Engineering the Non-catalytic Domain to Enhance Catalytic Activity and Thermal Stability of a Nκ2-Producing κ-Carrageenase.

κ-Carrageenases play an important role in achieving the high-value utilization of carrageenan polysaccharides. They can be used in the preparation of even-numbered κ-neocarrageenan oligosaccharides by degrading κ-carrageenan (KC). We previously identified and characterized a κ-carrageenase, CaKC16B, with high specificity for producing a single κ-neocarrabiose. It can produce a single κ-neocarrabiose from degrading KC. However, they also exhibited poor thermal stability and catalytic efficiency. To improve these properties, we introduced noncatalytic domains (nonCDs) from a heat-resistant κ-carrageenase, MtKC16A, into the C-terminus of CaKC16B to construct CaKC16BUN and CaKC16BUNB. Compared to the original CaKC16B, both of them exhibited improved enzymatic properties, including optimal reaction temperature, thermal stability, substrate affinity, and catalytic efficiency. Remarkably, the / values of 16BUN and 16BUNB increased by 127 and 290 times, respectively. Importantly, the addition of nonCDs did not alter the final products of degrading KC, retaining the high product specificity of CaKC16B. Interestingly, the addition of nonCDs changed CaKC16B's substrate specificity for hydrolyzing KC and βκ-carrageenan, with mutants exhibiting higher relative activity for βκ-carrageenan. We further observed through biolayer interferometry that the binding and dissociation process between MtUN nonCD and βκ-carrageenan is faster compared to that of KC. This may explain the change in the substrate specificity observed in the mutants of CaKC16B.