Insights into lignocellulose degradation: comparative genomics of anaerobic and cellulolytic Ruminiclostridium-type species.

Mesophilic, anaerobic, and cellulolytic Ruminiclostridium-type bacterial species can secrete an extracellular, multi-enzyme machinery cellulosome, which efficiently degrades cellulose. In this study, we first reported the complete genome of Ruminiclostridium papyrosolvens DSM2782, a single circular 5,027,861-bp chromosome with 37.1% G + C content, and compared it with other Ruminiclostridium-type species. Pan-genome analysis showed that Ruminiclostridium-type species share a large number of core genes to conserve basic functions, although they have a high level of intraspecific genetic diversity. Especially, KEGG mapping revealed that Ruminiclostridium-type species mainly use ABC transporters regulated by two-component systems (TCSs) to absorb extracellular sugars but not phosphotransferase systems (PTSs) that are employed by solventogenic clostridia, such as Clostridium acetobutylicum. Furthermore, we performed comparative analyses of the species-specific repertoire of CAZymes for each of the Ruminiclostridium-type species. The high similarity of their cohesins suggests a common ancestor and potential cross-species recognition. Additionally, both differences between the C-terminal cohesins and other cohesins of scaffoldins and between the dockerins linking with cellulases and other catalytic domains indicate a preference for the location of cellulosomal catalytic subunits at scaffoldins. The information gained in this study may be utilized directly or developed further by genetic engineering and optimizing enzyme systems or cell factories for enhanced biotechnological biomass deconstruction and biofuel production.

Development of an efficient ClosTron system for gene disruption in Ruminiclostridium papyrosolvens.

Ruminiclostridium papyrosolvens is an anaerobic, mesophilic, and cellulolytic clostridia, promising consolidated bioprocessing (CBP) candidate for producing renewable green chemicals from cellulose, but its metabolic engineering is limited by lack of genetic tools. Here, we firstly employed the endogenous xylan-inducible promoter to control ClosTron system for gene disruption of R. papyrosolvens. The modified ClosTron can be easily transformed into R. papyrosolvens and specifically disrupt targeting genes. Furthermore, a counter selectable system based on uracil phosphoribosyl-transferase (Upp) was successfully established and introduced into the ClosTron system, which resulted in plasmid curing rapidly. Thus, the combination of xylan-inducible ClosTron and upp-based counter selectable system makes the gene disruption more efficient and convenient for successive gene disruption in R. papyrosolvens. KEY POINTS: • Limiting expression of LtrA enhanced the transformation of ClosTron plasmids in R. papyrosolvens. • DNA targeting specificity can be improved by precise management of the expression of LtrA. • Curing of ClosTron plasmids was achieved by introducing the upp-based counter selectable system.

Internal Transcription Terminators Control Stoichiometry of ABC Transporters in Cellulolytic Clostridia.

The extracellular substrate-binding proteins (SBPs) of ATP-binding cassette (ABC) importers tend to be expressed in excess relative to their cognate translocators, but how the stoichiometry of ABC transporters is controlled remains unclear. Here, we elucidated a mechanism contributing to differential gene expression in operons encoding ABC importers by employing cellulolytic Clostridia species, specifically Ruminiclostridium cellulolyticum. We found that there were usually stem-loop structures downstream of SBP genes, which could prematurely terminate the transcription of ABC importers and were putative internal intrinsic terminators, resulting in high transcript levels of upstream SBP genes and low transcript levels of downstream cognate translocator genes. This was determined by their termination efficiencies. Internal terminators had a lower U content in their 3' U-rich tracts and longer GC-rich stems, which distinguishes them from canonical terminators and potentially endows them with special termination efficiencies. The pairing of U-rich tracts and the formation of unpaired regions in these internal terminators contributed to their folding energies, affecting the stability of their upstream SBP transcripts. Our findings revealed a strategy of internal transcriptional terminators controlling in vivo stoichiometry of their flanking transcripts. IMPORTANCE Operons encoding protein complexes or metabolic pathways usually require fine-tuned gene expression ratios to create and maintain the appropriate stoichiometry for biological functions. In this study, a strategy for controlling differential expression of genes in an operon was proposed by utilizing ABC importers from Ruminiclostridium cellulolyticum. We found that a stem-loop structure is introduced into the intergenic regions of operons encoding ABC importers as the putative internal terminator, which results in the premature termination of transcription. Consequently, the stoichiometric ratio of genes flanking terminators is precisely determined by their termination efficiencies and folding energies at the transcriptional level. Thus, it can be utilized as a promising synthetic biology tool to control the differential expression of genes in an operon.