Fungal unspecific peroxygenases (UPOs) are biocatalysts of outstanding interest. Providing access to novel UPOs using a modular secretion system was the central goal of this work. UPOs represent an enzyme class, catalysing versatile oxyfunctionalisation reactions on a broad substrate scope. They are occurring as secreted, glycosylated proteins bearing a haem-thiolate active site and solely rely on hydrogen peroxide as the oxygen source. Fungal peroxygenases are widespread throughout the fungal kingdom and hence a huge variety of UPO gene sequences is available. However, the heterologous production of UPOs in a fast-growing organism suitable for high throughput screening has only succeeded once—enabled by an intensive directed evolution campaign. Here, we developed and applied a modular Golden Gate-based secretion system, allowing the first yeast production of four active UPOs, their one-step purification and application in an enantioselective conversion on a preparative scale. The Golden Gate setup was designed to be broadly applicable and consists of the three module types: i) a signal peptide panel guiding secretion, ii) UPO genes, and iii) protein tags for purification and split-GFP detection. We show that optimal signal peptides could be selected for successful UPO secretion by combinatorial testing of 17 signal peptides for each UPO gene. The modular episomal system is suitable for use in Saccharomyces cerevisiae and was transferred to episomal and chromosomally integrated expression cassettes in Pichia pastoris. Shake flask productions in Pichia pastoris yielded up to 24 mg/L secreted UPO enzyme, which was employed for the preparative scale conversion of a phenethylamine derivative reaching 98.6 % ee. Our results demonstrate a rapid workflow from putative UPO gene to preparative scale enantioselective biotransformations.

The recent discovery of the mode of action of the CRISPR/Cas9 system has provided biologists with a useful tool for generating site-specific mutations in genes of interest. In plants, site-targeted mutations are usually obtained by stably transforming a Cas9 expression construct into the plant genome. The efficiency with which mutations are obtained in genes of interest can vary considerably depending on specific features of the constructs, including the source and nature of the promoters and terminators used for expression of the Cas9 gene and the guide RNA, and the sequence of the Cas9 nuclease itself. To optimize the efficiency with which mutations could be obtained in target genes in Arabidopsis thaliana with the Cas9 nuclease, we have investigated several features of its nucleotide and/or amino acid sequence, including the codon usage, the number of nuclear localization signals (NLS) and the presence or absence of introns. We found that the Cas9 gene codon usage had some effect on Cas9 activity and that two NLSs work better than one. However, the most important impact on the efficiency of the constructs was obtained by addition of 13 introns into the Cas9 coding sequence, which dramatically improved editing efficiencies of the constructs; none of the primary transformants obtained with a Cas9 lacking introns displayed a knockout mutant phenotype, whereas between 70% and 100% of primary transformants generated with intronized Cas9 displayed mutant phenotypes. The intronized Cas9 was also found to be effective in other plants such as Nicotiana benthamiana and Catharanthus roseus.

The exine of angiosperm pollen grains is usually covered by a complex mix of metabolites including pollen-specific hydroxycinnamic acid amides (HCAAs) and flavonoid glycosides. Whereas the biosynthetic pathways resulting in the formation of HCAAs and flavonol glycosides have been characterized, it is unclear, how these compounds are transported to the pollen surface. In this report we provide several lines of evidence that AtNPF2.8, a member of the nitrate/peptide NTR/PTR family of transporters is required for accumulation and transport of pollen-specific flavonol 3-O-sophorosides, characterized by a glycosidic β-1,2-linkage, to the pollen surface of Arabidopsis. Ectopic, transient expression of this flavonol sophoroside transporter, termed AtFST1, fused to green fluorescent protein (GFP) demonstrated localization of AtFST1 at the plasmalemma in epidermal leaf cells of Nicotiana benthamiana whereas the tapetum-specific AtFST1-expression was confirmed by promAtFST1:GFP-reporter lines. In vitro characterization of AtFST1-activity was achieved by microbial uptake assays based on 14C-labeled flavonol glycosides. Finally, rescue of an fst1-line by complementation with a genomic fragment of the AtFST1 gene restored flavonol glycoside accumulation of pollen grains to wild-type levels corroborating the requirement of AtFST1 for transport of flavonol-3-O-sophorosides from the tapetum to the pollen surface.

Genetic resources for the model plant Arabidopsis comprise mutant lines defective in almost any single gene in reference accession Columbia. However, gene redundancy and/or close linkage often render it extremely laborious or even impossible to isolate a desired line lacking a specific function or set of genes from segregating populations. Therefore, we here evaluated strategies and efficiencies for the inactivation of multiple genes by Cas9-based nucleases and multiplexing. In first attempts, we succeeded in isolating a mutant line carrying a 70 kb deletion, which occurred at a frequency of ~ 1.6% in the T2 generation, through PCR-based screening of numerous individuals. However, we failed to isolate a line lacking Lhcb1 genes, which are present in five copies organized at two loci in the Arabidopsis genome. To improve efficiency of our Cas9-based nuclease system, regulatory sequences controlling Cas9 expression levels and timing were systematically compared. Indeed, use of DD45 and RPS5a promoters improved efficiency of our genome editing system by approximately 25–30-fold in comparison to the previous ubiquitin promoter. Using an optimized genome editing system with RPS5a promoter-driven Cas9, putatively quintuple mutant lines lacking detectable amounts of Lhcb1 protein represented approximately 30% of T1 transformants. These results show how improved genome editing systems facilitate the isolation of complex mutant alleles, previously considered impossible to generate, at high frequency even in a single (T1) generation.

Methods that enable the construction of recombinant DNA molecules are essential tools for biological research and biotechnology. Golden Gate cloning is used for assembly of multiple DNA fragments in a defined linear order in a recipient vector using a one‐pot assembly procedure. Golden Gate cloning is based on the use of a type IIS restriction enzyme for digestion of the DNA fragments and vector. Because restriction sites for the type IIS enzyme used for assembly must be present at the ends of the DNA fragments and vector but absent from all internal sequences, special care must be taken to prepare DNA fragments and the recipient vector with a structure suitable for assembly by Golden Gate cloning. In this article, protocols are presented for preparation of DNA fragments, modules, and vectors suitable for Golden Gate assembly cloning. Additional protocols are presented for assembly of defined parts in a transcription unit, as well as the stitching together of multiple transcription units into multigene constructs by the modular cloning (MoClo) pipeline.

Modular cloning systems that rely on type IIS enzymes for DNA assembly have many advantages for complex pathway engineering. These systems are simple to use, efficient, and allow users to assemble multigene constructs by performing a series of one-pot assembly steps, starting from libraries of cloned and sequenced parts. The efficiency of these systems also facilitates the generation of libraries of construct variants. We describe here a protocol for assembly of multigene constructs using the Modular Cloning system MoClo. Making constructs using the MoClo system requires users to first define the structure of the final construct to identify all basic parts and vectors required for the construction strategy. The assembly strategy is then defined following a set of standard rules. Multigene constructs are then assembled using a series of one-pot assembly steps with the set of identified parts and vectors.

Availability of efficient DNA assembly methods is a basic requirement for synthetic biology. A variety of modular cloning systems have been developed, based on Golden Gate cloning for DNA assembly, to enable users to assemble multigene constructs from libraries of standard parts using a series of successive one-pot assembly reactions. Standard parts contain the DNA sequence coding for a genetic element of interest such as a promoter, coding sequence or terminator. Standard parts for the modular cloning system MoClo must be flanked by two BsaI restriction sites and should not contain internal sequences for two type IIS restriction sites, BsaI and BpiI, and optionally for a third type IIS enzyme, BsmBI. We provide here a detailed protocol for cloning of basic parts. This protocol requires the following steps (1) defining the type of basic part that needs to be cloned, (2) designing primers for amplification, (3) performing PCR amplification, (4) cloning of the fragments using Golden Gate cloning, and finally (5) sequencing of the part. For large basic parts, it is preferable to first clone subparts as intermediate level −1 constructs. These subparts are sequenced individually and are then further assembled to make the final level 0 module.

Fungal unspecific peroxygenases (UPOs) are biocatalysts of outstanding interest. Providing access to novel UPOs using a modular secretion system was the central goal of this work. UPOs represent an enzyme class, catalysing versatile oxyfunctionalisation reactions on a broad substrate scope. They are occurring as secreted, glycosylated proteins bearing a haem-thiolate active site and solely rely on hydrogen peroxide as the oxygen source. Fungal peroxygenases are widespread throughout the fungal kingdom and hence a huge variety of UPO gene sequences is available. However, the heterologous production of UPOs in a fast-growing organism suitable for high throughput screening has only succeeded once—enabled by an intensive directed evolution campaign. Here, we developed and applied a modular Golden Gate-based secretion system, allowing the first yeast production of four active UPOs, their one-step purification and application in an enantioselective conversion on a preparative scale. The Golden Gate setup was designed to be broadly applicable and consists of the three module types: i) a signal peptide panel guiding secretion, ii) UPO genes, and iii) protein tags for purification and split-GFP detection. We show that optimal signal peptides could be selected for successful UPO secretion by combinatorial testing of 17 signal peptides for each UPO gene. The modular episomal system is suitable for use in Saccharomyces cerevisiae and was transferred to episomal and chromosomally integrated expression cassettes in Pichia pastoris. Shake flask productions in Pichia pastoris yielded up to 24 mg/L secreted UPO enzyme, which was employed for the preparative scale conversion of a phenethylamine derivative reaching 98.6 % ee. Our results demonstrate a rapid workflow from putative UPO gene to preparative scale enantioselective biotransformations.

The recent discovery of the mode of action of the CRISPR/Cas9 system has provided biologists with a useful tool for generating site-specific mutations in genes of interest. In plants, site-targeted mutations are usually obtained by stably transforming a Cas9 expression construct into the plant genome. The efficiency with which mutations are obtained in genes of interest can vary considerably depending on specific features of the constructs, including the source and nature of the promoters and terminators used for expression of the Cas9 gene and the guide RNA, and the sequence of the Cas9 nuclease itself. To optimize the efficiency with which mutations could be obtained in target genes in Arabidopsis thaliana with the Cas9 nuclease, we have investigated several features of its nucleotide and/or amino acid sequence, including the codon usage, the number of nuclear localization signals (NLS) and the presence or absence of introns. We found that the Cas9 gene codon usage had some effect on Cas9 activity and that two NLSs work better than one. However, the most important impact on the efficiency of the constructs was obtained by addition of 13 introns into the Cas9 coding sequence, which dramatically improved editing efficiencies of the constructs; none of the primary transformants obtained with a Cas9 lacking introns displayed a knockout mutant phenotype, whereas between 70% and 100% of primary transformants generated with intronized Cas9 displayed mutant phenotypes. The intronized Cas9 was also found to be effective in other plants such as Nicotiana benthamiana and Catharanthus roseus.

Genome editing by RNA-guided nucleases in model species is still hampered by low efficiencies, and isolation of transgene-free individuals often requires tedious PCR screening. Here, we present a toolkit that mitigates these drawbacks for Nicotiana benthamiana and Arabidopsis thaliana. The toolkit is based on an intron-optimized SpCas9-coding gene (zCas9i), which conveys dramatically enhanced editing efficiencies. The zCas9i gene is combined with remaining components of the genome editing system in recipient vectors, which lack only the user-defined guide RNA transcriptional units. Up to 32 guide RNA transcriptional units can be introduced to these recipients by a simple and PCR-free cloning strategy, with the choice of three different RNA polymerase III promoters for guide RNA expression. We developed new markers to aid transgene counter-selection in N. benthamiana, and demonstrate their efficacy for isolation of several genome-edited N. benthamiana lines. In Arabidopsis, we explore the limits of multiplexing by simultaneously targeting 12 genes by 24 sgRNAs. Perhaps surprisingly, the limiting factor in such higher order multiplexing applications is Cas9 availability, rather than recombination or silencing of repetitive sgRNA TU arrays. Through a combination of phenotypic screening and pooled amplicon sequencing, we identify transgene-free duodecuple mutant Arabidopsis plants directly in the T2 generation. This demonstrates high efficiency of the zCas9i gene, and reveals new perspectives for multiplexing to target gene families and to generate higher order mutants.