glycosyltransferase family 1 (GT1) protein catalyzes the transfer of sugar moieties from activated donor molecules to specific acceptor molecules, forming glycosidic bonds; similar to Streptococcus oralis rhamnosyltransferase
glycosyltransferase family 4 proteins; This family is most closely related to the GT4 family ...
3-381
0e+00
glycosyltransferase family 4 proteins; This family is most closely related to the GT4 family of glycosyltransferases. Glycosyltransferases catalyze the transfer of sugar moieties from activated donor molecules to specific acceptor molecules, forming glycosidic bonds. The acceptor molecule can be a lipid, a protein, a heterocyclic compound, or another carbohydrate residue. This group of glycosyltransferases is most closely related to the previously defined glycosyltransferase family 1 (GT1). The members of this family may transfer UDP, ADP, GDP, or CMP linked sugars. The diverse enzymatic activities among members of this family reflect a wide range of biological functions. The protein structure available for this family has the GTB topology, one of the two protein topologies observed for nucleotide-sugar-dependent glycosyltransferases. GTB proteins have distinct N- and C- terminal domains each containing a typical Rossmann fold. The two domains have high structural homology despite minimal sequence homology. The large cleft that separates the two domains includes the catalytic center and permits a high degree of flexibility. The members of this family are found in certain bacteria and Archaea.
:
Pssm-ID: 340858 [Multi-domain] Cd Length: 379 Bit Score: 586.78 E-value: 0e+00
glycosyltransferase family 4 proteins; This family is most closely related to the GT4 family ...
3-381
0e+00
glycosyltransferase family 4 proteins; This family is most closely related to the GT4 family of glycosyltransferases. Glycosyltransferases catalyze the transfer of sugar moieties from activated donor molecules to specific acceptor molecules, forming glycosidic bonds. The acceptor molecule can be a lipid, a protein, a heterocyclic compound, or another carbohydrate residue. This group of glycosyltransferases is most closely related to the previously defined glycosyltransferase family 1 (GT1). The members of this family may transfer UDP, ADP, GDP, or CMP linked sugars. The diverse enzymatic activities among members of this family reflect a wide range of biological functions. The protein structure available for this family has the GTB topology, one of the two protein topologies observed for nucleotide-sugar-dependent glycosyltransferases. GTB proteins have distinct N- and C- terminal domains each containing a typical Rossmann fold. The two domains have high structural homology despite minimal sequence homology. The large cleft that separates the two domains includes the catalytic center and permits a high degree of flexibility. The members of this family are found in certain bacteria and Archaea.
Pssm-ID: 340858 [Multi-domain] Cd Length: 379 Bit Score: 586.78 E-value: 0e+00
Domain of unknown function (DUF1972); Members of this family of functionally uncharacterized ...
1-185
1.43e-112
Domain of unknown function (DUF1972); Members of this family of functionally uncharacterized domains are found in bacterial glycosyltransferases and rhamnosyltransferases.
Pssm-ID: 430520 Cd Length: 186 Bit Score: 326.36 E-value: 1.43e-112
glycosyltransferase family 4 proteins; This family is most closely related to the GT4 family ...
3-381
0e+00
glycosyltransferase family 4 proteins; This family is most closely related to the GT4 family of glycosyltransferases. Glycosyltransferases catalyze the transfer of sugar moieties from activated donor molecules to specific acceptor molecules, forming glycosidic bonds. The acceptor molecule can be a lipid, a protein, a heterocyclic compound, or another carbohydrate residue. This group of glycosyltransferases is most closely related to the previously defined glycosyltransferase family 1 (GT1). The members of this family may transfer UDP, ADP, GDP, or CMP linked sugars. The diverse enzymatic activities among members of this family reflect a wide range of biological functions. The protein structure available for this family has the GTB topology, one of the two protein topologies observed for nucleotide-sugar-dependent glycosyltransferases. GTB proteins have distinct N- and C- terminal domains each containing a typical Rossmann fold. The two domains have high structural homology despite minimal sequence homology. The large cleft that separates the two domains includes the catalytic center and permits a high degree of flexibility. The members of this family are found in certain bacteria and Archaea.
Pssm-ID: 340858 [Multi-domain] Cd Length: 379 Bit Score: 586.78 E-value: 0e+00
Domain of unknown function (DUF1972); Members of this family of functionally uncharacterized ...
1-185
1.43e-112
Domain of unknown function (DUF1972); Members of this family of functionally uncharacterized domains are found in bacterial glycosyltransferases and rhamnosyltransferases.
Pssm-ID: 430520 Cd Length: 186 Bit Score: 326.36 E-value: 1.43e-112
phosphatidyl-myo-inositol mannosyltransferase; This family is most closely related to the GT4 ...
3-380
2.86e-13
phosphatidyl-myo-inositol mannosyltransferase; This family is most closely related to the GT4 family of glycosyltransferases and named after PimA in Propionibacterium freudenreichii, which is involved in the biosynthesis of phosphatidyl-myo-inositol mannosides (PIM) which are early precursors in the biosynthesis of lipomannans (LM) and lipoarabinomannans (LAM), and catalyzes the addition of a mannosyl residue from GDP-D-mannose (GDP-Man) to the position 2 of the carrier lipid phosphatidyl-myo-inositol (PI) to generate a phosphatidyl-myo-inositol bearing an alpha-1,2-linked mannose residue (PIM1). Glycosyltransferases catalyze the transfer of sugar moieties from activated donor molecules to specific acceptor molecules, forming glycosidic bonds. The acceptor molecule can be a lipid, a protein, a heterocyclic compound, or another carbohydrate residue. This group of glycosyltransferases is most closely related to the previously defined glycosyltransferase family 1 (GT1). The members of this family may transfer UDP, ADP, GDP, or CMP linked sugars. The diverse enzymatic activities among members of this family reflect a wide range of biological functions. The protein structure available for this family has the GTB topology, one of the two protein topologies observed for nucleotide-sugar-dependent glycosyltransferases. GTB proteins have distinct N- and C- terminal domains each containing a typical Rossmann fold. The two domains have high structural homology despite minimal sequence homology. The large cleft that separates the two domains includes the catalytic center and permits a high degree of flexibility. The members of this family are found mainly in certain bacteria and archaea.
Pssm-ID: 340831 [Multi-domain] Cd Length: 366 Bit Score: 70.26 E-value: 2.86e-13
glycosyltransferases MtfB, WbpX, and similar proteins; This family is most closely related to ...
6-371
3.13e-07
glycosyltransferases MtfB, WbpX, and similar proteins; This family is most closely related to the GT4 family of glycosyltransferases. MtfB (mannosyltransferase B) in E. coli has been shown to direct the growth of the O9-specific polysaccharide chain. It transfers two mannoses into the position 3 of the previously synthesized polysaccharide.
Pssm-ID: 340838 [Multi-domain] Cd Length: 362 Bit Score: 51.60 E-value: 3.13e-07
Escherichia coli WbuB and similar proteins; This family is most closely related to the GT1 ...
3-377
2.25e-05
Escherichia coli WbuB and similar proteins; This family is most closely related to the GT1 family of glycosyltransferases. WbuB in E. coli is involved in the biosynthesis of the O26 O-antigen. It has been proposed to function as an N-acetyl-L-fucosamine (L-FucNAc) transferase.
Pssm-ID: 340825 [Multi-domain] Cd Length: 391 Bit Score: 46.18 E-value: 2.25e-05
Brucella melitensis Bme6 and similar proteins; This family is most closely related to the GT4 ...
134-378
2.08e-03
Brucella melitensis Bme6 and similar proteins; This family is most closely related to the GT4 family of glycosyltransferases. Bme6 in Brucella melitensis has been shown to be involved in the biosynthesis of a polysaccharide.
Pssm-ID: 340848 [Multi-domain] Cd Length: 377 Bit Score: 40.04 E-value: 2.08e-03
glycosyltransferase family 1 and related proteins with GTB topology; Glycosyltransferases ...
142-309
2.63e-03
glycosyltransferase family 1 and related proteins with GTB topology; Glycosyltransferases catalyze the transfer of sugar moieties from activated donor molecules to specific acceptor molecules, forming glycosidic bonds. The acceptor molecule can be a lipid, a protein, a heterocyclic compound, or another carbohydrate residue. The structures of the formed glycoconjugates are extremely diverse, reflecting a wide range of biological functions. The members of this family share a common GTB topology, one of the two protein topologies observed for nucleotide-sugar-dependent glycosyltransferases. GTB proteins have distinct N- and C- terminal domains each containing a typical Rossmann fold. The two domains have high structural homology despite minimal sequence homology. The large cleft that separates the two domains includes the catalytic center and permits a high degree of flexibility.
Pssm-ID: 340816 [Multi-domain] Cd Length: 235 Bit Score: 38.92 E-value: 2.63e-03
mannosyltransferase WbaZ and similar proteins; This family is most closely related to the GT4 ...
196-308
6.78e-03
mannosyltransferase WbaZ and similar proteins; This family is most closely related to the GT4 family of glycosyltransferases. WbaZ in Salmonella enterica has been shown to possess mannosyltransferase activity.
Pssm-ID: 340833 [Multi-domain] Cd Length: 356 Bit Score: 38.03 E-value: 6.78e-03
Database: CDSEARCH/cdd Low complexity filter: no Composition Based Adjustment: yes E-value threshold: 0.01
References:
Wang J et al. (2023), "The conserved domain database in 2023", Nucleic Acids Res.51(D)384-8.
Lu S et al. (2020), "The conserved domain database in 2020", Nucleic Acids Res.48(D)265-8.
Marchler-Bauer A et al. (2017), "CDD/SPARCLE: functional classification of proteins via subfamily domain architectures.", Nucleic Acids Res.45(D)200-3.
of the residues that compose this conserved feature have been mapped to the query sequence.
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Functional characterization of the conserved domain architecture found on the query.
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This image shows a graphical summary of conserved domains identified on the query sequence.
The Show Concise/Full Display button at the top of the page can be used to select the desired level of detail: only top scoring hits
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Domains are color coded according to superfamilies
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if a domain or superfamily has been annotated with functional sites (conserved features),
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click on the bars or triangles to view your query sequence embedded in a multiple sequence alignment of the proteins used to develop the corresponding domain model.
The table lists conserved domains identified on the query sequence. Click on the plus sign (+) on the left to display full descriptions, alignments, and scores.
Click on the domain model's accession number to view the multiple sequence alignment of the proteins used to develop the corresponding domain model.
To view your query sequence embedded in that multiple sequence alignment, click on the colored bars in the Graphical Summary portion of the search results page,
or click on the triangles, if present, that represent functional sites (conserved features)
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Concise Display shows only the best scoring domain model, in each hit category listed below except non-specific hits, for each region on the query sequence.
(labeled illustration) Standard Display shows only the best scoring domain model from each source, in each hit category listed below for each region on the query sequence.
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(labeled illustration) Four types of hits can be shown, as available,
for each region on the query sequence:
specific hits meet or exceed a domain-specific e-value threshold
(illustrated example)
and represent a very high confidence that the query sequence belongs to the same protein family as the sequences use to create the domain model
non-specific hits
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the domain superfamily to which the specific and non-specific hits belong
multi-domain models that were computationally detected and are likely to contain multiple single domains
Retrieve proteins that contain one or more of the domains present in the query sequence, using the Conserved Domain Architecture Retrieval Tool
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