Pengoptimuman Campuran Enzim Selulase Rekombinan Untuk Pencuraian Tandan Kosong Kelapa Sawit

Penggunaan enzim selulase untuk penguraian biojisim pertanian lignoselulosa telah lama dikaji dan pelbagai usaha telah dilakukan untuk meningkatkan kecekapan proses hidrolisis. Keberkesanan penguraian biojisim pertanian kepada gula ringkas memerlukan satu campuran enzim yang mengandungi pelbagai jenis aktiviti selulolitik. Dalam kajian ini, satu campuran multi-enzim rekombinan yang terdiri daripada tiga komponen asas selulase iaitu endoglukanase (EglB) dan β-glukosidase (BglA) daripada Aspergillus niger serta selobiohidrolase (CbhII) daripada Trichoderma virens telah dibentuk khusus untuk hidrolisis tandan kosong kelapa sawit (TKKS). Penghasilan enzim selulase rekombinan telah dilakukan menggunakan hos pengekspresan Pichia pastoris. Pengoptimuman nisbah enzim untuk tindak balas ditentukan menggunakan Kaedah Gerak Balas Permukaan (RSM). Hasil menunjukkan hidrolisis TKKS pada suhu 50 °C dan pH 5.0 menggunakan enzim pada nisbah 641.4 unit CMCase: 10.14 unit Avicelase: 93.8 unit β-glukosidase, menghasilkan gula terturun dan glukosa tertinggi, masing-masing sebanyak 63 mg dan 40 mg per gram substrat TKKS. Hasil hidrolisis TKKS oleh campuran multi enzim yang telah dibentuk dalam kajian ini menunjukkan ketiga-tiga gabungan enzim rekombinan ini berpotensi untuk digunakan bagi penguraian TKKS.

Production of Human Pancreatitis-Associated Protein (hPAP) in Komagataella phaffii (Pichia pastoris)

Pancreatitis-associated protein (PAP) is a pancreatic stress protein that is not produced in a healthy pancreas but is highly synthesized in pancreatic acinar cells in response to acute and chronic pancreatitis, hypoxia, toxins, diabetes, lipopolysaccharides hypotransferrinemia and organ transplantation. Changes in the PAP levels in serum are an important biological marker in the early stage of pancreatic diseases. In this study, the recombinant human PAP protein, which has the potential to be used as a diagnostic marker and as research material in proliferation, apoptosis, cell migration, cell invasion, and immunoassay studies, was expressed efficiently under the control of the AOX1 gene promoter in the Komagataella phaffii (Pichia pastoris) (K. phaffii) X33 strain. We describe the conditions required for the efficient production of PAP protein by methanol induction and its use without purification. The produced unpurified protein was tested in sandwich ELISA and showed consistent results with the commercial product. These results are encouraging that the protein produced can be used as a biomarker standard in ELISA tests without the cost and labor of purification.

Improved Production of Streptomyces sp. FA1 Xylanase in a Dual-Plasmid Pichia pastoris System

Methanol is considered as a potential hazard in the methanol-induced yeast expression of food-related enzymes. To increase the production efficiency of recombinant proteins in Pichia pastoris without methanol induction, a novel dual-plasmid system was constructed, for the first time, by a combining the strategies of genomic integration and episomal expression. To obtain a high copy number of the target gene, the autonomously replicating sequence derived from Kluyveromyces lactis (PARS) was used to construct episomal vectors carrying the constitutive promoters PGAP and PGCW14. In addition, an integrative vector carrying the PGCW14 promoter was constructed by replacing the PGAP promoter sequence with a partial PGCW14 promoter. Next, using xylanase XynA from Streptomyces sp. FA1 as the model enzyme, recombination strains were transformed with different combinations of integrating and episomal vectors that were constructed to investigate the changes in the protein yield. Results in shake flasks indicated that the highest enzyme yield was achieved when integrated PGAP and episomal PGCW14 were simultaneously transformed into the host strain. Meanwhile, the copy number of xynA increased from 1.14 ± 0.46 to 3.06 ± 0.35. The yield of XynA was successfully increased to 3925 U·mL−1 after 102 h of fermentation in a 3.6 L fermenter, which was 16.7-fold and 2.86-fold of the yields that were previously reported for the constitutive expression and methanol-induced expression of the identical protein, respectively. Furthermore, the high-cell-density fermentation period was shortened from 132 h to 102 h compared to that of methanol-induced system. Since the risk of methanol toxicity is removed, this novel expression system would be suitable for the production of proteins related to the food and pharmaceutical industries.