Abstract
This paper presents new data on the salt tolerance and avoidance mechanisms among various groups of halophytes in India. The halophytic flora in general has positive effect of high saline environments on growth and physiology. The coastal area of the Kachchh district in Gujarat includes about 350 km of shoreline along the Gulf of Kachchh. This study presents data on the elemental accumulation mechanisms in soil and halophytic flora (succulent and non-succulents). The halophytes were divided into two groups namely succulent with thick and fleshy leaves and stems as well as non-succulents with thin leaves and stem. The succulent halophytes included species such as Salicornia brachiata, Suaeda fruticosa and Suaeda nudiflora. The non-succulent halophytes include Aeluropus lagopoides and Urochondra setulosa. Plant parts namely leaves (Phylloclade for Salicornia), stems and roots were analyzed during the monsoon season. The results of soil and plant mineral ion contents differed widely across the intertidal zones in the same habitat. Likewise, the intra species have varied in all nutrient levels and salt concentration. The accumulation of elemental concentration was high during the monsoon season in the succulent Salicornia brachiata, especially in leaves that showed Na+ reaching high up to 7.6 meq g−1, whereas Cl− was noted to be 4.34 meq g−1. In the non-succulent halophytes, the accumulation of mineral ion concentration was lower when compared to succulent plants.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Introduction
Soil salinity continues to threaten the productivity of the land across the world. Scientists have predicted that the salinity will impact over half of the total arable land globally by 2025 leading to a 70% increase in the demand for food recourses1. The total land area impacted by salinity has been estimated at about 1125 million hectares2. Now in current situations, the coastal agricultural regions face several problems. Globally soil salinization is a scourge for agricultural productivity, crops grown on saline soils suffer on account of high osmotic stress, nutritional disorders and toxicities, poor soil physical conditions and reduced crop productivity3. In Bangladesh, some less positively use salt-affected land as shrimp culture-led land use activity, whereas another farmer handles this problem by applying lime, gypsum, etc.4. In India, Northern–west regions include, Hariyana, Punjab, Rajasthan (desert regions) and the coastal belt of Gujarat suffering from salinity problems. The coastal belt of Kachchh is primarily composed of sodium (Na+) in comparison to calcium and magnesium and the majority of the coastal belt is sodic in nature within 5 km of the shoreline, with the exception of some parts of Mandvi and Mundra taluka5. The toxicity of sodium and chloride is predominant in the soil around coastlines6,7. Overexploitation and unrestricted deeper drilling, which increase coastal salinity and allow seawater intrusion, are the main causes in the area. The use of this water frequently has a negative impact on human health, agriculture, and soil quality8. Some good approaches to utilize this land as growing medicinal plants and algal cultivation that performed and yield well under saline irrigation9.
Nevertheless, halophytes are suitable plant candidates for the phytoremediation phenomenon10. One of the succulent halophyte Suaeda fruticosa has the ability to tolerate lead and zinc metals, in the presence of trace metal elements in its root portion, it has basic characteristics to tolerant high capacity of phytostabilization of trace metal elements in its below-ground structures11. Halophytes have adaptations to survive in extreme salinity. Steiner12 has classified halophytes under three groups, (1) succulent halophytes with special characteristics to accumulate salt in cell sap and increase succulence, (2) non-succulent halophytes with special salt-secreting gland, and (3) the accumulating halophytes which do not have any kind of mechanisms for salt removal so they accumulate high concentration of salts till death. Some physiologically active molecules play a key role in the saline environment such as proline13. In grass Halopyrum mucronatum Ca+2 is reduced when accumulation of Na+ increased14. According to Khan15, the water and osmotic potential of the halophytic plant S. fruticosa becomes more negative with increasing salinity; they also noted that Ca+2, Mg+2 and K+ concentration decreases when salinity increases in the leaf. The presence of Na+ and Mg+2 content is responsible for alleviating the effects of K+. Under the higher concentration of Na+, Mg+2 and Ca+2 reported a decrease in K+ content, K+ in concentration is high or when the rest of the cation decrease16. According to Marschner17, K+ and Mg+2 play parallel key roles for the control of osmoregulation, enzyme activation and cellular pH. Succulent halophytic plants accumulate more salt than that non-succulent plants in their foliar organs. Results also reveal that the non-succulent plant can store a high amount of Ca2+, Mg+2 and K+ in all parts compared to succulent plants. The leaf and stem of the succulent plant have a high amount of Na+, S−2 and Mg+2 when there is a low concentration of Ca2+ and K+18. Salicornia fruticosa accumulates a high amount of Na+, Cakile maritima tissues have the highest values of Ca+2, P− and S−2. Another finding C. minimum showed Na+ ion accumulation higher when salinity increases and it directly affects Ca+2 and Mg+2 low accumulations19. The current research focused on salinity variation in the different coastal areas of Kachchh district with salt-accumulating plants, the future scope of the current research is to the reclamation of coastal salt-affected agriculture regions by selected halophytic groups.
Materials and methods
Study area
Kachchh district consists of approximately 350 km coastal belt out of 1600 km total coastline of Gujarat. Different types of coastal habitats were surveyed and selected for the study. An appropriate number of soil and plant samples were collected from the selected locations during the monsoon season. For sample collection coastal area of Kachchh district was divided into four zones, based on the intertidal area viz., zone 1 (20 km), zone 3 (5 km), zone 2 (100 m) and zone 4 (15 km) of the intertidal area20 (Fig. 1).
Permission statement
Selected sites (for the collection of samples from the coastal belt of Kachchh district) are not covered under any protected area or private land. Therefore permission is not required.
The experimental works
Sample collection
Experimental research and field studies on plants including a collection of plant materials according to the Indian Biodiversity Act (2002) and methods used for sample collection as per the American Public Health Association, & American Water Works Association21. From the selected locations along the coast of Kachchh district, dominant plant samples were collected from natural habitats in the monsoon during 2019. Soil samples (0–30 cm) were collected from each selected site supporting the coastal vegetation. The samples were collected in triplicate numbers and samples were sun-dried, and passed through a 20-mesh sieve before analysis. The plant samples were thoroughly washed to remove dust, mud, and salts and blotted to dryness. Further, it was dried in the oven at 75–80 °C to a constant weight. The dry material so obtained was finely powdered and preserved for further analysis. The samples were once more dried in an oven, before using for analysis of mineral ions.
Plant specimen identification
Plant species were identified by Mr. Kamlesh Gadhvi and Dr. Sandip Gamit with the help of Flora of Gujarat state22. The voucher specimens (BKNMU 034, 035, 036, 037 and 038) are deposited at the Department of Life Sciences, Bhakta Kavi Narsinh Mehta University, Junagadh, Gujarat.
Sample preparation
Plant analysis
1 g plant material was taken into a silica crucible, incinerated and ashed in a muffle furnace at a temperature of 450–480 °C. To achieve complete oxidation of the organic matter, about 0.5–1 ml of concentrated nitric acid was added to the crucibles after cooling them to room temperature. The acid was evaporated in a water bath and the crucibles were again placed in the furnace for complete ashing. After cooling at room temperature, 10 ml of 1:1 hydrochloric acid was added to the crucibles containing the ash and was evaporated in a water bath. This was followed by the addition of 20 ml distilled water and the extract was filtered through Whatman filter paper No. 44 with repeated washing and a final volume of 250 ml was made by adding deionized water. The aqueous extract was further used for the estimation of sodium (Na+) and potassium (K+) by flame photometry (Systronics-130, India), calcium (Ca2+) and magnesium (Mg2+) by EDTA titration. For chloride (Cl−) 1 g of dry material was boiled in 100 ml of deionized water in a water bath for 30 min. After cooling, the extract was filtered, made up to 100 ml in a volumetric flask and the filtrate was used for the estimation of chloride by Argentometric method23.
Soil analysis
100 gm dried soil in 200 ml distilled water was taken for mineral analysis. Extract of 1:2 (Soil: water) was made up to 250 ml for analysis of Ca+2, Mg+2, Na+ and mineral ions. The pure extract was used for EC and Cl− analysis24.
Statistical analysis
Primary data of mineral ions were subjected to statistical tools by using SPSS, ANOVA and Spearman's correlation coefficients were performed for observing the significant variation within the parts of each plant as well as between the groups of plants from different zones.
Results
Accumulation of elements in succulent plants
Salicornia brachiata Miq.
S. brachiata, a succulent perennial halophytic plant species showed electrical conductivity of 5.95 (mS/cm) of soil supporting the species. The elemental composition in the soil was ranging between 0.19 and 8.47 (meq g−100). The highest accumulation of (6.16 meq g−1) was noted for Na+ in the phylloclade of S. brachiata, whereas K+ 0.14 meq g−1 was observed in the stem and roots of this succulent halophytic species. The concentration of these mineral ions followed a sequence of the accumulation ratios in phylloclade is, Na+ > Cl− > Mg+2 > Ca+2 > K+, in stem and root it is, Na+ > Mg+2 > Cl− > Ca+2 > K+. S. brachiata accumulates a high amount of salt in phylloclade compared to the rest of the plants (Table 1).
Suaeda nudiflora Moq.
S. nudiflora plant grows under less saline soil compared to the other succulent halophytes. The EC value of soil is 1.30 (mS/cm), generally the habitat of this plant has low salt concentration. The element concentration in the soil of this plant is between 0.06 and 2.62 (meq g−100). The highest accumulated element was Na+ 3.87 (meq g−1) in the part leaves, whereas K+ was in a low amount (0.15 meq g−1) in roots. The storage of elements in leaves is followed by this high to a low value, Na+ > Cl− > Mg+2 > Ca+2 > K+, in the stem it is, Na+ > Mg+2 > Cl− > Ca+2 > K+, wherein the root, only changing Mg ions, Mg+2 > Na+ > Ca+2 > Cl− > K+ (Table 2).
Suaeda fruticosa Forssk. ex J.F.Gmel
S. fruticosa was the second-highest salt accumulator plant in current research. EC value of soil was 4.02 (mS/cm), whereas other elements ranging between low to high concentrations of 0.19 to 4.94 (meq g−100). The higher accumulated element was Na+ which is 4.37 (meq g−1) and the lowest was K+ 0.14 (meq g−1). The mineral accumulation in leaves high to low amount, Na+ > Cl− > Mg+2 > Ca+2 > K+, in stem it was, Na+ > Mg+2 > Ca+2 > Cl− > K+, when root has, Mg+2 > Na+ > Cl− > Ca+2 > K+ (Table 3).
Accumulation of elements in non-succulent plants
Aeluropus lagopoides (L.) Thwaites
In the current research non-succulent halophytic grass plant A. lagopoides showed high salt tolerance. The EC value of soil was (4.89 mS/cm), with other elements ranging between higher to lower 5.86 to 0.08 (meq g−100), respectively. Here also a high element accumulator part was leaves same as succulent halophytic plants. Na+ was in a higher value of 1.47 meq g−1, while K+ in the lowest amount was 0.10 meq g−1. Major element composition elements-wise, were, Na+ > Cl− > Mg+2 > Ca+2 > K+, these ratios followed by leaves. The amount of elements in stem was, Na+ > Mg+2 > Ca+2 > Cl− > K+, and in roots was, Na+ > Mg+2 > Cl− > Ca+2 > K+. Most of the elements are in a high amount in leaves but in the stem the Mg+2 with a high amount of 0.93 (meq g−1) while the root is high with the concentration of Ca+2 0.59 (meq. g−1) (Table 4).
Urochondra setulosa (Trin.) C.E.Hubb
Comparatively, U. setulosa accumulates low elements than A. lagopoides, but interestingly it growing under a highly saline environment than A. lagopoides, the soil of this plant has a high value of Na+, Cl−, was 6.32 and 6.77 (meq g−100) respectively. EC of soil was 5.88 (mS/cm), when other element concentration wise high to low ranged was, 6.77 to 0.12(meq g−100). Elements concentration ranges from high 1.19 (meq g−1) to low 0.06 (meq g−1). The ratios of accumulated elements in leaves, Na+ > Mg+2 > Cl− > Ca+2 > K+, whereas in stems, Mg+2 > Na+ > Ca+2 > Cl− > K+, these ratio followed by roots. The major ion stored in the stem and root of U. setulosa is Mg+2 (Table 5).
Comparative accumulation of elements in succulent and non-succulent halophytes
Results show among these halophytic groups, elements accumulation in three parts, has been varying at each part. Succulent plants stored the majority of the component in foliar organs when in non-succulent plants is to be in the root. The Mg+2 among these both groups of plants, in non-succulent plants accumulation of Mg+2 in the stem was high while in succulents plants it was higher in foliar parts (Fig. 2).
Spearman's correlation coefficient studies
The statistical analysis conducted on the data yielded intriguing findings, unraveling significant interactions among various elements within different parts of succulent and non-succulent halophytic plant species. These discoveries contribute to a deeper scientific understanding of the complex relationships governing these plants' physiological processes. In the succulent plants, an examination of the correlation coefficients revealed a strong positive correlation (0.857**) between K+ ions in the leaves and stems. This suggests a tightly coordinated transport mechanism between these plant parts, facilitating the efficient uptake and distribution of potassium ions. Furthermore, a positive correlation was observed between Cl− ions in the leaves and both stem Cl− ions and root Ca+2 and Cl−. This points to a potential interplay between chloride and calcium ions in maintaining ion homeostasis and osmotic regulation within succulent species.
Interestingly, a positive relation was identified between stem Ca+2 and both stem Cl− ions and root Ca+2. This implies a potential regulatory mechanism wherein calcium ions may modulate chloride ion transport or compartmentalization. In addition, a positive correlation was detected between stem and root Mg+2, indicating a concerted involvement of magnesium ions in essential physiological processes across these plant parts. A particularly noteworthy discovery emerged from the highly significant positive correlation (0.970**) observed between stem Cl− and root Ca+2. This association suggests a possible role for chloride and calcium ions in mediating ion transport and cellular signaling pathways crucial for plant growth and adaptation to saline environments. Intriguingly, negative correlations were identified, such as root K+ exhibiting an inverse relationship with leaves Cl− (− 0.810*) and both stem (− 0.762*) Mg+2 and Cl−. This highlights potential antagonistic interactions or regulatory mechanisms between potassium and chloride ions within succulent species (Table 6).
Turning to the non-succulent halophytic group, compelling correlations were uncovered. Leaves Ca+2 exhibited strong positive correlations with stem Ca+2 (0.929**), Mg+2 (0.994**), and root Ca+2 (0.810*), suggesting a coordinated regulation of calcium and magnesium ions across various plant parts. This likely reflects the importance of these divalent cations in maintaining cellular integrity, enzymatic activity, and signaling processes in non-succulent halophytes. Remarkably, stem Cl− demonstrated a significant positive correlation (0.786*) with leaves Mg+2, while exhibiting a significant negative correlation (− 0.762*) with leaves K+. This intricate interplay suggests the existence of complex ion transport systems and compartmentalization mechanisms involving chloride, magnesium, and potassium ions within non-succulent halophytes.
Further analyses unveiled a noteworthy negative correlation trend (− 0.714*) between leaves K+ and root Na+, indicating potential ion antagonism or cellular regulation between these two elements. Notably, stem Mg+2 and Ca+2 displayed a highly significant positive correlation (0.922**), implying their co-regulation and shared involvement in diverse metabolic and physiological processes within non-succulent halophytes. Additional investigations shed light on root Na+, which exhibited a significant positive correlation with both stem Na+ (0.714*) and root Cl− (0.857**). Concurrently, root Cl− displayed positive correlations with stem Na+ (0.833*) and root Na+ (0.810*). These associations suggest the potential involvement of sodium and chloride ions in osmotic regulation, ion transport, and ionic balance maintenance in the roots of non-succulent halophytes (Table 7).
Discussion
Halophytes are a wonderful group of plants having unique physiological adaptations against extreme saline environments. Physiological adaptation to minimize salt concentrations of the cells or physiological exclusion by root membranes. In principle, salt tolerance is achieved by only salt exclusion or salt inclusion. Marschner25, Koyro26, gave possible mechanisms of vascular halophytes to adjust to high external NaCl salinity. The ionic compositions of soils revealed that Na+ and Cl− were major constituents, with concentrations ranging from 2.09 to 8.47 meq g−100 for succulent plant habitat and 5.83 to 6.77 meq g−100 for non-succulent plant habitat. It was also observed that Cl− concentrations were higher than Na+ concentrations at all habitats. Rogel et al.27 found a similar trend for Na+ and Cl− in environments, supporting Arthrocnemum macrostachyum and Sarcocornia fruticosa.
Mineral ion assessment in Aeluropus lagopoides, etc., leaves and soil sediment of A. lagopoides shows efficient K+ uptake and shows maximum Fe+2, Mn+2, P− and N content than C. tagal. Leaves of A. lagopoides show high Na+ 2.75 and Cl− about 3.64 g/100 g dry weight, it has significant compared to C. tagal and L. racemosa. The leaves of the majority of halophyte plants accumulate of salt ions and other mineral ions, it is especially stored in foliar organs28,29. According to Milić, D30, S. europaea, S.maritima and S. soda, above-ground organs of these halophytes accumulate more Na+ than Mg+2, Ca+2 and K+, they also revealed that in different habitats these halophytes having more cations in maritime saline areas than inland saline areas. One of the interesting studies revealed by19 in the Eu-halophytes succulent and salt-recreating plants shows a high concentration of Na+, S−2, and Mg+2 and a low concentration of Ca+2 and K+ ions Whereas in pseudo-halophytes, facultative halophytes and eury-hydro-halophytic species, which lack succulent shoots, resulted in low concentration of Na+, S−2 and Mg+2 and high in Ca+2 and K+ in their leaves, although the study also targets some taxonomic identical families for this kind of elemental variation, in the family, Chenopodiaceae and Plumbaginaceae accumulate high Na+ and Mg+2, and low Ca+2 and K+, other families Caryophyllaceae having high K+, whereas Poaceae with low Na+2. The amount of foliar Ca+2 is high in Asteraceae, Boraginaceae and Brassicaceae families.
If the level of salinity increases, it has been observed by Khan31, the leaves of perennial halophytes, S. fruticosa Ca+2, Mg+2 and K+ concentration decrease. In another stem succulent plant, H. recurvum, the stage of succulence increases with low salinity and decreases with high salinity, here changes in different parts of plant-like, in shoot and root values of Ca+2, Mg+2 and K+ content reduce at high salinity. Gulzar32, some grass species like A. lagopoides and U. setlosa, high salt-tolerant non-succulent plants, concluded that it can be cultivated using saline water, and S. ioclados is comparatively less salt-tolerant, these plant species growing under its suitable habitat, where brackish water is accessible when water potential and osmotic potential is negative at that time in aerial parts of A. lagopoides salinity increases33. Joshi, A. J., & Iyengar, E. R. R.34 observed accumulation of Cl− in S. nudiflora in different seasons viz., monsoon 4.98 meq g−1, winter 5.88 meq g−1 and summer 5.71 meq g−1 and for S. brachiata, monsoon 9.83 meq g−1, winter 6.85 meq g−1 and summer 8.26 meq g−1 these results were higher compare to our study. Vyas35 noted Cl− in S. nudiflora about 8.15 to 12.52 meq g−1 these concentrations are also higher than the comparatively present study. Month-wise accumulation of Na+ and other ions in S. brachiata phylloclade, a high concentration noted in the month of September at about 7.65 meq g−1, while the lowest was noted during December at about 6.9 meq g−136. Studies on the accumulation of inorganic ions showed that Na+ ranged between 5.52 and 8.37 meq g−1 in two succulent halophytes S. brachiata and S. fruticosa37, which showed similar kind of observation.
Conclusion
The present investigation elucidated the mineral ion accumulation profiles of succulent and non-succulent halophytic plant species, showcasing their profound associations with diverse ions. Salicornia brachiata, a representative succulent species, exhibited a robust growth in saline, muddy areas, whereas Sueada nudiflora, another succulent plant, thrived predominantly in wasteland regions along the Kachchh coast. The salinity levels in all five species primarily stemmed from the contributions of Na+, Cl−, Mg+2, Ca+2 and K+. Remarkably, our dataset unveiled elevated concentrations of Na+ and Cl−, whereas K+ accumulation remained relatively low within these species. Notably, the surrounding soils of the supporting plants also displayed commensurate high concentrations of these ions.
Of particular interest was the observation of salt avoidance mechanisms in succulent species, in stark contrast to the salt tolerance mechanisms exhibited by non-succulent halophytes. The non-succulent plants effectively excreted salts from their leaves, resulting in the accumulation of ions at low concentrations. Intriguingly, K+ content was found to be minimal both in the soil and plant parts, yet it displayed a pronounced affinity for salinity within succulent plants. Furthermore, as the NaCl concentration increased, there was a concomitant decrease in the levels of Ca+2, Mg+2, and K+, as deduced from the outcomes derived from soil samples supporting both succulent and non-succulent halophytic species.
The adaptive propensities of succulent plants manifest as heightened elemental concentrations in their foliar structures. Specifically, our investigations revealed the pronounced accumulation of ions, particularly Na+ and Cl−, within the Phylloclade of S. brachiata. The comprehensive amalgamation of findings from three distinct succulent plant species demonstrated that leaves exhibited significantly greater accumulation of Na+, Cl−, and Mg+2 compared to stems and roots. The total salt content in all five species was predominantly contributed by Na+, Cl−, Mg+2, Ca+2 and K+, and corresponding high concentrations of these ions were also discernible in the associated soils.
The surplus mineral ion content was selectively allocated to the phylloclade and leaves, primarily due to the presence of adaptive mechanisms that facilitate stress management and facilitate the transformation of excess mineral ions into secondary metabolites, ultimately engendering succulence in these particular organs. The comprehensive correlation study ascertained a statistically significant positive correlation between Ca+2 and Mg+2 within both groups of plants. Moreover, a positive relationship was discerned between stem and root ions Na+ and Cl−, while a limited number of negative correlations, particularly involving K+, were also identified.
The comprehensive data pertaining to the elemental accumulation patterns across distinct plant parts of succulent and non-succulent halophytic species, as well as within their associated habitats, were furnished for the first time in this study. This pioneering work offers a promising avenue for harnessing the hyperaccumulation capacities inherent to succulent and non-succulent halophytes for phytoremediation endeavors, underscoring their potential utilization in addressing salinity-related challenges afflicting affected ecosystems.
Data availability
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.
References
Szabo, S. et al. Soil salinity, household wealth and food insecurity in tropical deltas: Evidence from south-west coast of Bangladesh. Sustain. Sci. 11, 411–421. https://doi.org/10.1007/s11625-015-0337-1 (2016).
Wicke, B. et al. The global technical and economic potential of bioenergy from salt-affected soils. Energy Environ. Sci. 4, 2669–2681. https://doi.org/10.1039/d0ee90035d (2011).
Shrivastava, P. & Kumar, R. Soil salinity: A serious environmental issue and plant growth promoting bacteria as one of the tools for its alleviation. Saudi J. Biol. Sci. 22(2), 123–131. https://doi.org/10.1016/j.sjbs.2014.12.001 (2015).
Ziaul Haider, M. & Zaber Hossain, M. Impact of salinity on livelihood strategies of farmers. J. Soil Sci. Plant Nutr. 13, 417–431. https://doi.org/10.4067/s0718-95162013005000033 (2013).
Shah, J. P. & Thivakaran, G. A. GIS study on chemical properties of salt affected soils of coastal kachchh, Gujarat, India. Annu. Res. Rev. Biol. 4, 3492–3503. https://doi.org/10.9734/arrb/2014/10086 (2014).
Vyas, S. & Gadhvi, K. Ionic composition in saline habitats on Kachchh (Gujarat) coast with reference to salt tolerant plants. Int. J. Bot. Stud. 5, 129–131 (2020).
Vyas, S. J., Kara, D. & Tank, S. Eco-physiological study of marshy and sandy habitats of Kachchh. Int. J. Sci. Res. Biol. Sci. 4, 1–7. https://doi.org/10.26438/ijsrbs/v4i6.17 (2017).
Shah, Y. et al. Spatial variations and trend analysis of groundwater salinity along coastal aquifers of Mundra-Kachchh over a decade—Using thematic maps and GIS mapping. Appl. Water Sci. 12, 1–19. https://doi.org/10.1007/s13201-022-01760-x (2022).
Tomar, O. S. & Minhas, P. S. Performance of medicinal plant species under saline irrigation. Indian J. Agron. 49, 209–211 (2014).
Manousaki, E. & Kalogerakis, N. Halophytes—An emerging trend in phytoremediation. Int. J. Phytorem. 13, 959–969. https://doi.org/10.1080/15226514.2010.532241 (2011).
Bankaji, I., Cacador, I. & Sleimi, N. Assessing of tolerance to metallic and saline stresses in the halophyte Suaeda fruticosa: The indicator role of antioxidative enzymes. Ecol. Ind. 64, 297–308. https://doi.org/10.1016/j.ecolind.2016.01.020 (2016).
Steiner, M. Die Pflanzengesellschaften der Salzmarschen in den nordöstlichen Vereinigten Staaten von Nordamerika (1935).
Waghmode, A. P. & Joshi, G. V. Chemical composition of leaves of halophytes and sediments in estuarine habitat (1982).
Khan, M. A., Ungar, I. A. & Showalter, A. M. Effects of salinity on growth, ion content, and osmotic relations in Halopyrum mucronatum (L.) Stapf. J. Plant Nutr. 22, 191–204. https://doi.org/10.1080/01904169909365617 (1999).
Khan, M. A., Ungar, I. A. & Showalter, A. M. The effect of salinity on the growth, water status, and ion content of a leaf succulent perennial halophyte, Suaeda fruticosa (L.) Forssk. J. Arid Environ. 45, 73–84. https://doi.org/10.1006/jare.1999.0617 (2000).
Diem, B. & Godbold, D. L. Potassium, calcium and magnesium antagonism in clones of Populus trichocarpa. Plant Soil 155, 411–414. https://doi.org/10.1007/BF00025070 (1993).
Marschner, H., Römheld, V. & Kissel, M. Different strategies in higher plants in mobilization and uptake of iron. J. Plant Nutr. 9, 695–713. https://doi.org/10.1080/01904168609363475 (1986).
Matinzadeh, Z., Akhani, H., Abedi, M. & Palacio, S. The elemental composition of halophytes correlates with key morphological adaptations and taxonomic groups. Plant Physiol. Biochem. 141, 259–278. https://doi.org/10.1016/j.plaphy.2019.05.023 (2019).
Agudelo, A., Carvajal, M. & Martinez-Ballesta, M. D. C. Halophytes of the Mediterranean Basin—Underutilized species with the potential to be nutritious crops in the scenario of the climate change. Foods 10, 1–13. https://doi.org/10.3390/foods10010119 (2021).
Kutch Coast–People, Environment & Livelihoods (2010). https://www.scribd.com/document/29210792/Kutch-Coast-Study-Fishmarc-and-Kutch-Nav-Nirman-Abhiyan
American Public Health Association, & American Water Works Association. Standard methods for the examination of water and wastewater. In: Standard methods for the examination of water and wastewater (1995).
Shah, G. L. Flora of Gujarat state (1978).
Chopra, S. L. & Kanwar, J. S. Analytical agricultural chemistry (1976).
Vogel, A. I. A text book of quantitative inorganic analysis. ELBS and Longman (New York 1978).
Marschner, H. in Mineral Nutrition of Higher Plants. (Academic Press, London, 1995). https://doi.org/10.1016/b978-0-12-473542-2.x5000-7
Koyro, H. W., Geissler, N., Hussin, S., Debez, A. & Huchzermeyer, B. Strategies of Halophytes to Survive in a Salty Environment 83–104 (Abiotic stress and plant responses. IK International Publishing House, 2008).
Rogel, J. Á., Silla, R. O. & Ariza, F. A. Edaphic characterization and soil ionic composition influencing plant zonation in a semiarid Mediterranean salt marsh. Geoderma 99, 81–98. https://doi.org/10.1016/s0016-7061(00)00067-7 (2001).
Joshi, A. J. & Khot, S. S. Edible succulent halophytes as good source of proteins for restoration of salt-affected soils. Bull. Natl. Inst. Ecol. 14, 25–32 (2004).
Joshi, A. J. Amino acids and mineral constituents in Sesuvium portulacastrum L., a salt marsh halophyte. Aquat. Bot. 10, 69–74. https://doi.org/10.1016/0304-3770(81)90006-1 (1981).
Milić, D. et al. Halophytes relations to soil ionic composition. J. Serb. Chem. Soc. 78, 1259–1268. https://doi.org/10.2298/JSC121102159M (2013).
Khan, M. A., Ungar, I. A. & Showalter, A. M. Effects of sodium chloride treatments on growth and ion accumulation of the halophyte Haloxylon recurvum. Commun. Soil Sci. Plant Anal. 31, 2763–2774. https://doi.org/10.1080/00103620009370625 (2000).
Gulzar, S. & Khan, M. A. Comparative salt tolerance of perennial grasses. In Ecophysiology of High Salinity Tolerant Plants 239–253 (Springer, Dordrecht, 2008). https://doi.org/10.1007/1-4020-4018-0_17
Joshi, A. J. Ecophysiological aspects of some tropical salt marsh halophytes. In Contributions to the ecology of halophytes 189–195 (Springer, Dordrecht, 1982). https://doi.org/10.1007/978-94-009-8037-2_13
Joshi, A. J., Engenhart, M., Wickern, M. & Breckle, S. W. Seasonal changes in the trace metals in salt marsh angiosperms. J. Plant Physiol. 128, 173–177. https://doi.org/10.1016/S0176-1617(87)80192-X (1987).
Vyas, S. J. & Joshi, A. J. Mineral composition in leaves of some halophytic species of ‘Bhal’region in Gujarat. Res. J. Biol. 2, 99–103 (2014).
Gulzar, S., Khan, M. A. & Ungar, I. A. Effects of salinity on growth, ionic content, and plant–water status of Aeluropus lagopoides. Commun. Soil Sci. Plant Anal. 34, 1657–1668. https://doi.org/10.1081/CSS-120021303 (2003).
Khot, S. S. & Joshi, A. J. Accumulation of organic and inorganic solutes in Salicornia brachiata Roxb., an edible succulent halophyte growing at Navlakhi port. Ecol. Environ. Conserv. 12, 699–703 (2006).
Acknowledgements
The present research work was funded by Science and Engineering Research Board (SERB) and Department of Science and Technology (DST), Govt. of India, New Delhi with file no. SERB/F/1482/2018-2019.
Author information
Authors and Affiliations
Contributions
S.V. designed and planned the current research, K.G. conducted field visits. K.G., S.G. and K.D. performed the data analysis and composed the first manuscript draft with the help of S.V and G.A. All authors contributed research work during and after the fieldwork, discussed and interpreted the results and revised the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Vyas, S., Agoramoorthy, G., Gadhvi, K. et al. Correlation of elemental hyperaccumulation among the succulent and non-succulent halophytes of Gujarat, India. Sci Rep 13, 16361 (2023). https://doi.org/10.1038/s41598-023-42980-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-023-42980-8
- Springer Nature Limited
This article is cited by
-
Carbohydrate accumulation patterns in mangrove and halophytic plant species under seasonal variation
Scientific Reports (2024)