networks.

Light serves as a crucial environmental signal for plants besides providing energy for photosynthesis. Photomorphogenesis, light-induced plant developmental responses, involves photoreceptors perceiving light signals to initiate signaling cascades with downstream transcriptional networks. Moreover, light is also absorbed by photopigments to drive photosynthetic light reactions, providing energy for growth and metabolism.

Genome wide investigation and transcriptional profiling of SWEET genes in two contrasting cultivars of foxtail millet under abiotic stresses.

The SWEET (Sugars will eventually be exported transporter) gene family is an important class of sugar transporters that regulates diverse aspects of plant physiology such as apoplastic phloem loading, plant-pathogen interactions and plant responses to abiotic stresses. While majority of the studies on SWEET family in plants have been performed in C3 species, there are limited reports on C4 plants. In this study we conducted genome wide investigation of the SWEET gene family in foxtail millet, a naturally stress tolerant C4 crop.

Nitric oxide cross-talks during low-temperature stress in plants.

Nitric oxide (NO) is a crucial signaling molecule, playing a pivotal role in response to low-temperature (LT) stress in plants. NO mediates cold acclimation mainly via modulation of redox homeostasis, phytohormone signaling, calcium signaling, transcription factors, and other secondary messengers. This review explores the intricate dialogue between NO and various plant growth regulators.

The rice heat shock transcription factor OsHSFC1b increases seed weight, size, and vigor, but its function is disrupted by isoaspartyl modification.

Plant optimizes seed size, weight, vigor, and various other features during seed development, which are important not only for their successful propagation and establishment but also for effective agriculture. Despite several studies conducted, understanding how plants coordinate the regulatory mechanisms to achieve optimal seed size, weight, and vigor remains elusive. Here, our study reveals the role of rice heat shock transcription factor OsHSFC1b in modulating various seed attributes.

Assessing cold stress resilience in wild chickpea accessions using physiological, biochemical, and reproductive traits.

Domesticated chickpea (Cicer arietinum L.) exhibits high sensitivity to temperatures below 20/10 °C during its reproductive phase resulting in substantial loss of flowers, pods and crop yields. With the aim to add new sources of cold tolerance and elucidate mechanism of cold-tolerance in wild species of chickpea, the present study evaluated 36 wild accessions of three Cicer species (Cicer judaicum, Cicer pinnatifidum, Cicer reticulatum) at the reproductive stage for yield, and reproductive, physiological and biochemical traits under cold stress (15/7 °C) for two consecutive years.

Physiological and genetic basis of superior phosphate uptake and utilization efficiency in the rice landrace Wazuhophek.

Low phosphorus (P) availability due to edaphic conditions or the scarcity of P fertilizers restricts agricultural productivity. Various rice-growing regions experience poor P availability. Landraces from these regions, such as Wazuhophek in Northeast India, may provide a source of critical genetic variation needed for developing highly efficient, tolerant rice varieties.

High-level production of health-beneficial glucoraphanin by multiplex editing of AOP2 gene family in mustard.

Intake of glucosinolates through the consumption of cruciferous vegetables has been associated with numerous health benefits. In recent decades, glucosinolate glucoraphanin has gained a lot of attention, as its hydrolysis product (sulforaphane) is known to possess numerous health-promoting benefits, including anti-cancer and chemopreventive activities. However, due to the low availability of glucoraphanin in most of the cultivated Brassica crops (except broccoli), there is an increasing interest in many laboratories around the world to manipulate the glucosinolate profile for human benefit.

Zinc Finger Transcriptional Repressor ZOS5-09 Regulates Grain Filling and Development in Rice.

Grain size is one of the key determinants of grain yield. Our study focuses on a novel seed-preferential CH zinc finger transcription factor, ZOS5-09 (LOC_Os05g38600) that plays an important role in regulating rice grain traits. Rice plants with the ZOS5-09 promoter::GUS construct showed high expression of ZOS5-09 in rice endosperm.

Cytokinin-mediated repression of anthocyanin biosynthesis in banana fruits.

Anthocyanins are pigments responsible for vibrant plant colors and play vital roles in plant physiology. This study compares two banana cultivars, Grand Naine (GN) and Red Banana (RB), which exhibit significant differences in anthocyanin pigmentation. Transcriptomic profiling of peel (PL) and pulp (PP) tissues revealed cytokinin-responsive type-B response regulators (RRs), MaRR_B9 and MaRR_B12, as key modulators of anthocyanin biosynthesis.

Editing cis-elements of OsPHO1;2 improved phosphate transport and yield in rice.

Increasing grain yield is the primary goal of crop improvement, which is globally affected by the low availability of soil phosphate (Pi). Overexpressing Pi transporters to enhance Pi uptake often results in Pi toxicity and growth retardation. Despite advances in genetic engineering, targeting the cis-regulatory motifs of Pi transporters remains underexplored for understanding plant mechanisms and improving Pi status.

OsDUF2488 acts synergistically with OsPrx1.1, regulates ROS metabolism and promotes dehydration tolerance in rice.

Stress-mediated regulation of energy metabolism and its relation to plant adaptation remain largely unknown. Mitochondrial redox potential is greatly influenced by stress-induced reactive oxygen species (ROS); therefore, we mapped the dehydration-induced alterations in the mitochondrial proteome of a resilient rice cultivar, Rasi, generating a proteome map representing the largest inventory of dehydration-responsive mitochondrial proteins from any plant species. Quantitative proteomic analysis led to the identification of an array of dehydration-responsive proteins (DRPs), associated with various cellular functions, conceivably impinging on the molecular mechanism of adaptation.

Dispersed components drive temperature sensing and response in plants.

Plants are highly sensitive to temperature, and climate change is predicted to have negative impacts on agricultural productivity. Warming temperatures, coupled with a growing population, present a substantial challenge for food security and motivate research to understand how plants sense and respond to changes in temperature. Here, we synthesize our current understanding of temperature sensing and response in plants.

Analysis of Genomic-Transcriptomic Dynamics Delineates Key Molecular Signatures Modulating Seed Size and Weight in Lentil.

Delineating key genetic determinants associated with seed size/weight is crucial for increasing productivity. In this study, the advantages of an integrated approach combining QTL mapping, GWAS and transcriptomics to identify robust candidates governing seed size and weight were demonstrated in lentil, an important grain legume. QTL mapping identified three stable QTLs harbouring 5113 genes.

Deciphering the dynamics of enzymes associated with the synthesis of cryoprotectants during cold acclimation in contrasting chickpea genotypes.

Chickpea, a vital legume crop, is highly susceptible to cold stress, especially during its reproductive phase, resulting in significant flower and pod abortions and reduced seed yield. Our previous study demonstrated that cold acclimation is effective in enhancing cold tolerance but benefits only cold-tolerant (CT) genotypes, while cold-sensitive (CS) genotypes remain unaffected. In this extended study aimed at probing the detailed mechanisms of this differential response, we further examined the expression profiles of enzymes involved in the synthesis and breakdown of osmolytes (pyrroline-5-carboxylate synthase, proline dehydrogenase (PDH), betaine aldehyde dehydrogenase) and sugars (sucrose synthase, acid invertase, trehalose-6-phosphate synthase, trehalose-6-phosphate phosphatase, and trehalase activity), along with the expression of various antioxidants (superoxide dismutase, catalase, ascorbate peroxidase, and glutathione reductase) in both CT and CS genotypes.

Key Determinants of Seed Size for Enhancing Genetic Gain in Legumes.

Legumes play a pivotal role in human nutrition due to their high nutritional value, especially protein content. Therefore, enhancing the productivity of grain legumes is desirable for ensuring food and nutritional security. Seed size and seed weight are key factors influencing productivity.

Anaerobic-Aerobic Swerve in Arsenic-Stressed Deepwater Rice Genotype Under Submergence.

Global floods in arsenic (As)-stressed paddy fields affect rice productivity. Future predictions of flood-related disasters provoke an urge to opt for climate-smart varieties for a secure supply. Thus, this study is designed to present the mechanisms favoring a traditional variety Mini mansoori (M.

Identification of NRPS and type II PKS biosynthetic gene cluster (s) encoding decaplanin and kigamicin from Amycolatopsis regifaucium DSM 45072T.

Amycolatopsis regifaucium, a Gram-positive actinomycete, is a prolific source of biologically active compounds, including polyphenol antibiotics like kigamicins. This study presents the draft genome of A. regifaucium DSM 45072T (= GY080T), which spans 8.

Nutrient use efficiency promoted hormonal crosstalk and stomatal dynamics in wheat under the co-impact of arsenic and drought.

This study presents the interlink of Nutrient use efficiency (NUE) influenced hormone and stomatal dynamics, in enhancing photosynthesis under the co-impact of drought (D) and arsenic (As) in wheat. We analyzed how nitrogen (N) and phosphorus (P) supplementation under D+As modulates these interactions with jasmonic acid (JA) and sucrose, as central regulators. Enhanced JA by NP-enrichment reduced abscisic-acid (ABA) and salicylic-acid (SA) production to promote stomatal opening via sugar-transporter-proteins; TaSTP12, TaSTP51, and TaKAT-like1.

Shaping the future: Unravelling regulators modulating plant architecture for next-generation crops.

Plant architecture traits in crops are modulated through intricate interactions of various genetic pathways, which helps them to adapt to diverse environmental conditions. Key developmental pathways involved in forming plant architecture include the LAZY-TAC (Tiller Angle Control) module regulating branch and tiller angle, the CLAVATA-WUSCHEL pathway controlling shoot apical meristem fate and the GID1-DELLA pathway governing plant height and tillering in major food crops. These pathways function in concert to shape the overall architecture of plants, which is essential for optimizing light capture, resource allocation, reproductive success and eventual crop yield enhancement.

Cellular Responses in the Pigeonpea Wild Relative to Herbivory: The Role of Methionine Sulfoxide Reductase B1 () in Enhanced Defense.

Understanding key cellular mechanisms leading to improved defense against various stressors is essential for cultivating robust nutritious crops capable of flourishing in diverse environments. We present an in-depth characterization of the defense response in the pigeonpea wild relative to herbivory by pod borer To fight the attacking pest, strategically activated non-enzymatic reactive oxygen species (ROS) scavengers and unleashed methionine sulfoxide reductases to safeguard the integrity of methionine residues. We unveiled for the first time physical interaction between MSRB1 and chorismate mutase (CM1.

Integration of metabolite and transcriptome profiles of cultivated and wild rice to unveil gene regulatory networks and key genes determining rice source and sink strength.

Targeting source and sink strength for crop yield increase requires a comprehensive genetic and metabolic understanding of desirable source and sink features. We performed comprehensive metabolite and transcriptomic comparisons of the photosynthetic flag leaves and milky-stage developing grains of two cultivated rice varieties (Oryza sativa L. ssp.

Unveiling the molecular mechanism underlying PSKR-mediated amplification of the ABA signaling in Arabidopsis thaliana.

Our research identified residues in AtPSKR1 and OsPSKR15 critical for kinase activity and interaction with ABA receptors, revealing PSKRs as core ABA signaling members that phosphorylate AtPYL4 and AtPYL9 receptors. Abscisic acid (ABA) serves as a vital signaling molecule that help plants respond to various environmental stresses, ensuring their survival and adaptability. The ABA signaling pathway begins when ABA is recognized by receptors known as PYR/PYL/RCAR.

In-silico prediction of coat protein structure of Indian citrus ringspot virus and their interactions with the Argonaut2/DCL4 proteins.

Unlabelled: The RNA silencing mechanism is a crucial regulatory system in plants, particularly in antiviral defense. However, most of the plant viruses encode a specific protein called RNA silencing suppressor protein that suppress the RNA silencing mechanism of host. This study employs the bioinformatics tools, including SWISS homology model and I-TASSER, to predict the coat protein (CP) tertiary structure of Indian citrus ringspot virus (ICRSV).

Differential resilience of chickpea's reproductive organs to cold stress across developmental stages: insights into antioxidant strategies for enhanced fertility.

Chickpea is highly sensitive to cold stress during its reproductive stages, leading to significant reductions in potential pod formation due to decreased reproductive success. This study aimed to investigate the specific responses of anthers and ovules to cold stress, explore the role of oxidative stress and antioxidant mechanisms, and understand the relationship between oxidative stress and reproductive function to enhance our understanding of chickpea responses to cold stress. Chickpea seeds of contrasting genotypes-cold-tolerant (ICC 17258, ICC 16349) and cold-sensitive (ICC 15567, GPF 2)-were sown outdoors in early November under optimal conditions (25.