Biochemical characterization of resurrected ancestral ammonia lyases

Sammanfattning: This study set out to express, purify and characterize twelve ammonia lyase enzymes for potential application as a supplement to a treatment of an inborn error of metabolism disease. The DNA sequence for two wild-type ammonia lyases, three modified ammonia lyases and seven resurrected ancestral ammonia lyases had been synthesized and cloned in vectors. These were transformed into Escherichia coli, expressed, purified using immobilized metal affinity chromatography and size exclusion chromatography and characterized. Ten of the enzymes were successfully expressed and purified. All enzymes had a higher turnover number with substrate 1 than with substrate 2. The wild-types showed the highest catalytic turnover and one of them displayed substrate cooperativity. The modified enzymes were inactive. Some ancestral enzymes were active and had decreasing kcat with age. A promising ancestral enzymes was found that showed a kcat of 2,85 s-1 with substrate 1 and 1,82 s-1 with substrate 2. The ancestral enzymes had a lower Km with substrate 2 compared to substrate 1, while one of the wild-types had a higher Km with substrate 2 than with substrate 1, indicating that the substrate affinity has switched. The ancestral enzymes had increased thermostability compared to the wild-types which increased with age. Ranging from a +7C increase in melting temperature with the youngest ancestral enzyme to +10,7C with the oldest tested enzyme, comparing with one of the wild-types. The promising ancestral enzyme displayed a higher stability than the wild-types during long term incubation in 37_C and 25_C, since it did not become prone to aggregation,it did not show visible degradation on SDS-PAGE and it retained the highest activity following incubation. It was also demonstrated that neither wild-types nor the promising ancestral enzyme were stable in a simulated gut environment. The promising ancestral enzyme and one of the wild-types degraded substrate 1 and 2 in serum. Using the resurrection of ancestral sequences a promising enzyme has been produced and characterized, displaying properties that are desired in therapeutic enzymes. The enzyme did not aggregate or become prone to aggregation over time, it was thermostable, it was active in serum and had acceptable catalytic properties. For therapeutic application of the ancestral enzyme, immunogenicty should be analyzed in silico and in vitro followed by further investigation in vivo.