Plant Zn Uptake Research Articles

Interaction Effects of Phosphorus and Zinc Application on Their Availability and Growth of Rice (<em>Oryza sativa</em>) in an Alfisol of Sri Lanka

This study investigated the interactive effects of phosphorus (P) and zinc (Zn) application on P and Zn availability, and growth of rice (Oryza sativa) in an Alfisol. In a laboratory incubation experiment, soil samples were supersaturated with treatment solutions with all possible combinations of four P levels (0, 6, 12, and 24 mg kg-1 equivalent to 0, 10, 20, and 40 kg ha-1, respectively) and three Zn levels (0, 1.2, and 2.4 mg kg-1 equivalent to 0, 2, and 4 kg ha-1, respectively), and then allowed to air-dry. Available P and Zn contents in soil increased as the application rates were increased but P×Zn rate interaction effect was not significant. In a pot experiment, rice (var Bg 358) was grown for 10 weeks with all possible combinations of three P levels (0, 5.5, and 16.5 mg kg-1) and three Zn levels (0, 1, and 2 mg kg-1). Initial soil P was higher than the critical level (12 mg kg-1), but available Zn was below the critical level (1.5 mg kg-1). The main effect of P rate did not significantly affect the number of tillers and shoot dry matter content while Zn application decreased them. Root dry matter, and root and shoot P concentrations were significantly (P<0.05) influenced by P×Zn rate interaction effect. While, plant P uptake was significantly decreased due to P and Zn application, plant Zn uptake was not affected. Therefore, for a better growth of rice plant, the soils with high available P and low Zn contents should be carefully fertilized with P and Zn fertilizers.

Zinc solubilization and organic acid production by the entomopathogenic fungus, Metarhizium pingshaense sheds light on its key ecological role in the environment

We report for the first-time higher zinc (Zn) solubilization efficiency and plant growth promotion by an entomopathogenic fungus (EPF), Metarhizium pingshaense IISR-EPF-14, which was earlier isolated from Conogethes punctiferalis, a pest of global importance. The Zn solubilizing efficiency of the fungus varied depending on the type of insoluble source of Zn used, which was observed to be 1.6 times higher in Zn3(PO4)2–amended media compared to ZnO media. In liquid media, there was a 6.2-fold increase in available Zn in ZnO–amended media, whereas a 20.2-fold increase in available Zn was recorded in Zn3(PO4)2 medium. We ascribe the production of various organic acids such as gluconic, keto-gluconic, oxalic, tartaric, malonic, succinic and formic acids, which in general, interact with insoluble Zn sources and make them soluble by forming metal cations and displacing anions as the major mechanism for Zn solubilization by M. pingshaense. However, the type and amount of organic acid produced in the media varied depending on the source of Zn used and the incubation period. Application of the fungus alone and in combination with insoluble Zn sources enhanced various plant growth parameters in rice and cardamom plants. Moreover, the uptake of Zn in rice plants was enhanced up to ~2.5-fold by fungal application. The fungus also exhibited various other plant growth-promoting traits, such as production of Indole-3-acetic acid, ammonia, siderophores, solubilization of mineral phosphate, and production of hydrolytic enzymes such as α-amylase, protease, and pectinase. Hence, apart from its use as a biological control agent, M. pingshaense has the potential to be used as a bio-fortifier to enhance the solubilization and uptake of Zn from nutrient poor soils under field conditions. Our findings shed light on the broader ecological role played by this fungus and widen its scope for utilization in sustainable agriculture.

The effect of chelating agents on the Zn-phytoextraction potential of hemp and soil microbial activity

BackgroundHemp (Cannabis sativa) is a crop with a wide range of uses, from the production of fiber and seeds to the secondary metabolites for medicinal purposes. In addition, it is characterized by high biomass yield and the ability to accumulate heavy metals, which makes this plant convenient for phytoremediation purposes. In this study, the effect of applying exogenous biodegradable chelating agents, citric acid (CA) and nitrilotriacetic acid (NTA), to zinc-contaminated soil on zinc (Zn) uptake by two industrial hemp varieties ‘Felina 32’ and ‘Monoica’ was studied. The effect of CA and NTA on available Zn in soils was investigated using an ‘in pot’ experiment under controlled conditions. The effect of both tested compounds on soil microbial activity was simultaneously evaluated.ResultsAfter the application of NTA at a concentration of 5 mmol L−1, a > threefold increased accumulation of Zn in the above-ground parts was recorded in the ‘Felina 32’ variety. In the ‘Monoica’ variety, the levels of Zn in the above-ground parts were increased > twofold. NTA affected the soil microbiome negatively, causing decreased enzyme activity (in ‘Monoica’ planted soil) and induced respiration (in ‘Monoica’ and especially in ‘Felina 32’ planted soil). On the other hand, CA application did not lead to significantly increased Zn levels in any of the studied hemp varieties. Together with CA’s negative effects on some soil enzymes, CA enhanced urease activity, dehydrogenase and several respiration types for the ‘Felina 32’ variety and exerted less detrimental effect on the soil microbiome. No toxic effects from increased Zn uptake and accumulation in experimental plants were detected, accounting for the unchanged physiological stress markers (levels of photosynthetic pigments and proline in leaves, chlorophyll fluorescence parameters) and selected growth traits of the above-ground organs and root system.ConclusionsFrom the studied varieties, ‘Felina 32’ seems to be more suitable for Zn-phytoextraction because of its higher tolerance to increased Zn levels, higher biomass production and Zn accumulation capacity. Our results indicate the potential of using the ‘Felina 32’ variety in NTA-assisted Zn phytoextraction from contaminated soils.Graphical

Characterization of zinc uptake in seedlings of wheat cultivars differing in Zn-deficiency tolerance as affected by histidine

Knowledge of the characteristics of zinc (Zn) uptake by plant roots may help in understanding the reasons for variations in the Zn deficiency tolerance of plant cultivars. We investigated the apoplastic and symplastic Zn uptake and proton secretion by roots of three bread wheat genotypes (Triticum aestivum cvs. Rushan, Kavir, and Falat) and a durum wheat genotype (Triticum durum cv. Yavarus) under influence of histidine addition in a nutrient solution. Seedlings of wheat genotypes were planted in a nutrient solution containing 10 µM Zn with or without added 50 mM histidine (His). A control with no added Zn or histidine was also used. A significant variation was found among wheat genotypes in shoot Zn content and the characteristics of Zn uptake by roots. The addition of Zn enhanced shoot Zn content compared to the control while the effect of His was genotype-dependent. His addition in combination with Zn enhanced shoot Zn content in Rushan and Falat but not in Kavir and Yavarus compared with the only Zn supply treatment. For all wheat genotypes, the addition of Zn enhanced the total, apoplastic, and symplastic root Zn concentration compared to the control. The highest and lowest amounts of proton (H+) were secreted from the roots of Rushan and Yavarus genotypes, respectively. In all wheat genotypes except Falat, the combined addition of zinc and histidine enhanced root H+ secretion compared with the only supply of Zn. Higher plant Zn uptake was associated with a higher ability to secretion of H+ from roots and higher proportion of symplastic to apoplastic Zn.

Influence of Zinc on Zinc Use Efficiency in Broccoli in Mid Hills of Himachal Pradesh

The present investigationt was carried out during rabi season of 2020-21 at the Experimental Research Farm of the Department of Vegetable Science, Dr. YS Parmar University of Horticulture and Forestry, Nauni, Solan, Himachal Pradesh to find out the effect of zinc on the nutrient use efficiency in Broccoli cv. (Palam Samridhi). The experiment was carried out in a Randomized Complete Block Design (RCBD) with three replications. Manures, synthetic fertilizers and micronutrients were replicated thrice in the form of nine treatments. The observations were recorded on marketable yield per plot (kg), Zn content in soil (mg kg-1), Zn uptake in plants (kg ha-1) and zinc use efficiency (%). The treatment combination having 50% N through vermicompost + 50% N through urea + RD of PK and FYM + ZnSO4 @15 kg/ha produced best results for all the parameters studied.

Effects of arbuscular mycorrhizal fungi on zinc uptake, translocation and accumulation in winter wheat during whole plant growth stages

Although arbuscular mycorrhizal fungi (AMF) could play important roles in zinc (Zn) uptake in host plants, the effects of AMF on Zn uptake and transport in winter wheat during the whole growth stage remain unclear. A pot experiment was conducted to investigate the effects of Funneliformis mosseae (Fm) and Claroideoglomus etunicatum (Ce) on Zn absorption, transport, and accumulation in winter wheat under different Zn levels (0, 2.5, and 25 mg kg–1) in soils. This study showed that there was a significant correlation between mycorrhizal colonization rate and Zn absorption efficiency in winter wheat roots during the post-anthesis period, but there was no significant correlation during the pre-anthesis period. AMF significantly increased Zn concentrations (0.64–0.81 times) in wheat grains under 0 mg kg-1 Zn level, but decreased Zn concentrations in wheat grains under 25 mg kg-1 Zn level. Additionally, under 0 and 2.5 mg kg–1 Zn treatments, AMF increased Zn absorption rate (3.3–14, 0.21–1.02 times) in roots at filling and maturity stages and the contribution of root Zn uptake (0.36–0.64, 0.27–0.37 times) to grain Zn. However, AMF decreased root Zn absorption rate (0.32–0.61 times) and increased the contribution of Zn remobilization (1.69–2.01 times) in vegetative tissues to grain Zn under 25 mg kg–1 Zn treatment. The present results would complement the mechanisms and effects of AMF on Zn absorption and transport in winter wheat and provide a potential method for the application of AMF to wheat grain Zn enrichment.

Soil (microbial) disturbance affect the zinc isotope biogeochemistry but has little effect on plant zinc uptake

Zinc (Zn) is an important micronutrient but can be toxic at elevated concentrations. We conducted an experiment to test the effect of plant growth and soil microbial disturbance on Zn in soil and plants. Pots were prepared with and without maize and in an undisturbed soil, a soil that was disturbed by X-ray sterilization and a soil that was sterilized but reconditioned with the original microbiome. The Zn concentration and isotope fractionation between the soil and the soil pore water increased with time, which is probably due to physical disturbance and fertilization. The presence of maize increased the Zn concentration and isotope fractionation in pore water. This was likely related to the uptake of light isotopes by plants and root exudates that solubilized heavy Zn from the soil. The sterilization disturbance increased the concentration of Zn in the pore water, because of abiotic and biotic changes. Despite a threefold increase in Zn concentration and changes in the Zn isotope composition in the pore water, the Zn content and isotope fractionation in the plant did not change. These results have implications for Zn mobility and uptake in crop plants and are relevant in terms of Zn nutrition.

Efficacy of ZnO nanoparticles in Zn fortification and partitioning of wheat and rice grains under salt stress

Zinc (Zn) deficiency is a major health concern in developing countries due to dependency on cereal based diet. Cereals are inherently low in Zn and inevitable use of stressed land has further elevated the problem. The aim of current research was to improve wheat and rice grains grain Zn concentration grown in saline soils through zinc oxide nanoparticles (ZnO-NPs) due to their perspective high availability. The ZnO-NPs were prepared by co-precipitation method and characterized through X-ray diffraction (XRD) and Scanning Electron Microscope (SEM). Two separate pot experiments for wheat and rice were conducted to check the relative effectiveness of ZnO-NPs compared to other bulk Zn sources i.e., zinc sulphate heptahydrate (ZnSO4·7H2O) and ZnO. Results showed that salt stress negatively impacted the tested parameters. There was a significant (p ≤ 0.05) improvement in growth, salt tolerance, plant Zn uptake and grain Zn concentrations by Zn application through Zn sources. The ZnO-NPs showed maximum improvement in crops parameters as compared to other sources due to their higher uptake and translocation in plants under both normal and stressed soil conditions. Thus, ZnO nanoparticles proved to be more effective for grain Zn fortification in both tested wheat and rice crops under normal and saline conditions.

Functions and strategies for enhancing zinc availability in plants for sustainable agriculture.

Zinc (Zn), which is regarded as a crucial micronutrient for plants, and is considered to be a vital micronutrient for plants. Zn has a significant role in the biochemistry and metabolism of plants owing to its significance and toxicity for biological systems at specific Zn concentrations, i.e., insufficient or harmful above the optimal range. It contributes to several cellular and physiological activities of plants and promotes plant growth, development, and yield. Zn is an important structural, enzymatic, and regulatory component of many proteins and enzymes. Consequently, it is essential to understand the interplay and chemistry of Zn in soil, its absorption, transport, and the response of plants to Zn deficiency, as well as to develop sustainable strategies for Zn deficiency in plants. Zn deficiency appears to be a widespread and prevalent issue in crops across the world, resulting in severe production losses that compromise nutritional quality. Considering this, enhancing Zn usage efficiency is the most effective strategy, which entails improving the architecture of the root system, absorption of Zn complexes by organic acids, and Zn uptake and translocation mechanisms in plants. Here, we provide an overview of various biotechnological techniques to improve Zn utilization efficiency and ensure the quality of crop. In light of the current status, an effort has been made to further dissect the absorption, transport, assimilation, function, deficiency, and toxicity symptoms caused by Zn in plants. As a result, we have described the potential information on diverse solutions, such as root structure alteration, the use of biostimulators, and nanomaterials, that may be used efficiently for Zn uptake, thereby assuring sustainable agriculture.

Effect of soil texture and zinc oxide nanoparticles on growth and accumulation of cadmium by wheat: a life cycle study

Cadmium (Cd) is getting worldwide attention due to its continuous accumulation in agricultural soils which is due to anthropogenic activities and finally Cd enters in food chain mainly through edible plants. Cadmium free food production on contaminated soils is great challenge which requires some innovative measures for crop production on such soils. The current study evaluated the efficiency of zinc oxide nanoparticles (ZnONPs) (0, 150 and 300 mg/kg) on the growth of wheat in texturally different soils including clay loam (CL), sandy clay loam (SCL), and sandy loam (SL) which were contaminated with were contaminated with 25 mg/kg of Cd before crop growth. Results depicted that doses of ZnONPs and soil textures significantly affected the biological yields, Zn and Cd uptake in wheat plants. The application of 300 mg/kg ZnONPs caused maximum increase in dry weights of shoot (66.6%), roots (58.5%), husk (137.8%) and grains (137.8%) in CL soil. The AB-DTPA extractable Zn was increased while Cd was decreased with doses of NPs depending upon soil textures. The maximum decrease in AB-DTPA extractable Cd was recorded in 300 mg/kg of ZnONPs treatment which was 58.7% in CL, 33.2% in SCL and 12.1% in SL soil as compared to respective controls. Minimum Cd concentrations in roots, shoots, husk and grain were found in 300 mg/kg ZnONPs amended CL soil which was 58%, 76.7%, 58%, and 82.6%, respectively. The minimum bioaccumulation factor (0.14), translocation index (2.46) and health risk index (0.05) was found in CL soil with the highest dose of NPs. The results concluded that use of ZnONPs significantly decreased Cd concentration while increased Zn concentrations in plants depending upon doses of NPs and soil textures.

Correction to: Synergistic interactions between zinc and nitrogen addition in promoting plant Zn uptake as counteracted by mowing management in a meadow grassland

Correction to: Synergistic interactions between zinc and nitrogen addition in promoting plant Zn uptake as counteracted by mowing management in a meadow grassland

Effects of Organic and Inorganic Farming Systems in Different Environment on the Availability and Uptake Of Zn and Cd in Rice Plants

The effectiveness of the cultivation process is dependent on the planting medium. Zinc (Zn) and Cadmium (Cd) are metal elements whose presence in the soil is influenced by the same factors. However, their effects on plants might be different. Therefore, this study was conducted to determine the effects of sites with different environmental conditions and farming systems on the uptake of Zn and Cd in rice plants. The research was arranged in a two-stage nested randomized block design, consisting of two sites (Fluvaquentic Epiaquepts and Typic Epiaquepst) and two treatments (organic and inorganic farming systems). The effect of soil type and the farming system resulted in the highest yield of Zn availability in inorganic Fluvaquentic Epiaquepts treatment with a value of 5,42mg.kg-1 at two days after planting (DAP), and the highest uptake was in the organic Fluvaquentic Epiaquepts treatment with a value of 1,04 mg.plant-1. The inorganic Typic Epiaquepst treatment had the maximum Cd availability and uptake, with 0.45 mg.kg-1 and 1.15 mg.plant-1, respectively, at 63 DAP. Zn uptake was significantly affected by different sites with different soil types, while Cd was significantly affected by both sites with different soil types and farming systems. Zn and Cd levels in soil and plants were within the normal threshold.

The Role of Membrane Transporters in the Biofortification of Zinc and Iron in Plants.

Over three billion people suffer from various health issues due to the low supply of zinc (Zn) and iron (Fe) in their food. Low supply of micronutrients is the main cause of malnutrition and biofortification could help to solve this issue. Understanding the molecular mechanisms of biofortification is challenging. The membrane transporters are involved in the uptake, transport, storage, and redistribution of Zn and Fe in plants. These transporters are also involved in biofortification and help to load the Zn and Fe into the endosperm of the seeds. Very little knowledge is available on the role and functions of membrane transporters involved in seed biofortification. Understanding the mechanism and role of membrane transporters could be helpful to improve biofortification. In this review, we provide the details on membrane transporters involved in the uptake, transport, storage, and redistribution of Zn and Fe. We also discuss available information on transporters involved in seed biofortification. This review will help plant breeders and molecular biologists understand the importance and implications of membrane transporters for seed biofortification.

Synergistic interactions between zinc and nitrogen addition in promoting plant Zn uptake as counteracted by mowing management in a meadow grassland

Synergistic interactions between zinc and nitrogen addition in promoting plant Zn uptake as counteracted by mowing management in a meadow grassland

Efficiency of MGDA and GLDA ligands in extracting plant-available Zn from calcareous soils: kinetics and optimization of extraction conditions

The selection of an appropriate soil nutrient-availability index, exhibiting high correlations with crop responses, is the first step in a soil-testing program. This study aimed to test if the quantity and rate of zinc (Zn) release from calcareous soils by two new extracting ligands provide suitable Zn availability indices for maize (Zea mays L.) or not. To this end, Zn extraction from diverse calcareous soils by three concentrations (0.005, 0.05, and 0.1 mol L−1) of glutamic acid N,N-diacetic acid (GLDA) and methylglycinediacetic acid (MGDA) ligands with different shaking times were studied. A greenhouse pot experiment was also conducted to determine how Zn absorption by maize plants is correlated to the quantity and rate of Zn release from the soils. The result showed that the initial Zn release rates from the soils were significantly (r = 0.77 to 0.94, P < 0.05) correlated to plant Zn uptake. The results of the greenhouse correlation study also revealed that Zn uptake by maize represented the highest correlations with the amount of Zn extracted from soils by 0.05 M GLDA for 2 h (r = 0.87, P < 0.05), 0.05 M MGDA for 1 h (r = 0.86, P < 0.05), and 0.005 M MGDA for 0.5 h (r = 0.84, P < 0.05). These correlations were stronger than those obtained between the DTPA-extractable soil Zn and plant Zn uptake (r = 0.77, P < 0.05). Based on the finding of this study, both quantity and rate of Zn release from the soil by MGDA and GLDA ligands could be satisfactorily considered as Zn availability indices for maize in calcareous soils.

Cross Talk Between Zinc-Solubilizing Bacteria and Plants: A Short Tale of Bacterial-Assisted Zinc Biofortification

A contemporary approach to bacterially mediated zinc (Zn) biofortification offers a new dimension in the crop improvement program with better Zn uptake in plants to curb Zn malnutrition. The implication of Zn solubilizing bacteria (ZSB) represents an inexpensive and optional strategy for Zn biofortification, with an ultimate green solution to enlivening sustainable agriculture. ZSB dwelling in the rhizospheric hub or internal plant tissues shows their competence to solubilize Zn via a variety of strategies. The admirable method is the deposition of organic acids (OAs), which acidify the surrounding soil environment. The secretion of siderophores as a metal chelating molecule, chelating ligands, and the manifestation of an oxidative–reductive system on the bacterial cell membrane are further tactics of bacterially mediated Zn solubilization. The inoculation of plants with ZSB is probably a more effective tactic for enhanced Zn translocation in various comestible plant parts. ZSB with plant growth-enhancing properties can be used as bioelicitors for sustainable plant growth via the different approaches that are crucial for plant health and its productivity. This article provides an overview of the functional properties of ZSB-mediated Zn localization in the edible portions of food crops and provides an impetus to explore such plant probiotics as natural biofortification agents.

Effect of Chelant-Based Soil Washing and Post-Treatment on Pb, Cd, and Zn Bioavailability and Plant Uptake

The remediation of Pb, Cd, and Zn contaminated soil by ex situ EDTA washing was investigated in two pot experiments. We tested the influence of (i) 0, 0.5, 1.0, and 1.5%wt zero-valent iron (ZVI) and (ii) a combination of 5%wt vermicompost, 2%wt biochar, and 1%wt ZVI on the metal availability in EDTA-washed soil using different soil extracts (Aqua regia, NH4NO3) and plant concentrations. We found that EDTA soil washing significantly reduced the total concentration of Pb, Cd, and Zn and significantly reduced the Cd and Zn plant uptake. Residual EDTA was detected in water extracts causing the formation of highly available Pb-EDTA complexes. While organic amendments had no significant effect on Pb behavior in washed soils, an amendment of ≥ 1%wt ZVI successfully reduced EDTA concentrations, Pb bioavailability, and plant uptake. Our results suggest that Pb-EDTA complexes adsorb to a Fe oxyhydroxide layer, quickly developing on the ZVI surface. The increase in ZVI application strongly decreases Zn concentrations in plant tissue, whereas the uptake of Cd was not reduced, but even slightly increased. Soil washing did not affect plant productivity and organic amendments improved biomass production.

Effect of biochar amendment on mobility and plant uptake of Zn, Pb and Cd in contaminated soil

This study aimed to assess the effect of rice straw biochar application as a soil amendment on the mobility, availability, speciation and plant uptake of Zn, Pb and Cd in contaminated soil. A pot experiment with maize (Zea mays L.) was conducted using different rates 0, 1, 2, and 5% (w/w) of rice straw biochar. The soil pore water properties; pH, EC, and DOC concentration, the dissolved metal concentrations in soil pore water as well as plant metals uptake were determined at the end of the experiment. The BCR sequential extraction procedure was adopted to determine the effect of biochar on speciation and partitioning of the studied metals.Results showed that the application of biochar is significantly increased the plant shoots biomass by 94.5% with 5% biochar rates compared to untreated soil. Similarly, the soil pore water properties pH, EC, and DOC concentration were also increased with biochar addition compared to untreated soil. The dissolved metal concentrations were decreased in soil pore water with the increasing of biochar rates by 92%, 81.5%, and 90% for Zn, Pb and Cd, respectively at 5% biochar rate. In the same trend, the plant metals uptake reduced significantly with the increasing of biochar dose. Compared to untreated soil, the BCR sequential extraction showed that the biochar addition induced the transformation of the exchangeable metal fractions to oxidizable and residual fractions. These results confirmed the ability of rice straw biochar to immobilize the studied metals and therefore reducing their bioavailability and their uptake by plant.

Zinc fractions and nutrition of maize (Zea mays L.) as affected by Olsen-P levels in soil

Zinc (Zn) deficiency with large phosphorus (P) application for plant nutrition is commonly an investigated antagonistic interaction. However, required P fertilization for optimum grain yield with desirable grain Zn content is a major constraint owing to poor understanding of relationships between P application rates, residual P accumulated in the soil after surplus fertilizer P applications, and soil Zn transformations together with plant Zn uptake. Results showed that the effect of added P fertilizer was more pronounced with decreasing availability of water-soluble and exchangeable (WS), specifically adsorbed (SPAD), Mn-Oxide bound (MnOX), amorphous Fe-oxides (FeOX), and organically bound (OM) zinc fractions in ‘high’ P (22.5–50 kg ha−1) soils than ‘medium’ (12.5–22.5 kg ha−1) and ‘low’ P (< 12.5 kg ha−1) soils. Further, the addition of farmyard manure (FYM) significantly improved the availability of all the soil Zn fractions. Plant Zn uptake decreases with P additions of 39 and 52 kg P ha−1 by 20 and 26% in ‘high’ P soils, 15 and 26% in ‘medium’ P soils, and 6 and 12% in low P soils respectively, indicating higher Olsen-P levels restricts the translocation of Zn from roots to above-ground parts of the plant. Maximum grain Zn content averaging 30 mg kg−1 over three years was observed at Olsen-P level of 21.5 mg kg−1. Path analysis highlighted that extractable OM and MnOX fractions in ‘high’ P soils, WS and FeOX fractions in ‘medium’ P, and WS fractions in low P soils were the most prevalent fractions that contribute towards Zn uptake of maize plants.

Residual effects of B and Zn fertilizers applied to dry season crops on the performance of the follow‐up crop of maize in Nepal

AbstractBackground: Diversified food crop production systems with high‐value vegetable crops are increasingly replacing conventional rice–wheat rotations across Nepal. These newly emerging systems are likely to enhance the demand for the micro‐nutrients boron (B) and zinc (Zn), which are already widely deficient throughout in Nepal. However, B and Zn fertilizers often are either unavailable in rural areas, not available in a timely manner, or when available not affordable by smallholder farmers.Aims: To overcome multiple constraints concerning the need and efficient use of B and Zn amendments in a technical feasible way with a high financial efficiency for farmers and without compromising the environment, the current study assessed whether soil stock provisioning, e.g., B and Zn fertilizer applications to dry season crops, may provide sufficient residual effects for the succeeding non‐fertilized wet season crop.Methods: A pot experiment was conducted in a sheltered greenhouse using two contrasting but representative soil types (Acrisol and Fluvisol) collected from rice‐ and from maize‐based production systems in Nepal. Boron and Zn amounts were supplied individually or in combination to wheat, cauliflower, and tomato grown in the dry season of 2018, whilst measuring biomass accumulation, B and Zn concentrations in plant tissues of all crops which allowed calculating B and Zn uptake in the unfertilized follow‐up crop of maize.Results: Soil‐applied B and Zn fertilizers, sole and combined, slightly enhanced biomass of the succeeding non‐fertilized maize only, but significantly increased total B and Zn plant uptake, with significant differences between soil types. Furthermore, while maize shoot B concentrations were consistently increased above the critical levels in both soils, but especially in the Fluvisol after wheat and cauliflower pre‐crops, Zn uptake of maize was more enhanced in the Acrisol.Conclusions: The residual effects of B and/or Zn applied to preceding dry season crops benefitted the subsequent wet season maize, especially after the pre‐crops wheat and cauliflower in the Fluvisol for B, and after wheat and tomato in the Acrisol for Zn. They may suffice to attain reasonable yields of wet season crops in the emerging vegetable‐based cropping systems of Nepal, even if fertilizers are not consistently available. The magnitude of the residual effects of pre‐applied Zn largely depended on the soil type, while those of B were mainly determined by the pre‐crop.