Genome sequencing and functional genes comparison between Sphingopyxis USTB-05 and Sphingomonas morindae NBD5

Abstract

ABSTRACTSphingomonadaceae has a large number of strains that can biodegrade hepatotoxins or environmental pollutants. The latest research reported that certain strains can also produce lutein. Based on the third-generation sequencing technology, we analyzed the whole genome sequence and compared related functional genes of two strains of Sphingomonadaceae isolated from different habitats. The genome of Sphingopyxis USTB-05 was 4,679,489 bp and contained 4312 protein coding genes. The 4,239,716 bp nuclear genome of Sphingomonas morindae NBD5, harboring 3882 protein coding genes, has two sets of chromosomes. Both strains had lutein synthesis metabolism pathway sharing identical synthetic genes of crtB, crtE, crtI, crtQ, crtL, crtR, atoB, dxs, dxr, ispD, ispE, ispDF, gcpE, ispG, ispH, ispA, ispB and ispU. Sphingopyxis USTB-05 had hepatotoxins microcystins and nodularin metabolic pathways related to 16 genes (ald, ansA, gdhA, crnA, phy, ocd, hypdh, spuC, nspC, speE, murI, murD, murC, hmgL, bioA and glsA), while these genes were not found in Sphingomonas morindae NBD5. The unique protein sequences of strain NBD5 and strain USTB-05 were 155 and 199, respectively. The analysis of whole genome of the two Sphingomonadaceae strains provides insights into prokaryote evolution, the new pathway for lutein production and the new genes for environmental pollutant biodegradation.IMPORTANCEUnderstanding the functional genes related to the special functions of strains is essential for humans to utilize microbial resources. The ability of Sphingopyxis USTB-05 to degrade hepatotoxins microcystins and nodularin has been studied in depth, however the complete metabolic process still needs further elucidation. Sphingomonas morindae NBD5 can produce lutein, and it is necessary to determine whether there is a new pathway of lutein. In this study, the whole genome sequencing of Sphingopyxis USTB-05 and Sphingomonas morindae NBD5 were performed for the first time. Lutein synthesis metabolic pathways and synthetic genes were discovered in Sphingomonadaceae. We predicted the existence of new lutein synthesis pathways and revealed most of the genes of the new synthesis pathways. A comparative analysis of the functional genes of the two strains revealed that Sphingopyxis USTB-05 contains a large number of functional genes related to the biodegradation of hepatotoxins or hexachlorocyclohexane. Among them, the functional genes related to the biodegradation and metabolism of hexachlorocyclohexane had not been previously reported. These findings lay the foundation for the biosynthesis of lutein using Sphingomonas morindae NBD5 or Sphingopyxis USTB-05 and the application of Sphingopyxis USTB-05 for the biodegradation of hepatotoxins microcystins and nodularin or environmental pollutants.