Because CGCFinder predicted no CGC for this PUL, the gene cluster depicted below contains dbCAN2 and CGC signature predictions for all genes in the PUL, instead of a predicted CGC.


PUL ID

PUL0313

PubMed

28983288, Front Microbiol. 2017 Sep 21;8:1808. doi: 10.3389/fmicb.2017.01808. eCollection 2017.
32585009, Nucleic Acids Res. 2020 Aug 20;48(14):7786-7800. doi: 10.1093/nar/gkaa533.

Characterization method

microarray,Northern Blot,RT-qPCR,electrophoretic mobility shift assay,clone and expression,gene deletion mutant and growth assay

Genomic accession number

FP476056.1

Nucelotide position range

4847515-4853424

Substrate

alginate

Loci

ZOBELLIA_4130-ZOBELLIA_4132

Species

Zobellia galactanivorans/63186

Degradation or Biosynthesis

degradation

Gene Name

Locus Tag

Protein ID

Gene Position

GenBank Contig Range

EC Number

alyA4 ZOBELLIA_4130 CAZ98265.1 0 - 2352 (+) FP476056.1:4847515-4849867 4.2.2.3
alyA5 ZOBELLIA_4131 CAZ98266.1 2368 - 3427 (+) FP476056.1:4849883-4850942 4.2.2.3
alyA6 ZOBELLIA_4132 CAZ98267.1 3576 - 5910 (+) FP476056.1:4851091-4853425 4.2.2.3

Cluster number

0

Gene name

Gene position

Gene type

Found by CGCFinder?

alyA4 1 - 2352 (+) CAZyme: PL6|PL6_1 No
alyA5 2369 - 3427 (+) CAZyme: PL7_5|PL7 No
alyA6 3577 - 5910 (+) CAZyme: PL6|PL6_1 No

PUL ID

PUL0313

PubMed

28983288, Front Microbiol. 2017 Sep 21;8:1808. doi: 10.3389/fmicb.2017.01808. eCollection 2017.

Title

Gene Expression Analysis of Zobellia galactanivorans during the Degradation of Algal Polysaccharides Reveals both Substrate-Specific and Shared Transcriptome-Wide Responses.

Author

Thomas F, Bordron P, Eveillard D, Michel G

Abstract

Flavobacteriia are recognized as key players in the marine carbon cycle, due to their ability to efficiently degrade algal polysaccharides both in the open ocean and in coastal regions. The chemical complexity of algal polysaccharides, their differences between algal groups and variations through time and space, imply that marine flavobacteria have evolved dedicated degradation mechanisms and regulation of their metabolism during interactions with algae. In the present study, we report the first transcriptome-wide gene expression analysis for an alga-associated flavobacterium during polysaccharide degradation. Zobellia galactanivorans Dsij(T), originally isolated from a red alga, was grown in minimal medium with either glucose (used as a reference monosaccharide) or one selected algal polysaccharide from brown (alginate, laminarin) or red algae (agar, porphyran, iota- or kappa-carrageenan) as sole carbon source. Expression profiles were determined using whole-genome microarrays. Integration of genomic knowledge with the automatic building of a co-expression network allowed the experimental validation of operon-like transcription units. Differential expression analysis revealed large transcriptomic shifts depending on the carbon source. Unexpectedly, transcriptomes shared common signatures when growing on chemically divergent polysaccharides from the same algal phylum. Together with the induction of numerous transcription factors, this hints at complex regulation events that fine-tune the cell behavior during interactions with algal biomass in the marine environment. The results further highlight genes and loci that may participate in polysaccharide utilization, notably encoding Carbohydrate Active enZymes (CAZymes) and glycan binding proteins together with a number of proteins of unknown function. This constitutes a set of candidate genes potentially representing new substrate specificities. By providing an unprecedented view of global transcriptomic responses during polysaccharide utilization in an alga-associated model flavobacterium, this study expands the current knowledge on the functional role of flavobacteria in the marine carbon cycle and on their interactions with algae.

PubMed

32585009, Nucleic Acids Res. 2020 Aug 20;48(14):7786-7800. doi: 10.1093/nar/gkaa533.

Title

Regulation of alginate catabolism involves a GntR family repressor in the marine flavobacterium Zobellia galactanivorans DsijT.

Author

Dudek M, Dieudonne A, Jouanneau D, Rochat T, Michel G, Sarels B, Thomas F

Abstract

Marine flavobacteria possess dedicated Polysaccharide Utilization Loci (PULs) enabling efficient degradation of a variety of algal polysaccharides. The expression of these PULs is tightly controlled by the presence of the substrate, yet details on the regulatory mechanisms are still lacking. The marine flavobacterium Zobellia galactanivorans DsijT digests many algal polysaccharides, including alginate from brown algae. Its complex Alginate Utilization System (AUS) comprises a PUL and several other loci. Here, we showed that the expression of the AUS is strongly and rapidly (<30 min) induced upon addition of alginate, leading to biphasic substrate utilization. Polymeric alginate is first degraded into smaller oligosaccharides that accumulate in the extracellular medium before being assimilated. We found that AusR, a GntR family protein encoded within the PUL, regulates alginate catabolism by repressing the transcription of most AUS genes. Based on our genetic, genomic, transcriptomic and biochemical results, we propose the first model of regulation for a PUL in marine bacteria. AusR binds to promoters of AUS genes via single, double or triple copies of operator. Upon addition of alginate, secreted enzymes expressed at a basal level catalyze the initial breakdown of the polymer. Metabolic intermediates produced during degradation act as effectors of AusR and inhibit the formation of AusR/DNA complexes, thus lifting transcriptional repression.