Persistent Memory as an Effective Alternative to Random Access Memory in Metagenome Assembly

Abstract

ABSTRACTThe assembly of metagenomes decomposes members of complex microbe communities and allows the characterization of these genomes without laborious cultivation or single-cell metagenomics. Metagenome assembly is a process that is memory intensive and time consuming. Multi-terabyte sequences can become too large to be assembled on a single computer node, and there is no reliable method to predict the memory requirement due to data-specific memory consumption pattern. Currently, out-ofmemory (OOM) is one of the most prevalent factors that accounts for metagenome assembly failures. In this study, we explored the possibility of using Persistent Memory (PMem) as a less expensive substitute for dynamic random access memory (DRAM) to reduce OOM and increase the scalability of metagenome assemblers. We evaluated the execution time and memory usage of three popular metagenome assemblers (MetaSPAdes, MEGAHIT, and MetaHipMer2) in datasets up to one terabase. We found that PMem can enable metagenome assemblers on terabyte-sized datasets by partially or fully substituting DRAM at a cost of longer running times. In addition, different assemblers displayed distinct memory/speed trade-offs in the same hardware/software environment. Because PMem was provided directly without any application-specific code modification, these findings are likely to be generalized to other memory-intensive bioinformatics applications.