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Difference between revisions of "Glycoside Hydrolase Family 48"

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The structure of the catalytic module of Cel48S of ''C. thermocellum'' showed a similar tunnel-shaped substrate-binding region formed by the alpha helices in the protein. The hydrolysis of the cellulose chain in Cel48S appeared to involve Glu87 (the equivalent of Glu55 in ''C. cellulolyticum'' Cel48F) as an acid to protonate the glycosidic oxygen atom and Tyr351 as a base to extract a proton from the nucleophilic water molecule that attacks the anomeric carbon atom. More recent studies of Cel48F failed to unambiguously identity the catalytic base in the cleavage reaction <cite>Parsiegla2008</cite>.
 
The structure of the catalytic module of Cel48S of ''C. thermocellum'' showed a similar tunnel-shaped substrate-binding region formed by the alpha helices in the protein. The hydrolysis of the cellulose chain in Cel48S appeared to involve Glu87 (the equivalent of Glu55 in ''C. cellulolyticum'' Cel48F) as an acid to protonate the glycosidic oxygen atom and Tyr351 as a base to extract a proton from the nucleophilic water molecule that attacks the anomeric carbon atom. More recent studies of Cel48F failed to unambiguously identity the catalytic base in the cleavage reaction <cite>Parsiegla2008</cite>.
  
A recent experimental study in ''Thermobifida fusca'' Cel48A confirmed that aspartic acid (Asp225) is the catalytic base in family 48 glycosyl hydrolases <cite>Kostylev2011</cite>. This residue is equivalent to D230 of ''C. cellulolyticum'' Cel48F and D255 of ''C. thermocellum'' Cel48S. In this study, site-directed mutagenesis demonstrated that the D225E mutation retained partial activity on soluble and insoluble substrates. Azide rescue hydrolysis assays showed that the D225G mutation restored its activity with added azide.
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A recent experimental study in ''Thermobifida fusca'' Cel48A confirmed that aspartic acid (Asp225) is the catalytic base in family 48 glycoside hydrolases <cite>Kostylev2011</cite>. This residue is equivalent to D230 of ''C. cellulolyticum'' Cel48F and D255 of ''C. thermocellum'' Cel48S. In this study, site-directed mutagenesis demonstrated that the D225E mutation retained partial activity on soluble and insoluble substrates. Azide rescue hydrolysis assays showed that the D225G mutation restored its activity with added azide.
  
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==

Latest revision as of 13:20, 18 December 2021

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Glycoside Hydrolase Family GH48
Clan GH-M
Mechanism inverting
Active site residues Proton donor: known;
Nucleophile: unknown
CAZy DB link
https://www.cazy.org/GH48.html


Substrate specificities

Family 48 glycoside hydrolases are major and key components of some cellulase systems, occurring in free enzyme systems (e.g., in Thermobifida fusca), multi-functional enzymes (e.g, in Caldicellulosiruptor saccharolyticus), anaerobic fungi (e.g., Piromyces equi) and every cellulosome system thus far described. The GH48 cellulase is commonly the most abundant enzyme subunit in cellulosome-producing bacteria. Each bacterium usually contains a single gene that codes for a GH48 enzyme, although a few bacteria (e.g., Clostridium thermocellum and Anaerocellum thermophilum) contain two or more GH48 genes. Of the two C. thermocellum GH48 enzymes, one (Cel48S) is a dockerin-containing cellulosomal enzyme, and the other (Cel48Y) is a free, non-cellulosomal enzyme that contains a cellulose-binding CBM3.

The following activities have been reported: endo-β-1,4-glucanase, chitinase, endo-processive cellulase and cellobiohydrolase. Its preferred substrate is amorphous or crystalline cellulose over carboxymethylcellulose (CMC), and its activity is strongly inhibited by the presence of cellobiose. Although its activity on various substrates is characteristically very low, it is thought to be a critically important enzyme which imparts a major component of synergy to its cellulase system.

Kinetics and Mechanism

The glycoside hydrolases of this family are inverting glycosidases, which preferentially attack the reducing end of the substrate [1].

The native and recombinant Cel48S from C. thermocellum displays typical characteristics of a processive exoglucanase [2], and its activity on amorphous cellulose is optimal at 70 °C and at pH 5–6.

Family 48 cellulases (i.e., CelS/S8 from C. thermocellum, Avicelase II of C. stercorarium) are stabilized at high temperatures by Ca2+ or other bivalent ions [3, 4, 5].

The Cel48F protein from C. cellulolyticum has been reported [6] to be a processive endo-glucanase, which performs a processive degradation of the cellulose chain after an initial endo-attack. A two-step mechanism was proposed [7], in which processive action and chain disruption occupy different subsites.

Catalytic Residues

The crystal structure of Cel48F, a cellulosome component of C. cellulolyticum, revealed the active center at the junction of the cleft and tunnel regions, where Glu55 is the proposed proton donor in the cleavage reaction, and the corresponding base was initially proposed to be either Glu44 or Asp230 [8].

The structure of the catalytic module of Cel48S of C. thermocellum showed a similar tunnel-shaped substrate-binding region formed by the alpha helices in the protein. The hydrolysis of the cellulose chain in Cel48S appeared to involve Glu87 (the equivalent of Glu55 in C. cellulolyticum Cel48F) as an acid to protonate the glycosidic oxygen atom and Tyr351 as a base to extract a proton from the nucleophilic water molecule that attacks the anomeric carbon atom. More recent studies of Cel48F failed to unambiguously identity the catalytic base in the cleavage reaction [7].

A recent experimental study in Thermobifida fusca Cel48A confirmed that aspartic acid (Asp225) is the catalytic base in family 48 glycoside hydrolases [9]. This residue is equivalent to D230 of C. cellulolyticum Cel48F and D255 of C. thermocellum Cel48S. In this study, site-directed mutagenesis demonstrated that the D225E mutation retained partial activity on soluble and insoluble substrates. Azide rescue hydrolysis assays showed that the D225G mutation restored its activity with added azide.

Three-dimensional structures

Three-dimensional structures are available for two family 48 enzymes: Cel48F (from Clostridium cellulolyticum) and Cel48A (from Clostridium thermocellum). Both enzymes have an (α/α)6 barrel topology.

3D structures of Cel48F in complex with different ligands are also available:

  • with cellotetraose (1f9d)
  • with the thio-oligosaccharide inhibitor PIPS-IG3 (1f9o)
  • with cellobiose (1fae)
  • with cellobiitol (1fbo)
  • with cellohexaose (1fbw)
  • with a thio-oligosaccharide (1g9j)
  • mutant E55Q with a thio-oligosaccharide (2qno)

Family Firsts

First sterochemistry determination
Cellulomonas fimi CenE, described as an endo-β-1,4-glucanase, catalyzes the hydrolysis of cellohexaose with inversion of anomeric carbon configuration, characteristic of a single displacement reaction [12].
First catalytic nucleophile identification
Asp225 was experimentally shown to be the catalytic base in T. fusca Cel48A [9].
First general acid/base residue identification
Glu was the proposed proton donor in the cleavage reaction [9].
First 3-D structure
The crystal structure of catalytic module of C. cellulolyticum Cel48F in complex with oligosaccharides [7].
First cloning and sequencing
The cel48S gene from C. thermocellum [13].

References

Error fetching PMID 8555231:
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Error fetching PMID 1909625:
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Error fetching PMID 8981979:
Error fetching PMID 18035374:
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Error fetching PMID 10985769:
Error fetching PMID 12096911:
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Error fetching PMID 12823562:
Error fetching PMID 10931180:
Error fetching PMID 21764975:
  1. Error fetching PMID 8555231: [Barr1996]
  2. Error fetching PMID 12096911: [Beatriz2002]
  3. Error fetching PMID 1909625: [Bronnenmeier1991]
  4. Error fetching PMID 2061292: [Morag1991]
  5. Error fetching PMID 7883725: [Kruus1995]
  6. Error fetching PMID 8981979: [Reverbel-Leroy1997]
  7. Error fetching PMID 18035374: [Parsiegla2008]
  8. Error fetching PMID 9755156: [Parsiegla1998]
  9. Error fetching PMID 21764975: [Kostylev2011]
  10. Error fetching PMID 10985769: [Parsiegla2000]
  11. Error fetching PMID 12096911: [Guimaraes2002]
  12. Error fetching PMID 8147863: [Shen1994]
  13. Error fetching PMID 8444792: [Wang1993]
  14. Error fetching PMID 12652902: [Steenbakkers2002]
  15. Error fetching PMID 9493383: [Zverlov1998]
  16. Error fetching PMID 16684504: [Fujita2006]
  17. Error fetching PMID 14761991: [Xu2004]
  18. Error fetching PMID 14679233: [Devillard2004]
  19. Error fetching PMID 12823562: [Sanchez2003]
  20. Error fetching PMID 10931180: [Irwin2000]

All Medline abstracts: PubMed