The University of Adelaide has developed a new software tool with enhanced genome-sequencing powers, increasing the speed and accuracy at which researchers can improve plants through breeding.
These improvements will allow farmers to grow more resilient crops in a dynamically changing climate and landscape.
Called CoreDetector, the tool was created to efficiently handle more computationally challenging genome-sequencing tasks, such as aligning large and evolutionary diverse genomes of plants.
“Whole genome alignment of species remains an important method for determining structural and sequence variations of populations,” said the University of Adelaide’s Dr Julian Taylor, who co-led the project.
“There are few tools which have the functionality to handle large and evolutionary diverse genomes, but CoreDetector harnesses the power of computational parallelisation to undertake the cumbersome task of pairwise sequence alignment between population member genomes.
“The tool can be applied to a wide range of species – from kilobyte bacteria genomes to gigabyte plant genomes, like wheat – and even supports diploid organisms, such as human and other animals.”
This will have immediate benefit for the plant pre-breeding and breeding research community, especially those working with more complex plant genomes.
The software is a java-based and easily transportable between operating systems.
“As high-throughput sequence technologies become more advanced and more species can be sequenced, we believe free access to CoreDetector will continue to allow rapid advancement in genetic research of diverse populations,” said the University’s Dr Fruzangohar, who also co-led the project.
“This will provide an efficient genome sequence analysis tool to plant breeders and researchers, which can form a component of an analytical pipeline for improving our genetic understanding of biological organisms.”
Dr Taylor and Dr Fruzangohar are members of the Biometry Hub, within the University’s School of Agriculture, Food and Wine.
The Hub was established to provide a space for researchers to collaboratively develop statistical models and computational tools, like CoreDetector, to answer industry-relevant biological questions.
Although CoreDetector was only recently made publicly available, Dr Taylor and Dr Fruzangohar are already working on the next iteration of the technology.
“We aim to extend CoreDetector’s theoretical and computational framework to obtain the core-genome plus accessory sequences of a population. This complete set of sequences is known as the pan-genome,” said Dr Taylor.
“We plan to collaborate with other bioinformaticians from external organisations linked to pan-genome research and develop a state-of-the-art heuristic algorithm to efficiently construct pan-genomes of populations.”
- Link to research (DOI): 10.1093/bioinformatics/btad628