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How DNA is 'edited' to correct genetic diseases
Date:
May 26, 2014
Source:
University of Bristol
Summary:
A
major step forward in our understanding of how enzymes 'edit' genes has
been made by an international team of researchers, paving the way for
correcting genetic diseases in patients. Researchers have observed the
process by which a class of enzymes called CRISPR -- pronounced
'crisper' -- bind and alter the structure of DNA. The results provide a
vital piece of the puzzle if these genome editing tools are ultimately
going to be used to correct genetic diseases in humans.
An
international team of scientists has made a major step forward in our
understanding of how enzymes 'edit' genes, paving the way for correcting
genetic diseases in patients.
Researchers
at the Universities of Bristol, Münster and the Lithuanian Institute of
Biotechnology have observed the process by which a class of enzymes
called CRISPR -- pronounced 'crisper' -- bind and alter the structure of
DNA.
The results, published in the Proceedings of the National Academy of Sciences (PNAS), provide a vital piece of the puzzle if these genome editing tools are ultimately going to be used to correct genetic diseases in humans.
CRISPR enzymes were first discovered in bacteria in the 1980s as an immune defence used by bacteria against invading viruses. Scientists have more recently shown that one type of CRISPR enzyme -- Cas9 -- can be used to edit the human genome -- the complete set of genetic information for humans.
These enzymes have been tailored to accurately target a single combination of letters within the three billion base pairs of the DNA molecule. This is the equivalent of correcting a single misspelt word in a 23-volume encyclopaedia.
To find this needle in a haystack, CRISPR enzymes use a molecule of RNA -- a nucleic acid similar in structure to DNA. The targeting process requires the CRISPR enzymes to pull apart the DNA strands and insert the RNA to form a sequence-specific structure called an 'R-loop'.
The global team tested the R-loop model using specially modified microscopes in which single DNA molecules are stretched in a magnetic field. By altering the twisting force on the DNA, the researchers could directly monitor R-loop formation events by individual CRISPR enzymes.
This allowed them to reveal previously hidden steps in the process and to probe the influence of the sequence of DNA bases.
Professor Mark Szczelkun, from Bristol University's School of Biochemistry, said: "An important challenge in exploiting these exciting genome editing tools is ensuring that only one specific location in a genome is targeted.
"Our single molecule assays have led to a greater understanding of the influence of DNA sequence on R-loop formation. In the future this will help in the rational re-engineering of CRISPR enzymes to increase their accuracy and minimise off-target effects. This will be vital if we are to ultimately apply these tools to correct genetic diseases in patients."
The work was funded at the University of Bristol by the Biotechnology and Biological Sciences Research Council (BBSRC) and the Wellcome Trust.
The results, published in the Proceedings of the National Academy of Sciences (PNAS), provide a vital piece of the puzzle if these genome editing tools are ultimately going to be used to correct genetic diseases in humans.
CRISPR enzymes were first discovered in bacteria in the 1980s as an immune defence used by bacteria against invading viruses. Scientists have more recently shown that one type of CRISPR enzyme -- Cas9 -- can be used to edit the human genome -- the complete set of genetic information for humans.
These enzymes have been tailored to accurately target a single combination of letters within the three billion base pairs of the DNA molecule. This is the equivalent of correcting a single misspelt word in a 23-volume encyclopaedia.
To find this needle in a haystack, CRISPR enzymes use a molecule of RNA -- a nucleic acid similar in structure to DNA. The targeting process requires the CRISPR enzymes to pull apart the DNA strands and insert the RNA to form a sequence-specific structure called an 'R-loop'.
The global team tested the R-loop model using specially modified microscopes in which single DNA molecules are stretched in a magnetic field. By altering the twisting force on the DNA, the researchers could directly monitor R-loop formation events by individual CRISPR enzymes.
This allowed them to reveal previously hidden steps in the process and to probe the influence of the sequence of DNA bases.
Professor Mark Szczelkun, from Bristol University's School of Biochemistry, said: "An important challenge in exploiting these exciting genome editing tools is ensuring that only one specific location in a genome is targeted.
"Our single molecule assays have led to a greater understanding of the influence of DNA sequence on R-loop formation. In the future this will help in the rational re-engineering of CRISPR enzymes to increase their accuracy and minimise off-target effects. This will be vital if we are to ultimately apply these tools to correct genetic diseases in patients."
The work was funded at the University of Bristol by the Biotechnology and Biological Sciences Research Council (BBSRC) and the Wellcome Trust.
Story Source:
The above story is based on materials provided by University of Bristol. Note: Materials may be edited for content and length.
The above story is based on materials provided by University of Bristol. Note: Materials may be edited for content and length.
Journal Reference:
- Mark D. Szczelkuna, Maria S. Tikhomirovab, Tomas Sinkunasd, Giedrius Gasiunasd, Tautvydas Karvelisd, Patrizia Pscherac, Virginijus Siksnysd and Ralf Seidel. Direct observation of R-loop formation by single RNA-guided Cas9 and Cascade effector complexes. PNAS, May 2014
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