Design Principles of a Novel Construct for HBB Gene-Editing and Investigation of Its Gene-Targeting Efficiency in HEK293 Cells

Beta-thalassemia is one of the most common monogenic inherited disorders worldwide caused by different mutations in the hemoglobin subunit beta (HBB) gene. Genome-editing based on clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9 system (CRISPR/Cas9) has raised the hope for life-long gene therapy of beta-thalassemia. In a proof-of-concept study, we describe the detailed design and assess the efficacy of a novel homology-directed repair (HDR)-based CRISPR construct for targeting the HBB locus. The selected sgRNAs were designed and cloned into an optimized CRISPR plasmid. The HDR donor templates containing a reporter and a selection marker flanked by the piggyBac Inverted Tandem Repeat (ITRs), the homology arms and the delta thymidine kinase (ΔTK) gene for negative selection were constructed. The efficiency of on-target mutagenesis by the eSpCas9/sgRNAs was assessed by mismatch assays. HDR-positive cells were isolated by treatment with G418 or selection based on truncated Neuron Growth Factor Receptor (tNGFR) expression using the Magnetic Activated Cell Sorting (MACS) method followed by ganciclovir (GCV) treatment to eliminate cells with random genomic integration of the HDR donor template. In-out PCR and sanger sequencing confirmed HDR in the isolated cells. Our data showed ~ 50% efficiency for co-transfection of CRISPR/donor template plasmids in HEK293 cells and following G418 treatment, the HDR efficiency was detected at ~ 37.5%. Moreover, using a clinically-relevant strategy, HDR events were validated after selection for tNGFR+ cells followed by negative selection for ΔTK by GCV treatment. Thus, our HDR-based gene-editing strategy could efficiently target the HBB locus and enrich for HDR-positive cells.

Breeding rice for yield improvement through CRISPR/Cas9 genome editing method: current technologies and examples

The impending climate change is threatening the rice productivity of the Asian subcontinent as instances of crop failures due to adverse abiotic and biotic stress factors are becoming common occurrences. CRISPR-Cas9 mediated genome editing offers a potential solution for improving rice yield as well as its stress adaptation. This technology allows modification of plant's genetic elements and is not dependent on foreign DNA/gene insertion for incorporating a particular trait. In this review, we have discussed various CRISPR-Cas9 mediated genome editing tools for gene knockout, gene knock-in, simultaneously disrupting multiple genes by multiplexing, base editing and prime editing the genes. The review here also presents how these genome editing technologies have been employed to improve rice productivity by directly targeting the yield related genes or by indirectly manipulating various abiotic and biotic stress responsive genes. Lately, many countries treat genome-edited crops as non-GMOs because of the absence of foreign DNA in the final product. Thus, genome edited rice plants with improved yield attributes and stress resilience are expected to be accepted by the public and solve food crisis of a major portion of the globe.

Supplementary Information

The online version contains supplementary material available at 10.1007/s12298-024-01423-y.

A novel CRISPR/Cas9 system with high genomic editing efficiency and recyclable auxotrophic selective marker for multiple-step metabolic rewriting in Pichia pastoris

The methylotrophic budding yeast Pichia pastoris has been utilized to the production of a variety of heterologous recombinant proteins owing to the strong inducible alcohol oxidase promoter (pAOX1). However, it is difficult to use P. pastoris as the chassis cell factory for high-valuable metabolite biosynthesis due to the low homologous recombination (HR) efficiency and the limitation of handy selective markers, especially in the condition of multistep biosynthetic pathways. Hence, we developed a novel CRISPR/Cas9 system with highly editing efficiencies and recyclable auxotrophic selective marker (HiEE-ReSM) to facilitate cell factory in P. pastoris. Firstly, we improved the HR rates of P. pastoris through knocking out the non-homologous-end-joining gene (Δku70) and overexpressing HR-related proteins (RAD52 and RAD59), resulting in higher positive rate compared to the basal strain, achieved 97%. Then, we used the uracil biosynthetic genes PpURA3 as the reverse screening marker, which can improve the recycling efficiency of marker. Meanwhile, the HR rate is still 100% in uracil auxotrophic yeast. Specially, we improved the growth rate of uracil auxotrophic yeast strains by overexpressing the uracil transporter (scFUR4) to increase the uptake of exogenous uracil from medium. Meanwhile, we explored the optimal concentration of uracil (90 mg/L) for strain growth. In the end, the HiEE-ReSM system has been applied for the inositol production (250 mg/L) derived from methanol in P. pastoris. The systems will contribute to P. pastoris as an attractive cell factory for the complex compound biosynthesis through multistep metabolic pathway engineering and will be a useful tool to improve one carbon (C1) bio-utilization.

Development of an endogenously myc-tagged TARDBP (TDP-43) zebrafish model using the CRISPR/Cas9 system and homology directed repair

Many of the modern advances in cellular biology have been made by the expression of engineered constructs with epitope tags for subsequent biochemical investigations. While the utility of epitope tags has permitted insights in cellular and animal models, these are often expressed using traditional transgenic approaches. Using the CRISPR/Cas9 system and homology directed repair we recombine a single myc epitope sequence following the start codon of the zebrafish ortholog of TARDBP (TDP-43). TDP-43 is an RNA binding protein that is involved in the neurodegenerative disease amyotrophic lateral sclerosis and frontotemporal dementia. We report that zebrafish expressing the myc-tardbp engendered allele produced a stable protein that was detected by both western blot and immunofluorescence. Furthermore, both heterozygous and homozygous carriers of the myc-tardbp allele developed to sexual maturity. We propose that the methodology used here will be useful for zebrafish researchers and other comparative animal biologists interested in developing animal models expressing endogenously tagged proteins.

Inhibition of DNA ligase IV enhances the CRISPR/Cas9-mediated knock-in efficiency in mouse brain neurons

CRISPR/Cas9-mediated gene knock-in in in vivo neurons using in utero electroporation is a powerful technique, but the knock-in efficiency is generally low. We previously demonstrated that co-transfection with RAD51, a key molecule of the initial step of homology-directed repair (HDR), expression vector increased EGFP knock-in efficiency in the β-actin site up to 2.5-fold in the pyramidal neurons in layer 2/3 of the somatosensory cortex of mouse brain. To further improve the efficiency, we examined the effect of inhibition of DNA ligase IV (LIG4) that is an essential molecule for non-homologous end joining (NHEJ). Co-transfection with small hairpin RNA for LIG4 (shlig4) expression vector increased the EGFP knock-in efficiency in the β-actin site up to 3.6-fold compared to the condition without shlig4. RAD51 and shlig4 expression vector co-transfection further increased the knock-in efficiency up to 4.7-fold of the control condition. These results suggest that the inhibition of LIG4 is more effective than RAD51 overexpression, and it enhances the effect of RAD51 overexpression on HDR-mediated gene knock-in in vivo neurons.

Role of RS-1 derivatives in homology-directed repair at the human genome ATG5 locus

Genome editing is a useful tool in basic and clinical research. Among the several approaches used in genome editing, the CRISPR-Cas9 system using clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR-associated protein 9 (Cas9) along with a guide RNA has been developed recently. The CRISPR/Cas9 system induces site-specific double-stranded DNA breaks, which result in DNA repair via non-homologous end joining (NHEJ) or homology-directed repair (HDR). However, HDR efficiency is lower than that of NHEJ and accordingly poses a challenge in genome modification studies. Several chemical compounds including RS-1 have been shown to enhance the HDR knock-in process by two- to six-fold in HEK 293 cells and rabbit embryos. Based on this finding, we developed an antibiotic resistance system to screen RS-1 chemical derivatives, which may promote efficient HDR. In this study, we report several chemical compounds with high knock-in efficiency at the ATG5 gene locus, using HeLa cell-based assays.

Rates of homology directed repair of CRISPR-Cas9 induced double strand breaks are lower in naïve compared to primed human pluripotent stem cells

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Kinetics of Cas9-induced double strand break repair in conventional hPSC.

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Homology directed repair to resolve Cas9-induced double strand breaks is 40% lower in naïve hPSC compared to conventional hPSC.

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Naïve hPSC (4iLA) have a higher number of cells in G₁ phase of the cell cycle.

Gene editing in human pluripotent stem cells (hPSC) is a powerful tool for understanding biology, for drug discovery and gene therapy. Naïve hPSC have been suggested to be superior for gene editing compared to conventional ‘primed’ hPSC. Using droplet digital PCR, we uncover the kinetics of Cas9-induced double strand break repair in conventional hPSC. Cut but unrepaired alleles reach their maximum after 12–24 h. Homology directed repair plateaus after 24 h, whereas repair by non-homologous end joining continues until 48 h after Cas9 introduction. Using this method, we demonstrate that the rate of homology directed repair to resolve Cas9-induced double strand breaks is 40% lower in naïve hPSC compared to conventional hPSC, correlating with, and feasibly explained by, a higher number of cells in G₁ phase of the cell cycle in naïve hPSC. Therefore, naïve hPSC are less efficient for CRISPR/Cas9-mediated homology directed repair.

DNA repair protein RAD51 enhances the CRISPR/Cas9-mediated knock-in efficiency in brain neurons

Gene knock-in using the CRISPR/Cas9 system can be achieved in a specific population of neurons in the mouse brain, by using in utero electroporation to introduce DNA fragments into neural progenitor cells. Using this strategy, we previously knocked-in the EGFP coding sequence into the N-terminal region of the β-actin gene specifically in the pyramidal neurons in layer 2/3 of the somatosensory cortex. However, the knock-in efficiency was less than 2% of the transfected neurons. In this study, we sought to improve the knock-in efficiency using this system. First, we varied the length of the homology arms of the β-actin donor template DNA, and found that the knock-in efficiency was increased to ∼14% by extending the length of the 5' and 3' homology arms to 1.6 kb and 2.0 kb, respectively. We then tested the effect of the DNA repair protein RAD51 and the knock-in efficiency was increased up to 2.5-fold when co-transfecting with two different β-actin and a camk2a targeting EGFP knock-in modules. The RAD51 overexpression did not alter the migration of developing neurons, density or morphology of the dendritic spines compared to those in neurons not transfected with RAD51. RAD51 expression will be useful for increasing the knock-in efficiency in neurons in vivo by CRISPR/Cas9-mediated homology directed repair (HDR).

CRISPR-Cas9-mediated genomic multiloci integration in Pichia pastoris

BACKGROUND

Pichia pastoris (syn. Komagataella phaffii) is a widely used generally recognized as safe host for heterologous expression of proteins in both industry and academia. Recently, it has been shown to be a potentially good chassis host for the production of high-value pharmaceuticals and chemicals. Nevertheless, limited availability of selective markers and low efficiency of homologous recombination make this process difficult and time-consuming, particularly in the case of multistep biosynthetic pathways. Therefore, it is crucial to develop an efficient and marker-free multiloci gene knock-in method in P. pastoris.

RESULTS

A non-homologous-end-joining defective strain (Δku70) was first constructed using the CRISPR-Cas9 based gene deficiency approach. It was then used as a parent strain for multiloci gene integration. Ten guide RNA (gRNA) targets were designed within 100 bp upstream of the promoters or downstream of terminator, and then tested using an eGFP reporter and confirmed as suitable single-locus integration sites. Three high-efficiency gRNA targets (PAOX1UP-g2, PTEF1UP-g1, and PFLD1UP-g1) were selected for double- and triple-locus co-integration. The integration efficiency ranged from 57.7 to 70% and 12.5 to 32.1% for double-locus and triple-locus integration, respectively. In addition, biosynthetic pathways of 6-methylsalicylic acid and 3-methylcatechol were successfully assembled using the developed method by one-step integration of functional genes. The desired products were obtained, which further established the effectiveness and applicability of the developed CRISPR-Cas9-mediated gene co-integration method in P. pastoris.

CONCLUSIONS

A CRISPR-Cas9-mediated multiloci gene integration method was developed with efficient gRNA targets in P. pastoris. Using this method, multiple gene cassettes can be simultaneously integrated into the genome without employing selective markers. The multiloci integration strategy is beneficial for pathway assembly of complicated pharmaceuticals and chemicals expressed in P. pastoris.

Molecular Aspects of Zinc Finger Nucleases (ZFNs)-Mediated Gene Editing in Rat Embryos

This chapter contains a collection of protocols involved in using ZFNs to create rat models with various types of genome editing, including simple knockout, point mutation, large deletions, floxing, and insertions. The protocols cover ZFN and donor design criteria, in vitro transcription of ZFNs, validation of ZFNs activity in cultured cells, RNA stability test, microinjection sample preparation, genotyping and in vitro confirmation of floxed alleles, and Southern blot analysis, most of which are not limited to using ZFNs. Instead they apply to model creation in general. When appropriate, a comparison between ZFNs and CRISPR is provided. Standard pronuclear microinjection per se is not discussed.

Comparative analysis of single-stranded DNA donors to generate conditional null mouse alleles

BACKGROUND

The International Mouse Phenotyping Consortium is generating null allele mice for every protein-coding gene in the genome and characterizing these mice to identify gene-phenotype associations. While CRISPR/Cas9-mediated null allele production in mice is highly efficient, generation of conditional alleles has proven to be more difficult. To test the feasibility of using CRISPR/Cas9 gene editing to generate conditional knockout mice for this large-scale resource, we employed Cas9-initiated homology-driven repair (HDR) with short and long single stranded oligodeoxynucleotides (ssODNs and lssDNAs).

RESULTS

Using pairs of single guide RNAs and short ssODNs to introduce loxP sites around a critical exon or exons, we obtained putative conditional allele founder mice, harboring both loxP sites, for 23 out of 30 targeted genes. LoxP sites integrated in cis in at least one mouse for 18 of 23 genes. However, loxP sites were mutagenized in 4 of the 18 in cis lines. HDR efficiency correlated with Cas9 cutting efficiency but was minimally influenced by ssODN homology arm symmetry. By contrast, using pairs of guides and single lssDNAs to introduce loxP-flanked exons, conditional allele founders were generated for all four genes targeted, although one founder was found to harbor undesired mutations within the lssDNA sequence interval. Importantly, when employing either ssODNs or lssDNAs, random integration events were detected.

CONCLUSIONS

Our studies demonstrate that Cas9-mediated HDR with pairs of ssODNs can generate conditional null alleles at many loci, but reveal inefficiencies when applied at scale. In contrast, lssDNAs are amenable to high-throughput production of conditional alleles when they can be employed. Regardless of the single-stranded donor utilized, it is essential to screen for sequence errors at sites of HDR and random insertion of donor sequences into the genome.

Easi-CRISPR: a robust method for one-step generation of mice carrying conditional and insertion alleles using long ssDNA donors and CRISPR ribonucleoproteins

BACKGROUND

Conditional knockout mice and transgenic mice expressing recombinases, reporters, and inducible transcriptional activators are key for many genetic studies and comprise over 90% of mouse models created. Conditional knockout mice are generated using labor-intensive methods of homologous recombination in embryonic stem cells and are available for only ~25% of all mouse genes. Transgenic mice generated by random genomic insertion approaches pose problems of unreliable expression, and thus there is a need for targeted-insertion models. Although CRISPR-based strategies were reported to create conditional and targeted-insertion alleles via one-step delivery of targeting components directly to zygotes, these strategies are quite inefficient.

RESULTS

Here we describe Easi-CRISPR (Efficient additions with ssDNA inserts-CRISPR), a targeting strategy in which long single-stranded DNA donors are injected with pre-assembled crRNA + tracrRNA + Cas9 ribonucleoprotein (ctRNP) complexes into mouse zygotes. We show for over a dozen loci that Easi-CRISPR generates correctly targeted conditional and insertion alleles in 8.5-100% of the resulting live offspring.

CONCLUSIONS

Easi-CRISPR solves the major problem of animal genome engineering, namely the inefficiency of targeted DNA cassette insertion. The approach is robust, succeeding for all tested loci. It is versatile, generating both conditional and targeted insertion alleles. Finally, it is highly efficient, as treating an average of only 50 zygotes is sufficient to produce a correctly targeted allele in up to 100% of live offspring. Thus, Easi-CRISPR offers a comprehensive means of building large-scale Cre-LoxP animal resources.

The zebrafish genome editing toolkit

Zebrafish (Danio rerio) is a unique model organism at the functional intersection between a high fecundity and conserved vertebrate physiology while being amenable to a multitude of genome editing techniques. The genome engineering field has experienced an unprecedented rate of growth in the recent years since the introduction of designer endonucleases, such as zinc finger nucleases, transcription activator-like effector nucleases, and clustered regularly interspaced short palindromic repeats-Cas9 systems. With the ever-evolving toolset available to the scientific community, the important question one should ask is not simply how to make a mutant line, but rather how best to do so. For this purpose, understanding the toolset is just one end of the equation; understanding how DNA is repaired once double-strand breaks are induced by designer endonucleases, as well as understanding proper fish handling and line maintenance techniques, are also essential to rapidly edit the zebrafish genome. This chapter is outlined to provide a bird's-eye view on each of these three components. The goal of this chapter is to facilitate the adoption of the zebrafish as a model to study human genetic disease and to rapidly analyze the function of the vertebrate genome.

Gene editing for corneal disease management

Gene editing has recently emerged as a promising technology to engineer genetic modifications precisely in the genome to achieve long-term relief from corneal disorders. Recent advances in the molecular biology leading to the development of Clustered Regularly Interspaced Short Palindromic Repeats (CRISPRs) and CRISPR-associated systems, zinc finger nucleases and transcription activator like effector nucleases have ushered in a new era for high throughput in vitro and in vivo genome engineering. Genome editing can be successfully used to decipher complex molecular mechanisms underlying disease pathophysiology, develop innovative next generation gene therapy, stem cell-based regenerative therapy, and personalized medicine for corneal and other ocular diseases. In this review we describe latest developments in the field of genome editing, current challenges, and future prospects for the development of personalized gene-based medicine for corneal diseases. The gene editing approach is expected to revolutionize current diagnostic and treatment practices for curing blindness.