Alginate Lyase Aly36B is a New Bacterial Member of the Polysaccharide Lyase Family 36 and Catalyzes by a Novel Mechanism With Lysine as Both the Catalytic Base and Catalytic Acid.

Alginate lyases, which are important in both basic and applied sciences, fall into ten polysaccharide lyase (PL) families. PL36 is a newly established family that includes 39 bacterial sequences and one eukaryotic sequence. Till now, the structures or catalytic mechanisms of PL36 alginate lyases have yet to be revealed. Here, we characterized a novel PL36 alginate lyase, Aly36B, from Chitinophaga sp. MD30. Aly36B is a polymannuronate specific endolytic alginate lyase. To probe the catalytic mechanism of Aly36B, the structures of wild-type Aly36B and its mutants (K143A/Y185A in complex with alginate tetrasaccharide and K143A/M171A with trisaccharide) were solved. The overall structure of Aly36B belongs to the ß-jelly roll scaffold, adopting a typical ß-sandwich fold. Aly36B contains a Ca2+, which is far away from the active center and plays an important role in stabilizing the structure of Aly36B. Based on structural and mutational analyses, the catalytic mechanism of Aly36B for alginate degradation was explained. During catalysis, Arg169, Tyr185, and Tyr187 are responsible for neutralizing the negative charge of the substrate, and Lys143 acts as both the catalytic base and the catalytic acid, which represents a new kind of catalytic mechanism of alginate lyases. Sequence alignment shows that these four residues involved in catalysis are highly conserved in all PL36 sequences, suggesting that PL36 alginate lyases may adopt a similar catalytic mechanism. Taken together, this study reveals the molecular structure and catalytic mechanism of a PL36 alginate lyase, broadening our knowledge on alginate lyases and facilitating future biotechnological applications of PL36 alginate lyases.

An extra peptide within the catalytic module of a ß-agarase affects the agarose degradation pattern.

Agarase hydrolyzes agarose into a series of oligosaccharides with repeating disaccharide units. The glycoside hydrolase (GH) module of agarase is known to be responsible for its catalytic activity. However, variations in the composition of the GH module and its effects on enzymatic functions have been minimally elucidated. The agaG4 gene, cloned from the genome of the agarolytic Flammeovirga strain MY04, encodes a 503-amino acid protein, AgaG4. Compared with elucidated agarases, AgaG4 contains an extra peptide (Asn(246)-Gly(302)) within its GH module. Heterologously expressed AgaG4 (recombinant AgaG4; rAgaG4) was determined to be an endo-type ß-agarase. The protein degraded agarose into neoagarotetraose and neoagarohexaose at a final molar ratio of 1.5:1. Neoagarooctaose was the smallest substrate for rAgaG4, whereas neoagarotetraose was the minimal degradation product. Removing the extra fragment from the GH module led to the inability of the mutant (rAgaG4-T57) to degrade neoagarooctaose, and the final degradation products of agarose by the truncated protein were neoagarotetraose, neoagarohexaose, and neoagarooctaose at a final molar ratio of 2.7:2.8:1. The optimal temperature for agarose degradation also decreased to 40 °C for this mutant. Bioinformatic analysis suggested that tyrosine 276 within the extra fragment was a candidate active site residue for the enzymatic activity. Site-swapping experiments of Tyr(276) to 19 various other amino acids demonstrated that the characteristics of this residue were crucial for the AgaG4 degradation of agarose and the cleavage pattern of substrate.