Foot rot tolerant transgenic rough lemon rootstock developed through expression of β‐1,3‐glucanase from Trichoderma spp.

Citrus (Citrus spp.) is grown worldwide commercially for consumption as fresh fruit and squeezed juice. The crop is most vulnerable to fungal pathogen Phytophthora parasitica that attacks citrus trees of all ages and incites foot rot disease, also known as gummosis causing significant fruit yield losses (Naqvi 2004). The infection occurs by entry of motile zoospores from soil into root cortex, thus decaying fibrous roots, and upon splashing of zoospores on trunk bark near the ground leading to entry in bark cambium through wounds or cracks resulting in exudation of gum from cracks, girdling of bark cambium, eventually killing the tree (Graham and Timmer 1994). Phytophthora infection can be managed by soil drainage, alleviated through application of systemic fungicides, though not always cost-effective and environment friendly (Naqvi 2004). This article is protected by copyright. All rights reserved.

Citrus (Citrus spp.) is grown worldwide commercially for consumption as fresh fruit and squeezed juice. The crop is most vulnerable to fungal pathogen Phytophthora parasitica that attacks citrus trees of all ages and incites foot rot disease, also known as gummosis causing significant fruit yield losses (Naqvi, 2004). The infection occurs by entry of motile zoospores from soil into root cortex, thus decaying fibrous roots, and upon splashing of zoospores on trunk bark near the ground leading to entry in bark cambium through wounds or cracks resulting in exudation of gum from cracks, girdling of bark cambium and eventually killing the tree (Graham and Timmer, 1994). Phytophthora infection can be managed by soil drainage, alleviated through application of systemic fungicides, though not always costeffective and environment-friendly (Naqvi, 2004). The pathogen infection has also been controlled by the use of biological agents, such as Trichoderma spp. that acts by producing various cell walldegrading enzymes; among these, b-1,3-glucanase hydrolyses b-1,3-glucosyl linkages of b-glucan-rich (90%) Phytophthora cell wall, resulting in inhibition of pathogen hyphae and restriction of disease development (Bartnicki-Garcia, 1966;Ben ıtez et al., 2004). Cloning of b-1,3-glucanase encoding genes, such as bgn13.1, gluc78, Tv-bgn1 and Tv-bgn2 from Trichoderma spp., and expression in transgenic plants confirmed their role in providing resistance against fungal pathogens (Ben ıtez et al., 2004). There is no information in literature about the expression of b-1,3-glucanase from Trichoderma in citrus for imparting resistance against Phytophthora spp.
Citrus crop is grown as composite trees with scion grafted onto a rootstock; the main reason for shifting citriculture from seedling to grafted plants was major losses caused by foot rot (Castle, 2010). Rootstocks exert strong influence on treesꞌ ability to confront stress, besides determining fruit yield and quality; however, every rootstock has certain unfavourable traits that preclude its universal use. Rough lemon (C. jambhiri) is a widely used rootstock possessing most desirable traits with ability to form congenial scionic combinations, but is highly susceptible to foot rot (Naqvi, 2004;Castle, 2010).
This study was undertaken to develop foot rot tolerant transgenic rough lemon rootstock through the expression of b-1,3-glucanase isolated from Trichoderma spp. The gene cassette carrying b-1,3-glucanase catalytic domain driven by CaMV 35S promoter and NOS terminator in pBI121 was mobilized into Agrobacterium strain LBA 4404 ( Figure 1a). The transgene was expressed constitutively as Phytophthora is persistently present in soil, infecting roots and trunk at various stages of plant development (Naqvi, 2004). Agrobacterium transformed epicotyl segments exhibited shoot emergence in clusters on cut edges within 8 weeks, and 188 T 0 plants were transferred to soil (Figure 1b-f). The presence of catalytic domain was verified in 13 putative plants through PCR; the absence of virG amplicon substantiated that these plants were not false positives contaminated by Agrobacterium. The transcription of transgene in 13 putative plants through semi-quantitative RT-PCR demonstrated successful uptake of T-DNA by host plant cells ( Figure 1g). The relative transgene expression in RT-PCR positive plants analysed through qRT-PCR revealed 2.81, 2.51, 2.58, 2.67, 3.25, 1.87 and 3.55-fold higher expression in seven transgenic plants designated as RL-5, RL-7, RL-12, RL-16, RL-17, RL-60 and RL-78, respectively, as compared to NT plant (Figure 1p), whereas expression in six plants RL-79, RL-96, RL-117, RL-120, RL-149 and RL-165 was comparable to NT plant. The total proteins extracted from 20week-old transgenic and NT plants were confronted in vitro with P. parasitica to test their antifungal activity. The results revealed inhibition of Phytophthora mycelial growth (20.49-31.69%) by transgenic plant proteins, as compared to no restrain on pathogen by NT proteins (Figure 1h). The scanning electron micrographs of mycelia inhibited by transgenic proteins displayed hyphal swelling (Figure 1i), cytoplasmic constrictions, termination of mycelial branches ( Figure 1j) followed by fragmentation ( Figure 1k) confirming structural degradation of mycelium, whereas mycelia around NT plant proteins were normal displaying unswollen hyphae (Figure 1l). The results pointed that recombinant protein might be acting as an impediment against Phytophthora. The antifungal action of b-1,3-glucanase enzymes BGN13.1 and GLUC78 from Trichoderma spp. is documented ; ‡ feeder root rot scale 1-5, where 1 = no visible symptoms, 2 = a few roots (1-25%) with rotting symptoms, 3 = majority of roots (26-50%) with rotting symptoms, 4 = all roots infected (51-75% rotting), major roots dead, 5 = majority of roots (>76% rotting) dead or missing; § propagule count was mean of three replicates; † † trunk girth was assessed at 20 cm above ground; ¶ ¶ plant height was measured from ground to highest point; ‡ ‡ canopy volume = 0.5236 9 plant height 9 canopy spread (north to south) 9 canopy spread (east to west); § § feeder root volume = mean feeder root volume/total soil volume, where total soil volume = 141.14 cc [Π 9 (radius of cylinder 1.59 cm) 2 9 height of cylinder 17.78 cm]; plant morphological parameters were recorded thrice, and P < 0.05 was statistically significant. (p) Quantitative RT-PCR in leaves, roots of transgenic plants before and after Phytophthora inoculation using qRT-PCR b-1,3-glucanase primers 5ꞌ-CTCTCCAGAATGCTATCACCAC-3ꞌ and 5ꞌ-GGTATATGTTCCCGGAGGAATG-3ꞌ; 18SrRNA reference gene primers 5ꞌ-TCGGGTGTTTTCACGTCTCA-3ꞌ and 5ꞌ-TGGATGCCGCTGGGAAGC-3ꞌ (FJ356261.1); error bars represent range of change in b-1,3-glucanase expression determined by 2 ÀΔΔC T method. (q) Transverse root section of susceptible NT plant revealing the occurrence of ligni-tubers (solid arrows) and callose deposition (broken arrows) in cortex cells. against a range of fungi including Phytophthora (de la Cruz et al., 1995).
The 18-month-old transgenic and NT plants were bioassayed for foot rot incidence by injecting P. parasitica inoculum in trunk (30 lL, 4 9 10 4 zoospores/mL) and inoculation of plant rhizospheric soil (20 propagules/cc), as the pathogen propagules >10/ cc soil are considered destructive (Naqvi, 2004). NT plant displayed susceptibility symptoms after 12 weeks of inoculation revealing severe gumming on trunk (Figure 1m), wilting and leaf defoliation, low feeder root volume due to 50% root rot with high pathogen propagule count/mg root, whereas transgenic plant RL-78 did not exhibit gumming (Figure 1n) with leaf chlorosis with had high feeder root volume with no visible root rot and significantly low pathogen propagule count (Figure 1o), pointing towards tolerance to Phytophthora. RL-17 showed slight gumming on trunk, light leaf chlorosis, high feeder root volume with a few roots (<25%) showing rotting and low pathogen propagule count, indicating moderate tolerance of plant towards the pathogen. RL-16 demonstrated moderate gumming on trunk, leaf necrosis, low feeder root volume with up to 25% root rot and high pathogen propagule count, evincing its moderate susceptibility to Phytophthora. The plants RL-5, RL-7, RL-12 and RL-60 were susceptible. Resistance against fungal pathogens through expression of b-1,3-glucanase from Trichoderma spp. has been demonstrated in transgenic rice, pearl millet, canola, strawberry and sugarcane (Nayyar et al., 2017).
The comparison of relative b-1,3-glucanase expression in transgenic plants through qRT-PCR before inoculation and 12 weeks after pathogen inoculation revealed that transgene expression increased twofold in leaves and threefold in roots of RL-17 and RL-78 after inoculation (Figure 1p). The level of up-regulation was more in tolerant plants as compared to susceptible and NT plants, suggesting involvement of transgene in imparting tolerance against foot rot. b-1,3-glucanase induction upon pathogen infection and its role in defence were substantiated in transgenic tobacco (Castresana et al., 1990).
Scanning electron microscopy of root cortex, xylem cells from Phytophthora-inoculated tolerant transgenic RL-78 and susceptible NT plants was carried out to observe pathogen invasion. The cortex cells of susceptible NT plant revealed the occurrence of digitate ligni-tubers and callose deposition (Figure 1q), whereas these entities were absent in tolerant plant RL-78 in response to Phytophthora inoculation (Figure 1r). The xylem cells of susceptible NT plant demonstrated the occurrence of zoospores (Figure 1s); on the contrary, zoospores were absent in xylem tissue of RL-78 (Figure 1t). The results confirmed that Phytophthora could not invade root cells of tolerant transgenic plant RL-78 due to sloughing off root cells; sloughed off cells usually discharge b-1,3glucanase among other antimicrobial proteins in rhizosphere that remain effective and stable even in the presence of active microflora with ability to bind tightly on plant root surface (Glandorf et al., 1997). The lignification of root cells in NT plant could not provide protection against Phytophthora, implying noneffectiveness of native plant defence mechanism. The noneffectiveness of lignin deposition in restricting pathogen growth was also shown in avocado rootstock root cells upon Phytophthora infection (van den Berg et al., 2018).
The root tissue of tolerant RL-78, moderately tolerant RL-17, susceptible NT plants after Phytophthora inoculation and noninoculated NT plant was evaluated for viable endophytic microbial cell count. The susceptible NT plant had highest count of P solubilizers, total fungi and substantial nitrogen fixers (Figure 1u). The non-inoculated NT plant exhibited highest count of total bacteria, nitrogen fixers, pseudomonads and considerable total fungi cell populations. RL-78 and RL-17 did not show the presence of pseudomonads, total fungi and had meagre count of P solubilizers with nitrogen fixers. The results indicated reduction in count of endophytic bacteria and total fungi inhabiting roots of tolerant plants. The constitutive b-1,3-glucanase expression in transgenic plants has been shown to reduce mycorrhizal symbiosis and rhizospheric microbial diversity due to alteration in structures of symbiotic microbes, and these have a role in plant growth stimulation (Glandorf et al., 1997). Phytophthora tolerant RL-78 exhibited slow growth as compared to moderately tolerant RL-17, moderately susceptible RL-16 and NT plants (Figure 1o), demonstrating inverse correlation between level of tolerance and plant development rate. The genotyping of transgenic plants revealed that allelic pattern of RL-78 generated using SSR marker CCSM-17 was homologous with the mother plant and homology was reaffirmed by CCSM-6 ( Figure 1v,w). The allelic pattern in RL-17 and RL-60 using CCSM-13 revealed their similarity to each other and mother plant; the same was confirmed by CCSM-18 (Figure 1x,y). The transgenic plants sharing genetic resemblance with the mother plant were identified as nucellar.
Phytophthora tolerance in transgenic rough lemon was due to fragmentation of pathogen hyphae on rhizoplane that occurred through direct action of b-1,3-glucanase protein on b-1,3glucosyl linkages of Phytophthora cell wall. In addition, indirect action of b-1,3-glucanase is hypothesized through liberation of oligosaccharide elicitors from fungal cell walls that elicit plant defence response. Thus, it is anticipated that a combination of protective activities initiated upon pathogen infection, and further studies may disclose the composite b-1,3-glucanasemediated tolerance mechanism.