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CORRECTION article

Front. Plant Sci.
Sec. Plant Breeding
Volume 15 - 2024 | doi: 10.3389/fpls.2024.1415052

Corrigendum: Genetic amelioration of fruit and vegetable crops to increase biotic and abiotic stress resistance through CRISPR Genome Editing

Provisionally accepted
  • Jogesh Chandra Chaudhuri College, University of Calcutta, Kolkata, India

The final, formatted version of the article will be published soon.

    Vegetables, fruits, nuts, ornamental, aromatic, and medicinal plants are grouped under horticultural crops. Vegetables and fruits are essential dietary components of our meals as they are excellent sources of carbohydrates, fibres, proteins, vitamins, organic acids, antioxidants, minerals, and trace elements. Climate change and global warming render various dreadful effects on agriculture resulting in loss of crop yield and its nutritional value owing to abiotic factors (heat waves, irregular and uneven precipitation patterns) and biotic factors (increase in plant pathogens and pests). Vegetable and fruit crops are generally more vulnerable to abiotic and biotic stresses leading to huge loss of productivity and nutritional value. Traditional crop breeding such as crossbreeding and mutation-breeding has been successful for a long time to introduce required genetic variations in horticultural crops (Schaart et al., 2016). However, with increasing population, conventional breeding methods, being time-consuming and laborious, are not been able to live up to the growing market demands (Gao, 2021). Transgenic breeding surely provides an alternative by creating genetically modified crops with desired traits in less time but their use is strictly restricted or legally prohibited by government agencies of several countries under safety regulations (Voytas and Gao, 2014). The discovery of genome-editing technology, particularly CRISPR/Cas, has enabled researchers to make precise modifications at specific sites in the DNA to generate horticultural crops possessing novel and desired traits within a short time (Tian et al., 2021) (Figure 1). With the advent of genome editing technology in the 1990s and significant advancements made in the years thereafter, different methods of gene editing have revolutionized the area of research involving functional genomics and crop improvement. Genome editing technology involves the recognition of particular DNA sequences, followed by the induction of double-stranded breaks (DSBs)at specific sites in the targeted DNA using synthetic sequence-specific nucleases (SSNs) (Yin and Qiu, 2019). To maintain genome integrity, cells of almost all living organisms can detect and repair DSBs via either non-homologous end-joining (NHEJ)or homology-directed repair (HDR)(Sonoda et al., 2006). NHEJ is the most common but error-prone DNA-repair process, where DNA ligase IV joins DSBs with minimal DNA end processing in the absence of a repair template, often causing random insertion or deletion of base pairs, leading to a frameshift mutation and thereby resulting in gene knock-out or knockdown. Contrarily, HDR is a high-fidelity repair pathway that uses a homologous repair template DNA to ligate DSBs leading to gene modification or insertion of a new gene (Kumari et al., 2022). Zinc Finger Nucleases (ZFNs) were the first generation SSNs that were synthesized artificially by the fusion of dimers of Cys2-His2 zinc finger (ZF) domains and FokI restriction endonuclease domains and have been successfully used in Arabidopsis, Nicotiana, and Zea mays. However, ZFNs face problems over high-expense, moderate complexity in design, low specificity, difficulty in multiplexing, and consuming time (Kamburova et al., 2017). Later, the identification of transcription activator-like effectors (TALEs) from Xanthomonas spp. led to the synthesis of TALENs by joining dimers of TALE domains with FokI domains. TALENs have been used with great success in rice, wheat, Arabidopsis, potato, and tomato, but high cost, difficulty in multiplexing, complex designing modules, low specificity during screening, and labour-intensiveness pose challenges to their usage (Tavakoli et al., 2021). In 2012, the invention of the CRISPR/Cas9 system from Streptococcus pyogenes by Jennifer Doudna and Emmanuelle Charpentier (Jinek et al., 2012), followed by several other discoveries on different CRISPR/Cas systems and rapid advancements and modifications in the technology over the last decade have completely transformed the universe of genome-editing, with multiple gene targeting (multiplexing) becoming a reality. CRISPR/Cas technology possesses several advantages over ZFNs and TALENs for being cheaper, simpler, time-saving, reproducible, and highly efficient in high-yield multiplexing. This article reviews the application of different types of CRISPR/Cas systems in horticultural crops to alleviate biotic and abiotic stresses and discusses challenges and probable solutions. In nature, CRISPR/Cas system serves as an adaptive immune system of bacteria and archaea against the invading foreign DNA originating from plasmids and bacteriophages. The CRISPR/Cas9 system was the first to be discovered and modified into an efficient genome editing tool (Ishino et al., 1987; Jinek et al., 2012). The CRISPR/Cas9 technology comprises two components: the Cas9 endonuclease and the single guide RNA (sgRNA), produced by linking CRISPR RNA (crRNA) with trans-activating crRNA (tracrRNA) and is generally designed with a specific 20-nucleotide spacer sequence complementary to the ‘target’ DNA. For CRISPR/Cas9-mediated genome editing, sgRNA first binds to the DNA target and then recruits Cas9 endonuclease. Next, Cas9 endonuclease thoroughly searches a protospacer-adjacent motif (PAM) sequence, i.e., 5′-NGG-3′ (for S. pyogenes), in the target DNA and snips the complementary and the non-complementary strands using its two nuclease domains, HNH and RuvC, respectively, producing a blunt DSB (Ran et al., 2013). To expand the range of this technology, several subsequent modifications were introduced into the SpCas9 for recognition of different PAM sequences present in the target DNA, like SpCas9-VQR (5'-NGAN-3′ or 5'-NGNG-3′), SpCas9-EQR (5'-NGAG-3′) SpCas9-VRER (5'-NGCG-3′) and xCas9 (5'-NG-3′, 5'-GAA-3′, and 5'-GAT-3′) (Hu et al., 2018; Yamamoto et al., 2019). Moreover, the discoveries of different PAM site-recognizing Cas9 endonucleases from several other prokaryotes, viz., Cas9 from Streptococcus thermophilus, Neisseria meningitidis, Brevibacillus laterosporus, Staphylococcus aureus, and Geobacillus stearothermophilus identifies 5'-NNAGAAW-3′ and 5′-NGGNG-3′, 5'-NNNNGATT-3′, 5'-NNNCND-3′, 5'-NNGRRT-3′, and 5′-NNNNCRAA-3′ PAM sites, respectively, have also increased the puissance of the technology (Kim et al., 2021). Another CRISPR/Cas technology, CRISPR/Cas12a (previously known as CRISPR from Prevotella and Francisella1) system uses a 24-nucleotide spacer complementary sequence for crRNA-DNA/gRNA-DNA binding, doesn’t require a tracrRNA and possesses a smaller endonuclease than most Cas9 orthologs. CRISPR/Cas12a generates staggered-end DSBs after recognizing an AT-rich PAM sequence with a high frequency in the genome and is proving to be a better substitute for CRISPR/Cas9 (Moon et al., 2018). Besides, CRISPR/Cas13a is a single RNA-guided RNA-editing system that needs a crRNA containing a 28-nucleotide spacer complementation sequence to bind adjacent to a protospacer flanking sequence (3′-A/U/C-5′) for Cas13a-mediated target recognition. Cas13a was first identified from Leptotrichia shahii and was demonstrated to cleave single-stranded RNAs without the requirement of a tracrRNA (Robertson et al., 2022). Biotic stress involves the interaction of plants with plant pathogens such as bacteria, viruses, fungi, oomycetes, nematodes, etc., that hampers the normal growth and development of plants leading to a huge loss in quality and yield (around 30% of crop production worldwide) (van Esse et al., 2020). The generation of disease-resistant crop varieties using CRISPR/Cas technologies has proven to be effective in combating plant diseases in fruits and vegetables (Table 1). CRISPR/Cas mediated resistance against viruses Plant viruses are perilous pathogens causing massive destruction of productivity in horticultural crops. Based on genome composition, plant viruses are grouped into five major categories: double-stranded RNA (dsRNA) viruses, positive sense single-stranded RNA (+ssRNA) viruses, negative sense single-stranded RNA (-ssRNA) viruses, single-stranded DNA (ssDNA) viruses and double-stranded DNA (dsDNA) viruses (Roossinck et al., 2015). Researchers have employed two main strategies to design sgRNAs for engineering virus-resistant plants. The first strategy involves direct targeting of the virus genome. For example, Tomato yellow leaf curl virus (TYLCV) is a whitefly-transmitted monopartite Begomovirus that causes significant loss of worldwide tomato production. Engineering tomato plants with CRISPR/Cas9 targeting the sequences encoding intergenic region (IR) and coat protein (CP) produced TYLCV-resistant plants where Cas9 was cloned under a virus-inducible rgsCaM promoter to overcome any potential off-target effects of Cas9 (Ghorbani Faal et al., 2020). In the plantain banana ‘Gonja Manjaya’, the presence of endogenous Banana streak virus (eBSV)as integrative viral elements in the genome limits banana production. CRISPR/Cas9 was utilized to introduce mutations that prevent proper transcription and/or translation into functional viral proteins to produce eBSV-resistant banana plants (Tripathi et al., 2019). Another devastating pathogen, Potato virus Y (PVY), belonging to the +ssRNA genome containing genus Potyvirus, brings about an 80% decrease in yield and poor tuber quality in potatoes. Targeting the PVY genome with CRISPR/LshCas13 system at the sequences encoding potyviral membrane protein (P3), cytoplasmic inclusion bodies laminating protein (CI), RNA-dependent RNA polymerase (NIb) or coat protein (CP) resulted in resistance against multiple strains of PVY in transgenic potato plants (Zhan et al., 2019). To enhance immunity in edited sweet potato plants against sweet potato virus disease, CRISPR/RfxCas13d system was used to target the Sweet potato chlorotic stunt virus genome encoding pathogenesis-related factor, RNase III endoribonuclease (Yu et al., 2022). The second strategy requires the manipulation of plant genes responsible for rendering plants susceptible to viruses. For instance, TYLCV-resistant tomatoes were obtained by CRISPR/Cas9-mediated mutagenesis of SlPelo that encodes a mRNA surveillance factor (Pramanik et al., 2021). CRISPR/Cas9-mediated multiplexed targeting of susceptibility genes in tomato plants also induces strong resistance to multiple viral diseases. Tomato Tobamovirus Multiplication 1a-d are functionally redundant genes essential for Tobamovirus multiplication in tomato. The generation of quadruple-mutant of SlTOM1a-d through CRISPR/Cas9 multiplexed genome editing exhibited enhanced resistance to Tobamoviruses (Ishikawa et al., 2022). RNA viruses hijack host cellular machinery, including eIF4E, eIF4G, and their isoforms, to complete their life cycle (Sanfaçon, 2015). Different isoforms of eIF4E were targeted by CRISPR/Cas9 to generate resistant varieties in tomato, potato, and cucumber against viruses belonging to Potyviridae (Chandrasekaran et al., 2016; Atarashi et al., 2020; Yoon et al., 2020; Lucioli et al., 2022; Noureen et al., 2022). Cassava is a tuberous root crop and a staple source of food for sub-Saharan African people. South African cassava mosaic virus (SACMV) is a whitefly-transmitted bipartite Begomovirus that causes regional pandemics in cassava production in East and Central Africa. Transformation of SACMV-susceptible and -resistant varieties of cassava protoplasts with a ribonucleoprotein complex containing the Cas9 nuclease and sgRNA (CRISPR/Cas9 RNPs) targeting the Ubiquitin E3 Ligase gene resulted in less virus titre in protoplasts of susceptible variety, similar to that of the resistant variety protoplasts (Chatukuta and Rey, 2020). Another group used RNP-mediated delivery of CRISPR/Cas9 machinery to enable editing of at least one allele of Coilin gene in potato. The edited Coilin gene-containing potato plants of the Chicago cultivar showed increased resistance to PVY (Makhotenko et al., 2019). Citrus canker, caused by Xanthomonas citri subsp. citri (Xcc), is one of the most economically destructive bacterial disease owing to its appearance at pre- and post-harvest stages. To suppress the immunity of citrus plants, Xcc secretes a TALE, PthA4 that binds to effector-binding elements present at the promoter region of Lateral Organ Boundaries 1 (LOB1) (Jia et al., 2016). Citrus canker resistance was first reported in Duncan grapefruit, where CRISPR/Cas9-mediated alteration of PthA4 effector binding elements of one allele of biallelic gene LOB1 gave partial resistance (Jia et al., 2016), and of two alleles gave complete resistance to Xcc (Jia et al., 2022a). In Wanjincheng orange, a multiplexed CRISPR/Cas9 genome editing strategy was applied to delete the entire PthA4 effector binding elements from the promoter region of all the alleles of CsLOB1 to produce citrus canker-resistant varieties (Peng et al., 2017) In Arabidopsis, Downy Mildew Resistance 6 (DMR6) encodes for 2-oxoglutarate Fe(II)-dependent oxygenase that facilitates pathogen infection. In tomato, targeting DMR6 ortholog, SlDMR6-1, via CRISPR/Cas9 resulted in broad-spectrum resistance against multiple pathogens, Pseudomonas syringae pv. tomato DC3000, Xanthomonas gardneri, X. perforans, Pseudoidium neolycopersici, and Phytophthora capsici (Thomazella et al., 2021). Likewise, CRISPR/Cas9-mediated mutagenesis of MusaDMR6 conferred resistance to Xanthomonas campestris pv. musacearum, which causes banana Xanthomonas wilt that accounts for huge losses in banana production in East and Central Africa (Tripathi et al., 2021). In apple, two independent research groups using two different transgene-free CRISPR/Cas9 genome editing strategies have demonstrated that editing of one or more genes belonging to the susceptibility gene family, DspA/E-Interacting Proteins From Malus , could alleviate fire blight susceptibility to Erwinia amilovora (Malnoy et al., 2016; Pompili et al., 2020). The successful application of CRISPR/Cas technology to mutate the genes responsible for susceptibility has led to the generation of horticultural crops resistant to fungal diseases. Oidium neolycopersici and Erysiphe necator cause powdery mildew in tomato and grapevine plants, respectively. Mildew Resistant Locus O (Mlo) encodes a seven-transmembrane domain-containing protein that is conserved throughout angiosperms and negatively regulates immunity to powdery mildew disease (Acevedo-Garcia et al., 2014). In tomato, two independent reports revealed CRISPR/Cas9-mediated targeting of SlMlo1 confer enhanced resistance to powdery mildew (Nekrasov et al., 2017; Pramanik et al., 2021). Further, (Nekrasov et al., 2017) tested and selfed a specific line of T0 transformants to obtain T-DNA-free slmlo1 plants. Transgene-free powdery mildew-resistant grapevine protoplasts were obtained by knocking out VvMlo7 via RNP-mediated delivery of CRISPR/Cas9 genome editing machinery (Malnoy et al., 2016). Another report showed CRISPR/Cas9-based alteration of VvMlo3 was able to produce powdery mildew-resistant grapevine plants (Wan et al., 2020). The multi-host fungal pathogen, Botrytis cinerea that causes grey mold disease in tomatoes and noble rot disease in grapevines, poses a serious threat to tomato and grapevine production at both pre- and post-harvest levels. The function of several tomato genes, including the well-characterized genes like Mitogen Activated Protein Kinase 3 (MAPK3), SlMYC2, Pectate Lyase, Acetylase 1a and 1b, and genes of unknown functions like Solyc12g100250, and Solyc12g100270, were identified during Botrytis cinerea infection through the generation of deletion mutants by CRISPR/Cas9. While knock-out mutants of SlMAPK3 and SlMYC2 were susceptible to Botrytis cinerea, loss-of-function of the other above-mentioned genes rendered tomato plants resistant to grey mold disease (Zhang et al., 2018; Shu et al., 2020; Jeon et al., 2020; Silva et al., 2021). In addition, both the single and double knock-out mutants of tomato Histone H3 Lysine Methyltransferases Set Domain Group33 and 34 (SDG33 and SDG34)produced via CRISPR/Cas9 exhibited alterations in H3K36 and H3K4 methylations. However, only the sdg33sdg34 plants and not sdg33 and sdg34 plants exhibited resistance to Botrytis cinerea (Bvindi et al., 2022). The fungal pathogen Colletotrichum spp. causes anthracnose of chilli resulting in major pre- and post-harvest losses. In chilli, CRISPR/Cas9-mediated modification Ethylene Response Factor 28 produced mutant lines with elevated resistance against anthracnose (Mishra et al., 2021). The causal organism of ring rot disease in apple is Botryosphaeria dothidea. CRISPR/Cas9-produced apple Cyclic Nucleotide-Gated Ion Channels 2 knock-out mutant calli exhibited significantly lower growth of B. dothidea, increased levels of salicylic acid accumulation and elevated expression of several defense-related genes including Pathogenesis-related genes, MdPR1, MdPR2, MdPR4, MdPR5, MdPR8, and MdPR10a compared to wild-type calli (Zhou et al., 2020). The most-well studied oomycete, Phytophthora infestans is famous for causing the devastating Irish potato famine of the 1840s, killing over a million people. Phytophthora infestans causes late blight in potato and tomato plants. Independent studies showing CRISPR/Cas9-targeted mutagenesis of five potato susceptibility genes, Defense, No Death1, CIB1/HBI1-like 1, DMR6-1, Caffeoyl-CoA O-methyltransferase and Signal Responsive 4, conferred resistance to late blight disease (Kieu et al., 2021; Hegde et al., 2021; Moon et al., 2022). However, knocking-out of MYB transcription factor S2 by CRISPR/Cas9 produced tomato mutants susceptible to P. infestans with increased necrotic cells, lesion sizes, disease index, and reduced expression of defense-related genes, indicating that SlMYBS2 acts as a positive regulator of resistance to P. infestans (Liu et al., 2021). CRISPR/Cas9-engineered cacao plants for the susceptible gene, Non-Expressor of Pathogenesis-Related 3, exhibited enhanced resistance to Phytophthora tropicalis (Fister et al., 2018). Editing of the virulent genes in oomycete pathogens provide an alternative strategy to achieve disease resistance. Phytophthora palmivora causes worldwide destruction of papaya plantations and reduction in yield. Extracellular cystatin-like cysteine protease inhibitor 8 is unique to P. palmivora and contributes to the virulence of the pathogen by inhibiting papain. CRISPR/Cas9-mediated PpalEPIC8 editing produced a less virulent version of the pathogen with reduced pathogenicity (Gumtow et al., 2018). Another oomycete, Peronophythora litchii causes downy blossom blight of litchi that results in tremendous economic loss in litchi production every year (Situ et al., 2020). Two independent research groups designed CRISPR/Cas9-based modification of two different virulent genes, Pectin Acetylesterase 5 and Avh142, from P. litchii. PlPAE5 encodes pectin acetylesterases that cause deacetylation of pectin and Avh142 is an RXLR effector that induces plant cell-death. Both strategies resulted in the production of less invasive and less virulent variants of P. litchii that are less capable of infecting litchi plants (Kong et al., 2019; Situ et al., 2020;). Plants experience single or multiple abiotic stresses simultaneously, which can lead to 50%-70% loss of crop productivity and poses a direct threat to achieving global food security. (Francini and Sebastiani, 2019). Apart from drought, salinity and temperature, the presence of heavy metals in the soil and excessive use of herbicides and weedicides also contribute to abiotic stress factors (Hamdan et al., 2022). Targeting one or more genes concomitantly utilising CRISPR/Cas technologies could be propitious for engineering abiotic stress-resilient varieties of fruits and vegetables (Table 2). Plants under drought stress manifest complex symptoms at multiple morphological, physiological, and biochemical levels that consequently lower the quality and yield of the produce. Knocking-out of tomato Auxin Response Factor 4 (ARF4) via CRISPR/Cas9 technology resulted in increased drought resistance and revival ability with induced morphological changes in stomata and vascular bundles, higher content of antioxidant substances, and up-regulated expression of ABA signal transduction pathway genes, like Scarecrow-Like 3 and Abscisic acid Insensitive 5 (Chen et al., 2021). Pipecolic acid is known to play an important role in salicylic acid-mediated plant immune response. CRISPR/Cas9-mediated targeting of tomato pipecolic acid biosynthetic pathway gene, Aberrant Growth and Death2-like Defense Response Protein 1, has led to increased drought resistance with enhanced CO2 assimilation, photosystems activities, antioxidant enzymes activities, ascorbate and glutathione content, and reduced reactive oxygen species accumulation, lipid peroxidation, and protein oxidation than the wild-type tomato plants (Wang et al., 2021a). Interestingly, the sdg33 and sdg34 tomato plants were drought-resistant and exhibited high water retention capacity during drought and improved recovery and survival, while sdg33sdg34 plants were superior drought stress-resistant (Bvindi et al., 2022). Contrarily, the positive regulators of drought stress were also identified by using CRISPR/Cas technology. For example, CRISPR/Cas9-generated SlMAPK3 mutant plants were drought-sensitive showing severe wilting symptoms, higher hydrogen peroxide content, and lower antioxidant enzymes activities as compared to the wild-type tomato plants (Wang et al., 2017). Knock-out mutant of another tomato pipecolic acid-related gene, Flavin-dependent Monooxygenase 1, exhibited damaged photosystems and impaired antioxidant systems and thus were more sensitive to drought (Wang et al., 2021a). In potato, Cycling Dof Factor 1 together with a long non-coding RNA (lncRNA) counterpart, StFLORE, regulate vegetative reproduction and water homeostasis. CRISPR/Cas9-mediated editing of StFLORE promoter region rendered potato mutant plants sensitive to drought due to disruption of stomatal growth and diurnal opening of stomata in an ABA-dependent manner (Ramírez Gonzales et al., 2021). Salinity stress impedes water absorption by altering the osmotic balance between plant roots and surrounding soil and severely affects the yield and quality of crops. CRISPR/Cas9-based precise removal of PRD domain, 8CM domain, or both of Hybrid Proline-rich Protein 1, resulted in high salinity tolerance at the germination and vegetative stages of tomato plants (Tran et al., 2021). CRISPR/Cas9 slarf4 mutants displayed decreased leaf area, CO2 assimilation, stomatal conductance, enhanced water use efficiency, and salt and osmotic stress resistance in comparison to wild-type tomato plants (Bouzroud et al., 2020). Transgene-free CRISPR/Cas12a-mediated HDR-based editing of one allele of tomato High-affinity K+ Transporter 1;2 has led to increased salinity stress tolerance, which was completely inherited by theprogeny plants (Vu et al., 2020). Another transgene-free genome editing approach was successful when potato plants manifested tolerance to salt and osmotic stress following CRISPR/Cas9 RNP-based editing of Coilin gene (Makhotenko et al., 2019). Alternatively, CRISPR/Cas9-mediated alteration of Salt Overlay Sensitive 1 resulted in increased sensitivity to salinity stress in tomato (Wang et al., 2021b). CRISPR/Cas9 slmapk3 plants, were showcasing salt stress-sensitivity with increased salinity-induced cell death, chlorophyll degradation, and reduced activities of antioxidant enzymes than wild-type tomato plants (Shu et al., 2022). In Cucurbita moschata, CRISPR/Cas9-based editing of Respiratory Burst Oxidase Homolog D showed salt stress hypersensitive phenotype with a decrease in root apex H2O2 and K+ content (Huang et al., 2019). Temperature stress occurs due to continuous rise or drop in temperature above or below the optimum temperature necessary for plant growth over a period of time. Both heat and cold stresses seriously affect the growth and productivity of crops. Despite being sensitive to drought and salinity stresses, tomato CRISPR/Cas9 slmapk3 displayed heat stress resistance accompanied by reduced wilting, membrane damage, and enhanced expression of transcripts of heat stress transcription factors and heat shock proteins (Yu et al., 2019). Conversely, CRISPR/Cas9-based modification of Calcium-Dependent Protein Kinase 28 rendered tomato plants sensitive to heat stress with increased levels of protein oxidation and lower antioxidant enzymes activities than wild-type plants (Hu et al., 2021). In lettuce, CRISPR/Cas9-generated knock-out mutants of 9-cis-Epoxycarotenoid Dioxygenase 4 were capable of seed germination above optimum temperature (Bertier et al., 2018). Compared to wild-type tomato plants, CRISPR/Cas9-produced C-repeat Binding Factor 1 knock-out plants demonstrated sensitivity to cold stress accompanied by more severe chilling-injury symptoms, higher electrolyte leakage, and less proline and protein contents, and antioxidant enzymes activities (Li et al., 2018). Excessive use of herbicides and weedicides causes herbicide stress that leaves a major effect on the physiology of the non-targeted crop plants. CRISPR/Cas technology was applied to prepare herbicide-resistant plants. For example, the tomato Acetolactate Synthase (ALS) gene was targeted using CRISPR/Cas9 technology to create herbicide-resistant plants (Yang et al., 2022). Moreover, transgene-free HDR-mediated genome editing of SlALS1 using Agrobacterium-assisted CRISPR/Cas9 delivery produced herbicide resistance in tomato plants (Danilo et al., 2019). Transgene-free herbicide-resistant watermelon plants were obtained via CRISPR/Cas9-mediated genome editing of ClALS (Tian et al., 2018). Likewise, PcALS gene of pear plant was manipulated by CRISPR/Cas9-based base-editing to obtain resistance to the herbicide, chlorosulfuron (Malabarba et al., 2021). Also, CRISPR/Cas9 base-editing of ALS gene was used to produce T-DNA-free imazapyr-resistant citrus Carrizo citrange plants (Alquézar et al., 2022). The application of CRISPR/Cas technology has proven to be quite successful in modern agriculture and in improving the agronomic traits of crops. However, barring tomato plants, the usage of CRISPR/Cas technology is very limited among horticultural crops. Though this technology is now being extended to different horticultural crops, researchers are experiencing several challenges during implementation. The success of CRISPR/Cas application depends on the availability of information about the whole-genome sequence, annotation of genes, and their functions in a particular crop. Therefore, more genome sequencing and functional genomics studies on vegetable and fruit plants are required due to the availability of limited data regarding the identification and characterization of genes controlling important traits, such as quality, yield, biotic, and abiotic stress tolerance (Li et al., 2022). Furthermore, polyploidy is common in vegetable and fruit crops, which make it difficult to study the genome due to their highly diverse and complex nature (Chen et al., 2019). Also, CRISPR/Cas technology has mostly been used to create loss-of-function mutations, which limits its application as gain-of-function mutations in positive regulators controlling important agronomic traits might prove to be advantageous in obtaining desired phenotype(s) in horticultural crops (Kim et al., 2021). Interestingly, a recent report demonstrating successful single or multiplexed activation of gene(s) present in anthocyanin and lignin biosynthesis pathways of pear calli via a third-generation CRISPR activation-mediated gain-of-function mutation system, CRISPR-Act3.0, raised the prospect of further broadening its application to other vegetable and fruit crops (Ming et al., 2022). Another major challenge resides in the perception of common people that do not make any distinction between genetically-modified and genome-edited crops and considers the production and consumption of both crop types to be hazardous to the environment and human health. Additionally, the absence of a common and unified legislative framework that differentiates genome-edited crops from genetically-modified crops and facilitates the production and marketing of genome-edited plants also aggravates the challenge (Bhatta and Malla, 2020). Every nation has drafted its legal framework for the release of genome-edited crops. In general, most countries of North and South America (USA, Canada, Argentina, Colombia), some countries of Asia (India, China, Japan), and Australia consider case-by-case procedures for the release of genome-edited crops and products, while most countries of Europe and New Zealand maintain a conservative approach by adhering to the same restrictive laws framed for production and release of both genetically-modified and genome-edited crops (Wang et al., 2022; Rukavtsova et al., 2023). The presence of the foreign DNA in GMOs is the main reason behind their non-acceptance in society, while the CRISPR/Cas-edited crops could be made transgene-free depending on the mode of delivery of CRISPR/Cas machinery during transformation and the choice of propagation method thereafter. Transgene can easily be removed from CRISPR/Cas-edited crops by self-pollinated sexual reproduction and off-target threat can be reduced by expressing CRISPR/Cas machinery under inducible promoters (Nekrasov et al., 2017; Ghorbani Faal et al., 2020). However, most horticultural crops are propagated vegetatively, especially fruit trees due to their long juvenile period. Moreover, propagation by sexual reproduction would produce transgene-free horticultural crops with undesirable traits as most of the important traits are best expressed when the corresponding genes are present in heterozygous conditions (Tsanova et al., 2021). For the generation of CRISPR/Cas-edited transgene-free horticultural crops, RNP-mediated delivery of CRISPR/Cas machinery through particle bombardment or protoplast transformation using PEG remains the most reliable method, closely followed by Agrobacterium-mediated transient expression of CRISPR/Cas cassette. Interestingly, transgene-free genome-edited plants can be produced from Agrobacterium-mediated stably transformed horticultural plants by using FLP/FRT and CRE/LOX site-specific recombination systems or by adding two additional Cas9 cleavage target sites at the T-DNA borders (Li et al., 2020b; Wan et al., 2021). The efficiency of transformation and regeneration of horticultural plants in case of both stable and transient transformation are quite low due to their recalcitrance nature towards regeneration protocols. Regeneration process involves tissue culture methods, which are quite difficult, expensive, time-consuming, and labour-intensive (Kumari et al., 2022). Therefore, invention of new technology is required that can bypass the regeneration phase of transformed plants. Plant virus-mediated delivery of CRISPR/Cas machinery has the potency to bypass the regeneration phase as this method takes advantage of virus replication and translocation within plants. The only disadvantage of this process is the limited cargo capacity of most DNA and +ssRNA viruses, which makes delivery of large DNA sequences deletion-prone and thereby preferred replication and translocation of deletion mutant viral vectors over the original vectors (Tsanova et al., 2021). Nevertheless, reports orchestrating the delivery of complete CRISPR/Cas9 machinery by Rhabdovirus and potato virus X and consequent successful editing of Nicotiana benthamiana genome enhances the possibility of extending the technology to horticultural plants (Ma et al., 2020; Ariga et al., 2020). Thus, transgene-free CRISPR/Cas-mediated gene/genome-edited mutants of horticultural crops are technically the same as those obtained in nature or from mutation breeding (Li et al., 2022). Conventional breeding and mutation breeding, besides being time-consuming, laborious, and expensive, lack specificity and cause introgression of undesired traits due to linkage drag. Conversely, CRISPR/Cas technology is simple, fast, versatile, and introduces changes in the target gene/genome in a well-defined and efficient manner (Wolter et al., 2019). Moreover, the ability of CRISPR/Cas technology to target multiple genes at one go with maximum precision compared to other existing technologies, and that too in a cost-effective manner, actually makes this technology truly exceptional for genome-edited plant breeding. The upcoming advancements in the CRISPR/Cas system itself and the associated technologies, such as delivery methods with or without regeneration phase, high-throughput sequence-based target analyses, whole genome sequencing, and other omics-based approaches, will simplify the process of identification of key genes controlling biotic and abiotic stress resistance pathways and thereby generation of biotic and abiotic stress-resistant plants.

    Keywords: Bacteria, Fungi, drought, Salinity, Fruits, Vegetables, CRISPR/Cas9

    Received: 09 Apr 2024; Accepted: 25 Jun 2024.

    Copyright: © 2024 Sardar. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) or licensor are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

    * Correspondence: Atish Sardar, Jogesh Chandra Chaudhuri College, University of Calcutta, Kolkata, India

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