Biochemical characterization of recombinant Penaeus vannamei trypsinogen.

Trypsinogens are the inactive precursors of trypsins (EC 3.4.21.4), which are digestive serine proteases. Despite knowing the properties of trypsins from Pacific white shrimp, Penaeus vannamei, the biochemical properties of shrimp trypsinogens including activation mechanisms and kinetics are unknown, due to difficulties isolating them from natural sources. In the present work, we describe the purification and biochemical characterization of four trypsinogen-like isoforms from recombinant P. vannamei trypsinogen, with a special emphasis on understanding its activation kinetics. The major trypsinogen-like isoform had an apparent molecular mass of 29 kDa. The other three forms of recombinant trypsinogen were: an N-glycosylated form of 32 kDa, a possibly O-glycosylated form of 41 kDa, and a likely double-chain form with a subunit of 23 kDa. The autoactivation profile of three-recombinant trypsinogen-like isoforms showed increased trypsin activity at a rate that was higher than that of bovine trypsinogen. This confirms the hypothesis proposed in the literature of a rapid trypsinogen autoactivation in the absence of aspartates in the activation peptide as it is for P. vannamei trypsinogen.

Shrimp (Litopenaeus vannamei) trypsinogen production in Pichia pastoris bioreactor cultures.

Recently, we engineered a Pichia pastoris Mut(+) strain to produce and secrete recombinant Litopenaeus vannamei trypsinogen. Despite the observed toxicity of the recombinant shrimp trypsinogen to the P. pastoris cell host, when high density cell cultures in shake flasks with alanine in the induction medium were used recombinant shrimp trypsinogen could be produced. To further improve the product yield, in this work, we evaluated L. vannamei trypsinogen production in P. pastoris using a bioreactor and two recombinant P. pastoris strains with different methanol utilization (Mut) phenotypes. The effect of pH and temperature during the induction step on the trypsinogen production was also evaluated. The results indicate that temperature, pH, and Mut phenotypes influence the production of the recombinant protein, with almost no observed effect on cell growth. All cultures with the Mut(+) strain had significant operational difficulties, such as in lowering the induction temperature, maintaining dissolved oxygen (DO) above 20%, and maintaining the methanol concentration at a constant value, and showed a decrease in metabolic activity due to trypsinogen toxicity to the cell host. In the culture with the Mut(s) strain, however, the temperature, methanol concentration, and DO could be more easily controlled, the temperature could be easily decreased, and the trypsinogen caused the lowest toxicity to the host cells. After 96 h of Mut(s) strain induction (pH 6 and 25°C), about 250 mg/L recombinant trypsinogen was detected in the culture medium.

Recombinant shrimp (Litopenaeus vannamei) trypsinogen production in Pichia pastoris.

Shrimp (Litopenaeus vannamei) trypsinogen has never been isolated from its natural source. To assess the production of L. vannamei trypsinogen, we engineered Pichia pastoris strains and evaluated two culture approaches with three induction culture media, to produce recombinant shrimp trypsinogen for the first time. The trypsinogen II cDNA was fused to the signal sequence of the Saccharomyces cerevisiae alpha mating factor, placed under the control of the P. pastoris AOX1 promoter, and integrated into the genome of P. pastoris host strain GS115. Using standard culture conditions for heterologous gene induction of a GS115 strain in shake flasks, recombinant shrimp trypsinogen was not detected by SDS-PAGE and Western blot analysis. Growth kinetics revealed a toxicity of recombinant shrimp trypsinogen or its activated form over the cell host. Thus, a different culture approach was tested for the induction step, involving the use of high cell density cultures, a higher frequency of methanol feeding (every 12 h), and a buffered minimal methanol medium supplemented with sorbitol or alanine; alanine supplemented medium was found to be more efficient. After 96 h of induction with alanine supplemented medium, a 29-kDa band from the cell-free culture medium was clearly observed by SDS-PAGE, and confirmed by Western blot to be shrimp trypsinogen, at a concentration of 14 microg/mL. Our results demonstrate that high density cell cultures with alanine in the induction medium allow the production of recombinant shrimp trypsinogen using the P. pastoris expression system, because of improved cell viability and greater stability of the recombinant trypsinogen.