key: cord-0922931-06f8qzzu
authors: Husaini, Amjad M.
title: High-value pleiotropic genes for developing multiple stress-tolerant biofortified crops for 21st-century challenges
date: 2022-02-16
journal: Heredity (Edinb)
DOI: 10.1038/s41437-022-00500-w
sha: b59c730c8760418c2c5f35c86a54d78f2cd6c393
doc_id: 922931
cord_uid: 06f8qzzu

The agriculture-based livelihood systems that are already vulnerable due to multiple challenges face immediate risk of increased crop failures due to weather vagaries. As breeders and biotechnologists, our strategy is to advance and innovate breeding for weather-proofing crops. Plant stress tolerance is a genetically complex trait. Additionally, crops rarely face a single type of stress in isolation, and it is difficult for plants to deal with multiple stresses simultaneously. One of the most helpful approaches to creating stress-resilient crops is genome editing and trans- or cis-genesis. Out of hundreds of stress-responsive genes, many have been used to impart tolerance against a particular stress factor, while a few used in combination for gene pyramiding against multiple stresses. However, a better approach would be to use multi-role pleiotropic genes that enable plants to adapt to numerous environmental stresses simultaneously. Herein we attempt to integrate and present the scattered information published in the past three decades about these pleiotropic genes for crop improvement and remodeling future cropping systems. Research articles validating functional roles of genes in transgenic plants were used to create groups of multi-role pleiotropic genes that could be candidate genes for developing weather-proof crop varieties. These biotech crop varieties will help create ‘high-value farms’ to meet the goal of a sustainable increase in global food productivity and stabilize food prices by ensuring a fluctuation-free assured food supply. It could also help create a gene repository through artificial gene synthesis for ‘resilient high-value food production’ for the 21st century.

Heredity; https://doi.org/10.1038/s41437-022-00500-w With newer 21st century challenges, agriculture transition has become imperative for food and nutritional security in the new era. Farming currently faces formidable challenges in feeding a growing population in a sustainable way (Firbank et al. 2018) . The situation has become complicated and worse in view of resource depletion, climate change, challenges due to pandemics like COVID-19. There is an immediate need to explore ways and means for developing a robust food production system that would survive the challenges of climate change, resource shrinkage and consumer preferences for nutritious food. In 2008, a High-Level Conference on World Food Security was convened by Food and Agricultural Organization, International Fund for Agricultural Development, United Nations World Food Programme and Consultative Group on International Agricultural Research. In this conference, 181 countries adopted a declaration that "It is essential to address the question of how to increase the resilience of present food production systems to challenges posed by climate change" (Husaini and Tuteja 2013) . National Climate Assessment by the United States, Global Change Research Program has highlighted that climate change poses several challenges to crop production, and crop yields are expected to decrease due to altered temperatures and water availability, soil erosion, and pest and disease outbreaks (Reidmiller et al. 2018 ). According to the Global Report on Food Crises (GRFC 2020), a joint consensus-based assessment of acute food insecurity situations around the world by 16 partner organizations, weather extremes were the primary drivers of the acute food insecurity situation for almost 34 million people in 25 countries in 2019 in comparison with 29 million in 2018. Furthermore, the growing intensity and severity of these extreme weather events caused an increase in the number of people facing food crises in 2019 in comparison with 2018 (GRFC 2020). These extreme weather events are generally an amulgam of multiple stress types and are very complicated to handle.

Crop plants often experience more than one biotic and abiotic stress (Hasanuzzaman et al. 2012) (Fig. 1) . Stress tolerance is genetically complex, and since plants rarely face a single type of stress in isolation, it becomes difficult for a plant to deal with multiple stresses simultaneously (Husaini 2014) . Stress tolerance results through an interplay of multiple genes. For example, multiple signaling cascades are used for broad-spectrum disease resistance. Induction of both salicylic acid (SA)-dependent and Jasmonic Acid /Ethylene-dependent defense response pathways may be required . Specific genes can be employed to develop plants with tolerance to multiple pathogens and biotic stresses. (Chun et al. 2012 ) have demonstrated the critical involvement of Nitric Oxide in both these pathways. Their study suggests that overexpression of Neuronal Nitric oxide synthase in Nicotiana tabacum can sufficiently induce both the JA/ETdependent pathway and the SA-dependent pathway and impart resistance against bacteria, fungi and viruses. Similarly, the overexpression of Arabidopsis thaliana Nonexpresser of PR GENES 1 (AtNPR1), a key regulator of broad-spectrum disease resistance (SAR), imparts resistance in Fragaria vesca L. against multiple pathogens. It imparts resistance against three fungal diseases (anthracnose caused by Colletotrichum acutatum, crown rot caused by C. gloeosporioides and powdery mildew caused by Podosphaera aphanis), and one bacterial disease viz. angular leaf spot caused by Xanthomonas fragariae (Silva et al. 2015) . These diseases cause considerable losses in fruit ranging between 50 and 80%.

This situation throws a big challenge to the food and nutritional security of the growing world population, which is projected to reach 9.7 billion by 2050 and will necessitate enhancement in agricultural production by at least 70-85% (Alexandratos and Bruinsma 2012) , (Ray et al. 2013) . However, the bright side is that there is impressive progress in plant biotechnology and the associated 'gene revolution' for crop improvement. The critical question is that can we mine biodiversity for food and nutritional security? (McCouch et al. 2013) suggested that the first step would be to obtain sequence information from the genomes of organisms to generate a 'parts list' that can help decipher mechanisms enabling plants to adapt to numerous environments and guide remodeling cropping systems for the future. There are arguably millions of traits in a complex organism such as the human, but the number of genes in the human genome is only about 20,000. Inevitably, there are at least some genes that affect multiple traits. The basic purpose of this paper is to provide a snapshot of this 'list' of candidate genes with critical roles that cause significant effects on the plant's phenotype, and can therefore be employed to develop biotech crops resilient to multiple stresses. Fig. 1 An overview of the 21st-century challenges and the high-value genes for breeding nutrient-dense weather-resilient crops. Crops can develop resilience towards stresses through genome engineering and increase uptake of nutrients through better nutrient use efficiency, and hence meet the food and nutritional security challenges. Such crops will support in establishing high-efficiency farms capable of giving better returns per unit of the applied input (time, space, labor, energy).

Pleiotropy is a phenomenon in which a single locus affects two or more distinct phenotypic traits. The term was formally introduced in 1910 by the German geneticist Ludwig Plate (Stearns 2010 ). Mendel too had described an early case of pleiotropy of three characters (seed coat color, flower color, and axial spots) in his classic 1866 paper (Stearns 2010) , (Fairbanks and Rytting 2001) . Pleiotropy cannot be treated as a unitary concept with a definable prevalence. It is a suite of conceptually related but empirically independent phenomena (Paaby and Rockman 2013) . Many classifications that are not mutually exclusive have been proposed by different workers (Paaby and Rockman 2013) , (Hodgkin 2002) , (Solovieff et al. 2013) , (Wagner and Zhang 2011) . At its essence, pleiotropy implies a mapping from one thing at the genetic level to multiple things at a phenotypic level (Paaby and Rockman 2013) . Pleiotropy is generally caused by a single molecular function involved in multiple biological processes (He and Zhang 2006) . Characterizing the underlying biological mechanism of a pleiotropic effect is a major challenge in the field as many alternative models for an apparent cross-phenotype effect can fit the observed data (Solovieff et al. 2013) . A popular method of measuring pleiotropy is to use knock-out genotypes in a homogenous background (Dudley et al. 2005) . By the same analogy, knock-in genotypes are used to validate the function of (trans)genes. In the last few decades, genetic modification (GM) techniques have been used to combine and modify genes from genetically distant individuals for conferring desired genetic traits on resultant biotech crops. The latest among these techniques focus on genome editing and include TALENand CRISPR-based methods like Cas-Clover, Crispr-Act3 (Abdallah et al. 2015; Xianghong et al. 2018; Luo et al. 2019; Pan et al. 2021; Roca Paixao et al. 2019) . Even there is scope to use CRISPR-based knock-out strategy to downregulate those cis-regulatory elements which function as negative regulators of abiotic stress (Zafar et al. 2020) .

Based on an in-depth perusal of earlier studies, we prepared a repository of pleitropic genes that should be the candidates for developing weather-resilient and nutrient-rich crop plants with inbuilt tolerance to multiple stresses. This review focuses on mining useful information about genes that promote abiotic stress tolerance (e.g. drought, salinity, submergence, cold, freezing and heat) and enhancing product quality. These 'high-value genes' can lay a strong foundation for a sustainable agricultural production model for assured food and nutritional security (Fig. 1) . For the sake of brevity, we focused on the cross-phenotype 'effects' of the selected transgenes, without much discussion about the underlying mechanisms of their action as that would have been beyond the scope of a single review. The information presented below shall be very useful for biotechnologists and breeders for developing better crops. For understanding the individual mechanisms in detail, it is recommended to refer to the respective cited research paper(s).

Oxidative damage in plants is a consequence of exposure to temperature extremes, high light intensity, water stress, salinity, and mineral deficiencies. During oxidative stress, the balance between reactive oxygen species production and the quenching activity of the antioxidants is disturbed. Plants with high antioxidant levels, either constitutive or induced, have better resistance to this oxidative damage. There is a well-known correlation between stress tolerance and activities of the major antioxidative enzymes viz. superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidise (APX), guaicol peroxidase, glutathione synthase and glutathione reductase (reviewed in (Hossain et al. 2011) ). Experiments using transgenic plant models that overproduce these antioxidant enzymes provide clear evidence that their over-production enhances tolerance against osmotic stress, high temperature, oxidative stress, photooxidative, and ozone damage ( (Husaini et al. 2010) ; (Kapoor et al. 2019) ; (Sun et al. 2020 )) ( Table 1) . A perusal of the table shows that it has been nearly one and a half decades since discovering their ROS scavenging properties using transgenic approach. However, still, they have not been exploited commercially. Critical evaluation of these engineered alterations in the antioxidant system on crop productivity under normal and multiple stress environments in field conditions should be allowed by the regulatory agencies to successfully meet the challenges of the 21st century.

Transcription factors play a significant role in controlling gene expression and activate the cascades of genes acting together. In order to impart tolerance against multiple stresses, a good strategy is to overexpress the transcription factor encoding genes that control stress-responsive multiple genes of various pathways. Some major families of transcription factors act under the influence of ethylene, jasmonic acid, SA, and other phytohormones, conferring abiotic stress tolerance.

Although much information about transcription factors has been gathered on their role in diverse abiotic stresses, selecting key TFs to develop abiotic stress-tolerant plants using transgenic technology is still an important issue before us ). Based on the perusal of available literature related to many TF families (including WRKY, NF-Y, Zn-finger etc.), we propose using some selected transcription factors that have a proven role in imparting tolerance against multiple stresses simultaneously (Table 1) .

AP2/Ethylene responsive element-binding proteins (EREBP) family includes a large group of plant-specific TFs. It is characterized by the presence of a highly conserved AP2/ ethylene-responsive element-binding factor (ERF) DNA-binding domain that directly interacts with GCC box and/or dehydrationresponsive element (DRE)/C-repeat element, cis-acting elements at the promoter of downstream target genes (Riechmann and Meyerowitz 1998) . These AP2/EREBP TFs are grouped into four major subfamilies: AP2 (Apetala2), RAV (related to ABI3/VP1), DREB (dehydration-responsive element-binding protein), and ERF (Sakuma et al. 2002) , (Sharoni et al. 2011) . We discuss the last two subfamilies as these are important for multiple stress tolerance.

(a) The Ethylene Responsive element-binding Factors: The ERF subfamily is the largest group of the AP2/EREBP TF family (Dietz et al. 2010 ) and functions in plant stress tolerance by regulating the stress-responsive genes through interacting with the cis-element GCC boxes with a core sequence of AGCCGCC (Ohme-Takagi and Shinshi 1995); (Hao et al. 1998 ). Ethylene Response Factor (ERF) gene imparts tolerance to multiple stress factors such as drought, salinity, cold, pathogens, etc. (Table 2 ). This is partly due to their involvement in hormonal signaling pathways like ethylene, JA, or SA (Liang et al. 2008) . ERFs act as a key regulatory hub. These are involved in ethylene, jasmonate, abscisic acid (ABA), and redox signaling in many abiotic stresses (Müller and Munné-Bosch 2015) . When constitutively overexpressed in transgenic tobacco, ERF from tomato confers enhanced tolerance to salt and pathogens by activating the expression of pathogen-related genes . Similarly, transgenic lines of tobacco overexpressing Tsi1 showed enhanced salt tolerance and resistance to pathogens (Park et al. 2001 ). The expression of many Pathogenesis-related (PR) genes, like PR1, PR2, PR3, SAR8.2 and osmotin got activated even under unstressed conditions. Overexpression A.M. Husaini of GmERF3 imparted resistance against tobacco mosaic virus (TMV) and enhanced salinity and drought tolerance in tobacco (Zhang et al. 2009 ). (b) Dehydration-Responsive Element-Binding Factors (DREB):

DREBs are well-characterized transcription factors known to play an important role in regulating gene expression in response to abiotic stresses via ABA-independent and ABAdependent manner ( Table 2) . Overexpression of HvCBF4 from barley in rice activates fifteen rice genes and increases tolerance to drought, high-salinity, and low-temperature stresses without stunting growth (Oh et al. 2007 ). (Hsieh et al. 2002) reported improved drought, chilling and oxidative stress tolerance of tomato plants expressing Arabidopsis DREB1. Similarly, overexpression of DREB1 in Arabidopsis results in the activation of expression of many stress-tolerance genes and tolerance of the plant to drought, high salinity, and/or freezing is improved (Jaglo-Ottosen et al. 1998); (Liu et al. 1998 ). Overexpression of DREB1A and OsDREB1 in transgenic Arabidopsis and rice plants, respectively, impart increased tolerance to drought, high salinity and freezing stress (Kasuga et al. 1999 ); (Gilmour et al. 2000) ; (Ito et al. 2006) . DREB1A induces the expression of stress-tolerance genes like kin1, rd29A, rd22, cor6.6, and cor15a (Park et al. 2001) . In an interesting study in Arabidopsis, it has been reported that a cystatin gene (cysteine proteinase inhibitor) AtCYSa possesses dehydration-responsive element (DRE) and abscisic acid (ABA)-responsive element (ABRE) in its promoter region . In transgenic Arabidopsis and yeast, this characteristic made AtCYSa as a DREB1A and AREB target gene, and enhanced tolerance against salt, oxidative, drought, and cold stresses. GmDREB2 and OsDREB2A overexpression in transgenic plants enhance drought and salt tolerance ); (Mallikarjuna et al. 2011) . Overexpression of ZmDREB2A results in improved droughtstress tolerance and enhanced thermo tolerance, indicating that ZmDREB2A had a dual function of mediating the expression of genes responsive to both water and heat stress (Qin et al. 2007) . Similarly, transgenic Arabidopsis plants overexpressing DREB2A show increased thermo tolerance, in addition to tolerance against water stress (Sakuma et al. 2006) .

Perception and signaling pathways are vital components of an adaptive response for plants' survival under stress conditions. Mitogen-Activated Protein Kinases (MAPKs) are serine/threonine protein kinases, which phosphorylate several substrates involved in numerous plant cellular responses. They perform a vital role in signal transduction pathways. Various stresses like low temperature, wounding, high osmolarity, high salinity, and ROS serve as signals for activating the MAPK cascade. MAPK cascade is a crucial convergent point for cross-talk between different abiotic stress responses (Table 3) . To elucidate, gene silencing and overexpression studies on GhRaf19, a Raf-like MAPKKK gene, revealed (Kovtun et al. 2000) .

OsMAPK5 overexpression in transgenic rice results in tolerance against salt stress and other abiotic stresses (Xiong and Yang 2003) . ZmMPK17 overexpression in transgenic tobacco results in enhanced tolerance against osmotic stress, cold and viral pathogens (Pan et al. 2012a) . Rice CDPK7 gene is a positive regulator in triggering salt/drought stress-responsive genes and has successfully imparted tolerance against cold, drought, and salinity stress in transgenic plants (Saijo et al. 2000) (Table 3) . 

Osmotin is a cysteine-rich PR-5c protein. It was discovered as a thaumatin-like stress-responsive protein synthesized and accumulated by tobacco cells under salt and desiccation stress (Singh et al. 1985) . It plays a major role in protecting plant plasma membranes under low plant water potential (Viktorova et al. 2012) . It gets accumulated in plants under prolonged exposure to cold also (D'angeli and Altamura 2007) , and its expression is also induced by SA, ABA, auxin, UV light, wounding, fungal infection, oomycetes, bacteria, and viruses (Fagoaga et al. 2001 ); (Anil Kumar et al. 2015) ; reviewed in (Husaini et al. 2011) ; (Husaini and Neri 2016) .

There are numerous reports which show that osmotin and its homologs impart: (a) salt tolerance (Singh et al. 1987 (Singh et al. , 1985 ; (Bol et al. 1990 ) ; (Zhu et al. 1993 (Zhu et al. ), 1995 (Barthakur et al. 2001) ; (Sokhansanj et al. 2006) ; (Husaini and Abdin 2008a) ; (Goel et al. 2010) , (b) drought tolerance (Barthakur et al. 2001) ; (Parkhi et al. 2009 ); (Sokhansanj et al. 2006) ; (Husaini and Abdin 2008b) ; (Goel et al. 2010 ), (c) cold tolerance (D'angeli and Altamura 2007), (d) and protection from fungal pathogens too (Raghothama et al. 1993) ; (Liu et al. 1994) ; (Abad et al. 1996) ; (Scovel et al. 2000) ; (Ramos et al. 2015) , (Xue et al. 2016) ; (Sripriya et al. 2017) . Osmotin from the resurrection plant Tripogon loliiformis has been used to confer tolerance to multiple abiotic stresses simultaneously (cold, drought, and salinity) in transgenic rice (Le et al. 2018) . Taken together, osmotin could be useful in developing biotic and abiotic stress-tolerant genetically engineered plants (reviewed in (Husaini and Rafiqi 2012) , (Husaini and Neri 2016) ) ( Table 4) .

Mineral deficiency in human beings is a grave global challenge . Approaches like diet diversification, supplementation through minerals, fortification of food items and biofortification are used to address the issue. Application of mineral micro-and macro-nutrients coupled with breeding Table 4 . Osmotin (PR-5 gene) gene is useful for incorporating multiple stress tolerance in plants.

Transgenic plant Response to abiotic stress References

Resistance to Phytophthora infestans (Liu et al. 1994) ; (Li et al. 1999) ; (Kaur et al. 2020) ; (Chen et al. 1999; Mackintosh et al. 2007 ); (Das et al. 2011) ; (Scovel et al. 2000) ; (Barthakur et al. 2001) ; (Noori and Sokhansanj 2008) ; (Sokhansanj et al. 2006) ; (Chowdhury et al. 2017) ; (Ouyang et al. 2005) ; (D'angeli and Altamura 2007); (Goel et al. 2010) ; (Husaini and Abdin 2008a) ; ; (Kumar et al. 2016) ; (Parkhi et al. 2009 Table 3 . Kinase genes useful for incorporating multiple stress tolerance in plants.

Zea mays Tolerance to cold, heat and salinity (Shou et al. 2004 ); (Pavlović et al. 2020) ; (Teige et al. 2004 ); (Jia et al. 2016) ; (Kovtun et al. 2000) ; (Long et al. 2014) ; (Xiong and Yang 2003) ; (Asano et al. 2012) ; (Pan et al. 2012a ); (Cai et al. 2014 ); (Saijo et al. 2000) ; (He et al. 2013 varieties with enhanced uptake of mineral elements, is a good strategy for biofortification of edible crops (Graham et al. 2001 ) (Graham et al. 2007 ); (Bouis 2000; Bouis et al. 2003) ; (Genc et al. 2005) ; (White and Broadley 2005) (Pfeiffer and McClafferty 2007) . An important consideration is that these elements must be bioavailable to humans so that the gut absorbs them during the process of digestion and assimilation. The use of transgenic plants for increasing the micronutrients in staple food crops is a promising approach. Iron content in rice seeds can be enhanced by overexpression of nicotianamine synthase (NAS) gene, catalyzing the trimerisation of S-adenosyl methionine to form nicotianamine (NA) and nicotianamine aminotransferase (Bashir et al. 2006) ; (Haydon and Cobbett 2007) ; (Kim et al. 2006) . Overexpression of NAS increases the secretion of phytosiderophores and the uptake of iron. NA chelates Fe(II) and Fe(III) cations, and plays an important role in its translocation and homeostasis (Takahashi et al. 2001) ; (Koike et al. 2004) . Iron is transported from the cytoplasm into the plastid by a permease in chloroplasts 1 (Duy et al. 2007) . It gets associated with ferritin, an iron-storage protein located in the plastid (Briat et al. 1999) ; (Petit et al. 2001) . In transgenic rice, the combined expression of Pvferritin and AtNAS1 has been shown to cause a six-fold increase in iron content in the endosperm. Phytase does not prevent this iron accumulation, but on the contrary helps reduce the iron anti-nutrient phytate. Hence, it can be concluded that the overexpression of NAS and ferritin in transgenic plants can increase metal translocation to seeds. Another approach is to knock-out genes involved in the biosynthetic pathway of phytate in crops, thereby increasing the bioavailability of iron and zinc to human beings. This approach has been successful in rice and wheat, where low phytate varieties were developed using RNAi or CRISPR-Cas mediated knockdown of Inositol 1,3,4,5,6-pentakisphosphate 2-kinase (IPK1) gene (Ali et al. 2013) , (Aggarwal et al. 2018) , (Ibrahim et al. 2021) .

In soil, mineral availability is influenced by its pH, cation exchange capacity, redox conditions, microbial activity, water content, soil structure, and organic matter content (Shuman 1998) ; (Frossard et al. 2000) . Fe, Zn, Cu, Ca and Mg in their cationic forms can be taken up by roots of all plant species, while Fe, Zn and Cu can be taken up by graminaceous species as metal-chelates too. Fe, Zn and Cu phytoavailability is generally enhanced in the rhizosphere of crops by the exudation of protons, siderophores and organic acids by roots (Hoffland et al. 2006) ; (Ismail et al. 2007 ); (Degryse et al. 2008) .

Plants use two strategies for uptake of iron from the soil (Grotz and Guerinot 2006) ; (Puig et al. 2007) . In non-graminaceous species, roots secrete organic acids and phenolic compounds to acidify the rhizosphere and enhance Fe 3+ concentration in the soil. Fe 3+ gets chelated to these compounds and is subsequently reduced by ferric reductases to Fe 2+ in the root epidermis (Robinson et al. 1999) ; (Wu et al. 2005) ; (Mukherjee et al. 2006) . Then zinc-regulated transporter and iron-regulated transporter (IRT) mediate Fe 2+ influx to root cells (Ishimaru et al. 2006; Vert et al. 2002) . In the second strategy, employed by cereals and grasses, phytosiderophores are secreated to chelate Fe 3+, and the Fe 3+ -phytosiderophore complex is taken up by root cells (Ishimaru et al. 2006; von Wirén et al. 1995) .

Maize yellow stripe 1 (YS1) protein belongs to the oligopeptide transporter (OPT) family and is a proton-coupled metal-complex symporter (Schaaf et al. 2004) . Its homologues play a vital role in the uptake of Fe 3+ -phytosiderophore by graminaceous species (strategy II plants) (Haydon and Cobbett 2007; Ishimaru et al. 2006; Puig et al. 2007) . YSL proteins and associated OPTs load and unload Fe 2+ -nicotianamine (Fe 2+ -NA) complexes into and out of the phloem for iron relocation within the plant. OsYSL2 is an Fe (II)-NA and Mn(II)-NA transporter involved in the phloem transport of both iron and manganese in rice (Koike et al. 2004) .

Furthermore, the YSL proteins catalyze the uptake of Znphytosiderophore complexes in graminaceous plant species (strategy II plants) (Haydon and Cobbett 2007; Suzuki et al. 2006; von Wirén et al. 1996) . Although some Ca 2+ channels in the plasma membrane are permeable to Zn 2+ White et al. 2002) , however, most of the Zn 2+ influx into the cytoplasm is facilitated by ZIPs (Assunção et al. 2001; Broadley et al. 2007; Colangelo and Guerinot 2006; Lopez-Millan et al. 2004; Palmgren et al. 2008; Pence et al. 2000) . ZIP family mediates Zn 2+ influx into the leaf cells (Ishimaru et al. 2005) . YSL proteins load zinc into the phloem, where it is transported as a Zn-NA complex to the sink tissues (Gross et al. 2003; Haydon and Cobbett 2007; Kruger et al. 2002; Puig et al. 2007; Waters and Grusak 2008) . Interestingly, plants that hyper-accumulate Zn exhibit constitutively high expression of genes encoding ZIPs, YSL proteins and NAS.

YSL protein has been shown to play a vital role in loading Cu into the phloem, which is then transported as Cu-NA complex (Mira et al. 2001 ) (DiDonato et al. 2004 Guo et al. 2003; Puig et al. 2007) ; (Waters and Grusak 2008) . Interestingly, the YSL proteins transport both Cu-NA complexes and the free Cu 2+ and Fe 2+ cations (Wintz et al. 2003) .

The above research findings clearly show that overexpression of YSL and NAS may increase metal uptake and translocation, especially iron, zinc, manganese and copper in transgenic plants. Such studies need to be undertaken to address the grave problems of mineral malnutrition in women and children. Various genes play a vital role in biofortification (Table 5) . However, there is a need to identify many more candidate genes that can impart gain-of-function attributes to genetically engineered crops. Based on the available literature, a set of few such candidate genes is presented in Table 6 .

The most successful crop breeding project was the incorporation of semidwarf genes to create the modern high-yielding varieties Table 5 . Genes useful for biofortification through mobilisation of multiple nutrients and enhancement of physiological parameters in plants.

Transgenic (Zeigler 2007) . Production of 'Golden Rice' was another significant advancement and involved the transfer of genes necessary for the accumulation of carotenoids (vitamin A precursors) in the rice endosperm (Ye et al. 2000) ; (Potrykus 2003) . It resulted in about 140 g of the rice providing a child's RDA for beta carotene (Raney and Pingali 2007) and has been shown to get efficiently converted to vitamin A in humans (Tang et al. 2009 ). GM crops have not met their full potential to deliver practical solutions to end-users, especially in developing countries. There was a report way back in 2001, wherein the European Commission confirmed the safety of GM crops and food, after painstaking research spanning 15 y and involving 81 projects with 400 scientists. Even the former founder of Greenpeace, Dr. Patrick Moore criticized Greenpeace as committing a "crime against humanity" for its opposition to GM Golden Rice. Further, 107 Nobel Laureates urged Greenpeace and its supporters to "abandon their campaign against 'GMOs' in general and Golden Rice in particular". However, golden rice has still not seen the light of the day, courtesy of biopolitics! A recent silver lining in the dark cloud is that the Philippines has recently in July 2021 approved the commercial production of golden rice and has become the first country to do so.

Costly regulatory regime favors multi-national companies Despite promising research results of genetically modified crops with beneficial agronomic traits like enhanced drought tolerance, salt tolerance and insect resistance, developed by publicly funded research, these have not reached end users because of the extremely high cost of regulatory compliance. Besides political, socioeconomic, cultural, and ethical concerns about modern biotech crops related to the fear of technological "neocolonialism" in developing countries, intellectual property rights, land ownership, customer choices, negative cultural and religious perceptions, and 'fear of the unknown' have impeded the spread of these crops. Such public concerns fueled and supported by vested interests have led to the over-regulation of this technology, threatening to retard its applications in agriculture reviewed in (Husaini and Tuteja 2013) . It is estimated that it costs up to US$20 million to gain commercial certification of a single GM crop. 1st World Food Prize Winner Professor M.S. Swaminathan has pitched for promoting more public-sector research in GM technology so that there can be inclusiveness in access to technology (Husaini and Sohail 2018) . It is high time that political will be shown to develop GM Crops in the public sector, as a complicated and costly regulatory regime is a blessing in disguise for MNCs! Table 6 . Some important genes for conferring traits beneficial for better crops.

Bioavailability Phytate degradation (Phytase) (White and Broadley 2009 ); (Bouis 2000) ; (Devappa et al. 2012) ; (Shewry and Ward 2012) ; (Shi et al. 2005) ; (Brinch-Pedersen et al. 2002) ; (Matuschek et al. 2001) ; (Shi et al. 2005) ; (Lucca et al. 2001) ; ; (Caimi et al. 1996) ; (Ali et al. 2013 

Agriculture is central to food and nutritional security as well as the general wellbeing of a majority population. Evolving resilient, holistic, and secure food systems that adapt to climate change and other stress factors is indispensable for human survival in the 21st century. Here, we demonstrate the role of major-effect multirole pleiotropic genes in imparting tolerance against multiple stresses per se or through modulation of regulatory pathways. The crops engineered using these genes can help better adopt resource conservation technologies, which are beneficial for environmental sustainability. These crops will possess better nutritional value, higher nitrogen and water use efficiencies, disease and pest tolerance, and can withstand water scarcity, flooding, high temperature, cold weather, salinity, mineral toxicity, etc. In addition to reducing carbon emissions by reducing fuel consumption, these can help in carbon sequestration too. In the future, biotech crops will be developed using genome engineering of these pleiotropic genes. They can even be synthesized artificially and pyramided to combat problems involving highly complex traits. To create a resilient high-value crop repertoire for 'High-Value Farms', these genes will be an indispensable asset.

Antifungal activity of tobacco osmotin has specificity and involves plasma membrane permeabilization

Genome editing for crop improvement: challenges and opportunities

RNAi-mediated downregulation of inositol pentakisphosphate kinase (IPK1) in wheat grains decreases phytic acid levels and increases Fe and Zn accumulation

World Agriculture towards 2030/2050: The 2012 Revision

Development of low phytate rice by RNAi mediated seed-specific silencing of inositol 1, 3, 4, 5, 6-pentakisphosphate 2-kinase gene (IPK1)

Osmotin: a plant sentinel and a possible agonist of mammalian adiponectin

Overexpression of a tobacco osmotin gene in carrot (Daucus carota L.) enhances drought tolerance

The Arabidopsis metal tolerance protein AtMTP3 maintains metal homeostasis by mediating Zn exclusion from the shoot under Fe deficiency and Zn oversupply

A rice calcium-dependent protein kinase OsCPK12 oppositely modulates salt-stress tolerance and blast disease resistance

Elevated expression of metal transporter genes in three accessions of the metal hyperaccumulator Thlaspi caerulescens

Enhanced tolerance to salt stress and water deficit by overexpressing superoxide dismutase in tobacco (Nicotiana tabacum) chloroplasts

Over-expression of osmotin induces proline accumulation and confers tolerance to osmotic stress in transgenic tobacco

Cloning and characterization of deoxymugineic acid synthase genes from graminaceous plants

Plant pathogenesis-related proteins induced by virus infection

Enrichment of food staples through plant breeding: a new strategy for fighting micronutrient malnutrition

Genetically modified food crops and their contribution to human nutrition and food quality

Regulation of plant ferritin synthesis: how and why

Engineering crop plants: getting a handle on phosphate

Zinc in plants

Cloning an ironregulated metal transporter from rice

ZmMKK1, a novel group A mitogenactivated protein kinase kinase gene in maize, conferred chilling stress tolerance and was involved in pathogen defense in transgenic tobacco

Fructan accumulation and sucrose metabolism in transgenic maize endosperm expressing a Bacillus amyloliquefaciens SacB gene

Overexpression of Populus tomentosa cytosolic ascorbate peroxidase enhances abiotic stress tolerance in tobacco plants

GmDREB2, a soybean DRE-binding transcription factor, conferred drought and high-salt tolerance in transgenic plants

Development of wheat scab symptoms is delayed in transgenic wheat plants that constitutively express a rice thaumatin-like protein gene

Increasing vitamin C content of plants through enhanced ascorbate recycling

The Arabidopsis ETHYLENE RESPONSE FACTOR1 regulates abiotic stress-responsive gene expression by binding to different cis-acting elements in response to different stress signals

Overexpression of a new osmotin-like protein gene (SindOLP) confers tolerance against biotic and abiotic stresses in sesame

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Put the metal to the petal: metal uptake and transport throughout plants

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Mobilization of Cu and Zn by root exudates of dicotyledonous plants in resin-buffered solutions and in soil

Arabidopsis thaliana root non-selective cation channels mediate calcium uptake and are involved in growth

The CarERF genes in chickpea (Cicer arietinum L.) and the identification of Car-ERF116 as abiotic stress responsive transcription factor

Localisation of antinutrients and qualitative identification of toxic components in Jatropha curcas seed

Gene expression profiling analysis of copper homeostasis in Arabidopsis thaliana

Arabidopsis Yellow Stripe-Like2 (YSL2): a metal-regulated gene encoding a plasma membrane transporter of nicotianamine-metal complexes

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Overexpression of TaPIEP1, a pathogen-induced ERF gene of wheat, confers host-enhanced resistance to fungal pathogen Bipolaris sorokiniana

A global view of pleiotropy and phenotypically derived gene function in yeast

The FRD3-mediated efflux of citrate into the root vasculature is necessary for efficient iron translocation

PIC1, an ancient permease in Arabidopsis chloroplasts, mediates iron transport

Two iron-regulated cation transporters from tomato complement metal uptake-deficient yeast mutants

Overexpression of monodehydroascorbate reductase in transgenic tobacco confers enhanced tolerance to ozone, salt and polyethylene glycol stresses

Increased tolerance to Phytophthora citrophthora in transgenic orange plants constitutively expressing a tomato pathogenesis related protein PR-5

Mendelian controversies: a botanical and historical review

Grand challenges in sustainable intensification and ecosystem services

Food Security Information Network (FSIN) Global Report on Food Crises 2020: Joint Analysis for Better Decisions World Food Programme

Potential for increasing the content and bioavailability of Fe, Zn and Ca in plants for human nutrition

Glutathione peroxidase-like protein of Synechocystis PCC 6803 confers tolerance to oxidative and environmental stresses in transgenic Arabidopsis

Tartary buckwheat FtMYB10 encodes an R2R3-MYB transcription factor that acts as a novel negative regulator of salt and drought response in transgenic Arabidopsis

Expression of TERF1 in rice regulates expression of stress-responsive genes and enhances tolerance to drought and high-salinity

Exploiting genotypic variation in plant nutrient accumulation to alleviate micronutrient deficiency in populations

Overexpression of the Arabidopsis CBF3 transcriptional activator mimics multiple biochemical changes associated with cold acclimation

Overexpression of osmotin gene confers tolerance to salt and drought stresses in transgenic tomato (Solanum lycopersicum L.)

Iron accumulation and enhanced growth in transgenic lettuce plants expressing the iron-binding protein ferritin

Addressing micronutrient malnutrition through enhancing the nutritional quality of staple foods: principles, perspectives and knowledge gaps

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FRD3 controls iron localization in Arabidopsis

Iron homeostasis related genes in rice

Molecular aspects of Cu, Fe and Zn homeostasis in plants

Characterization of the Arabidopsis metallothionein gene family: tissue-specific expression and induction during senescence and in response to copper N

Unique mode of GCC box recognition by the DNA-binding domain of ethylene-responsive element-binding factor (ERF domain) in plant

Enzymatic activity and functional analysis under multiple abiotic stress conditions of a dehydroascorbate reductase gene derived from Liriodendron Chinense

Plant response and tolerance to abiotic oxidative stress: antioxidant defense is a key factor Crop stress and its management: perspectives and strategies

Transporters of ligands for essential metal ions in plants

Molecular cloning and functional characterization of a novel cotton CBL-interacting protein kinase gene (GhCIPK6) reveals its involvement in multiple abiotic stress tolerance in transgenic plants

Toward a molecular understanding of pleiotropy

Seven types of pleiotropy

Organic anion exudation by lowland rice (Oryza sativa L.) at zinc and phosphorus deficiency

Glyoxalase system and reactive oxygen species detoxification system in plant abiotic stress response and tolerance: an intimate relationship

Tomato plants ectopically expressing Arabidopsis CBF1 show enhanced resistance to water deficit stress

Challenges of climate change: Omics-based biology of saffron plants and organic agricultural biotechnology for sustainable saffron production

Development of transgenic strawberry (Fragaria x ananassa Duch.) plants tolerant to salt stress

Overexpression of tobacco osmotin gene leads to salt stress tolerance in strawberry (Fragaria× ananassa Duch.) plants

Role of osmotin in strawberry improvement

Biotech crops: Imperative for achieving the Millenium Development Goals and sustainability of agriculture in the climate change era

Time to redefine organic agriculture: Can't GM crops be certified as organics?

Approaches for gene targeting and targeted gene expression in plants

Sustainable saffron (Crocus sativus Kashmirianus) production: technological and policy interventions for Kashmir

Modifying strawberry for better adaptability to adverse impact of climate change

Challenges of Climate Change to Strawberry Cultivation: Uncertainty and Beyond

CRISPR/Cas9 mediated disruption of Inositol Pentakisphosphate 2-Kinase 1 (TaIPK1) reduces phytic acid and improves iron and zinc accumulation in wheat grains

OsZIP4, a novel zinc-regulated zinc transporter in rice

Rice plants take up iron as an Fe3+-phytosiderophore and as Fe2+

Genetic and genomic approaches to develop rice germplasm for problem soils

Functional analysis of rice DREB1/CBF-type transcription factors involved in coldresponsive gene expression in transgenic rice

Arabidopsis CBF1 overexpression induces COR genes and enhances freezing tolerance

A loss-of-function mutation in AtYSL1 reveals its role in iron and nicotianamine seed loading

A Raf-like MAPKKK gene, GhRaf19, negatively regulates tolerance to drought and salt and positively regulates resistance to cold stress by modulating reactive oxygen species in cotton

Overexpression of AtMYB44 enhances stomatal closure to confer abiotic stress tolerance in transgenic Arabidopsis

Antioxidant enzymes regulation in plants in reference to reactive oxygen species (ROS) and reactive nitrogen species (RNS)

A combination of the Arabidopsis DREB1A gene and stress-inducible rd29A promoter improved drought-and low-temperature stress tolerance in tobacco by gene transfer

Improving plant drought, salt, and freezing tolerance by gene transfer of a single stressinducible transcription factor

Over-expression of osmotin (OsmWS) gene of Withania somnifera in potato cultivar 'Kufri Chipsona 1'imparts resistance to Alternaria solani

Localization of iron in Arabidopsis seed requires the vacuolar membrane transporter VIT1

Overexpression of the sweetpotato peroxidase gene swpa4 enhances tolerance to methyl viologen-mediated oxidative stress and dehydration in Arabidopsis thaliana

Overexpression of sweetpotato swpa4 peroxidase results in increased hydrogen peroxide production and enhances stress tolerance in tobacco

Expression of a sweet cherry DREB1/CBF ortholog in Arabidopsis confers salt and freezing tolerance

OsYSL2 is a rice metal-nicotianamine transporter that is regulated by iron and expressed in the phloem

Functional analysis of oxidative stressactivated mitogen-activated protein kinase cascade in plants

A metal-binding member of the late embryogenesis abundant protein family transports iron in the phloem Ofricinus communis L

Beyond just being foot soldiers-osmotin like protein (OLP) and chitinase (Chi11) genes act as sentinels to confront salt, drought, and fungal stress tolerance in tomato

Enhanced stress-tolerance of transgenic tobacco plants expressing a human dehydroascorbate reductase gene

Mobilization of vacuolar iron by AtNRAMP3 and AtNRAMP4 is essential for seed germination on low iron

An osmotin from the resurrection plant Tripogon loliiformis (TlOsm) confers tolerance to multiple abiotic stresses in transgenic rice

Simultaneous overexpression of both CuZn superoxide dismutase and ascorbate peroxidase in transgenic tall fescue plants confers increased tolerance to a wide range of abiotic stresses

Signaling crosstalk between salicylic acid and ethylene/jasmonate in plant defense: do we understand what they are whispering?

Transgenic potato plants expressing osmotin gene inhibits fungal development in inoculated leaves

A novel activator-type ERF of Thinopyrum intermedium, TiERF1, positively regulates defence responses

A novel strategy of natural plant ferritin to protect DNA from oxidative damage during iron oxidation

Osmotin overexpression in potato delays development of disease symptoms

Two transcription factors, DREB1 and DREB2, with an EREBP/AP2 DNA binding domain separate two cellular signal transduction pathways in drought-and lowtemperature-responsive gene expression, respectively, in Arabidopsis

GbMPK3, a mitogen-activated protein kinase from cotton, enhances drought and oxidative stress tolerance in tobacco

Identification and characterization of several new members of the ZIP family of metal ion transporters in Medicago truncatula

Genetic engineering approaches to improve the bioavailability and the level of iron in rice grains

Efficient TALEN-mediated gene editing in wheat

A novel DREB transcription factor from Halimodendron halodendron leads to enhance drought and salt tolerance in Arabidopsis

Overexpression of defense response genes in transgenic wheat enhances resistance to Fusarium head blight

Expression of OsDREB2A transcription factor confers enhanced dehydration and salt stress tolerance in rice

Oxidation of polyphenols in phytatereduced high-tannin cereals: effect on different phenolic groups and on in vitro accessible iron

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Evidence for the plant-specific intercellular transport of the Arabidopsis copper chaperone CCH

Expression profiling of the Arabidopsis ferric chelate reductase (FRO) gene family reveals differential regulation by iron and copper

Ethylene response factors: a key regulatory hub in hormone and stress signaling

Transgenic rice is a source of iron for iron-depleted rats

Wheat plants containing an osmotin gene show enhanced ability to produce roots at high NaCl concentration

Expression of barley HvCBF4 enhances tolerance to abiotic stress in transgenic rice

Ethylene-inducible DNA binding proteins that interact with an ethylene-responsive element

Transformation of tomatoes with osmotin and chitinase genes and their resistance to Fusarium wilt

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Zinc biofortification of cereals: problems and solutions

CRISPR-Act3. 0 for highly efficient multiplexed gene activation in plants

ZmMPK17, a novel maize group D MAP kinase gene, is involved in multiple stress responses

An ethylene response factor (ERF5) promoting adaptation to drought and salt tolerance in tomato

Overexpression of the tobacco Tsi1 gene encoding an EREBP/AP2-type transcription factor enhances resistance against pathogen attack and osmotic stress in tobacco

Expression of apoplastically secreted tobacco osmotin in cotton confers drought tolerance

Introduction of the Nicotiana protein kinase (NPK1) gene by combining Agrobacterium-mediated transformation and recurrent somatic embryogenesis to enhance salt tolerance in cauliflower

The molecular physiology of heavy metal transport in the Zn/Cd hyperaccumulator Thlaspi caerulescens

Structure and differential expression of the four members of the Arabidopsis thaliana ferritin gene family

HarvestPlus: breeding crops for better nutrition

Nutritionally enhanced rice to combat malnutrition disorders of the poor

Over expression of cytosolic copper/zinc superoxide dismutase from a mangrove plant Avicennia marina in indica rice var Pusa Basmati-1 confers abiotic stress tolerance

Copper and iron homeostasis in Arabidopsis: responses to metal deficiencies, interactions and biotechnological applications

Regulation and functional analysis of ZmDREB2A in response to drought and heat stresses in Zea mays L

Analysis of an osmotically regulated pathogenesis-related osmotin gene promoter

Root engineering in barley: increasing cytokinin degradation produces a larger root system, mineral enrichment in the shoot and improved drought tolerance

Crystal structure of an antifungal osmotin-like protein from Calotropis procera and its effects on Fusarium solani spores, as revealed by atomic force microscopy: Insights into the mechanism of action

Sowing a gene revolution

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The AP2/EREBP family of plant transcription factors

A ferric-chelate reductase for iron uptake from soils

Improved drought stress tolerance in Arabidopsis by CRISPR/dCas9 fusion with a Histone AcetylTransferase

Over-expression of a single Ca2 +-dependent protein kinase confers both cold and salt/drought tolerance on rice plants

DNA-binding specificity of the ERF/AP2 domain of Arabidopsis DREBs, transcription factors involved in dehydration-and cold-inducible gene expression

Functional analysis of an Arabidopsis transcription factor, DREB2A, involved in droughtresponsive gene expression

ZmYS1 functions as a proton-coupled symporter for phytosiderophore-and nicotianamine-chelated metals

Genetic engineering of agronomic and ornamental traits in carnation

Overexpression of the ethylene-responsive factor gene BrERF4 from Brassica rapa increases tolerance to salt and drought in Arabidopsis plants

Gene structures, classification and expression models of the AP2/EREBP transcription factor family in rice

Exploiting genetic variation to improve wheat composition for the prevention of chronic diseases

The maize low-phytic acid 3 encodes a myo-inositol kinase that plays a role in phytic acid biosynthesis in developing seeds

GhMPK7, a novel multiple stressresponsive cotton group C MAPK gene, has a role in broad spectrum disease resistance and plant development

Expression of the Nicotiana protein kinase (NPK1) enhanced drought tolerance in transgenic maize

Micronutrient fertilizers

The Arabidopsis NPR1 gene confers broad-spectrum disease resistance in strawberry

Micronutrient deficiency: A global challenge and physiological approach to improve grain productivity under low zinc availability

Proteins associated with adaptation of cultured tobacco cells to NaCl

Characterization of osmotin: a thaumatin-like protein associated with osmotic adaptation in plant cells

Comparison of bacterial and plant genes participating in proline biosynthesis with osmotin gene, with respect to enhancing salinity tolerance of transgenic tobacco plants

Pleiotropy in complex traits: challenges and strategies

Over-expression of ApKUP3 enhances potassium nutrition and drought tolerance in transgenic rice

Enhancement of sheath blight tolerance in transgenic rice by combined expression of tobacco osmotin (ap24) and rice chitinase (chi11) genes

One hundred years of pleiotropy: a retrospective

Overexpression of monodehydroascorbate reductase from a mangrove plant (AeMDHAR) confers salt tolerance on rice

Response of plants to water stress: a metaanalysis

Biosynthesis and secretion of mugineic acid family phytosiderophores in zincdeficient barley

Enhanced tolerance of rice to low iron availability in alkaline soils using barley nicotianamine aminotransferase genes

Golden Rice is an effective source of vitamin A

Overexpression of the pepper transcription factor CaPF1 in transgenic Virginia pine (Pinus virginiana Mill.) confers multiple stress tolerance and enhances organ growth

A roadmap for zinc trafficking in the developing barley grain based on laser capture microdissection and gene expression profiling

The MKK2 pathway mediates cold and salt stress signaling in Arabidopsis

SodERF3, a novel sugarcane ethylene responsive factor (ERF), enhances salt and drought tolerance when overexpressed in tobacco plants

Transgenic Arabidopsis plants expressing the rice dehydroascorbate reductase gene are resistant to salt stress

Enhanced iron and zinc accumulation in transgenic rice with the ferritin gene

IRT1, an Arabidopsis transporter essential for iron uptake from the soil and for plant growth

Osmotin, a pathogenesis-related protein

The pleiotropic structure of the genotype-phenotype map: the evolvability of complex organisms

Maize WRKY transcription factor ZmWRKY106 confers drought and heat tolerance in transgenic plants

Recent advances in utilizing transcription factors to improve plant abiotic stress tolerance by transgenic technology

Ectopic overexpression of tomato JERF3 in tobacco activates downstream gene expression and enhances salt tolerance

A novel ethylene-responsive factor from Tamarix hispida, ThERF1, is a GCC-box-and DRE-motif binding protein that negatively modulates abiotic stress tolerance in Arabidopsis

Overexpression of cytosolic ascorbate peroxidase in tomato confers tolerance to chilling and salt stress

Transgenic tomato (Lycopersicon esculentum) overexpressing cAPX exhibits enhanced tolerance to UV-B and heat stress

Whole-plant mineral partitioning throughout the life cycle in Arabidopsis thaliana ecotypes Columbia, Landsberg erecta, Cape Verde Islands, and the mutant line ysl1ysl3

Biofortifying crops with essential mineral elements

Biofortification of crops with seven mineral elements often lacking in human diets-iron, zinc, copper, calcium, magnesium, selenium and iodine

Genes for calciumpermeable channels in the plasma membrane of plant root cells

Expression profiles of Arabidopsis thaliana in mineral deficiencies reveal novel transporters involved in metal homeostasis

Uptake kinetics of ironphytosiderophores in two maize genotypes differing in iron efficiency

Roots of iron-efficient maize also absorb phytosiderophore-chelated zinc

Rice endosperm iron biofortification by targeted and synergistic action of nicotianamine synthase and ferritin

HMA P-type ATPases are the major mechanism for rootto-shoot Cd translocation in Arabidopsis thaliana

Molecular and biochemical characterization of the Fe (III) chelate reductase gene family in Arabidopsis thaliana

Transcriptional modulation of ethylene response factor protein JERF3 in the oxidative stress response enhances tolerance of tobacco seedlings to salt, drought, and freezing

Cas-CLOVER™: A High-Fidelity Genome Editing System for Safe and Efficient Modification of Cells for Immunotherapy

Disease resistance and abiotic stress tolerance in rice are inversely modulated by an abscisic acid-inducible mitogen-activated protein kinase

Increased expression of native cytosolic Cu/Zn superoxide dismutase and ascorbate peroxidase improves tolerance to oxidative and chilling stresses in cassava (Manihot esculenta Crantz)

Isolation and molecular characterization of the Triticum aestivum L. ethylene-responsive factor 1 (TaERF1) that increases multiple stress tolerance

Overexpression of OsOSM1 enhances resistance to rice sheath blight

The cotton WRKY transcription factor GhWRKY17 functions in drought and salt stress in transgenic Nicotiana benthamiana through ABA signaling and the modulation of reactive oxygen species production

ERF transcription factors involved in salt response in tomato

Engineering the provitamin A (β-carotene) biosynthetic pathway into (carotenoid-free) rice endosperm

High level of reduced glutathione contributes to detoxification of lipid peroxide-derived reactive carbonyl species in transgenic Arabidopsis overexpressing glutathione reductase under aluminum stress

Overexpression of soybean GmERF9 enhances the tolerance to drought and cold in the transgenic tobacco

Enhancement of stress tolerance in transgenic tobacco plants overexpressing Chlamydomonas glutathione peroxidase in chloroplasts or cytosol

Ectopic expression of pepper CaPF1 in potato enhances multiple stresses tolerance and delays initiation of in vitro tuberization

Engineering abiotic stress tolerance via CRISPR/Cas-mediated genome editing

Rice and the millennium development goals: the International Rice Research Institute's strategic plan

Overexpression of the soybean GmERF3 gene, an AP2/ERF type transcription factor for increased tolerances to salt, drought, and diseases in transgenic tobacco

A Cu/Zn superoxide dismutase gene from Saussurea involucrata Kar. & Kir., SiCSD, enhances drought, cold, and oxidative stress in transgenic tobacco

Two cysteine proteinase inhibitors from Arabidopsis thaliana, AtCYSa and AtCYSb, increasing the salt, drought, oxidation and cold tolerance

Expression of an ABA-responsive osmotin-like gene during the induction of freezing tolerance in Solanum commersonii

AMH is grateful to Ms. Asma Khurshid for the help in collecting relevant literature for the manuscript.

The author declares no competing interest.

Correspondence and requests for materials should be addressed to Amjad M. Husaini.

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