Abstract
Myxococcus xanthus DZ2, a model myxobacterium, has three reported genome assemblies, including two recent complete assemblies (MxDZ2_Tam and MxDZ2_Nan) from the same culture stock. These assemblies misreported their circular nature and differed by 6.4 kb, raising questions about their accuracy. After removing duplicate ends, aligning genomes to the origin of replication, and circularization, this computational analysis revealed a minimal 32 bp difference, with MxDZ2_Tam being slightly larger. Forty sequence variations including 38 indels and two substitutions, were impacting 18 coding genes via frameshift mutations. Although PacBio-HiFi technology boasts a low error rate, it remains higher than the 454-platform used for the earlier MxDZ2_Kirby draft assembly. Therefore, using MxDZ2_Kirby as a reference, we constructed a "truly circular" genome for M. xanthus DZ2. Additionally, analysis of Mx-alpha regions, involved in antagonism via the toxin gene sitA, across 61 myxobacterial genomes identified their presence in five taxonomically polyphyletic species, potentially influencing their physiology, development, and ecological interactions beyond predation. Only M. xanthus DZ2 and DZF1 contained all three Mx-alpha regions, whereas M. xanthus DK1622 has only one. Overall, this study underscores the need for meticulous validation of sequencing-based genome assemblies and their variations and provides novel insights into Mx-alpha regions as potential adaptive elements in myxobacteria.