1、Brassinosteroids improve the redox state of wheat florets under low

In summary, low-nitrogen stress disrupts the redox homeostasis of wheat spikes, leading to floret degeneration, while brassinosteroids alleviate floret degeneration by improving the redox state of wheat spikes.

2、Reducing brassinosteroid signalling enhances grain yield in

Here we describe a strategy to design semi-dwarf wheat varieties without the need for Rht-B1b or Rht-D1b alleles.

3、Effect of different boron levels on yield and nutrient content of wheat

Our results demonstrate that the integrated grain quality is optimal at 1.6 mg kg −1 B concentration in moderate B level soil. Boron (B) is an essential micronutrient for plant growth and development (Warrington 1923; Reid 2013).

BRacing for Water Stress: Brassinosteroid Signaling Promotes Drought

The study presented by Cui et al. (2019) provides a neat mechanism for how BR promotes drought tolerance in wheat, but it also highlights an important question.

Roles of Brassinosteroids in Mitigating Heat Stress Damage in Cereal

Brassinosteroids (BR) are a class of plant hormones that impact tolerance to various biotic and abiotic stresses and regulate cereal growth and fertility. Fine-tuning the action of BR has the potential to increase cereals’ tolerance and acclimation to heat stress and maintain yields.

Effects of Boron (B) doses and forms on boron use efficiency of wheat

However, there are few studies on B fertilization in wheat cultivation focusing on the best application method associated with the appropriate dose of this nutrient, aiming to improve the efficiency of boron fertilization.

Nutrient synergy in wheat: Impacts of nitrogen and boron on

Efficient nutrient management remains a critical challenge in wheat production, particularly in optimizing productivity while maintaining soil fertility. Among essential nutrients, nitrogen (N) and boron (B) play vital roles in plant growth and grain development, yet their combined effects are not fully understood.

Brassinosteroids improve the redox state of wheat florets under low

In summary, low-nitrogen stress disrupts the redox homeostasis of wheat spikes, leading to floret degeneration, while brassinosteroids alleviate floret degeneration by improving the redox state of wheat spikes.

Brassinosteroids: Molecular and physiological responses in plant growth

Brassinosteroids improves crop yields by altering plant metabolism and protecting plants from several abiotic stresses. Brassinosteroids regulate gene expression and signal transduction pathways to stimulate abiotic stress tolerance.

Exploring the recuperative potential of brassinosteroids and nano

In this regard, the present study investigated the impact of nano-biochar (NBC) and brassinosteroids (BR) in enhancing the growth and productivity of wheat under different drought stress...

Which is Better for Wheat: Brassinosteroid or Boron Fertilizer?

Both brassinosteroid and boron fertilizer are commonly used plant growth regulators that play important roles in agricultural production. their effectiveness and suitability vary depending on specific conditions, so it is essential to choose the appropriate nutrient based on individual circumstances.

I. Mechanism of Brassinosteroid Action

Brassinosteroid is a natural plant growth regulator that promotes plant growth and development, while improving crop yield and quality. It primarily works by inhibiting the activity of ethylene synthase enzymes, thereby reducing ethylene production within plants. This delays senescence and abscission. Additionally, brassinosteroid enhances photosynthesis and respiration, boosting the plant’s ability to absorb and utilize nutrients.

II. Mechanism of Boron Fertilizer Action

Boron fertilizer, a micronutrient fertilizer, supports plant growth, disease resistance, and stress tolerance. It influences cell wall composition and function, facilitating normal cell division and elongation, which accelerates growth rates and increases yields. Boron also strengthens a plant’s defense against pests and diseases, improving stability and resilience under adverse conditions.

III. Choosing Between Brassinosteroid and Boron Fertilizer

1. Crop Type: Different crops have varying demands. For example, crops requiring growth promotion (e.g., corn, rice) may benefit more from brassinosteroid, whereas those needing enhanced disease resistance or stress tolerance (e.g., cotton, soybean) might respond better to boron.

2. Growth Stage: Requirements change throughout a plant’s lifecycle. During the seedling stage, when growth is slow, brassinosteroid can stimulate root development and nutrient uptake. In flowering and maturity stages, when nutrient demand peaks, boron improves disease resistance and stress tolerance.

3. Soil Conditions: Soil nutrient levels and pH affect efficacy. In nutrient-rich soils, brassinosteroid may accelerate growth, while in nutrient-poor soils, boron enhances stress resilience.

4. Climate: Environmental factors also impact results. Under drought or heat stress, brassinosteroid improves drought resistance and photosynthetic efficiency. In cold or rainy conditions, boron increases cold tolerance and disease resistance.

IV. Rational Application of Brassinosteroid and Boron Fertilizer

When applying these regulators, consider the following:

1. Follow Recommended Dosages: Adhere to specified doses for different formulations to avoid phytotoxicity.

2. Apply Properly: Use foliar spraying or seed treatment for brassinosteroid, and soil application for boron. Follow protocols to ensure effectiveness.

3. Avoid Mixing with Other Fertilizers: Combining with certain fertilizers may cause chemical reactions, reducing efficacy or polluting the environment.

4. Monitor Crop Health: Regularly check plant growth after application to adjust fertilization strategies as needed.

the choice between brassinosteroid and boron depends on crop type, growth stage, soil, and climate. Proper use of these regulators fosters healthy plant development and boosts yields. To maximize benefits, always follow dosage guidelines, apply correctly, avoid incompatible mixtures, and monitor crop progress.