OsRLR4 binds to the OsAUX1 promoter to negatively regulate primary root development in rice

Overexpression of auxin early response gene LcSAUR1 (Leymus chinensis) increases sensitivity to alkali and drought stresses in Arabidopsis and rice

Alkali and drought stresses are two common abiotic factors affecting plants growth and development. Auxin signal also regulates plant responses to abiotic stresses. Especially, auxin early response genes can quickly respond after sensing auxin signal. However, auxin early response genes related to alkali and drought stresses are rarely reported in Leymus chinensis. In this study, LcSAUR1 (small auxin-up RNA) was isolated from the difference expression analysis of the transcriptome data in Leymus chinensis under alkali and drought stresses. And LcSAUR1 exhibited inhibitory expression under alkali and drought stresses. Further research showed that LcSAUR1 was localized in the nucleus, cell membrane, and chloroplast, suggesting that it might has special biofunction. Overexpression of LcSAUR1 led to shorter root lengths in LcSAUR1-transgenic Arabidopsis and rice. Under alkali and drought stresses, the OE-LcSAUR1-Col lines showed delayed germination and larger stomatal aperture, and the OE-LcSAUR1-NIP lines had lower survival rates. The determination of physiological indicators including hydrogen peroxide (H2O2), malondialdehyde (MDA), catalase (CAT), peroxidase (POD), superoxide dismutase (SOD), the contents of proline (PRO), and the staining of nitro-blue tetrazolium (NBT) and Diaminobenzidine (DAB) indicated that the overexpressed LcSAUR1-transgenic Arabidopsis and rice produced more reactive oxygen species (ROS). In addition, for the genes related to abiotic stresses, the expression of AtSnRK2.6, AtNCEB3, AtCAT2, and AtAPX1 in the OE-LcSAUR1-Col lines, and OsLEA3-2, OsABF1, OsCAT2, and OsAPX2 in the OE-LcSAUR1-NIP lines were all lower than their WT under alkali and drought stresses, suggesting that LcSAUR1 regulates alkali and drought tolerances might through those abiotic-related genes. The study suggests that the LcSAUR1 negatively regulates alkali and drought stresses, providing a novel insight into auxin signal and abiotic stresses.

Fine mapping of qROL1 for root length at early seedling stage from wild rice (Oryza nivara)

Root is an important tissue to absorb water and nutrients from soil in plant and root architecture is one of critical traits influencing grain yield in crop. However, the genetic basis of root architecture remains unclear. In the present study, we identified a wild rice (Oryza nivara) introgression line Ra33 with longer seedling root length compared with the recipient parent 9311, an indica variety. Observation of longitudinal sections of root showed that the meristem length of Ra33 was significantly longer than that of 9311. Using an F2 secondary segregating population derived from a cross between introgression line Ra33 and the recipient parent 9311, we detected a major QTL for root length at early seedling stage, qROL1, between the molecular markers M3 and M5 on chromosome 1, and the O. nivara-derived allele at qROL1 increased root length under the background of 9311. In addition, the near-isogenic line NIL-ROL1 showed a significant increase in root length compared with the recipient parent 9311, further demonstrating the genetic effect of qROL1. And then, a total of 159 recombinant individuals were screened from 3355 F2 individuals and the QTL qROL1 was narrowed down to an approximate 78 kb interval between markers M4 and RM3, including 12 predicted genes. Further sequence comparison and expression analysis of the predicted genes in the fine-mapping region indicated that eight genes might be the interesting candidates of qROL1. The findings will provide new clues to reveal the genetic basis of root length and genetic resources for root architecture improvement in rice.

Supplementary information

The online version contains supplementary material available at 10.1007/s11032-025-01564-2.

The involvement of auxin response factor OsARF7 in positively regulating root development by mediating the expression of OsCRL1 in rice (Oryza sativa L.)

The root is one of the most important organs that determines the final grain yield in rice. Auxin is essential for root development in plants. Rice auxin response factor7 (OsARF7), belonging to the ARF family, is a key regulator of root development. Here, we show that OsARF7 positively regulates root development via auxin signaling. The osarf7 mutants display a significant decrease in the root number, adventitious root (AR) number and length, and primary root (PR) length, compared with the wild-type. Exogenous NAA treatment significantly suppresses PR length in osarf7 mutants, OsARF7-OE lines, and its wild-type, does not affect the root number of osarf7 mutants, but suppresses the biomass of osarf7 mutants. At the molecular level, OsARF7 is preferentially expressed in the culm, root, and leaf, especially highly expressed in the tips of the PR, AR, root pericycle, and lateral root (LR) primordia; meanwhile, OsARF7 expression is significantly enhanced by exogenous NAA treatment, suggesting that the positive regulatory role of OsARF7 on root development is based on auxin signaling. A series of biochemical and genetic analyses demonstrate that OsARF7 functions upstream of OsCRL1 and acts downstream of OsMADS25 to regulate root development via auxin signaling. To conclude, OsARF7 is a key positive regulatory factor that regulates root development by activating the expression of OsCRL1 via auxin signaling, by which, OsMADS25 positively mediates OsARF7 expression in rice. This work provides valuable insight into the regulatory mechanism controlling root development and a genetic resource for the molecular improvement of root architecture.

The Combined Toxic Effects of Polystyrene Microplastics and Arsenate on Lettuce Under Hydroponic Conditions

The combined pollution of microplastics (MPs) and arsenic (As) has gradually been recognized as a global environmental problem, which calls for detailed investigation of the synergistic toxic effects of MPs and As on plants and their mechanisms. Therefore, the interaction between polystyrene microplastics (PS-MPs) and arsenate (AsO43-) (in the following text, it is abbreviated as As(V)) and its toxic effects on lettuce were investigated in this study. Firstly, chemisorption was identified as the main mechanism between PS-MPs and As(V) by the analysis of adsorption kinetics, adsorption thermodynamics, and Fourier transform infrared spectroscopy (FTIR). At the same time, the addition of As(V) promoted the penetration of PS-MPs through the continuous endodermal region of the Casparis strip. Furthermore, compared with the CK group, it was found that the co-addition of As(V) exacerbated the lowering effect of PS-MPs on the pH value of the rhizosphere environment and the inhibitory effect on root growth. In the P20V10 group, the pH decreased by 33.0%. Compared to the CK group, P20, P20V1, and P20V10 decreased the chlorophyll content by 68.45% (16 SPAD units), 71.37% (17.73 SPAD units), and 61.74% (15.36 SPAD units) and the root length by 19.31% (4.18 cm), 50.72% (10.98 cm), and 47.90% (10.37 cm) in lettuce. P5V10 and P20V10 increased CAT content by 153.54% (33.22 U·(mgprol)-1) and 182.68% ((38.2 U·(mgprol)-1)), Ca by 31.27% and 37.68%, and Zn by 41.85% and 41.85%, but the presence of As(V) reduced Na by 22.85% (P5V1) and 49.95% (P5V10). The co-exposure significantly affected the physiological and biochemical indicators as well as the nutritional quality of the lettuce. Finally, the metabolomic analysis of the lettuce leaves showed that combined pollution with PS-MPs and As(V) affected the metabolic pathways of the tricarboxylic acid cycle (TCA cycle), sulfur metabolism, and pyruvate metabolism. This study provides data for pollution management measures for co-exposure to PS-MPs and As(V).

Advances in auxin synthesis, transport, and signaling in rice: implications for stress resilience and crop improvement

Auxin, a crucial plant hormone, plays a pivotal role in regulating various aspects of rice growth and development, including cell elongation, root formation, and responses to environmental stimuli. Recent breakthroughs in auxin research have revealed novel regulatory mechanisms, such as the identification of auxin-related genes like DNR1 and OsARF18, which enhance rice nitrogen use efficience and resistance to glufosinate. Additionally, advancements in understanding auxin transport and signaling pathways have highlighted their potential in optimizing tillering, root architecture, and grain yield. This review examines these molecular mechanisms and their interactions with other hormones, emphasizing their integration into breeding programs for improved rice productivity. By synthesizing these findings, we provide a comprehensive overview of how auxin research informs strategies for developing rice varieties with enhanced adaptability and optimized growth, contributing to food security and sustainable agriculture.

Overexpression of the RAV Transcription Factor OsAAT1 Confers Enhanced Arsenic Tolerance by Modulating Auxin Hemostasis in Rice

Characterization of arsenic (As)-responsive genes is fundamental to solving the issue of As contamination in rice. Herein, we establish the involvement of an RAV transcription factor OsAAT1 (Arsenic Accumulation and Tolerance 1) in regulating As response in rice. The expression of OsAAT1 is significantly higher in roots and stems of rice seedlings and is clearly upregulated by higher concentrations of arsenite [As(III)]. Compared with wild-type (WT) plants, OsAAT1-overexpressed transgenic lines (OE-OsAAT1) exhibit tolerance, while OsAAT1-knockout mutants (Osaat1) are sensitive to As(III) stress. Notably, the application of exogenous 1-naphthylacetic acid (NAA) greatly enhances the As tolerance of WT and transgenic lines, with stronger effects on OE-OsAAT1. The change in OsAAT1 expression leads to the alteration of As and auxin accumulation in transgenic plants by regulating the expression of OsLsi1, OsLsi2, OsCRL4, and OsAUX1 genes. Moreover, overexpression of OsAAT1 accelerates ROS scavenging and phytochelatins (PCs) synthesis, especially with the addition of exogenous NAA. OsAAT1 localizes in the nucleus and works as a transcriptional suppressor. OsGH3-12, belonging to the auxin-responsive GH3 gene family, is the downstream target gene of OsAAT1, whose expression is extensively downregulated by As(III). These findings provide new insights into As response via auxin signaling pathway in rice.

Genomic Identification and Expression Analysis of Regulator of Chromosome Condensation 1-Domain Protein Family in Maize

Abiotic stress affects the growth and development of maize (Zea mays). The regulator of chromosome condensation 1 (RCC1)-containing proteins (RCPs) plays crucial roles in plant growth and development and response to abiotic stresses. However, a comprehensive analysis of the maize RCP family has not been reported in detail. This study presents a systematic bioinformatics analysis of the ZmRCP family, identifying a total of 30 members distributed across nine chromosomes. The physicochemical properties and cis-acting elements in the promoters of ZmRCP members are predicted. The results of subcellular localization showed that ZmRCP3 and ZmRCP10 are targeted to mitochondria and ZmRCP2 is localized in the nucleus. A heatmap of expression levels among family members under abiotic stress conditions revealed varying degrees of induced expression, and the expression levels of 10 ZmRCP members were quantified using RT-qPCR under abiotic stress and plant hormone treatments. The results showed that ZmRCP members exhibit induced or inhibited responses to these abiotic stresses and plant hormones. These results contribute to a better understanding of the evolutionary history and potential role of the ZmRCP family in mediating responses to abiotic stress in maize.

Epigenetics and plant hormone dynamics: a functional and methodological perspective

Plant hormones, pivotal regulators of plant growth, development, and response to environmental cues, have recently emerged as central modulators of epigenetic processes governing gene expression and phenotypic plasticity. This review addresses the complex interplay between plant hormones and epigenetic mechanisms, highlighting the diverse methodologies that have been harnessed to decipher these intricate relationships. We present a comprehensive overview to understand how phytohormones orchestrate epigenetic modifications, shaping plant adaptation and survival strategies. Conversely, we explore how epigenetic regulators ensure hormonal balance and regulate the signalling pathways of key plant hormones. Furthermore, our investigation includes a search for novel genes that are regulated by plant hormones under the control of epigenetic processes. Our review offers a contemporary overview of the epigenetic-plant hormone crosstalk, emphasizing its significance in plant growth, development, and potential agronomical applications.

Genetic mapping of regions associated with root system architecture in rice using MutMap QTL-seq

The root system architecture is an important complex trait in rice. With changing climatic conditions and soil nutrient deficiencies, there is an immediate need to breed nutrient-use-efficient rice varieties with robust root system architectural (RSA) traits. To map the genomic regions associated with crucial component traits of RSA viz. root length and root volume, a biparental F2 mapping population was developed using TI-128, an Ethyl Methane Sulphonate (EMS) mutant of a mega variety BPT-5204 having high root length (RL) and root volume (RV) with wild type BPT-5204. Extreme bulks having high RL and RV and low RL and RV were the whole genome re-sequenced along with parents. Genetic mapping using the MutMap QTL-Seq approach elucidated two genomic intervals on Chr.12 (3.14-3.74 Mb, 18.11-20.85 Mb), and on Chr.2 (23.18-23.68 Mb) as potential regions associated with both RL and RV. The Kompetitive Allele Specific PCR (KASP) assays for SNPs with delta SNP index near 1 were associated with higher RL and RV in the panel of sixty-two genotypes varying in root length and volume. The KASP_SNPs viz. Chr12_S4 (C→T; Chr12:3243938), located in the 3' UTR region of LOC_Os12g06670 encoding a protein kinase domain-containing protein and Chr2_S6 (C→T; Chr2:23181622) present upstream in the regulator of chromosomal condensation protein LOC_Os2g38350. Validation of these genes using qRT-PCR and in-silico studies using various online tools and databases revealed higher expression in TI-128 as compared to BPT- 5204 at the seedling and panicle initiation stages implying the functional role in enhancing RL and RV.

Modulating root system architecture: cross-talk between auxin and phytohormones

Root architecture is an important agronomic trait that plays an essential role in water uptake, soil compactions, nutrient recycling, plant-microbe interactions, and hormone-mediated signaling pathways. Recently, significant advancements have been made in understanding how the complex interactions of phytohormones regulate the dynamic organization of root architecture in crops. Moreover, phytohormones, particularly auxin, act as internal regulators of root development in soil, starting from the early organogenesis to the formation of root hair (RH) through diverse signaling mechanisms. However, a considerable gap remains in understanding the hormonal cross-talk during various developmental stages of roots. This review examines the dynamic aspects of phytohormone signaling, cross-talk mechanisms, and the activation of transcription factors (TFs) throughout various developmental stages of the root life cycle. Understanding these developmental processes, together with hormonal signaling and molecular engineering in crops, can improve our knowledge of root development under various environmental conditions.

Advances in structure and function of auxin response factor in plants

Auxin is a crucial phytohormone that has various effects on the regulators of plant growth and development. Auxin signal transduction is mainly controlled by two gene families: auxin response factor (ARF) and auxin/indole-3-acetic acid (Aux/IAA). ARFs are plant-specific transcription factors that bind directly to auxin response elements in the promoters of auxin-responsive genes. ARF proteins contain three conserved regions: a conserved N-terminal B3 DNA-binding domain, a variable intermediate middle region domain that functions in activation or repression, and a C-terminal domain including the Phox and Bem1p region for dimerization, similar to the III and IV elements of Aux/IAA, which facilitate protein-protein interaction through homodimerization of ARF proteins or heterodimerization of ARF and Aux/IAA proteins. In the two decades following the identification of the first ARF, 23 ARF members have been identified and characterized in Arabidopsis. Using whole-genome sequencing, 22, 25, 23, 25, and 36 ARF genes have been identified in tomato, rice, wheat, sorghum, and maize, respectively, in addition to which the related biofunctions of some ARFs have been reported. ARFs play crucial roles in regulating the growth and development of roots, leaves, flowers, fruits, seeds, responses to biotic and abiotic stresses, and phytohormone signal crosstalk. In this review, we summarize the research progress on the structures and functions of ARFs in Arabidopsis, tomato, and cereal crops, to provide clues for future basic research on phytohormone signaling and the molecular design breeding of crops.

Genome-wide identification and expression analysis of the regulator of chromosome condensation 1 gene family in wheat (Triticum aestivum L.)

Wheat (Triticum aestivum L., 2n = 6x = 42, AABBDD) is the world's most widely cultivated crop and an important staple food for humans, accounting for one-fifth of calories consumed. Proteins encoded by the regulator of chromosome condensation 1 (RCC1) are highly conserved among eukaryotes and consist of seven repeated domains that fold into a seven-bladed propeller structure. In this study, a total of 76 RCC1 genes of bread wheat were identified via a genome-wide search, and their phylogenetic relationship, gene structure, protein-conserved domain, chromosome localization, conserved motif, and transcription factor binding sites were systematically analyzed using the bioinformatics approach to indicate the evolutionary and functional features of these genes. The expression patterns of 76 TaRCC1 family genes in wheat under various stresses were further analyzed, and RT-PCR verified that RCC1-3A (TraesCS3A02G362800), RCC1-3B (TraesCS3B02G395200), and RCC1-3D (TraesCS3D02G35650) were significantly induced by salt, cold, and drought stresses. Additionally, the co-expression network analysis and binding site prediction suggested that Myb-7B (TraesCS7B02G188000) and Myb-7D (TraesCS7D02G295400) may bind to the promoter of RCC1-3A/3B and upregulate their expression in response to abiotic stresses in wheat. The results have furthered our understanding of the wheat RCC1 family members and will provide important information for subsequent studies and the use of RCC1 genes in wheat.

Interplay of phytohormones and epigenetic regulation: A recipe for plant development and plasticity

Both phytohormone signaling and epigenetic mechanisms have long been known to play crucial roles in plant development and plasticity in response to ambient stimuli. Indeed, diverse signaling pathways mediated by phytohormones and epigenetic processes integrate multiple upstream signals to regulate various plant traits. Emerging evidence indicates that phytohormones and epigenetic processes interact at multiple levels. In this review, we summarize the current knowledge of the interplay between phytohormones and epigenetic processes from the perspective of phytohormone biology. We also review chemical regulators used in epigenetic studies and propose strategies for developing novel regulators using multidisciplinary approaches.

Root-Related Genes in Crops and Their Application under Drought Stress Resistance—A Review

Crop growth and development are frequently affected by biotic and abiotic stresses. The adaptation of crops to stress is mostly achieved by regulating specific genes. The root system is the primary organ for nutrient and water uptake, and has an important role in drought stress response. The improvement of stress tolerance to increase crop yield potential and yield stability is a traditional goal of breeders in cultivar development using integrated breeding methods. An improved understanding of genes that control root development will enable the formulation of strategies to incorporate stress-tolerant genes into breeding for complex agronomic traits and provide opportunities for developing stress-tolerant germplasm. We screened the genes associated with root growth and development from diverse plants including Arabidopsis, rice, maize, pepper and tomato. This paper provides a theoretical basis for the application of root-related genes in molecular breeding to achieve crop drought tolerance by the improvement of root architecture.