Abstract
Targeted gene replacement to generate knock-outs and knock-ins is a commonly used method to study the function of unknown genes. In the methylotrophic yeast Pichia pastoris, the importance of specific gene targeting has increased since the genome sequencing projects of the most commonly used strains have been accomplished, but rapid progress in the field has been impeded by inefficient mechanisms for accurate integration. To improve gene targeting efficiency in P. pastoris, we identified and deleted the P. pastoris KU70 homologue. We observed a substantial increase in the targeting efficiency using the two commonly known and used integration loci HIS4 and ADE1, reaching over 90% targeting efficiencies with only 250-bp flanking homologous DNA. Although the ku70 deletion strain was noted to be more sensitive to UV rays than the corresponding wild-type strain, no lethality, severe growth retardation or loss of gene copy numbers could be detected during repetitive rounds of cultivation and induction of heterologous protein production. Furthermore, we demonstrated the use of the ku70 deletion strain for fast and simple screening of genes in the search of new auxotrophic markers by targeting dihydroxyacetone synthase and glycerol kinase genes. Precise knock-out strains for the well-known P. pastoris AOX1, ARG4 and HIS4 genes and a whole series of expression vectors were generated based on the wild-type platform strain, providing a broad spectrum of precise tools for both intracellular and secreted production of heterologous proteins utilizing various selection markers and integration strategies for targeted or random integration of single and multiple genes. The simplicity of targeted integration in the ku70 deletion strain will further support protein production strain generation and synthetic biology using P. pastoris strains as platform hosts.
Highlights
The methylotrophic yeast Komagataella pastoris, commonly known as Pichia pastoris has become one of the major eukaryotic hosts for recombinant protein production, mainly because of its strong and tightly regulated AOX1 promoter [1], ease of manipulation, growth to high cell-densities in inexpensive media and ability to perform complex post-translational modifications [2]
One of the aims of our study was to investigate if the non-homologous end joining (NHEJ) pathway plays an important role in the site targeted specific integration in the genome of P. pastoris (NRRL-Y 11430, ATCC 76273) and if the NHEJ mechanism can be impaired by knock-out mutagenesis
In filamentous fungi and higher eukaryotic organisms, the integration of foreign DNA has been reported to occur preferentially via the NHEJ pathway joining DNA ends with little or no homology [53], while in S. cerevisiae HR has been reported to be dominant and non-homologous recombination only observed if HR was blocked or homologous chromosome unavailable to serve as a template [54]
Summary
The methylotrophic yeast Komagataella pastoris, commonly known as Pichia pastoris has become one of the major eukaryotic hosts for recombinant protein production, mainly because of its strong and tightly regulated AOX1 promoter [1], ease of manipulation, growth to high cell-densities in inexpensive media and ability to perform complex post-translational modifications [2]. The genome sequence of the P. pastoris histidine auxotrophic variant GS115 has been published with a curated annotation for its 5313 protein coding genes [3] This most commonly used and commercially available strain had been derived by mutagenesis of the P. pastoris WT strain NRRLY11430 (ATCC 76273), which was deposited in the Netherlands as P. pastoris CBS7435. Most gaps were closed in the new genome sequence and some sequence and annotation mistakes were corrected This new information shed light on the formerly poorly known, but important pathways that are responsible for methanol utilization, secretion, glycosylation, proteolytic processing and protein folding. This information has increased the potential of P. pastoris and enabled its further development towards a customized and highly efficient host for heterologous protein production
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
