dbCAN-PUL

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	PUL0386
PubMed	20013800, Proteomics. 2010 Feb;10(3):541-54. doi: 10.1002/pmic.200900311.
Characterization method	ion trap liquid chromatography,mass spectrometry,target decoy database analysis,high performance anion exchange chromatography
Genomic accession number	NC_011898.1
Nucelotide position range	1505662-1529139
Substrate	hemicellulose
Loci	CCEL_RS06160-CCEL_RS06210
Species	Ruminiclostridium cellulolyticum/1521
Degradation or Biosynthesis	degradation

Gene Name	Locus Tag	Protein ID	Gene Position	GenBank Contig Range	EC Number
-	CCEL_RS06160	WP_015924734.1	0 - 1608 (+)	NC_011898.1:1505662-1507270	-
-	CCEL_RS06165	WP_015924735.1	1713 - 3339 (+)	NC_011898.1:1507375-1509001	-
-	CCEL_RS06170	WP_015924736.1	3406 - 4981 (+)	NC_011898.1:1509068-1510643	-
-	CCEL_RS06175	WP_015924737.1	5003 - 6476 (+)	NC_011898.1:1510665-1512138	-
-	CCEL_RS06180	WP_015924738.1	6551 - 8792 (+)	NC_011898.1:1512213-1514454	-
-	CCEL_RS06185	WP_015924739.1	8875 - 10486 (+)	NC_011898.1:1514537-1516148	-
-	CCEL_RS06190	WP_015924740.1	10560 - 12090 (+)	NC_011898.1:1516222-1517752	-
-	CCEL_RS06195	WP_015924741.1	12178 - 15046 (+)	NC_011898.1:1517840-1520708	-
-	CCEL_RS06200	WP_015924742.1	15154 - 16969 (+)	NC_011898.1:1520816-1522631	-
-	CCEL_RS06205	WP_015924743.1	16998 - 20367 (+)	NC_011898.1:1522660-1526029	-
-	CCEL_RS06210	WP_015924744.1	20430 - 23478 (+)	NC_011898.1:1526092-1529140	-

Cluster number	0
Gene name	Gene position	Gene type	Found by CGCFinder?
-	1 - 1608 (+)	CAZyme: GH43\|CBM6\|GH43_16	No
-	1714 - 3339 (+)	CAZyme: GH10\|CBM6	No
-	3407 - 4981 (+)	CAZyme: GH43_29\|GH43\|CBM6	No
-	5004 - 6476 (+)	CAZyme: CE1\|CBM6	No
-	6552 - 8792 (+)	CAZyme: GH43_10\|CBM6	No
-	8876 - 10486 (+)	CAZyme: GH62\|CBM6	No
-	10561 - 12090 (+)	CAZyme: GH43_29\|GH43\|CBM6	No
-	12179 - 15046 (+)	CAZyme: GH146\|CBM22	No
-	15155 - 16969 (+)	CAZyme: GH27\|CBM6	No
-	16999 - 20367 (+)	CAZyme: GH59\|CBM6	No
-	20431 - 23478 (+)	CAZyme: GH2\|CBM6	No

PUL ID	PUL0386
PubMed	20013800, Proteomics. 2010 Feb;10(3):541-54. doi: 10.1002/pmic.200900311.
Title	Modulation of cellulosome composition in Clostridium cellulolyticum: adaptation to the polysaccharide environment revealed by proteomic and carbohydrate-active enzyme analyses.
Author	Blouzard JC, Coutinho PM, Fierobe HP, Henrissat B, Lignon S, Tardif C, Pages S, de Philip P
Abstract	Clostridium cellulolyticum is a model mesophilic anaerobic bacterium that efficiently degrades plant cell walls. The recent genome release offers the opportunity to analyse its complete degradation system. A total of 148 putative carbohydrate-active enzymes were identified, and their modular structures and activities were predicted. Among them, 62 dockerin-containing proteins bear catalytic modules from numerous carbohydrate-active enzymes' families and whose diversity reflects the chemical and structural complexity of the plant carbohydrate. The composition of the cellulosomes produced by C. cellulolyticum upon growth on different substrates (cellulose, xylan, and wheat straw) was investigated by LC MS/MS. The majority of the proteins encoded by the cip-cel operon, essential for cellulose degradation, were detected in all cellulosome preparations. In the presence of wheat straw, the natural and most complex of the substrates studied, additional proteins predicted to be involved in hemicellulose degradation were produced. A 32-kb gene cluster encodes the majority of these proteins, all harbouring carbohydrate-binding module 6 or carbohydrate-binding module 22 xylan-binding modules along dockerins. This newly identified xyl-doc gene cluster, specialised in hemicellulose degradation, comes in addition of the cip-cel operon for plant cell wall degradation. Hydrolysis efficiencies determined on the different substrates corroborates the finding that cellulosome composition is adapted to the growth substrate.

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