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Rootstock

A rootstock, also known as a stock or understock, is the lower portion of a , typically consisting of the roots and lower , that serves as the base onto which a (the upper portion of another ) is grafted in . This technique allows for the of plants that are difficult to root from cuttings, alters the vigor and size of the resulting , and imparts desirable traits such as resistance, tolerance, and adaptation to specific or climate conditions. Rootstocks are widely used in the cultivation of fruit trees, grapevines, and other crops to improve , , and overall performance.

Fundamentals

Definition and Purpose

In , a rootstock refers to the lower portion of a grafted , consisting primarily of the and the basal , which serves as the foundational structure onto which the —the upper portion providing desirable above-ground traits—is attached. This combination forms a composite where the rootstock provides essential below-ground functions, including anchorage in the , absorption and transport of and nutrients, and overall structural support for the . The primary purposes of using rootstocks in grafting are to enhance the performance and adaptability of the scion by imparting traits such as improved resistance to soil-borne diseases and pests, tolerance to adverse environmental conditions like poor or , control over plant vigor and mature size, and facilitation of the of elite scion varieties on more resilient root systems. For instance, rootstocks can dwarf the overall plant size to suit high-density orchards or enable cultivation in regions where the scion alone would fail due to incompatible or climate factors. These benefits arise from the rootstock's influence on architecture, uptake efficiency, and physiological interactions with the scion, ultimately improving , , and economic viability in commercial production. While the determines key above-ground characteristics such as fruit quality, flower color, and canopy architecture, the specifically contributes below-ground attributes like depth, branching patterns, and overall vigor, creating a synergistic relationship that neither part could achieve independently. This distinction underscores the 's in mitigating limitations of the , such as susceptibility to root pathogens or inability to thrive in specific edaphic conditions. Rootstocks are categorized into two main types based on propagation methods: seedling rootstocks, often derived from seeds of wild or related species to provide and hardiness, and clonal rootstocks, which are vegetatively propagated through methods like cuttings or to ensure uniformity and preservation of selected traits across generations. Seedling types are commonly used for their vigor in open-pollinated scenarios, whereas clonal types offer predictability in performance, particularly for dwarfing or disease-resistant varieties.

Grafting Principles

Grafting involves joining a scion from one plant to the rootstock of another to form a functional union, with success depending on precise techniques that ensure close contact between the vascular tissues. Basic methods include whip-and-tongue, cleft, and bud grafting, each designed to maximize cambium alignment while minimizing exposure to air and pathogens. In the whip-and-tongue method, a diagonal cut is made on both the scion and rootstock, followed by a secondary "tongue" cut about one-third of the way down to interlock the pieces, promoting stability during healing. The cleft graft splits the rootstock lengthwise to insert wedge-shaped scions, typically two for balance, ensuring at least one cambium layer aligns on each side. Bud grafting, or chip budding, entails removing a single bud with a thin layer of wood from the scion and inserting it into a matching T-shaped incision on the rootstock bark. Common steps across these methods involve making clean, angled cuts with a sharp knife to expose fresh tissue, aligning the cambium layers—the thin, actively dividing cell layer beneath the bark—for nutrient exchange, and securing the union tightly with grafting tape, rubber bands, or wax to prevent desiccation and infection. Biologically, successful grafting relies on compatibility between the scion and rootstock, primarily through the , which facilitates the reconnection of and for water, nutrient, and photosynthate transport. Upon joining, wound response triggers formation, where undifferentiated cells proliferate across the interface to bridge the gap, typically within 2-3 weeks under optimal conditions like high and moderate temperatures. Hormonal signaling plays a key role in this process: auxins from the scion promote proliferation and vascular differentiation at the base, while cytokinins enhance cell division and support expansion, ensuring the union develops into a continuous vascular system. In compatible grafts, these mechanisms lead to the formation of new and functional vessels, often completing integration in 4-8 weeks. Rootstocks are propagated asexually to preserve desirable traits and ensure clonal uniformity, avoiding from seeds. Cuttings, such as semi- or types taken during , are rooted in moist, sterile media with treatments to stimulate adventitious , yielding genetically identical . involves bending a to the ground or mounding over shoots while still attached to the parent, allowing to develop before separation, which is effective for woody rootstocks like those in fruit trees. , or , uses sterile explants in nutrient media with hormones to produce virus-free clones rapidly, ideal for scaling up uniform rootstock lines in commercial settings. Common challenges in graft union formation include incompatibility, manifesting as poor knitting where callus fails to bridge adequately, leading to , , or breakage under stress. Symptoms may appear delayed, such as yellowing foliage or months after , often due to biochemical mismatches or insufficient genetic relatedness. Basic mitigation involves selecting compatible rootstock-scion pairs based on taxonomic proximity and testing small batches, alongside maintaining optimal environmental conditions like 70-80% to support healing.

Historical Development

Ancient Origins

The practice of grafting rootstocks originated in ancient civilizations, with documented evidence emerging in by the 6th century CE, as detailed in agricultural texts like the Qi Min Yao Shu by Jia Sixie, which described grafting methods, including optimal timing in spring, selection of compatible rootstocks, and approaches like inarching to join scions and stocks, reflecting empirical knowledge likely developed centuries earlier for propagation and repair of damaged trees. Earlier practices may have existed, but specific records for woody plants such as pears date to this period. In , similar techniques extended to mulberries and , with mulberry cultivation traced back over 5,000 years to the period in regions like the valley, where it supported and fruit production by adapting trees to sandy soils through approach grafting of one-year-old branches onto robust rootstocks. In the Mediterranean, was well-established by the 4th century BCE, as described by the Greek philosopher in his Enquiry into Plants, where he explained the process as inserting a or "eye" into a of similar to improve vigor, noting that cultivated varieties thrived on wild rootstocks like the wild for olives and figs. Techniques such as approach adjacent branches or to tissues—were commonly used for and figs in and later , allowing of elite fruit trees and ornamental enhancements in gardens. Roman agricultural writers like in De Re Rustica (1st century CE) further elaborated on these methods for figs grafted onto mulberries and onto wild stocks, emphasizing their role in repairing storm-damaged plants and creating diverse orchards. In ancient , mango propagation relied on early vegetative methods dating to around 2000 BCE, with techniques emerging later to multiply superior varieties, though specific ancient records are sparse compared to and Mediterranean practices. Across these regions, rootstock held profound cultural significance, bolstering through reliable crop yields in and production; for instance, texts highlight its essential role in expanding vineyards for wine , symbolizing agricultural innovation and imperial expansion. These empirical techniques, driven by observation rather than , laid the for sustained horticultural practices into the medieval period, facilitating along routes like the where grafted mulberries and varieties were exchanged.

19th-20th Century Advances

The crisis, which devastated European vineyards starting in the 1860s, marked a pivotal advancement in rootstock use, as the aphid-like pest destroyed the roots of grapes across and beyond by the 1880s. This catastrophe prompted the widespread adoption of resistant American rootstocks, such as those derived from and , which were grafted with European scions to rebuild the industry; by the late , onto these phylloxera-tolerant species had become the standard solution in and other affected regions. In the United States, entomologist Charles V. Riley advocated for this approach in the 1870s, influencing early federal efforts to import and propagate resistant stocks. In the early 20th century, the East Malling Research Station in , , systematized apple rootstock development through systematic trials beginning around 1912, collecting and evaluating over 300 accessions to identify clones with desirable traits like dwarfing and vigor control. This work led to the release of the Malling series (M.1 to M.9) in the 1910s and 1920s, with M.9 emerging as a breakthrough dwarfing rootstock that reduced tree size to about 30-35% of standard while promoting early fruiting; the first U.S. shipment of these stocks arrived in 1920 for testing at institutions like Pennsylvania State College. Building on this, the Malling-Merton hybrids (MM series), developed in the 1950s through crosses with resistant species like Malus robusta, enhanced disease tolerance, including to woolly apple aphid and collar rot, while maintaining semi-dwarfing effects. The 20th century also saw the rise of virus-free clonal rootstocks, with efforts intensifying in the late 1960s to eliminate latent viruses through indexing and , improving compatibility and yield in apples and other crops; this built on earlier clonal techniques refined at East Malling. Institutional contributions were central: the USDA's breeding programs, active since the early 1900s, focused on resistant rootstocks for pears and stone fruits, releasing hybrids tolerant to and s. In , INRA advanced grapevine rootstock selection from the mid-20th century, emphasizing and resistance in hybrids like 101-14 and 3309. California's programs, through UC Davis and USDA collaborations, developed stone fruit rootstocks like peach-almond hybrids in the 1950s-1970s, targeting replant disease and size control for almonds and prunes. Additionally, Japanese researchers contributed to pear rootstock breeding in the 1920s-1950s, developing Pyrus serotina-based stocks for improved anchorage and cold tolerance, influencing Asian and global orchards. The U.S. Plant Quarantine Act of 1912 played a key role by mandating inspections and restricting imports, which accelerated domestic breeding of resistant rootstocks to safeguard against pests like and promote certified, disease-free propagation. Post-World War II, the adoption of dwarfing rootstocks like M.9 facilitated the expansion of high-density orchards, enabling closer tree spacing (up to 1,000 trees per acre) and mechanized harvesting, which boosted global apple production efficiency by the 1950s-1970s.

Applications in Horticulture

Fruit Trees

In fruit tree horticulture, rootstocks play a pivotal role in enhancing by enabling size control, improved , and resilience to environmental challenges, particularly for pome fruits like apples and pears, and stone fruits such as cherries and peaches. Dwarfing and semi-dwarfing rootstocks allow for high-density orchards, which can increase fruit production per unit area while facilitating mechanical harvesting and easier management. These benefits stem from the rootstock's influence on scion vigor, nutrient uptake, and overall tree architecture, leading to earlier fruiting—often within 2-3 years of planting compared to 5-7 years on standard rootstocks—and higher yield efficiency. Prominent examples in apple production include the Malling series, developed at the East Malling Research Station in , where M.9 induces strong (trees reaching 25-35% of standard size), promoting precocious bearing and suitability for intensive systems, while M.26 provides semi- (about 40-50% of standard) with greater anchorage and cold hardiness. The series, bred at Cornell University's New York State Agricultural Experiment Station, offers disease-resistant alternatives; for instance, Geneva 41 (G.41) matches M.9 in effect but provides high resistance to , root rot, woolly apple aphid, and apple replant disease, enabling adaptation to infested soils without fumigation. In cultivation, the OHxF (Old Home × Farmingdale) series, such as OHxF 87 and OHxF 333, delivers semi- (50-70% of standard size) with resistance to and pear decline, supporting vigorous growth in diverse soils. rootstocks, like Quince C, induce (trees to 8-10 feet after 5-10 years) for earlier production but require milder climates due to limited cold hardiness. For stone fruits, the Gisela series has transformed cherry orchards; Gisela 5, a rootstock (45-50% of Mazzard standard), induces precocious bearing and high productivity, allowing trees to fruit heavily by the third year and supporting densities up to 400-600 trees per acre. This has led to case studies showing substantial impacts, such as in global apple production where rootstocks like M.9 and series now dominate commercial orchards, revolutionizing efficiency and contributing to over 80 million tons of annual output through intensified planting and earlier returns. Similarly, Gisela rootstocks have boosted cherry yields in and by enabling precocious, high-density systems that reduce labor and improve fruit quality. Key selection criteria for rootstocks emphasize scion-rootstock compatibility to ensure successful and uniform performance, as mismatches can lead to poor strength or delayed fruiting. efficiency is prioritized through rootstocks that channel resources to rather than excessive vegetative , often measured by fruit weight per tree volume. Regional adaptations guide choices, such as cold-hardy options like M.26 for northern climates or replant-resistant Geneva 41 for disease-prone areas, balancing vigor control with site-specific needs like and pressures.

Grapevines

In , rootstocks have been essential for protecting grapevines, particularly cultivars used in wine and production, from soil-borne diseases and environmental stresses. The practice originated as a response to the 19th-century crisis, which devastated European vineyards, prompting the of susceptible European scions onto resistant rootstocks derived from North American species. A key historical example is the AxR1 rootstock, a hybrid of and 'Aramon', introduced in the 1880s and widely adopted in through the 1980s for its initial resistance. However, it failed in many regions by the late when populations adapted, developing biotype B that overcame its defenses, leading to widespread vineyard replanting. Modern rootstocks continue to prioritize resistance while addressing additional challenges like nematodes and . Widely used selections include 101-14 (V. riparia × V. rupestris), which offers moderate-to-high to root-knot nematodes and performs well in deep, well-drained soils; 3309 (V. riparia × V. rupestris), suited to gravelly sites with low-to-medium but lower nematode resistance; and Riparia (V. riparia), which provides moderate-to-high root-knot nematode and adapts to moist, clay soils. For vigorous growth in lighter soils, (V. berlandieri × V. riparia) is commonly selected, exhibiting medium-to-high and moderate nematode resistance. These rootstocks enable the successful propagation of V. vinifera s on phylloxera-resistant American bases, facilitating global while modulating vine performance. Rootstock choice influences scion vigor, which in turn affects size, , and compounds; for instance, high-vigor rootstocks like 1103P increase and uptake, potentially leading to larger berries and higher yields but sometimes diluting intensity, whereas lower-vigor options like 101-14 promote concentrated flavors and improved profiles in wines. Regionally, selections are tailored to local conditions: in , drought-tolerant rootstocks such as 110R (V. berlandieri × V. rupestris) are prevalent in arid inland areas to maintain vine health under water-limited regimes. In , where most vineyards are phylloxera-infested and routinely grafted, rootstocks are also adopted in rare phylloxera-free zones—such as certain sandy or volcanic soils—to combat other pests like nematodes and enhance adaptation to site-specific stresses.

Vegetables and Ornamentals

In vegetable production, is widely employed to enhance disease resistance and productivity in crops such as tomatoes, watermelons, and other cucurbits. For tomatoes, susceptible varieties are commonly grafted onto interspecific hybrid rootstocks derived from wild species or ( spp.), which provide resistance to soilborne pathogens like caused by . This approach allows growers to avoid soil fumigation and extend flexibility in intensive systems. Studies have shown that such grafting can increase marketable yields by 28-31% compared to non-grafted plants, primarily through improved vigor and reduced disease incidence. Similarly, watermelons ( lanatus) are frequently grafted onto squash or bottle gourd (Lagenaria siceraria) rootstocks to confer resistance to , , and root-knot nematodes, enabling cultivation in infested soils without yield losses. These rootstocks also promote firmer fruit texture and higher overall productivity, with grafted plants demonstrating tolerance to multiple soilborne diseases that affect non-grafted cultivars. For other cucurbits like cucumbers and melons, grafting onto resistant hybrids mitigates similar stresses while maintaining fruit quality. In ornamental horticulture, rootstocks are selected to impart vigor, adaptability, and hardiness to decorative plants, particularly in landscape and nursery production. Roses (Rosa spp.) are often grafted onto Dr. Huey (Rosa 'Dr. Huey') or multiflora (Rosa multiflora) rootstocks, which enhance overall plant vigor, improve soil adaptability in alkaline or arid conditions, and provide resistance to certain root diseases. For woody shrubs such as lilacs (Syringa spp.), grafting onto hardy rootstocks like Syringa vulgaris seedlings boosts cold tolerance and establishment in challenging climates, though own-root propagation remains common for maximum hardiness. The primary advantages of rootstock grafting in and ornamentals include prolonged field longevity in high-density systems and decreased reliance on chemical pesticides, as resistant rootstocks suppress buildup in . In production, this practice originated in in the 1920s for solanaceous crops and has become standard in the for cucurbits, where it supports cycles and reduces nematicide applications by up to 50%. Emerging trends focus on rootstocks tailored for systems, which combine with compatibility for scions, enabling pesticide-free production without yield penalties. In ornamentals, advanced rootstocks are being developed to enhance nutrient uptake efficiency, such as improved phosphorus acquisition in low-fertility soils, thereby reducing inputs in settings.

Key Traits and Selection Criteria

Vigor and Size Control

Rootstocks play a pivotal role in modulating the vigor and overall size of grafted , enabling growers to tailor architecture for optimal density and management. Vigor refers to the rate of vegetative , often quantified through metrics such as cross-sectional area (TCSA), which measures the increase in stem diameter as an indicator of canopy development. By selecting appropriate rootstocks, horticulturists can achieve controlled stature that balances productivity with practical considerations like and harvesting. The primary mechanisms by which rootstocks influence scion vigor involve hormonal signaling and architecture. Roots produce and transport hormones such as s, which promote and shoot elongation in the scion; dwarfing rootstocks typically exhibit reduced synthesis, leading to slower growth rates. Additionally, variations in root architecture affect and uptake efficiency, with compact root systems in low-vigor rootstocks limiting resource availability to the scion and thereby constraining overall plant size. Rootstocks are categorized based on their vigor impact: dwarfing types reduce scion height by 50-90% compared to standard vigorous rootstocks, semi-dwarfing options achieve moderate reductions of 30-50%, and vigorous rootstocks promote full-sized growth. In apples, for instance, the Malling series includes examples like M9, which limits tree height to about 30-40% of standard size, facilitating high-density planting. These categories are assessed using vigor indices such as TCSA, where rootstocks consistently yield smaller annual increments in trunk diameter. Genetic factors contribute to these effects, as seen in the apple Malling rootstocks, where the Dw1 locus on is a major (QTL) responsible for by influencing unloading and vascular development. The Dw1 , present in most dwarfing and semi-dwarfing selections, interacts with Dw2 to amplify size control, reducing canopy vigor and enabling benefits such as improved mechanical harvesting and reduced labor for . Selection of rootstocks for vigor control emphasizes matching the desired growth rate to site-specific conditions, such as and . Low-vigor rootstocks are preferred on fertile, well-drained soils to prevent excessive vegetative growth and maintain balanced fruit production, while vigorous types suit nutrient-poor or stressful environments to ensure adequate development. This approach optimizes resource use and minimizes issues like overgrowth in high-input settings.

Disease and Environmental Resistance

Rootstocks play a crucial role in conferring resistance to biotic stresses, particularly soil-borne diseases and pests, by providing genetic barriers that protect the grafted plant. For instance, in avocado cultivation, rootstocks such as 'Dusa', 'Uzi', and 'Zentmyer' exhibit tolerance to Phytophthora cinnamomi, the pathogen causing root rot, through mechanisms that limit fungal spread in the root zone, enabling sustained tree health in infested soils. Similarly, in grapevines, rootstocks like 'Freedom', 'Harmony', and 'Dog Ridge', derived from Vitis champinii and other wild American species, offer robust resistance to root-knot nematodes (Meloidogyne spp.) by restricting nematode reproduction and gall formation on roots. These resistances often trace back to wild relatives, which harbor genes for pathogen avoidance or suppression absent in commercial scions. Abiotic stresses are mitigated by rootstock traits that enhance environmental adaptation, ensuring plant survival under adverse conditions. is achieved through deeper root systems in rootstocks like 110 Richter and 1103 Paulsen in grapes, which access subsoil moisture more effectively than shallow-rooted alternatives, reducing during dry periods. For , rootstocks in and grapes employ ion exclusion mechanisms, selectively blocking uptake of toxic and sodium s into the , as seen in selections from species that maintain low levels under saline . Cold hardiness is bolstered by rootstocks such as Bud.9 and the Geneva series (e.g., G.890) in apples, which influence freezing by stabilizing vascular tissues and promoting earlier hardening, thereby minimizing winter injury in temperate regions. Resistance mechanisms in rootstocks encompass physical, biochemical, and symbiotic strategies that collectively deter stressors. Physical barriers include reinforced root architectures, such as lignified tissues that impede penetration, while biochemical defenses involve the production of antimicrobial compounds like and phytoanticipins, which inhibit fungal and in the . Symbiotic associations, particularly with arbuscular mycorrhizal fungi, enhance resistance by improving nutrient uptake, bolstering through extended hyphal networks, and activating defenses against root pathogens. Evaluation of these traits relies on rigorous field trials to assign resistance ratings, ensuring reliable performance across environments. For example, rootstocks like G.41 and G.202 have demonstrated high resistance to (Erwinia amylovora) in apples through multi-year orchard inoculations, where they limit bacterial canker progression compared to susceptible standards, guiding selections for disease-prone sites.

Breeding and Innovation

Traditional Methods

Traditional methods for rootstock development emphasize empirical selection and controlled hybridization to capture desirable traits like disease resistance and vigor in perennial horticultural crops. These approaches, originating in the early 20th century, rely on phenotypic observation and long-term field evaluations rather than genetic markers, accommodating the extended juvenile periods of species such as apples and grapes. Breeders identify and propagate variants through vegetative to ensure uniformity, with processes often spanning decades due to the need for multi-generational testing in varied environments. Selection processes traditionally involve screening superior seedlings from open-pollinated populations of wild species or existing hybrids, where natural variability reveals traits such as adaptability to conditions or pest tolerance. In apple rootstock breeding, for example, seedlings are initially assessed for survival in controlled settings before advancing to field trials that evaluate growth and yield over several years. facilitates trait by repeatedly crossing promising hybrids back to a recurrent , thereby incorporating specific resistances—such as phylloxera tolerance in grapes—while minimizing linkage drag from undesirable donor traits. This method has been instrumental in refining rootstocks from wild populations into commercially viable lines. Hybridization techniques center on deliberate controlled crosses between interspecific or intraspecific parents to amalgamate complementary attributes, such as from with lime tolerance from V. berlandieri in grape rootstocks. Notable examples include the development of hybrids like 3309C (V. riparia × V. rupestris), achieved through manual pollination and seed propagation of F1 progeny. For perennials, progeny testing extends 10-15 years, involving replicated plantings to monitor compatibility, yield stability, and environmental across seasons and sites, ensuring only robust selections advance. Propagation standards for maintaining selected rootstock clones prioritize vegetative methods to preserve genetic fidelity, with stool bedding serving as a cornerstone technique for . In this process, rootstock plants are spaced 12-18 inches apart in well-drained beds, topped back in spring to stimulate basal shoots, and mounded with or to 12-15 inches high over multiple earthing-ups, yielding up to 60,000 rooted liners per upon harvest in . The East Malling Research Station pioneered systematic trialing of apple rootstocks through such protocols, establishing replicated evaluation plots since 1917 to standardize vigor assessment and clonal multiplication. Historical outputs from these methods include the Malling-Merton (MM) series, released in the 1950s via collaborative breeding at the East Malling and Innes Institutes, which introduced virus-tolerant apple rootstocks through selective hybridization with Northern Spy for woolly apple resistance. Rootstocks like MM.106 demonstrated enhanced tree health by reducing viral transmission and supporting consistent performance, influencing global apple cultivation for decades.

Modern Genetic Approaches

Modern genetic approaches in rootstock development leverage molecular tools to accelerate breeding, overcome limitations of traditional methods, and target complex traits such as disease resistance and environmental adaptability. uses DNA markers linked to specific genes to identify and select desirable traits early in the breeding process, reducing the time and resources needed compared to phenotypic evaluation alone. For instance, in apple rootstocks, targets the Dw1 and Dw2 quantitative trait loci, which control dwarfing and vigor; markers associated with these loci have enabled the selection of seedlings carrying dwarfing alleles, streamlining the development of size-controlling rootstocks like those in the Geneva series. Genetic engineering has introduced transgenic walnut trees with enhanced pest resistance by incorporating genes from other organisms. In walnuts, transgenic trees expressing the cry1Ac gene from Bacillus thuringiensis (Bt) provide resistance to lepidopteran insects such as the codling moth, reducing damage to kernels and allowing field trials since the 1990s without broad-spectrum insecticides. Cisgenesis, a non-transgenic variant, transfers native genes from the same or closely related species using genetic modification techniques but without foreign DNA, minimizing regulatory hurdles; this approach has been applied in fruit crops to introgress resistance traits without linkage drag, as seen in potato and apple breeding programs adaptable to rootstocks. Emerging technologies like CRISPR/Cas9 enable precise to modify resistance genes directly in rootstock lines. CRISPR/Cas9 studies on plants have targeted genes such as SlNPR1 and SlMAPK3, demonstrating their role in through loss-of-function mutants that exhibit reduced resilience, increased levels, and heightened sensitivity to osmotic stress; these findings inform strategies for enhancing water-use efficiency via targeted activation or other edits. Genomic sequencing complements this by mapping quantitative trait loci for root architecture and stress responses; for example, whole-genome sequencing of apple rootstocks like 'M9' and 'MM106' has identified variants influencing and uptake, facilitating predictive models. Recent advances as of November 2025 integrate multi-omics approaches—combining , transcriptomics, and —to develop climate-resilient rootstocks capable of withstanding combined abiotic stresses like and . In horticultural crops, multi-omics profiling of and apple rootstocks has revealed regulatory networks for , such as salt stress mechanisms in grapevine rootstocks and cold resistance genes in apples, enabling the stacking of traits for and water stress tolerance through integrated data analytics. Regulatory frameworks for rootstocks differ significantly: in the , the USDA often deregulates gene-edited varieties without foreign DNA under the 2018 SECURE Rule, allowing faster commercialization, whereas as of November 2025, the classifies most CRISPR-edited plants as GMOs under Directive 2001/18/EC amid ongoing negotiations for new genomic techniques (NGT) that may exempt certain edits, subjecting them to rigorous risk assessments and limiting approvals in the interim.

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