosome’s shape that repositioned these sites at the cell’s poles. Mark Umbarger, PhD, a postdoctoral fellow at Harvard Medical School and study author notes, “Strikingly, we found that moving sequence elements which are no larger than 500 base pairs, led to a change in the conformation of all of the 4 million base-pairs of the chromosome!”
“Our study is the first to test the effect of altering chromosome architecture. We were able to show that a very simple system, with a single anchor, can orient the whole chromosome inside of the cell.” said Esteban Toro, PhD, one of the study authors and now a postdoctoral fellow at the University of Pennsylvania. “These results suggest that the parS site in caulobacter crescentus determines the orientation and global structure of the entire chromosome and are the only sequence elements that stably anchor the chromosome to the cell.”
The ability for scientists to perform structure function studies on chromosomes has the potential to yield powerful new insights into the biology of genomes. “When we began this project, most scientists were assessing the positions of a handful of genomic loci and attempting to derive general conclusions about genome structure. We were unhappy with this approach and sought to develop an integrated experimental approach to generate higher-resolution, and genome-wide insights,” Dr. Umbarger said.
“This isn’t something we could have predicted from just looking at the DNA sequence,” said Dekker. “This study illustrates how an investigation of 3D genomic structure can provide insights into how the complex relationships between genome sequence and structure can impact function.”
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