Novel LysM motifs for antigen display on lactobacilli for mucosal immunization

We characterized two LysM domains of Limosilactobacillus fermentum, belonging to proteins Acglu (GenBank: KPH22907.1) and Pgb (GenBank: KPH22047.1) and bacterium like particles (BLP) derived from the immunomodulatory strain Lacticaseibacillus rhamnosus IBL027 (BLPs027) as an antigen display platform. The fluorescence protein Venus fused to the novel LysM domains could bind to the peptidoglycan shell of lactobacilli and resisted harsh conditions such as high NaCl and urea concentrations. Acglu with five LysM domains was a better anchor than Pgb baring only one domain. Six-week-old BALB/c mice were nasally immunized with the complex Venus-Acglu-BLPs027 at days 0, 14 and 28. The levels of specific serum IgG, IgG1 and IgG2a and the levels of total immunoglobulins (IgT) and IgA in broncho-alveolar lavage (BAL) were evaluated ten days after the last boosting. Venus-Acglu-BLPs027, nasally administered, significantly increased specific BAL IgT and IgA, and serum IgG levels. In addition, spleen cells of mice immunized with Venus-Acglu-BLPs027 secreted TNF-α, IFN-γ and IL-4 when stimulated ex vivo in a dose-dependent manner. We constructed a Gateway compatible destination vector to easily fuse the selected LysM domain to proteins of interest for antigen display to develop mucosal subunit vaccines.

A simple and efficient cloning system for CRISPR/Cas9-mediated genome editing in rice

Rapidly growing genetics and bioinformatics studies provide us with an opportunity to obtain a global view of the genetic basis of traits, but also give a challenge to the function validation of candidate genes. CRISPR/Cas9 is an emerging and efficient tool for genome editing. To construct expression clones for the CRISPR/Cas9, most current methods depend on traditional cloning using Gateway reaction or specific type IIS restriction enzymes and DNA ligation, based on multiple steps of PCR. We developed a system for introducing sgRNA expression cassette(s) directly into plant binary vectors in one step. In this system, one sgRNA expression cassette(s) is generated by an optimized multiplex PCR, in which an overlapping PCR took place. Whilst, two sgRNA expression cassettes were amplified in a single round of PCR. Subsequently, an LR or Golden gate reaction was set up with unpurified PCR product and befitting destination vector. We are able to construct expression clones within 36 h, which greatly improves efficiency and saves cost. Furthermore, the efficiency of this system was verified by an agrobacterium-mediated genetic transformation in rice. The system reported here provides a much more efficient and simpler procedure to construct expression clones for CRISPR/Cas9-mediated genome editing.

Start-Stop Assembly: a functionally scarless DNA assembly system optimised for metabolic engineering

ABSTRACTDNA assembly allows individual DNA constructs or designed mixtures to be assembled quickly and reliably. Most methods are either: (i) Modular, easily scalable and suitable for combinatorial assembly, but leave undesirable ‘scar’ sequences; or (ii) bespoke (non-modular), scarless but less suitable for construction of combinatorial libraries. Both have limitations for metabolic engineering. To overcome this trade-off we devised Start-Stop Assembly, a multi-part, modular DNA assembly method which is both functionally scarless and suitable for combinatorial assembly. Crucially, 3 bp overhangs corresponding to start and stop codons are used to assemble coding sequences into expression units, avoiding scars at sensitive coding sequence boundaries. Building on this concept, a complete DNA assembly framework was designed and implemented, allowing assembly of up to 15 genes from up to 60 parts (or mixtures); monocistronic, operon-based or hybrid configurations; and a new streamlined assembly hierarchy minimising the number of vectors. Only one destination vector is required per organism, reflecting our optimisation of the system for metabolic engineering in diverse organisms. Metabolic engineering using Start-Stop Assembly was demonstrated by combinatorial assembly of carotenoid pathways inE. coliresulting in a wide range of carotenoid production and colony size phenotypes indicating the intended exploration of design space.GRAPHICAL ABSTRACT

Episomal tools for RNAi in the diatom Phaeodactylum tricornutum

Background. The diatom Phaeodactylum tricornutum is a model photosynthetic organism. Functional genomic work in this organism has established a variety of genetic tools including RNA interference (RNAi). RNAi is a post-transcriptional regulatory process that can be utilized to knockdown expression of genes of interest in eukaryotes. RNAi has been previously demonstrated in P. tricornutum, but in practice the efficiency of inducing RNAi is low. Methods. We developed an efficient method for construction of inverted repeat hairpins based on Golden Gate DNA assembly into a Gateway entry vector. The hairpin constructs were then transferred to a variety of destination vectors through the Gateway recombination system. After recombining the hairpin into the destination vector, the resulting expression vector was mobilized into P. tricornutum using direct conjugation from E. coli. Because the hairpin expression vectors had sequences allowing for episomal maintenance in P. tricornutum, we tested whether a consistent, episomal location for hairpin expression improved RNAi induction efficiency. Results. We successfully demonstrated that RNAi could be induced using hairpin constructs expressed from an episome. After testing two different reporter targets and a variety of hairpin sequences with 3 polymerase II and 2 polymerase III promoters, we achieved a maximal RNAi induction efficiency of 25% of lines displaying knockdown of reporter activity by 50% or more. We created many useful genetic tools through this work including Gateway destination vectors for P. tricornutum expression from a variety of polymerase II and III promoters including the P. tricornutum FCPB, H4, and 49202 polymerase II promoters as well as the U6 and snRNA polymerase III promoters. We also created Gateway destination vectors that allow a cassette cloned in an entry vector to be easily recombined into a transcriptional fusion with either ShBle or, for polymerase III promoters, the green fluorescent Spinach aptamer. Such transcriptional fusions allow for linkage of expression with a marker such as bleomycin resistance or fluorescence from the Spinach aptamer to easily select or screen for lines that maintain transgene expression. Discussion. While RNAi can be used as an effective tool for P. tricornutum genetics, especially where targeted knockouts may be lethal to the cell, induction of this process remains low efficiency. Techniques resulting in higher efficiency establishment of RNAi would be of great use to the diatom genetics community and would enable this technique to be used as a forward genetic tool for discovery of novel gene function.

Episomal tools for RNAi in the diatom Phaeodactylum tricornutum

Background. The diatom Phaeodactylum tricornutum is a model photosynthetic organism. Functional genomic work in this organism has established a variety of genetic tools including RNA interference (RNAi). RNAi is a post-transcriptional regulatory process that can be utilized to knockdown expression of genes of interest in eukaryotes. RNAi has been previously demonstrated in P. tricornutum, but in practice the efficiency of inducing RNAi is low. Methods. We developed an efficient method for construction of inverted repeat hairpins based on Golden Gate DNA assembly into a Gateway entry vector. The hairpin constructs were then transferred to a variety of destination vectors through the Gateway recombination system. After recombining the hairpin into the destination vector, the resulting expression vector was mobilized into P. tricornutum using direct conjugation from E. coli. Because the hairpin expression vectors had sequences allowing for episomal maintenance in P. tricornutum, we tested whether a consistent, episomal location for hairpin expression improved RNAi induction efficiency. Results. We successfully demonstrated that RNAi could be induced using hairpin constructs expressed from an episome. After testing two different reporter targets and a variety of hairpin sequences with 3 polymerase II and 2 polymerase III promoters, we achieved a maximal RNAi induction efficiency of 25% of lines displaying knockdown of reporter activity by 50% or more. We created many useful genetic tools through this work including Gateway destination vectors for P. tricornutum expression from a variety of polymerase II and III promoters including the P. tricornutum FCPB, H4, and 49202 polymerase II promoters as well as the U6 and snRNA polymerase III promoters. We also created Gateway destination vectors that allow a cassette cloned in an entry vector to be easily recombined into a transcriptional fusion with either ShBle or, for polymerase III promoters, the green fluorescent Spinach aptamer. Such transcriptional fusions allow for linkage of expression with a marker such as bleomycin resistance or fluorescence from the Spinach aptamer to easily select or screen for lines that maintain transgene expression. Discussion. While RNAi can be used as an effective tool for P. tricornutum genetics, especially where targeted knockouts may be lethal to the cell, induction of this process remains low efficiency. Techniques resulting in higher efficiency establishment of RNAi would be of great use to the diatom genetics community and would enable this technique to be used as a forward genetic tool for discovery of novel gene function.

Cloning and Characterization of Alcohol Dehydrogenase (Adh) Promoter Region for Expression Under Submergence and Salinity Stress

The characterization of promoter is important for developing stress tolerant crops as well as understanding the role of promoters in regulating gene expression. The current study was initiated with an aim to characterize the Adh promoter under salinity and submergence stress in rice calli. The upstream regions (~1kb) of the Adh gene was amplified from the genomic DNA of Arabidopsis (Columbia Ecotype). The amplified product was then cloned successively into an entry and promoter-characterization binary destination vector having the reporter gene ?-glucuronidase (GUS) by applying Gateway Technology. A positive clone was confirmed by applying PCR, restriction digestion and sequencing. The construct was then transformed into Agrobacterium tumefaciens LBA4404 strain and rice calli infected with the latter. In both salt and submergence stresses, Adh could selectively express GUS gene activity up to two-fold compared to control. Plant Tissue Cult. & Biotech. 24(1): 111-120, 2014 (June) D. O. I. http://dx.doi.org/10.3329/ptcb.v24i1.19252

Construction and Expression of Sugar Kinase Transcriptional Gene Fusions by Using the Sinorhizobium meliloti ORFeome

ABSTRACT The Sinorhizobium meliloti ORFeome project cloned 6,314 open reading frames (ORFs) into a modified Gateway entry vector system from which the ORFs could be transferred to destination vectors in vivo via bacterial conjugation. In this work, a reporter gene destination vector, pMK2030, was constructed and used to generate ORF-specific transcriptional fusions to β-glucuronidase (gusA) and green fluorescent protein (gfp) reporter genes. A total of 6,290 ORFs were successfully transferred from the entry vector library into pMK2030. To demonstrate the utility of this system, reporter plasmids corresponding to 30 annotated sugar kinase genes were integrated into the S. meliloti SM1021 and/or SM8530 genome. Expression of these genes was measured using a high-throughput β-glucuronidase assay to track expression on nine different carbon sources. Six ORFs integrated into SM1021 and SM8530 had different basal levels of expression in the two strains. The annotated activities of three other sugar kinases were also confirmed.