BACKGROUND: Actinobacteria form a major bacterial phylum that includes numerous human pathogens. Actinobacteria are primary contributors to carbon cycling and also represent a primary source of industrial high value products such as antibiotics and biopesticides. Consistent with other members of the actinobacterial phylum, Saccharopolyspora erythraea undergo a transitional switch. This switch is characterized by numerous metabolic and morphological changes. RESULTS: We performed RNA sequencing to analyze the transcriptional changes that occur during growth of Saccharopolyspora erythraea in batch culture. By sequencing RNA across the fermentation time course, at a mean coverage of 4000X, we found the vast majority of genes to be prominently expressed, showing that we attained close to saturating sequencing coverage of the transcriptome. During the metabolic switch, global changes in gene expression influence the metabolic machinery of Saccharopolyspora erythraea, resetting an entirely novel gene expression program. After the switch, global changes include the broad repression of half the genes regulated by complex transcriptional mechanisms. Paralogous transposon clusters, delineate these transcriptional programs. The new transcriptional program is orchestrated by a bottleneck event during which mRNA levels are severely restricted by targeted mRNA degradation. CONCLUSIONS: Our results, which attained close to saturating sequencing coverage of the transcriptome, revealed unanticipated transcriptional complexity with almost one third of transcriptional content originating from un-annotated sequences. We showed that the metabolic switch is a sophisticated mechanism of transcriptional regulation capable of resetting and re-synchronizing gene expression programs at extraordinary speed and scale.
BACKGROUND: Actinobacteria form a major bacterial phylum that includes numerous human pathogens. Actinobacteria are primary contributors to carbon cycling and also represent a primary source of industrial high value products such as antibiotics and biopesticides. Consistent with other members of the actinobacterial phylum, Saccharopolyspora erythraea undergo a transitional switch. This switch is characterized by numerous metabolic and morphological changes. RESULTS: We performed RNA sequencing to analyze the transcriptional changes that occur during growth of Saccharopolyspora erythraea in batch culture. By sequencing RNA across the fermentation time course, at a mean coverage of 4000X, we found the vast majority of genes to be prominently expressed, showing that we attained close to saturating sequencing coverage of the transcriptome. During the metabolic switch, global changes in gene expression influence the metabolic machinery of Saccharopolyspora erythraea, resetting an entirely novel gene expression program. After the switch, global changes include the broad repression of half the genes regulated by complex transcriptional mechanisms. Paralogous transposon clusters, delineate these transcriptional programs. The new transcriptional program is orchestrated by a bottleneck event during which mRNA levels are severely restricted by targeted mRNA degradation. CONCLUSIONS: Our results, which attained close to saturating sequencing coverage of the transcriptome, revealed unanticipated transcriptional complexity with almost one third of transcriptional content originating from un-annotated sequences. We showed that the metabolic switch is a sophisticated mechanism of transcriptional regulation capable of resetting and re-synchronizing gene expression programs at extraordinary speed and scale.
Authors: S D Bentley; K F Chater; A-M Cerdeño-Tárraga; G L Challis; N R Thomson; K D James; D E Harris; M A Quail; H Kieser; D Harper; A Bateman; S Brown; G Chandra; C W Chen; M Collins; A Cronin; A Fraser; A Goble; J Hidalgo; T Hornsby; S Howarth; C-H Huang; T Kieser; L Larke; L Murphy; K Oliver; S O'Neil; E Rabbinowitsch; M-A Rajandream; K Rutherford; S Rutter; K Seeger; D Saunders; S Sharp; R Squares; S Squares; K Taylor; T Warren; A Wietzorrek; J Woodward; B G Barrell; J Parkhill; D A Hopwood Journal: Nature Date: 2002-05-09 Impact factor: 49.962
Authors: Pavel A Zhulidov; Ekaterina A Bogdanova; Alex S Shcheglov; Laura L Vagner; George L Khaspekov; Valery B Kozhemyako; Mikhail V Matz; Ella Meleshkevitch; Leonid L Moroz; Sergey A Lukyanov; Dmitry A Shagin Journal: Nucleic Acids Res Date: 2004-02-18 Impact factor: 16.971
Authors: Cuauhtemoc Licona-Cassani; Pablo Cruz-Morales; Angel Manteca; Francisco Barona-Gomez; Lars K Nielsen; Esteban Marcellin Journal: Front Bioeng Biotechnol Date: 2015-12-09
Authors: Esteban Marcellin; Cuauhtemoc Licona-Cassani; Tim R Mercer; Robin W Palfreyman; Lars K Nielsen Journal: BMC Genomics Date: 2013-10-11 Impact factor: 3.969
Authors: Carlos H Luna-Flores; Chris C Stowers; Brad M Cox; Lars K Nielsen; Esteban Marcellin Journal: Biotechnol Biofuels Date: 2018-08-13 Impact factor: 6.040
Authors: Benjamin Kirm; Vasilka Magdevska; Miha Tome; Marinka Horvat; Katarina Karničar; Marko Petek; Robert Vidmar; Spela Baebler; Polona Jamnik; Štefan Fujs; Jaka Horvat; Marko Fonovič; Boris Turk; Kristina Gruden; Hrvoje Petković; Gregor Kosec Journal: Microb Cell Fact Date: 2013-12-17 Impact factor: 5.328
Authors: Katarina Karničar; Igor Drobnak; Marko Petek; Vasilka Magdevska; Jaka Horvat; Robert Vidmar; Špela Baebler; Ana Rotter; Polona Jamnik; Štefan Fujs; Boris Turk; Marko Fonovič; Kristina Gruden; Gregor Kosec; Hrvoje Petković Journal: Microb Cell Fact Date: 2016-06-03 Impact factor: 5.328
Authors: Tim McCubbin; R Axayacatl Gonzalez-Garcia; Robin W Palfreyman; Chris Stowers; Lars K Nielsen; Esteban Marcellin Journal: Genes (Basel) Date: 2020-09-23 Impact factor: 4.096