Salicylic Acid Research Articles

Boosting Stevia's sweetness: Growth regulators mitigate salt stress and enhance steviol glycosides

Stevia rebaudiana Bertoni is a plant species with sweet-tasting leaves that can be used as a natural, low-calorie sweetener with potential health benefits. Salt stress can reduce plant growth and productivity, but the application of growth regulators like salicylic acid (SA), methyl jasmonate (MeJ), and spermidine (Spd) can manage various plant abiotic stresses and improve plant growth and productivity. In this work, we investigated the role of exogenous SA, MeJ, and Spd in conferring salt stress tolerance in Stevia by analyzing plant growth, chlorophyll (Chl), total phenolic, total carotenoid content, antioxidant defense system and steviol glycosides. The aim of a recent study was to assess the effects of these regulators on Stevia plants under both individual and combined salt stress conditions. Foliar application of these regulators improved plant growth under salt stress, with moderate salinity stress increasing glycoside compounds. SA was most effective in increasing rebaudioside A (Reb A), while MeJ + Spd combination was best for increasing stevioside (Stv) content. Individual applications of Spd, MeJ, and SA significantly impacted plant growth and antioxidant content, although their combined use was less effective. Spd application under salt stress yielded the highest increases in total carotenoid and Chl a content, while MeJ and Spd together significantly boosted Chl b content. The study found that SA enhanced superoxide dismutase (SOD) activity and reduced catalase (CAT) activity under salt stress, whereas MeJ alone increased both CAT and SOD activity. The distinct responses to Spd, SA, and MeJ suggest varied mechanisms in oxidative stress-induced antioxidant production. Overall, the use of these growth regulators can improve the growth, yield, and nutritional value of Stevia under salt stress, offering significant implications for agriculture and food security.

Glycine betaine application improved seed cotton yield and economic returns under deficit irrigation

BackgroundDeficit irrigation exerts devastating effects on the productivity and economic returns of cotton crop, as well as carbon dioxide (CO2) emission form soil. Osmolytes play a significant role in facilitating the adaptation of cotton plants to abiotic stresses and improve productivity. MethodsThis study investigated the effects of different osmolytes (glycine betaine, ascorbic acid, salicylic acid 100 mg L−1 each) and deficit irrigation (50 %-I50, 75 %-I75, 100 %-I100) on seed cotton yield, greenhouse gas emission (CO2-C), emission factor (EFs) and economic returns of cotton in Southern Anatolia, Türkiye. ResultsDeficit irrigation and osmolyte treatment, both separately and in combination, had a substantial impact on seed cotton yield, CO2-C emission and EFs. The lowest (3800 kg ha−1) and the highest (4746 kg ha−1) seed cotton yield was noted under I50, and I100 treatments, respectively. Similarly, no osmolyte application and application of glycine betaine resulted in the lowest (4097 kg ha−1) and the highest (4545 kg ha−1) seed cotton yield, respectively. The interactive effect indicated that application of glycine betaine and salicylic acid produced better yield than control treatment under all irrigation treatments. The lowest (1.55) and the highest (1.94 mg) CO2-C emission (mg CO2-C m−2 h−1) was recorded for I50, and I100 treatments respectively. Likewise, the lowest (1.52) and the highest (2.19) daily carbon emission were recorded for salicylic acid and glycine betaine application, respectively. The lowest and the highest EFs values were observed for glycine betaine and ascorbic acid application, respectively. Application of glycine betaine resulted in the highest economic returns under all irrigation treatments which was comparable to salicylic acid, whereas the lower economic returns were recorded for control treatment. ConclusionIt is concluded that application of glycine betaine can be used to improve seed cotton yield and economic returns under deficit irrigation. Similarly, glycine betaine proved helpful in reducing CO2-C emission under deficit irrigation compared to normal irrigation.

Seasonal Changes in Salicylic and Jasmonic Acid Levels in Poplar with Differing Stress Responses

Poplars are essential tree species with critical roles in wood production, ecological conservation, environmental protection, and climate change mitigation. Plants of different poplar populations exhibit varying responses to biotic and abiotic stresses, largely driven by phytohormones—key regulators of plant growth and stress responses. Phytohormones control fundamental processes such as cell division, growth, tissue differentiation, organ development, and resistance to environmental challenges such as temperature extremes and drought. In this study, we conducted a quantitative analysis of phytohormone levels in the leaves of two populations of poplar species from the same geographical region over a one-year period, covering the early, mid, and late growth stages. Our results revealed that salicylic acid (SA) and jasmonic acid (JA) concentrations in the stress-resistant poplar (RP) increased significantly during the late growth stage (September), particularly in response to elevated pathogen pressure and fluctuating climatic conditions. In contrast, the susceptible poplar (SP) consistently exhibited lower levels of SA and JA across all growth stages, particularly during the mid-growth stage (characterized by high temperatures and low precipitation) and the late growth stage, when pathogen stress typically intensifies. The limited increase in phytohormone levels in the SP suggests a weaker defense response compared with the RP. These findings demonstrate that climatic factors significantly influence the phytohormonal dynamics in poplars, with the RP exhibiting more robust regulation of SA and JA to mitigate both biotic and abiotic stresses. This study provides a theoretical framework for better understanding the resistance mechanisms in Populus and offers insights for improving stress tolerance in future breeding programs.

Preharvest salicylic acid and chitosan treatments reduce red drupelet reversion and enhance antioxidant capacity in blackberry fruit

Red drupelet reversion (RDR) is a postharvest physiological disorder affecting fresh blackberries during commercialization. The drupelets revert from fully black to red, causing detriments of the commercial value. The specific mechanism is still being investigated, some reports suggest that the occurrence of RDR is associated with pigment degradation in the fruit, and can be caused or aggravated by mechanical damage and storage conditions. Even, though studies report no significant alteration in blackberry organoleptic properties caused by RDR, the visual aspect of it affects the consumer perception of the fruit quality reducing marketability and ultimately generating economic losses. In this regard, preharvest treatments have been recently reported to have positive effects in reducing RDR in blackberries. In this study, we investigated the effects of chitosan (COS) and salicylic acid (SA) as preharvest treatments on the phenolic compound content and antioxidant capacity of blackberry fruit. The results showed that SA 3 mM and COS 0.25% treatments increased the total phenolic and flavonoid content while also enhancing the antioxidant capacity of blackberries. We also observed that the content of specialized metabolites and the activity of antioxidant enzymes have a negative correlation with the occurrence of RDR in blackberries.

SSA-ZP on Scalp Seborrheic Dermatitis: Regulating Sebum Levels and Scalp Barrier.

The occurrence of scalp seborrheic dermatitis (SD) is closely related to the production of sebum and scalp barrier function. Supramolecular salicylic acid has the keratolytic and anti-inflammatory properties, and zinc pyrithione is an antifungal drug delivered as a microparticle to skin epithelia. This study aimed to assess the efficacy and safety of 2% supramolecular salicylic acid (SSA) combined with 0.8% zinc pyrithione conditioner (SSA-ZP) in treating scalp SD focusing on key outcome measures including sebum levels and scalp barrier function. Five patients with mild to moderate scalp SD were included in the 2-week self-controlled prospective study, receiving daily SSA-ZP treatment. Evaluation on days 0, 7, and 14 included dermoscopy, the adherent scalp flaking scale (ASFS), sebum level, transepidermal water loss (TEWL), pH, and stratum corneum hydration. We also performed the fungal count across specific scalp regions, such as the left and right sides of the forehead, the top of the head, and the occiput. Five patients with mild to moderate scalp SD participated in this study. After 2 weeks of SSA-ZP treatment, significant reductions in ASFS scores, sebum levels, and fungal count were observed, alongside improvements in TEWL and pH values across multiple scalp regions. Moreover, there was no difference in the hydration of stratum corneum. SSA-ZP demonstrated efficacy in treating scalp SD without adverse effects, suggesting its potential as a first-line treatment option. Further research with larger sample sizes and longer follow-up periods is warranted to validate these findings.

The cardiovascular polypill strategy (acetyl salicylic acid, atorvastatin, ramipril) as baseline treatment after a cardiovascular event supported by compelling evidence: a global expert consensus

Abstract Background The SECURE trial demonstrated that the CV-polypill strategy (acetylsalicylic acid [ASA]+atorvastatin+ramipril) reduces CV mortality by 33% in patients with acute myocardial infarction (MI) compared to standard care over 3 years (median). The 2023 ACS ESC Guidelines recommend the polypill strategy to improve outcomes and treatment adherence. The CV-polypill inclusion in the 2023 World Health Organization's essential medicines list signifies its effective and affordable response to a global secondary prevention healthcare requirement. Purpose To reach consensus among medical experts from various countries regarding key implementation aspects of the CV-polypill strategy (ASA+atorvastatin+ramipril) as baseline preventive treatment after a CV event (CVe) in routine clinical practice. Methods A two-round modified Delphi method was employed. A questionnaire consisting of 30 evidence-based statements was developed and validated with input from 8 distinguished cardiologists. The Delphi panel, 50 physicians from 19 countries across Europe, Latin America, and Asia, used a three-point Likert scale to establish their agreement and perceived importance of the statements. Consensus was reached when ≥80% agreed or deemed statements 'very important' or 'important. Statements without consensus in the first round underwent refinement based on evidence and panellists’ feedback in the second round. Persistent disagreements were resolved in a face-to-face meeting with experts. Descriptive statistics were applied. Results 38/50 panellists participated in round 1, and 37/50 in round 2. 31/38 were cardiologists. 28/38 routinely prescribed the CV-polypill strategy. 97.4% of panellists believed that the 24% relative risk reduction in major CVe over 3 years (median), attained with the CV-polypill strategy (ASA+atorvastatin+ramipril) compared to standard care could replicate in clinical practice while maintaining equal safety (97.4%). Unanimous consensus (100%) supported initiating the CV-polypill strategy as baseline preventive treatment upon hospital discharge or at first follow-up. Its efficacy and safety were also acknowledged for stroke (94.7%), peripheral artery disease (92.1%), and both genders (84.2%). 89.5% supported CV-polypill affordability for preventing CHD events and strokes. Algorithms for initiation (97.3%) and transition (97.4%) to the CV-polypill strategy from cardioprotective drugs, considering patient preferences (97.5%), were confirmed. A unanimous consensus (100%) affirmed the positive impact of the simplified CV-polypill treatment on patient satisfaction, with 94.7% recognizing its convenience (Figure 1). Conclusions Skilled medical experts across continents reached consensus on critical implementation aspects and strongly endorse the early use of the CV-polypill strategy (ASA+atorvastatin+ramipril). This adoption aims to reduce CVD recurrence, improve prognosis, and potentially enhance affordability in CVD treatment after a CVe.Consensus on CV polypill implementation

Pathogen challenge in Arabidopsis cotyledons induces enhanced disease resistance at newly formed rosette leaves via sustained upregulation of WRKY70.

Pathogenic microorganisms often target seedlings shortly after germination. If plants exhibit resistance or resilience to pathogens, those exposed to pathogen challenge may grow further and form new unchallenged leaves. The purpose of this study was to examine disease resistance in the newly formed leaves of plants subjected to pathogen challenge. We used Arabidopsis thaliana and the oomycete pathogen Hyaloperonospora arabidopsidis (Hpa) as the model pathosystem. We found that Arabidopsis seedlings primarily challenged with the avirulent isolate Hpa exhibited enhanced disease resistance against the virulent isolate Hpa in newly formed rosette leaves (NFRLs). Our observations indicated that the transcript levels of the transcription factor gene WRKY70, which is essential for full resistance to the virulent isolate HpaNoco2, were elevated and maintained at high levels in the NFRLs. In contrast, the transcript levels of the salicylic acid marker gene PR1 and systemic acquired resistance-related genes did not exhibit sustained elevation. The maintenance of increased transcript levels of WRKY70 operated independently of non-expressor of pathogenesis-related gene 1. These findings suggest that prolonged upregulation of WRKY70 represents a defensive state synchronized with plant development to ensure survival against subsequent infections.

CaWRKY20 Negatively Regulates Plant Resistance to Colletotrichum scovillei in Pepper.

Chili anthracnose, a fungal disease caused by Colletotrichum scovillei, is among the most devastating diseases affecting pepper (Capsicum annuum L.). Although WRKY transcription factors play important roles in plant immunity, it is unknown how WRKY gene family members contribute to pepper plant resistance to C. scovillei. Here, CaWRKY20 was found to negatively regulate pepper resistance to C. scovillei, which was demonstrated by virus-induced gene silencing and transient overexpression in pepper. Moreover, overexpression of CaWRKY20 enhanced susceptibility to C. scovillei in tomato. Additionally, our findings demonstrated that CaWRKY20 can indirectly regulate the expression of salicylic acid (SA)-related defense genes (CaPR1, CaPR10 and CaSAR8.2) as well as reactive oxygen species (ROS)-scavenging enzyme genes (CaCAT, CaPOD and CaSOD) in response to C. scovillei. In addition, CaWRKY20 was found to interact with CaMIEL1 in the nucleus to regulate the defense response to C. scovillei in pepper. Furthermore, CaWRKY20 directly bound to the W-box in the promoter of SYSTEMIC ACQUIRED RESISTANCE DEFICIENT 1 (CaSARD1) and suppressed its expression, resulting in reduced resistance to C. scovillei. These results will clarify the mechanism by which WRKY transcription factors are involved in pepper disease resistance and can thus facilitate molecular breeding for anthracnose-resistant varieties.

Influence of Seed Priming Treatments on Plant Growth Parameters of Barley (Hordeum vulgare L.)

The effects of different seed priming treatments, namelytap water, KNO3 @ 2.5%, Thiourea @ 1000 ppm, CaCl2 @ 2%, Nacl2 @ 2%, ZnSo4 @ 1%, KH2PO4 @ 1% and Salicylic acid @ 100 ppm solutions, on plant growthparameters of Barley cv. K-1055 and K-409 in Factorial Randomized Block Design with three replications were investigated during Rabi 2022-23 and 2023-24 at Chandra Shekhar Azad University of Agriculture & Technology, Kanpur. Analysis of variance revealed that the plant growth parameters were significantly affected by various seed priming treatments. Priming with Thiourea @ 1000 ppm significantlyincreased the plant growth parameters.

Molecular insights into Solanum sisymbriifolium’s resistance against Globodera pallida via RNA-seq

BackgroundThe presence of potato cyst nematodes (PCN) causes a significant risk to potato crops globally, leading to reduced yields and economic losses. While the plant Solanum sisymbriifolium is known for its resistance to PCN and can be used as a trap crop, the molecular mechanisms behind this resistance remain poorly understood. In this study, genes differentially expressed were identified in control and infected plants during the early stages of the S. sisymbriifolium - G. pallida interaction.ResultsGene expression profiles were characterized for two S. sisymbriifolium cultivars, Melody and Sis6001, uninfected and infected by G. pallida. The comparative transcriptome analysis revealed a total of 4,087 and 2,043 differentially expressed genes (DEGs) in response to nematode infection in the cultivars Melody and Sis6001, respectively. Gene ontology (GO) enrichment analysis provided insights into the response of the plant to nematode infection, indicating an activation of the plant metabolism, oxidative stress leading to defence mechanism activation, and modification of the plant cell wall. Genes associated with the jasmonic and salicylic acid pathways were also found to be differentially expressed, suggesting their involvement in the plant’s defence response. In addition, the analysis of NBS-LRR domain-containing transcripts that play an important role in hypersensitive response and programmed cell death led to the identification of ten transcripts that had no annotations from the databases, with emphasis on TRINITY_DN52667_C1_G1, found to be upregulated in both cultivars.ConclusionsThese findings represent an important step towards understanding the molecular basis underlying plant resistance to nematodes and facilitating the development of more effective control strategies against PCN.

Establishment of numerical model for precooling broccoli with ice water integrated with salicylic acid and its effect on broccoli apparent quality

Postharvest precooling is crucial for delaying yellowing of broccoli efficiently removing field heat. In this experiment, a numerical model for ice water precooling broccoli was established, and based on this, the main precooling parameters were optimized. Furthermore, the appropriate concentration of salicylic acid (SA) in the process of ice water integrated with SA precooling was determined. Through numerical simulation and experimental validation, the ice water precooling treatment with a 30 % ice volume fraction and a 1:1 mass ratio of ice water to broccoli was identified as optimal for achieving the best precooling uniformity and meeting the specified temperature requirements. Application of 2 mmol L-1 SA integrated with ice water precooling treatment effectively delayed yellowing, and maintained the apparent quality of broccoli, manifested as a higher h° value (chromaticity value) and chlorophyll content, a lower yellowing index. The shelf life of the treated broccoli was extended by 3 d

Isolation and Identification of Multi-Traits PGPR for Sustainable Crop Productivity Under Salinity Stress

High salinity poses a significant threat to arable land globally and contributes to desertification. Growth-promoting rhizobacteria assist plants in mitigating abiotic stresses and enhancing crop productivity through the production of siderophores, exopolysaccharides (EPS), solubilisation of phosphate, indole-3-acetic acid (IAA), and other secondary metabolites. This study aimed to isolate, identify, and characterise bacteria that exhibit robust growth-promoting properties. A total of 64 bacterial isolates from the rhizosphere of Miscanthus sinensis were evaluated for plant growth-promoting (PGP) traits, including IAA, EPS, siderophores, and solubilisation of phosphate. Among them, five isolates were selected as plant growth-promoting rhizobacteria (PGPR) based on their PGP features and identified via 16S rRNA sequencing: Enterococcus mundtii strain INJ1 (OR122486), Lysinibacillus fusiformis strain INJ2 (OR122488), Lysinibacillus sphaericus strain MIIA20 (OR122490), Pseudomonas qingdaonensis strain BD1 (OR122487), and Pseudomonas qingdaonensis strain MIA20 (OR122489), all documented in NCBI GenBank. BD1 demonstrated a higher production of superoxide dismutase (SOD) (17.93 U/mg mL), catalase (CAT) (91.17 U/mg mL), and glutathione (GSH) (0.18 U/mg mL), along with higher concentrations of IAA (31.69 µg/mL) and salicylic acid (SA) (14.08 ng/mL). These isolates also produced significant quantities of amino and organic acids. BD1 exhibited superior PGP traits compared to other isolates. Furthermore, the NaCl tolerance of these bacterial isolates was assessed by measuring their growth at concentrations ranging from 0 to 200 mM at 8-h intervals. Optical density (OD) measurements indicated that BD1 and INJ2 displayed significant tolerance to salt stress. The utilisation of these isolates, which enhances plant growth and PGP traits under salt stress, may improve plant development under saline conditions.

Characterization of a Rho GDP dissociation inhibitor gene OsRhoGDI1 from rice

The Rho GDP dissociation inhibitor gene OsRhoGDI1 was isolated as the putative partner of OsRac5 from rice young panicles by the yeast two-hybrid screening, but the characterization and functions of the gene remains unknown. In this study, on the basis of the bioinformatics analysis, expression profile chip mining and RT-qPCR were employed to analyze the expression pattern of OsRhoGDI1, and it was found that the gene was widely expressed in various tissues of rice, especially with high abundance during the development of young panicles, and its expression was regulated by abscisic acid (ABA), brassinolide (BL), salicylic acid (SA), indole-3-acetic acid (IAA), gibberellin (GA) and high salinity. Subcellular localization identification showed that OsRhoGDI1 was distributed in the cytomembrane, cytoplasm, and nucleus. Bimolecular fluorescence completion (BiFC) was further performed to identify the in vivo interaction between OsRhoGDI1 and OsRac5, the results suggested that the interaction occurred in the nucleus, cytomembrane, and cytoplasm. In addition, OsRhoGDI1 interacted with OsRac1 in the cytomembrane. Our results indicated that OsRhoGDI1 may be involved in rice panicle development, and participate in regulating various biological processes such as rice growth and development, hormone response, and abiotic stress by regulating the activities of different Rho/Rop proteins via interactions.

Comprehensive analysis of transcription factor binding sites and expression profiling of rice pathogenesis related genes (OsPR1)

Pathogenesis-related (PR) proteins, found in plants, play a crucial role in responding to both biotic and abiotic stresses and are categorized into 17 distinct families based on their properties and functions. We have conducted a phylogenetic analysis of OsPR1 genes (rice PR1 genes) in conjunction with 58 putative PR1 genes identified in Brachypodium distachyon, Hordeum vulgare, Brassica rapa, and Zea mays through BLASTP predictions. We extensively investigated the responses of the remaining 11 rice PR1 genes, using OsPR1a as a reference, under various stress conditions, including phytohormone treatments (salicylic acid and brassinosteroid [BR]), wounding, and heat stress (HS). In rice, of the 32 predicted OsPR1 genes, 12 have been well-characterized for their roles in disease resistance, while the functions of the remaining genes have not been studied extensively. In our study, we selected an additional 11 OsPR1 genes for further analysis and constructed a phylogenetic tree based on the presence of a 10-amino-acid-long conserved motif within these proteins. The phylogenetic analysis revealed that both OsPR1a from earlier studies and OsPR1-74 from our current study belong to the same clade. These genes consistently exhibit upregulation in response to diverse stress treatments such as biotic stress and abiotic stresses such as heat, drought, and salinity, indicating their potential roles in enhancing stress tolerance in rice. Significantly, this study delves into the previously unexplored role of OsPR1 genes in responding to Brassinosteroid (BR) and heat stress (HS) treatments, confirming their involvement in stress responses through qRT-PCR analysis. We found that seven genes were upregulated by EBR treatment. During heat stress (HS), six and seven genes were upregulated at 1hand 4h HS, respectively. The remaining genes OsPR1-22 and OsPR1-75 were upregulated at 1h but downregulated at 4h HS and under EBR treatment. In contrast, OsPR1-76 was upregulated at both 1h and 4h HS, but downregulated under EBR treatment. Promoters of PR1 genes in rice and other crops are rich in transcription factor binding sites (TFBSs) and feature a conserved Cysteine-rich secretory protein (SCP or CAP) motif. This study advances our understanding of PR1 gene regulation and its potential to enhance stress tolerance in rice.

Mechanism of Exogenous Jasmonic Acid-Induced Resistance to Thrips palmi in Hemerocallis citrina Baroni Revealed by Combined Physiological, Biochemical and Transcriptomic Analyses

Jasmonic acid (JA) is a regulator of plant resistance to phytophagous insects, and exogenous JA treatment induces plant insect resistance. This study investigated the mechanism of exogenous JA-induced resistance of Hemerocallis citrina Baroni (daylily) to Thrips palmi at the biochemical and molecular levels. Daylily leaves sprayed with JA showed significantly higher levels of secondary metabolites—tannins, flavonoids, and total phenols, and activity of defense enzymes—peroxidase, phenylalanine ammonia lyase, polyphenol oxidase, and protease inhibitor (PI) than control leaves; the most significant effects were observed with 1 mmol L−1 JA. Owing to an improved defense system, significantly fewer T. palmi were present on the JA-treated plants than control plants. The JA-treated leaves had a smoother wax layer and fewer stomata, which was unfavorable for insect egg attachment. The differentially expressed genes (DEGs) were significantly enriched in insect resistance pathways such as lignin and wax biosynthesis, cell wall thickening, antioxidant enzyme synthesis, PI synthesis, secondary metabolite synthesis, and defense hormone signaling. A total of 466 DEGs were predicted to be transcription factors, mainly bHLH and WRKY family members. Weighted gene co-expression network analysis identified 13 key genes; TRINITY_DN16412_c0_g1 and TRINITY_DN6953_c0_g1 are associated with stomatal regulation and lipid barrier polymer synthesis, TRINITY_DN7582_c0_g1 and TRINITY_DN11770_c0_g1 regulate alkaloid synthesis, and TRINITY_DN7597_c1_g3 and TRINITY_DN1899_c0_g1 regulate salicylic acid and ethylene biosynthesis. These results indicate that JA treatment of daylily improved its resistance to T. palmi. These findings provide a scientific basis for the utilization of JA as an antagonist to control T. palmi in daylily.

Understanding plant defense mechanisms: exploring the effects of karrikin, salicylic acid, and humic acid treatments on Eustoma grandiflorum

Understanding plant defense mechanisms: exploring the effects of karrikin, salicylic acid, and humic acid treatments on Eustoma grandiflorum

Maize DLR1/NHX7 Is Required for Root Development Under Potassium Deficiency.

Root System Architecture (RSA) is a crucial plant trait that governs a plant's ability to absorb water and nutrients. In this study, we describe a mutant with nutrient-dependent defects in root development, affecting both the primary root and lateral roots (LRs). This mutant, identified through a screen for defects in LR development, has been designated dlr1-1. The dlr1-1 mutant exhibits impaired LR emergence rather than defects in the LR primordium (LRP) formation, particularly under potassium (K+)-deprivation conditions. This impairment likely stems from inhibited cell proliferation caused by the dlr1-1 mutation. K+ deprivation specifically leads to the accumulation of salicylic acid (SA) in the dlr1-1 mutant, consistent with the upregulation of SA biosynthesis genes. Moreover, exogenous application of SA to wild-type plants (B73) mimics the dlr1-1 phenotype. Conversely, treatment of the dlr1-1 mutant with 2-aminoindane-2-phosphonic acid, an SA biosynthesis inhibitor, partially restores LR emergence, indicating that elevated SA levels may be responsible for the mutant's developmental defects. MutMap analysis and allelism tests confirmed that the phenotypes of the dlr1-1 mutant results from the loss of the Na+/H+ antiporter, ZmNHX7. Additionally, the application of NaCl exacerbates the dlr1-1 mutant phenotype, suggesting that the root defects in dlr1-1 mutant depend on ion homoeostasis. In conclusion, our findings demonstrate that maize DLR1/NHX7 is essential for root development under potassium deprivation.

Time-course analysis of the transcriptome of Arabidopsis thaliana leaves under high-concentration ammonium sulfate treatment

ABSTRACT Ammonium fertilization is of great interest for future agriculture, as unlike nitrate, ammonium use efficiency does not decrease in C3 plants, even in environments with elevated CO2 concentrations. However, excess ammonium often results in toxic effects such as growth suppression and chlorosis, i.e. ammonium toxicity. The addition of nitrate, a major source of nitrogen commonly found in soils, has been shown to alleviate these toxic effects. Understanding the mechanisms of ammonium toxicity in the presence of nitrate is crucial for the effective use of ammonium fertilizers in crop cultivation. To elucidate these responses, a time-course analysis of the transcriptome was performed on A. thaliana leaves treated with high concentrations of ammonium sulfate in the presence of sufficient nitrate. The expression of nitrate-inducible genes tended to be downregulated by the treatment. The expression of genes relating to abscisic acid (ABA), jasmonic acid (JA), salicylic acid (SA), and membrane trafficking was upregulated, whereas that of photosynthesis-, auxin-, and cytokinin-related genes involved in growth and development was downregulated. The induction of many osmotic stress-responsive genes and nitric oxide (NO)-inducible genes suggests the involvement of osmotic stress and NO signaling in the response. This study provides a novel and comprehensive overview of transcriptional changes occurring in response to high ammonium sulfate concentrations with sufficient nitrate, and sheds light on potential pathways involved in ammonium toxicity under these conditions.

Spectrometric method for simultaneous quantification of nadifloxacin and salicylic acid in a novel topical dosage form

Acne vulgaris is a prevalent skin disorder that affects many individuals. In the search for effective acne therapy, researchers have found that a combination of Nadifloxacin and Salicylic Acid may produce a synergistic effect. To further investigate this, a study was conducted to devise a spectrophotometric method for simultaneously measuring the concentrations of Nadifloxacin and Salicylic Acid in a novel topical formulation. Simultaneous Estimation Method was employed using methanol as the solvent. Nadifloxacin exhibited an absorbance maximum of 291 nm, while Salicylic Acid showed an absorbance maximum of 297 nm in methanol. Linearity experiments were conducted to determine the concentration ranges for both drugs, which were found to be 2–12 ppm for Nadifloxacin and 5–30 ppm for Salicylic Acid. The recovery results of Nadifloxacin ranged from 82 % to 95 %, while those of Salicylic Acid ranged from 97 % to 110 %. These results indicate the accuracy and reliability of the method. This method was further validated in accordance with the guidelines provided by the International Council for Harmonization (ICH) of Technical Requirements for Human Use. The proposed method has demonstrated its applicability for the simultaneous and quantitative assessment of Nadifloxacin and Salicylic Acid in various dosage forms. This development is significant as it provides a reliable and efficient means of measuring the concentrations of these two drugs in acne therapy formulations.

Sulfated peptides: key players in plant development, growth, and stress responses

Peptide hormones regulate plant development, growth, and stress responses. Sulfated peptides represent a class of proteins that undergo posttranslational modification by tyrosylprotein sulfotransferase (TPST), followed by specific enzymatic cleavage to generate mature peptides. This process contributes to the formation of various bioactive peptides, including PSKs (PHYTOSULFOKINEs), PSYs (PLANT PEPTIDE CONTAINING SULFATED TYROSINE), CIFs (CASPARIAN STRIP INTEGRITY FACTOR), and RGFs (ROOT MERISTEM GROWTH FACTOR). In the past three decades, significant progress has been made in understanding the molecular mechanisms of sulfated peptides that regulate plant development, growth, and stress responses. In this review, we explore the sequence properties of precursors, posttranslational modifications, peptide receptors, and signal transduction pathways of the sulfated peptides, analyzing their functions in plants. The cross-talk between PSK/RGF peptides and other phytohormones, such as brassinosteroids, auxin, salicylic acid, abscisic acid, gibberellins, ethylene, and jasmonic acid, is also described. The significance of sulfated peptides in crops and their potential application for enhancing crop productivity are discussed, along with future research directions in the study of sulfated peptides.