Crop Enhancement
Improving plant growth, yield, and nutrient efficiency through advanced biological strategies.
Pathfinder in RNA-based innovations
Harnessing the power of Extracellular RNA for a sustainable, non-GMO future of food.
Inspired by the natural mechanisms of bacterial extracellular RNA, we translate molecular biology into field-ready solutions that enhance growth, resilience, and yield — without modifying the genome.
Non-GMO by designField-validated trialsResearch-backed
Polyhouse → Field
Validated across 3 environments
About exRNA Agro
Bacterial exRNA, applied to the field.
At exRNA Agro, we are revolutionizing agricultural practices by harnessing the power of bacterial extracellular RNA (exRNA) to accelerate crop growth and enhance resilience. Our pioneering research focuses on utilizing exRNA to promote faster growth and improved flourishing of crops, surpassing traditional growth methods.
Through extensive studies and trials, our team has developed a novel approach where bacterial exRNA has been shown to stimulate vital plant processes — leading to accelerated growth rates and better overall health compared to control crops. This groundbreaking technique involves isolating and applying exRNA derived from beneficial bacteria, known for their natural ability to influence plant growth, nutrient uptake, and disease resistance.
Our Mission
01
Develop RNA-based solutions for crop improvement
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Enhance plant resistance against stress and pathogens
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Validate innovations through multi-environment trials
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Empower farmers with science-backed technologies
Our Core Areas
Four focus areas. One field-ready platform.
From crop enhancement to disease resistance — every product line at exRNA Agro is built on extracellular RNA biology and validated under real growing conditions.
RNA-Based Agricultural Innovation
Leveraging extracellular RNA biology to regulate plant responses and stress adaptation.
Soil & Microbiome Engineering
Enhancing soil fertility and microbial balance for sustainable agriculture.
Disease Resistance
Developing natural molecular solutions to strengthen plant immunity.
The molecular layer of agriculture
Non-coding RNA regulations as future of Agriculture
Non-coding RNAs (ncRNAs) represent an edge in agricultural biotechnology, proffering unheard-of potential to regulate gene expression and intensify plant growth. These molecules, which do not encode proteins, play a critical role in regulating various biological processes — such as stress responses, growth, and development in plants. By modulating gene expression, ncRNAs help plants adapt to environmental stresses like drought, disease, and nutrient deficiency, making them crucial for improving crop resilience. The ability to manipulate ncRNAs could unlock new strategies for crop improvement, fostering faster growth, better disease resistance, and higher yields. Moreover, understanding and leveraging plant-specific ncRNAs opens up the possibility of developing sustainable solutions that minimize the need for chemical fertilizers and pesticides.
5'non-coding RNA3'
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Regulate gene expression without changing the genome — non-GMO by design
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Modulate stress responses to drought, disease, and nutrient deficiency
03
Unlock faster growth, stronger immunity, and higher yields
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Reduce dependence on synthetic fertilisers and pesticides
Epigenetic regulation5+ ncRNA classesNon-GMOField-applicable
Field Validation & Trials
Tested at every scale, from polyhouse to open field.
To ensure reliability and scalability, exRNA Agro conducts rigorous testing across three progressively realistic environments — moving every solution from controlled validation to real-world performance.
Polyhouse Trials
In the polyhouse, we work under controlled environmental conditions to promote sustainable agriculture and systematically evaluate crop performance. Temperature, humidity, irrigation, and light exposure are carefully regulated to create an ideal microclimate for crop growth.
- Precise environmental control
- Regulated temperature, humidity & light
- Early-stage validation
Greenhouse Trials
Greenhouse trials let us test how crops adapt when exposed to variable light intensity, airflow, and external climate influences while still receiving structural protection — bridging controlled-environment biology and real-field conditions.
- Realistic growing conditions
- Repeatable, consistent data
- Lab-to-field translation
Open Field Analysis
In the open field, crops are grown entirely under natural environmental conditions without any artificial control — natural temperature, humidity, sunlight, rainfall, soil, and real pest and disease pressure. This setting reveals how solutions perform in a true farming environment.
- Real pest & disease pressure
- Natural climate & soil conditions
- Yield & sustainability validation
Polyhouse Greenhouse Open Field
Technology & Innovation
The hidden language of plants — made useful.
Extracellular RNA acts as a biological communication system influencing gene expression and environmental response. At exRNA Agro, we translate that signal into practical, field-ready agricultural innovation.
Plant-to-plant communication
We use exRNA signals to enhance how crops coordinate stress responses with neighbouring plants.
Plant–microbe interactions
Tuning the conversation between roots and the soil microbiome to unlock nutrient and immune benefits.
RNA-based bio-solutions
Field-ready formulations that deliver targeted molecular instructions where and when crops need them.
Precision farming approaches
Translating molecular signals into per-field, per-season decisions for growers and agronomists.
Built on rigorous science. Designed for the field.
Our research stack combines extracellular RNA biology, bioinformatics, and structured multi-environment trials — so every solution we release is rooted in molecular evidence and proven under realistic growing conditions.
- RNA-based bio-solutions
- Plant-microbe optimisation
- Field-portable workflows
- Open research partnerships
Why Choose exRNA Agro
Science you can trust. Outcomes you can measure.
What makes exRNA Agro different is not just the biology — it’s the discipline behind it. Every solution is research-backed, field-validated, and built to perform under real growing conditions.
Science-driven innovation
Every product begins with peer-grade biology — not marketing claims.
Real-world validation
Each solution moves through Polyhouse → Greenhouse → Field before it reaches a grower.
Sustainable & eco-friendly
RNA-based, biodegradable inputs that work with — not against — the ecosystem.
Productivity & resilience
Outputs that show up on the balance sheet: higher yield, fewer losses, stronger crops.
Advanced molecular agriculture
A next-generation toolkit for growers, cooperatives, and research partners.
Our Impact
What changes when biology becomes the input.
When growers adopt RNA-led practices, the gains compound — at the plant, the soil, and the system level.
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Outcome areas
Compounding
Season over season
Productivity
Higher crop yield & quality
Stronger plants, denser produce, and more consistent harvests across seasons.
Inputs
Reduced chemical dependency
Lower pesticide, fungicide, and synthetic-fertiliser loads at the field level.
Soil Health
Improved soil health
Living soils that hold water, cycle nutrients, and rebuild themselves over time.
Resilience
Climate-resilient farming
Crops better equipped to handle heat, drought, and emerging pest pressure.
Compounding outcomes, not one-shot gains.
Stronger plants build healthier soils — and healthier soils grow stronger plants. The system improves with every cycle.
Latest Insights
View all articlesFrom the field & the lab
Research, crop guides, and field notes from the exRNA Agro community.
Crop Health
9 min read
May 03, 2026
Sunflower: The Golden Crop of Sustainable Agriculture
An agriculture-department style guide to sunflower (Helianthus annuus) — global oilseed context, the major fungal and bacterial diseases that drive 30–60% yield loss in India, and the integrated biocontrol-led management that protects oil quality and seed yield from sowing to harvest.
Crop Health
9 min read
May 02, 2026
Tomato Plant Care, Diseases, and Solutions
An agriculture-department style guide to tomato (Solanum lycopersicum) — global production context, the major fungal, bacterial and viral diseases driving 30–80% yield loss, and the integrated biocontrol-led management that keeps tomato plants productive from nursery to harvest.
Crop Health
9 min read
May 1, 2026
The Banana Crisis: Decoding the devastating impact of Panama Disease
Bananas are vital to global and Indian agriculture but are uniquely vulnerable to disease — and the single biggest threat is Fusarium oxysporum f. sp. cubense (Foc TR4), the cause of Panama disease. A complete guide to the disease landscape, the mechanism behind Foc TR4, visual diagnostics, and eco-friendly biocontrol strategies for sustainable banana farming.
Let’s collaborate
Build the future of farming with us
Whether you’re a research institution, an agri-business, or a cooperative of farmers — we’d love to explore how extracellular RNA biotechnology can support your work.