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What are Plant Hormones?
Plant Metabolomics, as a research field focusing on plants, primarily investigates the metabolic changes of plants in different growth and developmental stages or in response to various external stimuli. This discipline utilizes metabolomics techniques to comprehensively study the variations in metabolites. It has found widespread applications in the realms of plant biology and related fields.
Plant hormones, also known as phytohormones, are pivotal in mediating a wide array of physiological processes within plants. Phytohormones are naturally occurring compounds synthesized endogenously within plant tissues. They play critical roles in regulating plant responses to external environmental changes, modulating growth patterns, and ensuring resilience against adverse conditions. These hormones are integral to essential metabolic processes, influencing phenomena such as seed germination, root and shoot development, flowering, and fruit ripening. Moreover, phytohormones are vital for plants' defense mechanisms against pests and diseases, contributing to overall plant health and stability.
The significance of phytohormones in plants extends beyond their regulatory functions; they are also central to agricultural practices. With the increasing focus on sustainable agriculture, there is a growing interest in utilizing metabolomics techniques specifically designed for the targeted quantification of phytohormones. This approach allows researchers and agronomists to better understand the hormonal responses of plants under various stress conditions, thereby facilitating the development of strategies to enhance crop resilience and yield. By integrating metabolomics with phytohormonal studies, scientists can uncover the complex networks of hormone interactions and their effects on plant metabolism, ultimately leading to advancements in plant breeding, protection, and management practices.
Why Is It Necessary To Detect Plant Hormones?
On one hand, plant hormones play a crucial regulatory role in plant growth, development, and responses to the environment. On the other hand, as essential agricultural and horticultural products, plants can significantly improve crop yield and quality through the precise regulation of plant hormones (such as auxins, gibberellins, and cytokinins), which can influence plant architecture and yield composition. Hormones like jasmonic acid, salicylic acid, and brassinosteroids also play pivotal roles in plant defense against pests and diseases. Therefore, the qualitative and quantitative analysis of plant hormones is essential for understanding hormone action mechanisms, plant life processes, improving crop and horticultural plant quality, and targeted genetic modification.
Challenges in Plant Hormone Detection
Plant hormones are secondary metabolites in plants and exist in extremely low quantities. They are typically present in the range of nanograms (ng) or even picograms (pg) per gram of fresh plant material.
Substantial variations in hormone content can exist among different samples, with fresher samples often yielding better results.
Matrix effects can cause significant interference. Matrix refers to components in the sample other than the analyte, which can disrupt the analysis and affect the accuracy of the results; this interference is known as the matrix effect.
Our Plant Hormone Quantification Service
With state-of-the-art high-specificity, high-resolution mass spectrometry instrumentation and an expert bioinformatics team, our company has effectively developed the proficiency to quantitatively assess numerous plant hormones across diverse plant sample types. We provide a comprehensive research service encompassing sample preparation, analytical testing, and bioinformatics analysis. We have curated a comprehensive library of targeted plant hormones, employing internal standards for precise quantification of nine primary classes and 107 distinct categories of plant hormones. These encompass Auxin, Cytokinin (CK) , Jasmonic Acid (JA), Salicylic Acid (SA), Abscisic Acid (ABA), Gibberellic Acid (GA), 1-Aminocyclopropane-1-carboxylic Acid (ACC), Brassinosteroids (BR), and Strigolactones (SL).
| No. | Full Name | Abbreviation | Classification | CAS |
|---|---|---|---|---|
| 1 | Indole-3-acetic acid | LAA | Auxin | 87-51-4 |
| 2 | 3-Indolebutyric acid | IBA | Auxin | 133-32-4 |
| 3 | Methyl indole-3-acetate | ME-IAA | Auxin | 1912-33-0 |
| 4 | Indole-3-carboxaldehyde | ICA | Auxin | 487-89-8 |
| 5 | 6-Benzylamino Adenine | BA | Auxin | 39924-52-2 |
| 6 | Naphthylacetic Acid | NAA | Auxin | 86-87-3 |
| 7 | N6-Isopentenyladenine | IP | CK | 2365--40-4 |
| 8 | Isopentenyl adenosine | IPA | CK | 7724-76-7 |
| 9 | trans-Zeatin-riboside | tZR | CK | 6025-53-2 |
| 10 | trans-Zeatin | tZ | CK | 1637-39-4 |
| 11 | Cis-Zeatin | cZ | CK | 32771-64-5 |
| 12 | Dihydrozeatin | Dh-Z | CK | 14894-18-9 |
| 13 | Kinetin | K | CK | 525-79-1 |
| 14 | Isopentenyladenine | IP | CK | 2365-40-4 |
| 15 | Methylsalicylate | MESA | SA | 119-36-8 |
| 16 | Brassinolide | BL | BR | 72962-43-7 |
| 17 | Methyljasmonate | MeJA | JA | 39924-52-2 |
| 18 | Dihydrojasmonic acid | H2JA | JA | 3572-64-3 |
| 19 | N-Jasimonic acidisoleucine-Isoleucine | JA-lle | JA | 120330-92-9 |
| 20 | (±)-Jasmonic acid | JA | JA | 77026-92-7 |
| 21 | Salicylic acid | SA | SA | 69-72-7 |
| 22 | Abscisic acid | ABA | ABA | 21293-29-8 |
| 23 | Gibberellin Al | GA1 | GA | 545-97-1 |
| 24 | Gibberellin A3 | GA3 | GA | 77-06-5 |
| 25 | Gibberellin A4 | GA4 | GA | 468-44-0 |
| 26 | Gibberellin A7 | GA7 | GA | 510-75-8 |
| 27 | 1-Aminocyclopropanecarboxylic acid | ACC | Ethylene Synthesis | 22059-21-8 |
| 28 | Castasterone | CS | BR | 80736-41-0 |
| 29 | 6-Deoxocastasterone | 6-DeoxoCS | BR | 87833-54-3 |
| 30 | 5-Deoxo-Strigol | 5DS | SL | 151716-18-6 |
| 31 | 1-Aminocyclopropanecarboxylic acid synthase | ACCG FXAS | Ethylene Synthesis | |
| 32 | Gibberellin (GA1 GA3 GA4 GA5 GA6 GA7 GA8 GA9 GA13 GA14 GA15 GA19 GA20 GA24 GA29 GA44 GA51 GA53) | GA | GA | |
| ... | ||||
Brochures
Metabolomics Services
We provide unbiased non-targeted metabolomics and precise targeted metabolomics services to unravel the secrets of biological processes.
Our untargeted approach identifies and screens for differential metabolites, which are confirmed by standard methods. Follow-up targeted metabolomics studies validate important findings and support biomarker development.
Download our brochure to learn more about our solutions.
Plant Hormone Detection Methods
Creative Proteomics provides a robust platform for plant hormone analysis, offering services that leverage ELISA, HPLC, and LC-MS/MS technologies. Our state-of-the-art equipment and expert analysis ensure high-quality results, catering to the diverse needs of researchers in the field of plant metabolomics. Whether you require large-scale screening or precise quantification of hormones, our services are designed to meet your specific requirements efficiently and effectively.
ELISA is a simple and cost-effective method that offers rapid detection. It is suitable for large-scale screening but has lower precision and is less effective for detecting low-concentration hormones.
HPLC is widely used for hormone analysis and can be combined with detectors such as the Agilent 1260 Infinity. It allows direct analysis of multiple hormones, including Indole-3-Acetic Acid (IAA), Abscisic Acid (ABA), and Salicylic Acid (SA), providing higher sensitivity than ELISA.
LC-MS/MS, utilizing instruments like the AB Sciex QTRAP 6500 or Waters Xevo TQ-S, combines liquid chromatography's separation capabilities with mass spectrometry's specificity and sensitivity. It achieves detection precision at the picogram level, making it ideal for comprehensive coverage of nearly all known plant hormones and meeting the high accuracy demands of researchers.
Workflow of Plant Hormone Quantification
Da Cao et al,. Frontiers in Plant Science 2020
Advantages of Plant Hormone Analysis
Comprehensive Service: Our service encompasses the full spectrum of plant sample handling, testing, and rigorous bioinformatics analysis. Leveraging advanced technology and extensive expertise, we provide a holistic solution.
Swift Testing Turnaround: Employing batch-based liquid-liquid extraction for sample pre-processing translates to a remarkably brief testing cycle.
Unwavering Precision: Utilizing UPLC-MS/MS enables us to achieve meticulous quantification, coupled with stringent quality control practices, ensuring scientifically sound outcomes.
Comprehensive Substance Profiling: Our focus extends to nine primary classes of plant hormones, with a particular emphasis on functionally significant ones.
Gold Standard Quantification: We adhere to the gold standard by employing isotope internal standards for absolute quantification.
Unparalleled Specificity: Our meticulously optimized pre-processing techniques ensure an exceptional level of specificity for plant hormones. We pair this with suitable chromatographic and mass spectrometry detection conditions.
Remarkable Sensitivity: Our high-sensitivity mass spectrometry system empowers us to detect hormones at levels as low as picograms and even femtograms, guaranteeing the precise quantification of exceedingly minute hormone concentrations.
Sample Requirements for Plant Hormones Analysis
| Category | Requirements |
|---|---|
| General Sample Format | Liquid Samples: - Volume: 100 µL - Must be in a suitable container (e.g., microcentrifuge tubes) to prevent contamination. - Ensure samples are homogenized if they contain solid particles. Plant Samples: - Weight: 100 mg - Collect fresh or frozen plant material, ensuring it is free from contamination and mold. - Samples should be stored in a way that preserves their integrity (e.g., freezing immediately after collection). |
| Sample Storage/Shipment | Use 2.0 mL cryovials or 1.5 mL Eppendorf tubes for sample storage and shipment. |
| Labeling | All tubes must be clearly labeled with unique sample identifiers. Direct marking is preferred over stick-on labels, as the latter may peel off when frozen. |
| Shipping Instructions | Include a hard copy of the completed manifest with your sample shipment. Email an electronic copy of the completed sample manifest in Excel format to us prior to shipping. |
Typical Chromatogram for Simultaneous Detection of Multiple Plant Hormones
Customer Case: Lina Duan, Juan Manuel Pérez-Ruiz, Francisco Javier Cejudo, José R Dinneny, "Characterization of CYCLOPHILLIN38 shows that a photosynthesis-derived systemic signal controls lateral root emergence
Journal: Plant Physiology
Published: 2021
Method: Targeted Quantification of Plant Hormones
Abstract
The research illuminates a critical aspect of plant physiology, shedding light on the intricate relationship between photosynthesis and root architecture, specifically in the context of sucrose and auxin metabolism.
By meticulously conducting mutant screens and delving into the Arabidopsis thaliana CYCLOPHILIN 38 (CYP38) gene, the study uncovers the profound impact of photosynthesis on lateral root emergence. The findings, highlighting the role of CYP38 in stabilizing photosystem II (PSII) and its non-cell-autonomous influence on root development, significantly contribute to our understanding of plant growth mechanisms.
Moreover, the observation that low-light conditions and perturbations in photosynthetic activity affect lateral root emergence independently of shoot size underscores the importance of these insights. The elucidation of the interplay between sucrose, auxin biosynthesis, and CYP38-dependent photosynthetic activity in root architecture refinement under limited light conditions represents a noteworthy advancement in plant science.
Results
CYP38 Mutation Alters Root Development
A recessive mutant (presto) with an 85.4% reduction in lateral root (LR) density and a 51% reduction in primary root (PR) growth was identified. This mutant carried a CYCLOPHILIN 38 (CYP38) gene mutation, confirmed through mapping and complementation. Pre-emergence stage LRs were significantly enriched, indicating LR initiation disruption. Despite larger shoot sizes in mutants, LR emergence defects persisted, suggesting specific root development alterations. These findings highlight the critical role of CYP38 in root architecture, independent of overall plant growth.
CYP38 mutation reduces LR density, alters LR stages, and affects PR length in Arabidopsis.
CYP38 Primarily Localized to Chloroplasts
CYP38, known for its role in PSII assembly and stability, exhibits predominant expression in shoot tissues, with limited expression in roots. Subcellular localization studies confirm its exclusive presence in chloroplasts, emphasizing its chloroplast-specific function in Arabidopsis.
CYP38 is highly expressed in shoots and localized in plastids.
CYP38 Regulates LR Emergence via Shoot Signals
Grafting experiments reveal that LR growth defects are primarily determined by the shoot genotype. CYP38 mRNA and protein show limited movement across the shoot–root junction. Despite low transcript levels in the rootstock, LR development is rescued, highlighting CYP38's non-autonomous role in LR emergence from photosynthetic shoot tissues.
The activity of CYP38 in shoots is essential for LR emergence.
Auxin Downregulation Mediates cyp38 Root Phenotype
Shoot-derived auxin plays a crucial role in LR emergence. The cyp38 mutant and low-light conditions lead to reduced IAA levels in roots, primarily affecting distal mature tissues. Transcriptional reporter assays show decreased auxin response in cyp38 mutants and under low light, particularly in cortex cells surrounding LRP. Exogenous IAA application rescues LR emergence in both cyp38 mutants and low-light-treated WT seedlings, suggesting that limited photosynthetic output may hinder auxin biosynthesis from IPA conversion. These findings highlight the role of auxin biosynthesis and signaling in mediating the cyp38 root phenotype under altered light conditions.
Auxin is involved in CYP38-dependent regulation of LRs.
Conclusions
In summary, the study elucidates the role of photosynthesis in shaping root system architecture, focusing on CYP38 function. The author discovered that shoot-derived systemic signals influence a distinct LR development stage, operating independently of known root-regulating signals like sucrose, HY5, or β-cyclocitral. Instead, their findings propose a connection between auxin biosynthesis and cellular redox status, serving as a long-distance signal to control LR emergence.
Reference
- Lina Duan, Juan Manuel Pérez-Ruiz, Francisco Javier Cejudo, José R Dinneny, Characterization of CYCLOPHILLIN38 shows that a photosynthesis-derived systemic signal controls lateral root emergence, Plant Physiology, Volume 185, Issue 2, February 2021, Pages 503–518.
What are the lowest limits of quantification (LLOQ) for various hormones analyzed by Creative Proteomics?
| Compound | LOD, nM 10 uL injection |
|---|---|
| ABA | 0.8000 |
| cZ | 0.0128 |
| cZR | 0.0128 |
| IAA | 0.8000 |
| IAA-Ala | 8.0000 |
| IAA-Asp | 0.4000 |
| IAA-Trp | 0.4000 |
| JA | 0.3200 |
| JA-ILE | 0.0800 |
| MethylIAA | 0.1600 |
| OPDA | 8.0000 |
| SA | 10.0000 |
| tZ | 0.0320 |
| tZR | 0.0128 |
| GA1 | 0.8000 |
| GA3 | 0.8000 |
| GA4 | 4.0000 |
| GA8 | 0.8000 |
| GA9 | 4.0000 |
| GA12 | 4.0000 |
| GA19 | 0.8000 |
| GA20 | 4.0000 |
| GA24 | 4.0000 |
| GA29 | 4.0000 |
| GA53 | 0.8000 |
Learn about other Q&A about metabolomics technology.
Plant Growth Promotion, Phytohormone Production and Genomics of the Rhizosphere-Associated Microalga, Micractinium rhizosphaerae sp. nov.
Quintas-Nunes, Francisco, et al.
Journal: Plants
Year: 2023
Disruption of CYCLOPHILIN 38 function reveals a photosynthesis-dependent systemic signal controlling lateral root emergence.
Duan, Lina, et al.
Journal: bioRxiv
Year: 2020
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Priyanka, Govindegowda, et al.
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Year: 2024
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Raman, Rosy, et al.
Journal: Frontiers in Plant Science
Year: 2024
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