LoFreq detects
single-nucleotide variants of E. coli bacteria with greater sensitivity than
competing programs.
A
new computer program readily identifies rare mutations harbored within diverse
populations of cancer cells and microorganisms
A tumor is not a uniform mass of identical cells.
However, teasing apart genetic heterogeneity within a biopsied tumor can be
difficult. Researchers often fail to tell the difference between a rare variant
in a DNA dataset or a small error because of imprecision in existing
high-throughput sequencing technologies.
Now, a new computer program developed at A*STAR could
help. Thanks to open-source software called LoFreq — so-called because it can
detect mutations at extremely LOw FREQuencies — researchers can reliably pick
out rare subpopulations of cells from heterogeneous populations of cancer
cells, microorganisms and other biological samples1.
“This is key to a wide range of scientific
investigations, from understanding how pathogens evolve and escape the immune
system, to uncovering the processes through which cancers grow and spread,”
says Niranjan Nagarajan, a senior scientist at the A*STAR Genome Institute of
Singapore, who helped to develop the program.
Nagarajan and his co-workers wrote the algorithm that
forms the foundations of LoFreq. Their aim was for the software not only to
adapt to sequencing biases, but also to detect single DNA differences with
frequencies below the specific level of noise introduced by sequencing errors.
The researchers first tested the program against existing computer programs for
analyzing large DNA datasets using simulated sequences from dengue virus. They
then validated the approach using real genomic libraries from samples of
Escherichia coli bacteria (see image), human gastric cancer biopsies, and
dengue viruses collected before and after antiviral drug treatment — an
exposure that often leads to the evolution of drug resistance in some
subpopulations of virus.
“Previous attempts to describe this evolution have had
to wait for the selection process to near completion,” Nagarajan says. “In this
new work, we have greatly increased the sensitivity of detecting these
mutations and thus can catch their evolution in ‘real time’, observing how this
process develops.”
LoFreq proved itself to have near-perfect specificity
for rare variants, with significantly improved sensitivity compared to existing
methods, regardless of the high-throughput sequencing platform. The method also
pinpointed a handful of low-frequency polymorphisms in whole-genome readouts
from individual gastric cancer patients, and flagged mutational hotspots in
dengue samples from a clinical drug trial.
“Almost anybody who is interested in studying
evolutionary processes at a higher resolution, ranging from researchers who
study how viruses and bacteria evolve and become more pathogenic, to cancer
scientists looking at the evolution of a tumor,” could benefit from LoFreq,
Nagarajan says. The software is freely available via this link.
The A*STAR-affiliated researchers contributing to this
research are from the Genome
Institute of Singapore
References
- Wilm, A., Aw, P. P. K., Bertrand, D., Yeo, G. H. T., Ong, S.
H. et al. LoFreq: a sequence-quality aware, ultra-sensitive
variant caller for uncovering cell-population heterogeneity from
high-throughput sequencing datasets.Nucleic Acids Research 40, 11189–11201
(2012). | article
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