key: cord-0007155-fu2doy3h authors: He, Jiali; Zhuang, Xiaolei; Zhou, Jiangtao; Sun, Luyang; Wan, Huixue; Li, Huifeng; Lyu, Deguo title: Exogenous melatonin alleviates cadmium uptake and toxicity in apple rootstocks date: 2020-03-16 journal: Tree Physiol DOI: 10.1093/treephys/tpaa024 sha: 0e0d8239bb05a29c391a63bad05f4871f660c976 doc_id: 7155 cord_uid: fu2doy3h To examine the potential roles of melatonin in Cd uptake, accumulation and detoxification in Malus plants, we exposed two different apple rootstocks varying greatly in Cd uptake and accumulation to either 0 or 30 μM Cd together with 0 or 100 μM melatonin. Cd stress stimulated endogenous melatonin production to a greater extent in the Cd-tolerant M. baccata than in the Cd-susceptible M. micromalus ‘qingzhoulinqin’. Melatonin application attenuated Cd-induced reductions in growth, photosynthesis, and enzyme activity, as well as ROS and MDA accumulation. Melatonin treatment more effectively restored photosynthesis, photosynthetic pigments, and biomass in Cd-challenged M. micromalus ‘qingzhoulinqin’ than in Cd-stressed M. baccata. Exogenous melatonin lowered root Cd(2+) uptake, reduced leaf Cd accumulation, decreased Cd translocation factors (T(f)s), and increased root, stem, and leaf melatonin contents in both Cd-exposed rootstocks. Melatonin application increased both antioxidant concentrations and enzyme activities to scavenge Cd-induced ROS. Exogenous melatonin treatment altered the mRNA levels of several genes regulating Cd uptake, transport, and detoxification including HA7, NRAMP1, NRAMP3, HMA4, PCR2, NAS1, MT2, ABCC1, and MHX. Taken together, these results suggest that exogenous melatonin reduced aerial parts Cd accumulation and mitigated Cd toxicity in Malus plants, probably due to the melatonin-mediated Cd allocation in tissues, and induction of antioxidant defense system and transcriptionally regulated key genes involved in detoxification. Cadmium (Cd) is a nonessential and highly phytotoxic heavy metal (HM). It accumulates in orchard soils via the application of metal-based pesticides, fungicides, and fertilizers and wastewater irrigation (Pizzol et al. 2014 , Duan et al. 2016 , Sungur 2016 ). According to a recent survey, the Cd levels in 55% and 66% of the soil samples from 91 orchards exceeded the Cd safety standard before flowering and after harvesting, respectively (Fang and Zhu 2014) . Cd is highly mobile and readily absorbed by plants (Luo et al. 2016) . It negatively affects plant metabolism, causes various morphological, physiological, biochemical, and 3 cellular changes, and hampers plant growth (Clemens et al. 2013) . Apple trees may accumulate toxic Cd levels (Fang and Zhu 2014, Sungur 2016) . Cd accumulation in edible plant parts poses a serious threat to human and animal health, as Cd toxicity may cause various human and animal diseases (Nawrot et al. 2006) . Therefore, reliable methods are needed to reduce Cd accumulation in the aerial organs of apple trees and other crops. Melatonin (N-acetyl-5-methoxytryptamine) is a ubiquitous signal molecule. It enhances plant tolerance to various abiotic stressors such as extreme temperatures, drought, salinity, and HM exposure , Lee et al. 2017 . Exogenous melatonin may reduce Cd concentrations in the aerial organs of tomato (Hasan et al. 2015) and wheat (Kaya et al. 2019) . Upregulation of the genes governing melatonin biosynthesis and elevated endogenous melatonin levels were observed in herbaceous plants subjected to Cd (Byeon et al. 2015 , Hasan et al. 2015 . Thus, melatonin may be implicated in Cd accumulation and translocation. However, it is still unknown how exogenous melatonin influences rhizosphere net Cd 2+ fluxes or whether it affects Cd translocation from the roots to the aerial organs of apple trees. Exogenous melatonin enhances Cd detoxification in herbaceous plants via several mechanisms . First, melatonin and its synthetic precursors chelate heavy metals (HMs) and induce chelate production . Second, melatonin and its metabolites directly scavenge reactive oxygen species (ROS) (Reiter et al. 2007 ). Third, it promotes antioxidant enzyme activity which scavenges excess ROS induced by Cd . Melatonin is critical for Cd detoxification. Therefore, exogenous melatonin has been applied to Cd-stressed herbaceous plants such as tomato (Hasan et al. 2015 ), rice (Byeon et al. 2015) , wheat (Ni et al. 2018 , Kaya et al. 2019 , and alfalfa (Gu et al. 2017) in an attempt to enhance their Cd tolerance. To our knowledge, however, there are no studies on the efficacy of exogenous melatonin in enhancing Cd detoxification in woody fruit crops or the putative mechanisms involved. Cd uptake, translocation, and detoxification are mediated by several genes (Luo et al. 2016 ). Plasma membrane (PM) H + -ATPases furnish the proton motive force needed to ferry ions across the PM and play important roles in Cd uptake . The transcript levels of HA7 encoding H + -ATPase were higher in the Cd-susceptible Malus micromalus "qingzhoulinqin" than in the Cd-tolerant M. baccata, thus contributing to higher Cd influxes into roots . Natural resistance associated macrophage protein 1 (NRAMP1) located in the PM affects Cd entry into root cell cytosols (Gao et al. 2011, Lin and Aarts 2012) . Cd cations in the root cells may complex with metal-binding chelators such as nicotianamine (NA), phytochelatin (PC), and metallothionein (MT) (Luo et al. 2016 ). Cytosolic Cd cations or PC-Cd complexes may be sequestered in vacuoles via tonoplast-localized magnesium proton exchangers (MHX) and ATP-binding cassette transporter C1 (ABCC1) (Berezin et al. 2008 , Park et al. 2012 . Vacuole-sequestered HMs, including Cd, may be remobilized via the tonoplast-localized metal efflux transporter NRAMP3 and transported into the apoplast by PM-localized transporters such as HM ATPase 4 (HMA4) and plant cadmium resistance protein 2 (PCR2), which are critical for Cd translocation from the roots to the shoots (Thomine et al. 2000 , Verret et al. 2004 , Song et al. 2010 , Lin and Aarts 2012 . Exogenous melatonin upregulated ABC transporter and PCR2 in alfalfa, and HMA4 in Arabidopsis (Gu et al. 2017) . To the best of our knowledge, however, there is no information on the transcriptional regulation of the genes governing melatonin-mediated Cd uptake, translocation, and tolerance in apple trees. Fruit tree rootstocks are used in vegetative propagation and control HM uptake and translocation to the aerial organs (Podazza et al. 2016) . Previously, we evaluated Cd accumulation and tolerance among various apple rootstocks and established that M. baccata and M. micromalus "qingzhoulinqin" differed greatly in terms of Cd uptake and accumulation (Zhou et al. 2017) . To examine the potential roles of melatonin in Cd uptake, accumulation 5 and detoxification in M. baccata and M. micromalus "qingzhoulinqin", we exposed the rootstocks to either 0 or 30 μM Cd together with 0 or 100 μM melatonin for 20 d. We measured their growth characteristics, net root Cd 2+ flux, Cd accumulation, melatonin concentrations, ROS and antioxidants levels, and the key genes involved in Cd uptake, translocation, and detoxification. The results obtained from this study will provide a basis for the development of reliable methods for reducing Cd accumulation and increasing Cd tolerance in apple and other fruit trees. Seeds of Malus baccata Borkh. (Mb) and M. micromalus "qingzhoulinqin" (Mm) were stratified at 0-4 °C for 40 d. After germination, the seedlings were cultivated for 45 d in a greenhouse under natural light and temperature conditions (day/night temperature: 26/18 °C; relative humidity (RH): 50-60%) on seedling matrices in nursery plates. Seedlings of uniform height (~8 cm) were transferred to plastic pots (20 cm × 20 cm × 18 cm) containing clean sand. One seedling per pot was irrigated with half-strength Hoagland nutrient solution (pH 6.0) every second evening. After 6 weeks, plants from both species with similar growth performance were transferred to aerated half-strength Hoagland nutrient solution (pH 6.0) that was refreshed every 2 d. After cultivation in a hydroponic system for 1 week, 72 plants of both species similar in size and growth performance were equally divided among four groups (18 plants per group). The plants in each group were exposed to either 0 or 30 μM Cd together with 0 or 100 μM melatonin (M5250; Sigma-Aldrich Corp., St. Louis, MO, USA) by adding CdCl 2 ·2.5H 2 O or melatonin to the half-strength Hoagland nutrient solution. The Cd and melatonin treatments continued for up to 20 d before harvest. Six plants were randomly selected per experimental group to measure net Cd 2+ fluxes. The other 12 plants were 6 harvested after measuring their gas exchange rates. Root net Cd 2+ fluxes in both apple rootstocks were measured as previously described ) by a noninvasive micro-test technique (NMT system BIO-IM; Younger Corp., Amherst, MA, USA) at Xuyue Science & Technology Co. Ltd. (Beijing, China). An ion-selective microelectrode with an external tip (diameter range: ∼2-4 μm) was fabricated and silanized with tributylchlorosilane and the tip was backfilled with an ion-selective cocktail (XY-SJ-Cd; Younger Corp., Amherst, MA, USA). Before the measurements were taken, the microelectrode was calibrated with 10 μM and 100 μM Cd 2+ . To determine the position of maximal Cd 2+ fluxes along the root tip, six fine white roots (diameter ∼1.5 mm) were selected from each rootstock species treated with 30 μM Cd 2+ . A preliminary experiment was conducted by taking measurements at 300 μm, 600 μm, 1,200 μm, 1,500 μm, and 3,000 μm from the root tips. The fine roots were cut from the plants and immediately transferred to 5 mL measuring solution (0.03 mM CdCl 2 , 0.1 mM KCl, 0.5 mM NaCl, 0.3 mM MES, and 0.2 mM Na 2 SO 4 ; pH 6.0). After 15 min equilibration, each fine root was transferred to fresh measuring solution and the net Cd 2+ fluxes were measured for 5 min per position. Cd 2+ gradients near the root surface (∼2-5 μm) were measured by moving the Cd 2+ -selective microelectrode between two positions 30 μm apart and perpendicular to the root surface. Net Cd 2+ fluxes data were processed in imFlux coupled to the NMT system. Before harvest, gas exchange was measured for three mature leaves (leaf plastochron index range: 7-9) per plant in a CIRAS-2 photosynthesis system (PP Systems, Amesbury, MA, USA) as recommended by Zhou et al. (2017) . Root, stem, and leaf tissues were then excised from each plant. The roots were rinsed 7 with 20 mM EDTA disodium for 5 min and washed with deionized water for 5 min to remove any Cd 2+ adhering to their surfaces (Shi et al. 2019) . The fresh weights of the excised root, stem, and leaf tissues were recorded. The materials were immediately frozen in liquid nitrogen, ground to a fine powder in a ball mill (MM400; Retsch, Haan, Germany) and stored at -80 °C until the subsequent biochemical and molecular analyses. To calculate the fresh-to-dry mass ratio, fresh root, stem, and leaf powders (~50 mg each) were dried at 60 °C for 72 h. The biomass of each tissue type was calculated according to its fresh-to-dry mass ratio and fresh weights. Fine root and stem subsamples were harvested for histochemical analysis. To measure the chlorophyll concentrations, fine leaf powder was extracted in 5 mL of 80% (v/v) acetone in the dark for 24 h. Absorbances of the extract were measured by spectrophotometry (UV-3802, Unico Instruments Co. Ltd, Shanghai, China) at 663, 646 and 470 nm, respectively (Wellburn 1994) . Root and stem Cd localization was investigated by histochemical staining method as suggested by He et al. (2013) . Intact tissues or hand sections of fresh fine root and stem samples were rinsed in deionized H 2 O and exposed to a staining solution (30 mg diphenylthiocarbazone in 60 mL acetone, 20 mL H 2 O, and 100 μL glacial acetic acid) for 1 h. The tissues were quickly rinsed in deionized H 2 O. Samples containing abundant red-black Cd-dithizone precipitate were immediately observed and photographed under an Eclipse E200 light microscope (Nikon, Tokyo, Japan) fitted with a CCD camera (DS-Fi1; Nikon, Tokyo, Japan) and connected to a computer. Determinations of Cd concentration, BCF, and T f 8 Fine root, stem, and leaf powders (~100 mg each) were digested in a mixture of 7 mL concentrated HNO 3 plus 1 mL concentrated HClO 4 at 170 °C as previously described . Cd concentrations were determined by flame atomic absorbance spectrometry (Hitachi 180-80; Hitachi Ltd., Tokyo, Japan). The bioconcentration factor (BCF) is the ratio of the root and shoot Cd content to the Cd concentration of the solution (He et al. 2015) . The translocation factor (T f ) is the ratio of the shoot to root Cd concentrations multiplied by 100% (He et al. 2015) . Melatonin concentrations in the roots, stems and leaves were measured by enzyme-linked immunosorbent assay (ELISA) according to Pape and Lüning (2006) •− in the roots, stems, and leaves were measured by monitoring the nitrite formation from hydroxylamine spectrophotometrically at 530 nm as previously described (Elstner and Heupel 1976) with some modifications (Verma and Mishra 2005) . The H 2 O 2 concentrations were measured in a spectrophotometer according to the method of Patterson et al. (1984) . The malondialdehyde (MDA) concentrations were measured spectrophotometrically at 450, 532 and 600 nm as suggested by Hodges et al. (1999) . The concentrations of free proline were determined according to the method of Bates et al. (1973) , whereas soluble phenolics were measured as described previously by Swain and Goldstein (1964) , total thiols (T-SH) according to Sedlak and Lindsay (1968) , ascorbate (ASC) according to Kampfenkel et al. (1995) , and reduced glutathione (GSH) according to Griffith (1980) with minor modifications. Soluble proteins were extracted from the roots, stems, and leaves and quantified according to a previously described method (Bradford 1976) . The activity levels of catalase (CAT) and peroxidase (POD) were analyzed according to Chance and Maehly (1955) . The ascorbate peroxidase (APX) activity was measured according to the method of Nakano and Asada (1981) . The activity of glutathione reductase (GR) was measured according to the method of Connell and Mullet (1986) . The gene transcript levels were measured according to a previously described method . Total root RNA was extracted and purified with a plant RNA extraction kit (R6827; Omega Bio-Tek, Norcross, GA, USA) according to the manufacturer"s instructions. RNA concentration and quality in each sample were determined by spectrophotometry (NanoDrop 2000; Thermo Fisher Scientific, Waltham, MA, USA) and agarose gel electrophoresis, respectively. One-microgram aliquots of total RNA were used to generate first-strand cDNA with a PrimeScript RT Reagent Kit with gDNA Eraser (DRR037A; Takara, Dalian, China) in a total volume of 20 μL. Quantitative reverse-transcription polymerase chain reaction was run with 10 μL of 2×SYBR Green Premix Ex Taq II (DRR820A; Takara, Dalian, China), 0.5 μL cDNA, and 0.2 μM primer per gene (Table S1 ) in a CFX96 Real Time System (CFX96; Bio-Rad Laboratories, Hercules, CA, USA). β-Actin was the reference gene (Table S1 ). A melting curve program was used to confirm PCR product homogeneity. Relative mRNA expression was calculated according to the 2 -∆∆Ct method (Livak and Schmittgen 2001) . The expression level was set to 1 for each gene in the roots of M. baccata (Mb) treated with 0 μM Cd and 0 μM melatonin (-Cd-MEL). The corresponding fold changes relative to this control were calculated for the other treatments. A gene expression heatmap was plotted according to the average log base 2 expression fold changes in heatmap.2 of the "gplots" package in R (http://www.r-project.org/) as previously described . Data were processed in Statgraphics (Statgraphics Technologies, Inc., The Plains, VA, USA) after checking for normality. To test for significant changes in root average net Cd 2+ fluxes, the main effects of species (S) and melatonin (M) were analyzed by two-way ANOVA. For the other data, three-way ANOVA was used with Cd treatment (T), species (S), and melatonin (M) as factors. All P values obtained from the multiple comparisons were corrected by the Tukey-HSD method to reduce the chance of type I errors. Differences between means were considered significant at P < 0.05. For the principal component analysis (PCA), the data were standardized and computed with the prcomp package in R (http://www.r-project.org/) as previously recommended (He et al. 2015) . Cd exposure severely reduced foliar carbon assimilation rate (A), stomatal conductance (g s ), and transpiration rate (E) in M. baccata and M. micromalus "qingzhoulinqin" relative to their controls (Table S2 ). However, under Cd exposure conditions, A and E were 1.3-and 1.6-fold higher, respectively, in M. micromalus "qingzhoulinqin" treated with melatonin than those without exogenous melatonin treatment (Table S2 ). The Cd treatment also lowered foliar photosynthetic pigment concentrations in both apple rootstocks exposed to Cd, but to a 11 relatively greater extent in the Cd-susceptible M. micromalus "qingzhoulinqin". Exogenous melatonin alleviated Cd-induced adverse effects. These were more pronounced in M. micromalus 'qingzhoulinqin" (Cd-susceptible) than in M. baccata (Cd-tolerant) (Table S2) . Consistent with Cd-induced photosynthetic inhibition, the root, stem and leaf dry weights in both species were substantially reduced by Cd exposure (Table 1) . However, the melatonin treatment markedly alleviated Cd-induced decreases in stem and leaf dry biomass for M. micromalus "qingzhoulinqin" but not M. baccata (Table 1) . For all Cd exposures and melatonin treatments, the maximum net Cd 2+ influxes in M. baccata and M. micromalus "qingzhoulinqin" occurred 300-600 μm from the root tips ( Figure 1a ). In both rootstocks, the net Cd 2+ fluxes dramatically decreased with increasing distance from the root tips. In response to Cd exposure without melatonin, M. baccata even presented with a net Cd 2+ efflux of 3,000 μm from the root tips. For all Cd exposures and melatonin treatments, the net Cd 2+ fluxes were always greater in the roots of M. micromalus "qingzhoulinqin" than in those of M. baccata (Figure 1a ). Exogenous melatonin reduced the average net Cd 2+ fluxes by 65.4 % and 10.4% at 300 μm and 600 μm from the root tips of Cd-exposed M. baccata and M. micromalus "qingzhoulinqin", respectively ( Figure 1b) . Dithizone histochemical staining revealed that Cd was deposited in the roots and stems of Cd-exposed M. baccata and M. micromalus "qingzhoulinqin" (Figure 2 ). The Cd localization had a similar pattern in both species (Figure 2 ). In the roots, the Cd was localized mainly to the cell walls and intercellular spaces. In the stems, dark brown deposits were detected in phloem parenchyma cells. There was more Cd-dithizone staining in the roots and stems of M. micromalus "qingzhoulinqin" than in those of M. baccata (Figure 2 ). In both species, exogenous melatonin application had no obvious effect on root Cd deposition but significantly decreased Cd accumulation in the stems relative to the Cd treatment alone ( Figure 2 ). Cd accumulated in the root, stem, and leaf tissues of both Malus species (Figure 3) . However, the Cd concentrations were lower in all tissues of M. baccata than in those of M. micromalus "qingzhoulinqin". Melatonin application did not alter root Cd accumulation but significantly reduced foliar Cd accumulation in both species relative to the Cd treatment alone (Figures 3a and 3c) . Nevertheless, the melatonin treatment decreased the relative foliar Cd accumulation in M. micromalus "qingzhoulinqin" by 51.4% whereas for M. baccata it lowered it by only 38.2% (Figure 3c ). BCF and T f were calculated for both species to compare their Cd accumulation and translocation capacities ( Figure 4 ). Root and aerial organs BCF were consistently higher for M. micromalus "qingzhoulinqin" than for M. baccata ( Figure 4a ). Exogenous melatonin had no influence on root or aerial organs BCF in Cd-exposed M. baccata. Relative to M. micromalus "qingzhoulinqin" exposed to Cd alone, however, the melatonin treatment significantly decreased root and aerial organs BCF by 10.9% and 14.4%, respectively ( Figure 4a ). Melatonin application significantly reduced T f by ~5.8% and ~6.1% in Cd-exposed M. baccata and M. micromalus "qingzhoulinqin", respectively, relative to the Cd treatment alone (Figure 4b ). Endogenous melatonin concentrations were determined for the roots, stems, and leaves of both Malus species under study ( Figure 5 ). In Cd-exposed plants, endogenous melatonin concentrations increased in the roots and leaves of M. baccata and M. micromalus "qingzhoulinqin" relative to that in plants not exposed to Cd (Figures 5a and 5c) . Cd exposure had no significant effects on endogenous melatonin concentration in the stems of either species (Figure 5b ). Endogenous melatonin concentrations were always higher in the roots 13 and leaves of M. baccata than in those of M. micromalus "qingzhoulinqin" without exogenous melatonin addition (Figures 5a and 5c ). Irrespective of Cd exposure, increased endogenous melatonin concentrations were found in the roots, stems, and leaves of both apple rootstocks treated with exogenous melatonin, except for leaves of M. baccata treated with exogenous melatonin under no Cd exposure conditions (Figures 5a-c) . Further, the increase in endogenous melatonin was more pronounced in M. micromalus "qingzhoulinqin" than in M. baccata after the addition of exogenous melatonin, irrespective of Cd exposure (Figures 5a-c) . Compared with the untreated controls of both species, the plants exposed to Cd alone presented with significantly elevated root, stem, and leaf O 2 •− concentrations ( Figure 6 ). Nevertheless, these increments were greater for M. micromalus "qingzhoulinqin" than for M. baccata ( Figure 6 ). Melatonin application significantly reduced O 2 •− accumulation by 19.4%, 24.7%, and 34.8%, respectively, in the roots, stems, and leaves of Cd-challenged M. baccata and by 29.4%, 29.1%, and 8.7%, respectively, in the same organs of Cd-stressed M. micromalus "qingzhoulinqin" (Figure 6 ). Relative to the untreated controls, the Cd-treated M. baccata presented with H 2 O 2 concentrations that were 30.3%, 30.5%, and 59.0% higher in the roots, stems, and leaves, respectively. For Cd-treated M. micromalus "qingzhoulinqin", the root, stem, and leaf H 2 O 2 concentrations were 68.5%, 57.8%, and 60.4% higher, respectively, than those of the untreated controls ( Figure 6 ). Exogenous melatonin alleviated Cd-induced Table S3 ). PC2 reflected the effects of melatonin and covered 21% of the total variance (Figure 7a ). The concentrations of soluble phenolics in the roots, the GSH concentrations in the roots and leaves, and the CAT and GR activities in the roots, the APX activity in the roots and leaves were the major positive contributors to PC2 (Supplementary Table S3 ). For M. micromalus "qingzhoulinqin", however, the opposite results were returned. PC1 separated the effects of melatonin treatment while PC2 disclosed variations in the effects of Cd treatment (Figure 7b ). PC1 and PC2 accounted for 58% and 24% of the observed variation, respectively (Figure 7b ). The key positive contributors to PC1 were the concentrations of free proline in the roots, stems and leaves, the T-SH concentrations in the stems and leaves, the ASC concentrations in the leaves, the POD and GR activities in the roots, stems, and leaves (Supplementary Table S4 ). In contrast, the concentrations of GSH, ASC, and the soluble phenolics in the roots, the APX activity in the roots were the important positive factors for PC2 (Supplementary Table S4 ). Notably, treatments of +Cd-MEL and +Cd+MEL located at different quadrants of PCA in both apple rootstocks (Figures 7a and 7b) , indicating the significant effects of melatonin on baccata (Figures 7a and 7b) . The transcript levels of the genes involved in Cd uptake, transport, and detoxification were assessed for the roots of M. baccata and M. micromalus "qingzhoulinqin" (Figure 8 ). HA7 and NRAMP1 probably participate in root Cd uptake and transport. Relative to the control, the abundances of HA7 in the roots of M. baccata and NRAMP1 in the roots of both species markedly decreased after Cd treatment, irrespective of melatonin application (Figure 8 ). Under Cd exposure, the mRNA levels of HA7 and NRAMP1 decreased by 2.3-and 49.1-fold, respectively, in the roots of M. baccata due to the application of exogenous melatonin. Whereas exogenous melatonin raised HA7 transcript level in the Cd-treated roots of M. micromalus "qingzhoulinqin" (Figure 8 ). The transcript levels of HA7 were 8.4-fold higher in the roots of M. micromalus "qingzhoulinqin" than in those of M. baccata supplied with exogenous melatonin under Cd exposure (Figure 8 ). Regardless of melatonin treatment, reduced transcript levels of NRAMP1 were found in the roots of Cd-challenged M. baccata compared with Cd-exposed M. micromalus "qingzhoulinqin ( Figure 8 ). Vacuolar Cd cations may be exported to the cytoplasm by tonoplast-localized transporters such as NRAMP3 which also initiates Cd translocation to the shoot (Thomine et al. 2000) . In the absence of exogenous melatonin, the NRAMP3 transcript levels were higher in the roots of both tree species exposed to Cd than in those of the untreated controls ( Figure 8 ) This effect was especially pronounced for PCR2 in the roots of M. micromalus "qingzhoulinqin" (Figure 8 ). Under Cd treatment, the HMA4 and PCR2 transcript levels were always higher in the roots of M. micromalus "qingzhoulinqin" than in those of M. baccata regardless of exogenous melatonin (Figure 8 ). NAS1 and MT2 may detoxify Cd in plants (Luo et al. 2016) . Transcriptional NAS1 upregulation occurred in the roots of both apple rootstocks subjected to Cd and melatonin together but not in those exposed to melatonin alone (Figure 8 ). Under Cd treatment, the root NAS1 transcript levels in M. baccata were 1.6-and 2.6-fold higher than those of M. micromalus "qingzhoulinqin" without and with melatonin treatment, respectively (Figure 8 ). In contrast, Cd treatment significantly downregulated MT2 in the roots of both Malus species relative to the control rootstocks ( Figure 8 ). However, melatonin application upregulated root MT2 mRNA levels in the roots of both Cd-treated apple rootstocks (Figure 8 ). Cd and Cd-containing complexes in the cytosol may be transported to the vacuoles by MHX and ABCC1, respectively, in the tonoplast (Berezin et al. 2008 , Park et al. 2012 MHX and ABCC1 mRNA levels were higher in the roots of Cd-exposed M. baccata than in those of Cd-treated M. micromalus "qingzhoulinqin" in the absence of melatonin (Figure 8 ). Cd is not essential element for plant growth. However, it is readily absorbed by the roots and is partially transported to the shoots (Salt et al. 1995) . Plants tolerate Cd by excluding and detoxifying it and by mobilizing antioxidant defense mechanisms (Baker 1987) . Exclusion comprises the inhibition of root Cd uptake and the restriction of Cd translocation to the shoots (Hasan et al. 2009 ). Previous studies reported that exogenous melatonin influences metal exclusion in herbaceous plants. Gu et al. (2017) found that melatonin pretreatment significantly inhibited Cd accumulation in alfalfa seedling roots but not in their shoots. In contrast, exogenous melatonin had no effect on tomato root Cd accumulation but substantially lowered tomato leaf Cd content (Hasan et al. 2015) . These discrepancies suggest that exogenous melatonin may have different effects on various plant species in terms of Cd uptake and accumulation. Only limited information is available regarding the mechanisms by which melatonin mediates Cd uptake and translocation from the roots to the aerial organs in Malus species. To clarify the influences of exogenous melatonin on Cd uptake, net Cd 2+ fluxes along the root tips of two apple rootstocks differing in Cd accumulation were monitored by NMT fitted with a Cd-selective microelectrode (Figure 1 ). The relatively low Cd uptake rates in the roots of M. baccata and M. micromalus "qingzhoulinqin" after exogenous melatonin application showed that this treatment inhibited root Cd uptake. A previous study showed that melatonin and its synthetic precursors combine with HMs such as Cd 2+ , thereby reducing their absorption by plants . Earlier studies showed that reducing Cd translocation from the roots limits Cd accumulation in the shoots (Akhter et al. 2012 (Akhter et al. , 2014 . Here, decreasing net Cd 2+ influx did not lower root Cd accumulation. Nevertheless, it significantly reduced Cd accumulation and T f s in the aerial organs of both species treated with melatonin (Figures 3 and 4) . Thus, melatonin application altered Cd allocation to various apple rootstock organs. Melatonin treatment may promote the formation of a barrier against Cd translocation to the shoots and protect the photosynthetic apparatus from Cd-induced damage (Jakovljevic et al. 2014 ). There was far less Cd accumulation in the aerial organs of Cd-stressed M. micromalus "qingzhoulinqin" than in those of Cd-treated M. baccata due to the addition of exogenous melatonin (Figure 3) . Therefore, melatonin application had a comparatively stronger impact on Cd-susceptible apple species. This conclusion aligns with previous findings reported for Malus species subjected to drought stress . Melatonin-suppressed root Cd uptake and translocation to the aerial organs in both apple rootstocks is probably associated with melatonin-modulated transcription of genes regulating Cd uptake and accumulation. PM-bound H + -ATPases, NRAMPs, HMA4, and PCR2 regulate divalent cation uptake and transport in plants (Luo et al. 2016 , Shi et al. 2019 ). HA7 encodes PM-bound H + -ATPases. Its downregulation lowered net Cd 2+ influxes into the roots of M. baccata more than those of other apple rootstocks ). In the present study, exogenous melatonin decreased HA7 and NRAMP1 mRNA levels ( Figure 8 ). This finding was consistent with the observed decreases in root Cd influxes (Figure 1 ). The localized PM transporters HMA4 and PCR2 exclude cytosolic Cd 2+ to the apoplast. This process is crucial for loading HMs into the root stele xylem (Song et al. 2010 , Nouet et al. 2015 . Melatonin-regulated genes participating in Cd 2+ transport have been reported for herbaceous plants. Melatonin application to alfalfa seedling roots increased their PCR2 mRNA levels and decreased their Cd content (Gu et al. 2017) . Here, however, we found that melatonin downregulated root HMA4 and PCR2 in both Malus species subjected to Cd ( Figure 8 ). These inconsistencies may be explained by the relative differences between herbaceous and woody plants in terms of Cd uptake and accumulation. In general, fruit trees have strong abilities to accumulate Cd in their roots and block its translocation to their aerial organs (Nada et al. 2007 , Zhou et al. 2017 ). In the present study, melatonin-promoted HMA4 and PCR2 downregulation further restricted Cd translocation from the roots to the aerial organs of the apple trees. These observations were confirmed by the measured decreases in stem and leaf Cd content and T f (Figures 3 and 4) . Regardless of exogenous melatonin, the roots of Cd-exposed M. micromalus "qingzhoulinqin" had relatively higher HA7, NRAMP1, 20 HMA4, and PCR2 mRNA levels than those of Cd-stressed M. baccata (Figure 8 ). These results were consistent with the comparatively higher root Cd influxes and aerial organ Cd translocation and accumulation rates (Figures 1, 3 and 4) . Cd has no known biological function and is toxic to most organisms (Luo et al. 2016) . Here, the observed reductions in photosynthetic rate, chlorophyll, content, and overall biomass and increases in ROS and MDA in the apple rootstocks subjected to Cd suggest that they were reacting to Cd exposure and toxicity. A previous study reported that melatonin might regulate plant growth and development (Tan et al. 2012 ). Our results indicated that exogenous melatonin enhanced the photosynthetic rates, increased the chlorophyll levels and biomass, and reduced the ROS and MDA levels in various tissues of both apple rootstocks subjected to Cd stress. However, these beneficial effects were particularly strong in M. micromalus "qingzhoulinqin". Thus, exogenous melatonin alleviated the toxic effects of Cd in these plants, which aligns with previous reports , Ni et al. 2018 . Under Cd exposure conditions, more endogenous melatonin was found in the roots and leaves of M. baccata than in those of M. micromalus "qingzhoulinqin" ( Figure 5 ). Therefore, the former produced sufficient melatonin to contend with Cd-induced oxidative stress. This response is consistent with its relatively high Cd tolerance and comparatively low loss of photosynthetic pigments and biomass in response to Cd stress. However, exogenous melatonin enhanced endogenous melatonin concentrations and alleviated Cd-induced toxicity in all tissues of both apple rootstocks but especially in M. micromalus "qingzhoulinqin". Thus, exogenous melatonin may have antioxidant efficacy in addition to its other regulatory functions in several Cd tolerance pathways. Plants subjected to Cd stress present with impaired redox homeostasis, accumulate ROS, and undergo PM lipid peroxidation (Podazza et al. 2012) . Plants have several non-enzymatic and enzymatic antioxidant mechanisms to counteract the destructive effects of Cd-induced ROS (Guo et al. 2019) . Non-enzymatic antioxidants such as free proline, soluble phenolics, T-SH, GSH, and ASC, while enzymatic antioxidants including CAT, POD, APX, and GR, can scavenge Cd-induced ROS (He et al. 2013 , Shi et al. 2019 . Melatonin induces the antioxidant system to scavenge stress-induced ROS, prevent lipid peroxidation, and protect cells from oxidative damage (Romero et al. 2014 . In wheat, melatonin application mitigated Cd-induced ROS by upregulating SOD, POD, and APX (Ni et al. 2018 ). Here, exogenous melatonin increased the free proline, soluble phenolic, T-SH, GSH, and ASC concentrations (Supplementary Figure S1 ) and activated CAT, POD, APX, and GR (Supplementary Figure S2 ). All of these might have contributed to Cd-induced ROS scavenging. Overall, melatonin may modulate Cd chelator levels, initiate antioxidant defense systems, thereby attenuate Cd-induced oxidative stress in apple rootstocks. Cd-stressed plants modulate the transcription of genes participating in Cd detoxification (Ding et al. 2017) . Our previous study showed that the mRNA levels of the AtNAS1 ortholog in the roots of M. baccata were higher than those of three other apple rootstocks . Arabidopsis thaliana overexpressing the Brassica juncea gene encoding MT2 shows elevated Cd tolerance relative to the WT seedlings . Previous studies have shown that MHX and ABCC1 transport Cd ions or PC-Cd into the vacuoles, thereby detoxifying Cd (Gaash et al. 2013 , Song et al. 2014 ). There is little empirical evidence that melatonin mediates transcriptional regulation of the genes involved in Cd detoxification. Here, elevated endogenous melatonin was detected in the roots of apple rootstocks treated with exogenous melatonin. This response might have upregulated Cd-detoxifying genes such as NAS1, MT2, MHX, and ABCC1 ( Figure 8 ). However, further study is required to elucidate the mechanisms underlying the melatonin-mediated transcription of genes involved in Cd detoxification. As summarized in Figure 9 , Cd was absorbed by the roots and partially translocated to the aerial organs of apple rootstocks. In response, photosynthesis, pigment content, and biomass accumulation were all reduced. Cd stress alone more strongly decreased photosynthesis and biomass and perturbed redox homeostasis and enzyme activity in M. micromalus "qingzhoulinqin" than in M. baccata. A plausible explanation is that the former had lower endogenous melatonin levels than the latter. and toxicity in apple rootstocks exposed to Cd. The left chart represents apple rootstocks exposed to Cd alone (a-b), and the right chart depicts apple rootstocks treated with Cd and exogenous melatonin (c-d). Exogenous melatonin decreased Cd uptake rates in the roots and translocation to the aerial organs in the apple rootstocks. Moreover, exogenous melatonin relieved Cd-induced oxidative stress via improving antioxidant defense system. CW, cell wall; PM, plasma membrane; V, vacuole; MEL, metolanin. SAM, S-adenosyl-l-methionine; HA7, PM H + -ATPases 7; NRAMP1 and NRAMP3, natural resistance associated macrophage 40 protein 1 and 3; HMA4, P-type heavy metal ATPase 4; PCR2, plant cadmium resistance protein 2; NAS1, nicotianamine synthase 1; MT2, metallothionein 2; ABCC1, ATP-binding cassette transporter C1; MHX, magnesium proton exchanger protein. Table 1 The dry mass (g) of root, stem, leaf and whole plant of Malus baccata (Mb) and M. micromalus "qingzhoulinnqin" (Mm) exposed to 0 or 30 μM CdCl 2 combined with either 0 or 100 μM melatonin for 20 days. Reduced translocation of cadmium from roots is associated with increased production of phytochelatins and their precursors Localization and chemical speciation of cadmium in the roots of barley and lettuce Expression of BjMT2, a metallothionein 2 from Brassica juncea, increases copper and cadmium tolerance in Escherichia coli and Arabidopsis thaliana, but inhibits root elongation in Arabidopsis thaliana seedlings Metal tolerance Rapid determination of free proline in water stress studies Overexpression of AtMHX in tobacco causes increased sensitivity to Mg 2+ , Zn 2+ , and Cd 2+ ions, induction of V-ATPase expression, and a reduction in plant size A rapid and sensitive method for the quantification of microgram quantities of proteins utilizing the principle of protein-dye binding Coordinated regulation of melatonin synthesis and degradation genes in rice leaves in response to cadmium treatment Assay of catalases and peroxidases Plant science: the key to preventing slow cadmium poisoning Pea chloroplast glutathione reductase: Purification and characterization Exogenous glutathione enhances cadmium accumulation and alleviates its toxicity in Populus × canescens Distribution of heavy metal pollution in surface soil samples in China: a graphical review Inhibition of nitrite formation from hydroxylammonium chloride: a simple assay for superoxide dismutase High content of five heavy metals in four fruits: Evidence from a case study of Pujiang County Phylogeny and a structural model of plant MHX transporters Comparison of cadmium-induced iron-deficiency responses and genuine iron-deficiency responses in Malus xiaojinensis Determination of glutathione and glutathione disulfide using glutathione reductase and 2-vinylpyridine Melatonin confers plant tolerance against cadmium stress via the decrease of cadmium accumulation and reestablishment of microRNA-mediated redox homeostasis Cadmium stress increases antioxidant enzyme activities and decreases endogenous hormone concentrations more in Cd-tolerant than Cd-sensitive wheat varieties Melatonin mitigates cadmium phytotoxicity through modulation of phytochelatins biosynthesis vacuolar sequestration, and antioxidant potential in Solanum lycopersicum L Cadmium: toxicity and tolerance in plants Overexpression of bacterial gamma-glutamylcysteine synthetase mediates changes in cadmium influx, allocation and detoxification in poplar A transcriptomic network underlies microstructural and physiological responses to cadmium in Populus × canescens Improving the thiobarbituric acid-reactive-substances assay for estimating lipid peroxidation in plant tissues containing anthocyanin and other interfering compounds Adaptive response of poplar (Populus nigra L.) after prolonged Cd exposure period Extraction and determination of ascorbate and dehydroascorbate from plant tissue Melatonin-mediated nitric oxide improves tolerance to cadmium toxicity by reducing oxidative stress in wheat plants The interaction of melatonin and its precursors with 27 aluminium, cadmium, copper, iron, lead, and zinc: An adsorptive voltammetric study Cadmium-induced melatonin synthesis in rice requires light, hydrogen peroxide, and nitric oxide: key regulatory roles for tryptophan decarboxylase and caffeic acid O-methyltransferase Melatonin mediates the regulation of ABA metabolism, free-radical scavenging, and stomatal behaviour in two Malus species under drought stress Melatonin mediates selenium-induced tolerance to cadmium stress in tomato plants The interaction of melatonin and its precursors with aluminium, cadmium, copper, iron, lead, and zinc: an adsorptive voltammetric study The molecular mechanism of zinc and cadmium stress response in plants Analysis of relative gene expression data using real-time quantitative PCR and the 2 -∆ ∆CT method Global poplar root and leaf transcriptomes reveal links between growth and stress responses under nitrogen starvation and excess Heavy metal accumulation and signal transduction in herbaceous and woody plants: paving the way for enhancing phytoremediation efficiency Ectomycorrhizas with Paxillus involutus enhance cadmium uptake and tolerance in Populus × canescens Cadmium-induced growth inhibition and alteration of biochemical parameters in almond seedlings grown in solution culture Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts Environmental exposure to cadmium and risk of cancer: a prospective population-based study Exogenous melatonin confers cadmium tolerance by counterbalancing the hydrogen peroxide homeostasis in wheat seedlings Functional analysis of the three HMA4 copies of the metal hyperaccumulator Arabidopsis halleri Quantification of melatonin in phototrophic organisms The phytochelatin transporters AtABCC1 and AtABCC2 mediate tolerance to cadmium and mercury Estimation of hydrogen peroxide in plant extracts using titanium (IV) External costs of cadmium emissions to soil: a drawback of phosphorus fertilizers Cadmium accumulation and strategies to avoid its toxicity in roots of the citrus rootstock Citrumelo Early interconnectivity between metabolic and defense events against oxidative stress induced by cadmium in roots of four citrus rootstocks Melatonin and its metabolites: new findings regarding their production and their radical scavenging actions A review of metal-catalyzed molecular damage: protection by melatonin Mechanisms of cadmium mobility and Aaccumulation in Indian Mustard Estimation of total, protein-bound, and nonprotein sulfhydryl groups in tissue with Ellman's reagent Abscisic 30 acid enhances lead translocation from the roots to the leaves and alleviates its toxicity in Populus × canescens Expression of the P1B-type ATPase AtHMA4 in tobacco modifies Zn and Cd root to shoot partitioning and metal tolerance Arabidopsis PCR2 ss a zinc exporter involved in both zinc extrusion and long-distance zinc transport A rice ABC transporter, OsABCC1, reduces arsenic accumulation in the grain Heavy metals mobility, sources, and risk assessment in soils and uptake by apple (Malus domestica Borkh.) leaves in urban apple orchards The quantitative analysis of phenolic compounds Functional roles of melatonin in plants, and perspectives in nutritional and agricultural science Cadmium and iron transport by members of a plant metal transporter family in Arabidopsis with homology to Nramp genes Putrescine alleviation of growth in salt stressed Brassica juncea by inducing antioxidative defense system Overexpression of AtHMA4 enhances root-to-shoot translocation of zinc and cadmium and plant metal tolerance The spectral determination of chlorophyll-a and chlorophhyll-b, as well as total carotenoids, using various solvents with spectrophotometers of different resolution Roles of melatonin in abiotic stress resistance in plants Integration of cadmium accumulation, subcellular distribution, and physiological responses to understand cadmium tolerance in apple rootstocks Net cadmium flux and gene expression in relation to differences in cadmium accumulation and translocation in four apple rootstocks The authors thank Editage (www.editage.cn) for English language editing.