Epigenetic regulation refers to the heritable control of gene expression without alterations in the DNA sequence, achieved through mechanisms such as DNA methylation, histone modification, RNA modification, chromatin remodeling and non-coding RNAs. Epigenetics provides an additional and flexible source of trait variation for horticultural crop improvement, opening innovative avenues for breeding new varieties capable of addressing challenges like climate change adaptation, disease and pest resistance, and quality enhancement. This review systematically synthesizes current research progress on the epigenetic regulation of key agronomic traits in horticultural crops and summarizes relevant breeding tools and methods developed for their use in horticultural crop breeding. It aims to provide a theoretical reference for further understanding the epigenetic basis of the formation of horticultural crop traits, and provide a theoretical basis and technical support for the promotion and application of epigenetic breeding in horticultural crops.
To establish an efficient and sustainable RNAi breeding control system, this paper summarizes the application potential of RNAi technology in crop disease and pest resistance, reviews the current research and development status of transgenic RNAi crops, and analyzes the design strategies and synergistic resistance mechanisms of multi-target tandem RNAi. The key points of elaboration include the "dsRNA/microRNA stable expression system", the "combined control model of complex pests and diseases (wheat scab - aphids, cotton wilt - cotton aphids)", and the "precise gene intervention approach for delaying resistance evolution", etc. It is pointed out that low delivery efficiency, poor environmental stability of dsRNA and high production cost remain the bottlenecks for large-scale application. This paper proposes that through the precise release technology of nano-carrier-plant symbiotic delivery, tandem expression of multi-gene silencers, and combined with ecological balance monitoring, the coordinated management of multiple pests and diseases can be achieved within 5 to 10 years. It is believed that this system will promote the transformation of agriculture towards a sustainable model of "precise genetic intervention + ecological balance maintenance", providing key support for global food security.
Soil salinization poses a severe threat to global food security and ecological environments. Cultivating salt-tolerant crop varieties and enhancing crop salt tolerance can effectively address salinization stress and utilize saline-alkali lands. We elucidate the molecular mechanisms of plant salt tolerance and focus on the cutting-edge technologies in crop salt tolerance breeding, systematically elaborating on the principles and application achievements of technologies such as multi-omics integrated analysis, gene editing, plant growth-promoting rhizobacteria (PGPR) and epigenetic modifications in crop salt tolerance breeding. These advanced technologies provide guidance for crop salt tolerance breeding. Through technological integration and innovation, it may be hold the potential to rapidly and precisely develop new salt-tolerant crop varieties, thereby promoting efficient and sustainable agricultural development in saline-alkali lands.
This study analyzed the relevant information information breeding and trait big data (
In this study, we focus on the genetic mechanisms underlying culm strength in rice, aiming to provide a robust theoretical foundation for molecular breeding of lodging-resistant varieties. By systematically reviewing and conducting in-depth analyses of academic literature and research reports, we explore the regulatory mechanisms of genes associated with culm strength, culm chemical composition, hormonal regulation, and plant architecture, as well as their molecular mechanisms in conferring lodging resistance. Consequently, rice culm strength is influenced by both morphological traits (e.g., basal internode diameter and culm wall thickness) and chemical components (including cellulose, hemicellulose, and lignin contents). Notably, the mechanical properties of lower internodes are key determinants of rice lodging resistance. In terms of genetics, SCM3 (an allele of OsTB1) enhances culm strength via the strigolactone signaling pathway. WAK10 regulates cellulose synthesis in secondary cell walls. OsTCP19 facilitates the balance between lignin and cellulose. IPA1 achieves synergistic improvements in lodging resistance and yield by optimizing plant architecture—specifically, by reducing ineffective tillers, increasing culm diameter, and balancing lodging resistance with an increased number of grains per panicle. In terms of breeding applications, molecular marker-assisted selection has been employed to screen for quantitative trait loci (QTLs) associated with culm strength, such as prl5 and lrt5. Additionally, gene-editing technologies (e.g., CRISPR/Cas9) have been utilized to modify key genes governing culm strength in rice lodging resistance breeding. Through backcrossing to develop near-isogenic lines (NILs), multiple strong culm genes (including SCM1-4) have been pyramided—resulting in NIL-SCM1, NIL-SCM2, NIL-SCM3, NIL-SCM4, as well as double and triple NIL combinations. This approach has enabled the successful development of lodging-resistant varieties, namely 'Sakura Prince' and 'Monster Rice 1'. This study proposes that future work should be carried out in the following aspects: mining novel lodging resistance genes (e.g., the STRONG2 module) and analyzing multi-gene synergistic effects, establishing a genetic balance model involving stem strength, panicle weight, and panicle number, optimizing gene pyramiding strategies in combination with genome-wide association analysis, and exploring the impacts of environmental factors (such as typhoons and dense planting) on culm strength. These efforts aim to achieve enhancement of rice lodging resistance and yield simultaneously.
Ethylene Responsive Factor (ERF) transcription factors belong to the plant AP2/ERF transcription factor superfamily and are key regulatory factors in plants responses to biotic and abiotic stresses. They bind to the cis-acting element GCC-box through the conserved AP2/ERF domain, thereby regulating the spatiotemporal expression of target genes. This article reviews the structural characteristics, classification system, distribution patterns, and biological functions of plant ERF transcription factors. Structurally, they contain functional regions such as the DNA-binding domain and transcriptional regulatory domain, among which the amino acids at positions 14 and 19 of the AP2/ERF domain are key markers for classification. In terms of classification, both the ERF and DREB subfamilies can be further divided into 6 subgroups. In terms of distribution, the number of members of this family varies significantly among different plants, and the number of ERF subfamily members in dicotyledonous plants is usually more than that in monocotyledonous plants. The functional mechanism of ERF in biotic stress response is emphatically elaborated as follows. On the one hand, it enhances plant resistance to pathogens by activating disease-resistant genes such as PR and PDF1.2; on the other hand, ERFs containing the EAR motif can act as negative regulators to inhibit the expression of target genes. At the same time, this article summarizes the research status of peanut ERF, including family identification (our research group identified 76 ERF family members in cultivated peanuts in 2022), verification of stress resistance functions (such as AhERF008 and AhERF019 can enhance abiotic stress tolerance), and current limitations (such as insufficient systematic analysis and unclear regulatory mechanisms). Finally, the future research directions are prospected, proposing that multi-omics and gene editing technologies should be combined to analyze the ERF-mediated stress resistance network, so as to provide a theoretical basis and technical targets for peanut stress resistance molecular breeding and facilitate research on peanut stress resistance engineering.
This study reviews the application of molecular breeding technologies for genetically improving Brassica crops. It focuses on three hybrid seed production systems: Genic Male Sterility (GMS), Cytoplasmic Male Sterility (CMS), and Self-Incompatibility (SI). The work details how CRISPR/Cas9 gene editing enables targeted development of GMS systems—such as creating double mutants of genes like DAD1, BnaMS1, BnaMS2, and OPR3 or thermosensitive two-line systems. For CMS systems, fertility restoration is achieved by knocking out genes like orf138. Novel SI parental lines are created by editing genes such as BnS6-Smi2, BoSP11, and Exo84c. Molecular markers based on sterility genes (orf224/atp6, orf222, orf138) allow precise identification of three cytoplasmic types (Pol, Nap, Ogu, etc.) in Brassica napus. These technologies significantly enhance heterosis utilization efficiency by enabling precise creation of sterile lines and efficient selection of elite germplasm. This facilitates breeding of new cultivars with high yield, superior quality, and stress resistance. Future research directions include: (1) In-depth exploration of the functions of mitochondrial genes associated with CMS; (2) Optimization of CRISPR/Cas9-mediated strategies for coordinated multi-gene editing; (3) Integration of multi-omics data with artificial intelligence algorithms for hybrid combination prediction; (4) Development of novel techniques for creating transgene-free self-compatible lines. This study provides a theoretical foundation and technical support for overcoming bottlenecks in traditional breeding and advancing precision breeding in Brassica crops.
Wheat powdery mildew, caused by Blumeria graminis f. sp. tritici (Bgt), is a destructive fungal disease that significantly reduces wheat yield and grain quality worldwide. This study aimed to evaluate powdery mildew resistance in Sichuan wheat varieties (lines) and characterize their resistance genes, which will provide an important theoretical basis and practical guidance for disease-resistant wheat breeding. A total of 168 Sichuan wheat varieties (lines) were screened for seedling powdery mildew resistance under artificial climate chamber, which were inoculated with Bgt isolate E09, and the resistance gene was analyzed by molecular marker detection and genomic in situ hybridization (GISH). The result showed that 35 wheat materials (20.8%) were resistant. Molecular marker analysis showed that 34 materials carries the Pm21 gene, and ‘Shumai 2352’ carries Pm56. GISH analysis further confirmed that wheat cultivar ‘Mianmai 367’ carries a whole-arm chromosomal translocation of V chromosome (6VS·6AL) harboring Pm21, and ‘Shumai 2352’ possesses a whole-arm translocation of R chromosome (6RS·6AL) containing Pm56. The study highlights the limited genetic diversity of powdery mildew resistance in Sichuan wheat germplasm which are mainly relying on the Pm21 resistance gene, and emphasizes the urgent need to diversify resistance sources by introducing more Pm genes to broaden the genetic basis of disease resistance sources.
The study aims to explore differentially expressed genes related to reproductive traits in Xinjiang goats and screen out key genes associated with goat reproduction. In this study, transcriptome sequencing analysis was used to compare the transcriptomes of hypothalamic tissues between Xinjiang goats with different fecundity during the follicular phase and luteal phase, aiming to screen key reproduction-related genes in the hypothalamus of Xinjiang goats with high and low fecundity during these two phases. In the differential expression analysis of the hypothalamus during the follicular phase, a total of 680 differentially expressed genes were identified in the XJLSX vs XJLDX group (high-fecundity ewes vs low-fecundity ewes in the follicular phase), among which 210 were up-regulated and 470 were down-regulated. GO and KEGG functional analyses of these differentially expressed genes revealed 9 GO Terms containing 16 differentially expressed genes and 8 KEGG pathways containing 23 differentially expressed genes that were related to goat reproductive traits. Combined with protein-protein interaction network analysis of differentially expressed genes and relevant literature, 6 differentially expressed genes, namely NPR1, KITLG, GABRAI, CRHR2, ADCYAP1, IGF2BP3, were screened out as potential key genes affecting the reproductive traits of Xinjiang goats. In the differential expression analysis of the hypothalamus during the luteal phase, a total of 656 differentially expressed genes were found in the XJHSX vs XJHDX group (high-fecundity ewes vs low-fecundity ewes in the luteal phase), with 178 up-regulated and 478 down-regulated. GO and KEGG functional analyses showed that 7 GO Terms, involving 9 differentially expressed genes, were associated with oocyte growth and differentiation, follicular development, and reproductive hormones; 6 KEGG signaling pathways, containing 10 differentially expressed genes, were related to goat reproductive traits. Through integration with protein-protein interaction network analysis and literature review, 5 differentially expressed genes (WT1, IGF1, ESR1, NR5A1, MET) were identified as potential key genes influencing the reproductive traits of Xinjiang goats. This study screened out key genes related to goat reproduction, which provided a theoretical basis and molecular markers for breeding new high-fecundity and multi-fetal strains of Xinjiang goats.
The purpose of this study is to screen candidate genes associated with muscle growth in Dexin mutton type fine-wool sheep at different developmental stages using RNA-Seq technology, preliminarily elucidate the molecular mechanisms underlying differential development of the longissimus dorsi muscle, and provide a theoretical foundation for muscle growth research in this breed. Male Dexin mutton type fine-wool sheep at 3, 6, and 12 months of age, raised under identical conditions, were utilized as research subjects. Carcass traits of the longissimus dorsi muscle were analyzed and compared. Transcriptomic sequencing was performed on the longissimus dorsi muscle using the Illumina NovaSeq platform for mRNA sequencing and analysis to identify candidate genes influencing muscle growth. RNA-Seq analysis identified 2468 differentially expressed genes (DEGs) across the three age groups. Among these, 30 DEGs were commonly expressed in all three groups, while 468, 458, and 544 DEGs were specifically expressed in the 3-month, 6-month, and 12-month groups, respectively. Gene Ontology (GO) functional annotation revealed significant enrichment of DEGs in 2997 GO terms (P<0.05). Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis demonstrated DEG involvement in 93 pathways, including growth-related pathways such as: JAK-STAT signaling pathway, PI3K-Akt signaling pathway, MAPK signaling pathway, Cytokine-cytokine receptor interaction, and FoxO signaling pathway. Subsequent screening prioritized two key candidate genes (IGF2 and MYL4). The candidate genes IGF2 and MYL4 provide critical molecular insights into muscle growth and development, establishing a theoretical basis for subsequent research on muscle regulation in Dexin mutton type fine-wool sheep.
Aiming at the problems of soil structure degradation and crop growth limitation in saline-alkali farmland in Tumochuan irrigation area of Inner Mongolia, this study explored the mechanism of new compound modifier to improve the yield of silage maize, and provided theoretical basis for ecological improvement of saline-alkali land in semi-arid area. A field experiment was conducted with three treatments: control (CK), single granular amendment (T1), and compound amendment (granular + drip-irrigation amendment, T2). We measured the soil pH, electrical conductivity (EC), saturated hydraulic conductivity (Ks) and other physical and chemical properties in 0-20, 20-40 and 40-60 cm soil layers. Combined with X-ray CT scanning technology, the key pore structure parameters such as soil porosity were quantified, and the yield dynamics of silage maize were monitored simultaneously. The results showed that the compound amendment (T2) treatment significantly improved the cultivated layer structure. Compared with CK, the average weight diameter of 0-20 cm aggregates increased by 75.6%, Ks increased by 99.7%, porosity, pore equivalent volume and Euler number increased by 16.7%, 17.4% and 28.6%, respectively. T2 treatment effectively alleviated saline-alkali stress while enhancing soil nutrient content. During the maize growth period, the average pH across the 0-60 cm soil profile decreased by 6.5%, EC decreased by 67.19%, and soil organic carbon content increased by 4.97%. Ultimately, maize yield under T2 increased significantly, with the fresh weight of silage maize at maturity reaching 57585.82 kg/hm2, representing a 120.99% increase over CK and a significant improvement compared to T1. The new compound amendment effectively improves saline-alkali farmland and significantly enhances silage maize yield by synergistically optimizing soil pore structure, reducing soil alkalinity and salinity, which verified its good applicability in the ecological restoration of saline-alkali land in Tumochuan irrigation area.
In order to address soil quality degradation and fruit quality decline in continuous cropping vineyards, this research investigated the effects of a soil conditioner (BGA), conventional fertilizer (NPK), and their reduced-rate combined application (H-BGA+NPK) on soil physicochemical properties, active organic carbon fractions, aggregate structure, and grape quality, while exploring the underlying mechanisms. Results showed that fertilization treatments exhibited significant temporal specificity in influencing soil parameters. During the fruit expansion stage, the H-BGA+NPK treatment synergistically enhanced soil organic matter (21.67% higher than NPK), total nitrogen (3.61% higher than NPK), and microbial biomass carbon (20.53% higher than NPK), optimizing early-stage nutrient supply through the combined effect of rapid nitrogen release from fertilizer and slow carbon input from the conditioner. In the maturity stage, sole BGA application promoted sustained mineralization of organic components, leading to substantial increases in soil organic matter (59.89% higher than NPK) and nitrate nitrogen (169.27% higher than NPK), significantly improving the soil carbon-nitrogen pool. Soil aggregate analysis revealed that H-BGA+NPK significantly promoted the formation of macro-aggregates (>0.25 mm), increasing their proportion by 45.90% compared to NPK, while sole NPK application increased the proportion of micro-aggregates (<0.053 mm), highlighting the structural optimization effect of conditioner-fertilizer combination. Regarding fruit quality, the H-BGA+NPK treatment achieved the highest soluble sugar content (12.46%), which was 5.68% and 1.71% higher than NPK and BGA alone, respectively, demonstrating optimal balance of the sugar-acid ratio. Sole BGA application significantly increased titratable acid (9.49% higher than NPK) and soluble solids (1.03%-4.08% higher than NPK), making it suitable for high-acid grape cultivation. Correlation analysis indicated that soluble sugar was negatively correlated with soil bulk density and dissolved organic carbon (P<0.05), while titratable acid showed strong negative correlations with soil pH, total nitrogen, and other nutrient indices (P<0.001), and positive correlations with bulk density and dissolved organic carbon (P<0.05), confirming that soil structure and carbon fractions are key regulators of fruit quality. This research confirms that precise integration of soil conditioner and fertilizer based on crop growth stages can balance short-term nutrient supply and long-term soil health, providing a theoretical and practical framework in sustainable high-yield and high-quality vineyard management.
To explore the effects of different amendments on the soil bacterial community structure and oat growth in soda saline-alkali land, and provide a basis for efficient improvement of saline-alkali land and the high-yield cultivation of oats, a field experiment was carried out in Dongfeng Farm, Daqing City. Five treatments were set up, namely, without amendment (CK), aluminum sulfate (AS), desulfurized gypsum (DG), vinegar residue (VR) and biochar (BC). High-throughput sequencing technology was used to analyze the structure and diversity of soil bacterial communities, and the agronomic traits of oats were measured. The results showed that the four improvers significantly increased the soil bacterial community diversity (P<0.05). Among them, the number of OTUs, Chao1 index, and Ace index were the highest in the DG treatment, the Shannon index was the highest in the VR treatment, and the Simpson index was the lowest in the BC treatment. At the phylum level, Pseudomonadota, Acidobacteriota and Actinomycetota were the main phyla. The relative abundance of Pseudomonadota was the highest (29.47%) in the BC treatment, the relative abundance of Acidobacteriota was the lowest (17.12%) in the AS treatment, and the relative abundance of Actinomycetota was the lowest (11.00%) in the DG treatment. At the genus level, norank_Pyrinomonadaceae, norank_Gemmatimonadaceae and norank_Vicinamibacterales were the main genera. After the application of amendments, the plant height, spike length, 1000-grain weight, fresh weight and dry weight of oats all increased. The BC treatment effect was the most prominent. The plant height of oats was 130.37 cm, the spike length was 21.80 cm, the 1000-grain weight was 27.00 g, and the fresh weight and dry weight reached 8337.35 kg/hm2 and 7141.30 kg/hm2, respectively. The DG and AS treatments also promoted the growth of oats. In terms of fresh weight and dry weight, they were not as good as the BC treatment. The promoting effect of the VR treatment was relatively weak. The traits of oat plants were closely related to the α-diversity index of the soil bacterial community. In conclusion, the four amendments, aluminum sulfate, desulfurized gypsum, vinegar residue and biochar, could all improve the soil bacterial community structure and promote the growth of oats. Biochar had the best effect, followed by desulfurized gypsum and aluminum sulfate, and vinegar residue had a relatively weak effect.
This study investigates the effects of brackish water irrigation and nitrogen fertilizer types on the growth and yield of rice, providing a theoretical basis and practical guidance for integrated management of water and fertilizer as well as the improvement of crop yield in coastal saline farmlands. Taking moderately coastal saline soil (salt content=2.2 g/kg) as the test soil, a four-month field column experiment was conducted using ‘Y-Liangyou-911’ rice variety as material. The experiment was designed with two factors: the salinity of irrigation water [freshwater (W1), mixed irrigation of freshwater and brackish water (W2), and brackish water (W3) alone] and nitrogen fertilizer types [urea (N1), polyurethane-coated urea (N2), and urea formaldehyde (N3)]. The tillering number, plant height, leaf area as well as yield and its components of rice were analyzed. The results showed that, under the same nitrogen fertilizer type treatment, compared with fresh water irrigation (W1), brackish water irrigation (W2 and W3) significantly promoted the tillering of rice, but reduced the plant height and leaf area. The nitrogen fertilizer type only significantly affected tillering number under fresh water irrigation. Specifically, the tillering number under W1N3 treatment was significantly higher than that under W1N2 and W1N1 treatments. However, nitrogen fertilizer type had no significant effect on plant height and leaf area. Regarding rice yield and its components, brackish water irrigation had no significant effect on the panicle number and grains per panicle, but significantly reduced the thousand-grain weight, consequently resulting in a decrease in yield. Compared with W1 treatment, the yield under W2 and W3 treatments decreased by 17%-28% and 22%-35%, respectively. The nitrogen fertilizer type had no significant effect on panicle number and thousand-grain weight, but significantly increased grains per panicle and yield. Notably, compared with three treatments under fresh water irrigation, the rice yield under W2N2 treatment showed no significant decrease. In coastal saline areas, appropriate brackish water irrigation can promote rice tillering but inhibits plant height and leaf growth, thereby significantly reducing thousand-grain weight and causing yield reduction. Polyurethane-coated urea can effectively mitigate the negative impact of brackish water irrigation on rice yield. Overall, the practice combining the mixed irrigation with freshwater and brackish water (<1.50 g/L) and the application of polyurethane-coated urea as a basal fertilizer is an effective management strategy of water and fertilizer. This approach efficiently facilitates the utilization of brackish water resources and the stabilization of crop yield in coastal saline areas.
Saline and acid combined stress represents a major constraint for agricultural production and coastal saline soil utilization in South China. This study investigated the synergistic effects of combined organic and inorganic amendments on the physicochemical properties of coastal saline soils and the growth of Mesembryanthemum crystallinum L., aiming to provide theoretical insights for the efficient remediation of coastal saline soils and cultivation of salt-tolerant crops. Using coastal saline soil and M. crystallinum, a pot experiment was conducted to compare three treatments: control, 0.1% soil conditioner, and combined 0.05% calcium-magnesium-phosphate fertilizer + 0.05% organic fertilizer. Amendments were evaluated for impacts on soil salinization, acidification, plant growth and stress resistance. The results showed that the 0.1% soil conditioner treatment increased soil pH by 2.68 units but showed no significant effects on soil electrical conductivity, total salt content, Na+ concentration, M. crystallinum biomass or stress resistance. In contrast, the combined application of calcium-magnesium-phosphate fertilizer and organic fertilizer increased soil pH by 2.15 units, reduced exchangeable Al3+, exchangeable H+, total exchangeable acidity and hydrolytic acidity by 85.3%, 87.9%, 86.0% and 59.5%, respectively, decreased soil electrical conductivity, salt content, and Na+ by 21.0%, 20.9%, and 31.0%, and increased soil available P concentration by 116%. Additionally, it enhanced the shoot fresh weight of M. crystallinum by 174%, reduced leaf malondialdehyde content by 37.0%, and increased root tip number by 42.8% compared to CK. Redundancy analysis identified soil available P, available K, and Na+ as key drivers of M. crystallinum growth in coastal saline soils. While soil conditioner alone alleviated acidification, its efficacy against saline-acid stress was limited. The combination of calcium-magnesium-phosphate fertilizer and organic fertilizer synergistically improved soil physicochemical properties (elevating pH, reducing salinity, mitigating Na+ toxicity, elevating available P) and optimized root morphology, significantly enhancing M. crystallinum stress resistance and yield. This integrated approach outperforms single amendments in suppressing soil acidification and salinization, offering an effective strategy for the sustainable coastal saline soil utilization.
This study employed a single-factor randomized block design with six treatments: control (CK), microalgal nutrient solution (WZ), desulfurization gypsum (SG), fulvic acid (HFS), organic fertilizer (YJF) and biochar (SWT). Combining field plot experiments with laboratory analysis, the research aimed to investigate the effects of different amendments on soil organic carbon (SOC) fractions and aggregate stability in saline-alkali soil of the Qaidam Basin. The improvement efficacy of the amendments was evaluated based on SOC fractions and aggregate stability. The results showed that biochar application significantly enhanced SOC fraction contents. The SOC, particulate organic carbon (POC), mineral-associated organic carbon (MAOC) and easily oxidizable organic carbon (EOC) contents under the SWT treatment were significantly higher than those under other treatments, reaching to 8.25, 2.00, 3.11 and 2.85 g/kg. Compared with the CK treatment, these values were increased by 112.53%, 282.19%, 70.13% and 203.19%, respectively. Fulvic acid application effectively increased the proportion of water-stable aggregates in the 0.053-0.25 mm and >0.25 mm size classes, showing increases of 17.89% and 7.14 % compared to CK. Furthermore, the HFS treatment yielded the highest mean weight diameter (MWD) and geometric mean diameter (GMD) values among all treatments, at 7.131 mm and 0.089 mm. These values were 5.69% and 18.67% higher than those of the CK treatment. Correlation analysis indicated no significant relationship between SOC fractions and either the composition or stability of water-stable aggregates. SOC and EOC showed a positive correlation with the content of aggregates <0.053 mm, but a negative correlation with the contents of 0.053-0.25 mm aggregates, >0.25 mm aggregates, MWD and GMD. In conclusion, biochar application facilitated SOC accumulation, while fulvic acid application promoted soil structural improvement.
This study systematically reviews the scientific and technological advancements in wheat breeding for saline-alkali farmland in China, analyzes current technical bottlenecks, and provides theoretical support for enhancing wheat productivity in saline-alkali soils. Through literature review and empirical analysis, we integrated research achievements in salt-alkali-tolerant germplasm development, gene discovery, variety breeding, and demonstration promotion, while considering regional saline-alkali soil characteristics and policy orientations. The results demonstrate significant progress in salt-alkali-tolerant wheat breeding innovations in China. A series of novel salt-alkali-tolerant germplasms have been developed, with key functional genes such as TaSRO1 and TaHKT1;5-D being identified. Ten nationally certified salt-alkali-tolerant wheat varieties, including 'Jingmai 189', have been bred, achieving an average yield of 7410 kg/hm2 in regional trials with a 7.3% yield increase. Two major saline-alkali tolerance testing systems have been established in the Bohai Rim and Southern Xinjiang, with demonstration and promotion areas exceeding 18700 hm2. However, the study also reveals existing challenges, including suboptimal breeding efficiency, incomplete technical systems, and inadequate promotion efforts. Therefore, future efforts should focus on enhancing gene discovery and molecular design breeding, establishing an efficient technical system, and promoting large-scale application of salt-alkali-tolerant varieties to provide scientific and technological support for China's food security strategy in saline-alkali regions.
This study investigated the synergistic ameliorative effects of Trichoderma harzianum in combination with different soil amendments on saline-alkali soils, and their impact on cotton growth. A pot experiment was conducted with six treatments: control (CK), T. harzianum alone (T), T. harzianum combined with biochar (BT), humic acid (HT), organic fertilizer (AT), and microbial inoculant (MT). The effects on soil physicochemical properties and the physiological performance of cotton were comprehensively assessed. Results showed that the AT treatment (combination with organic fertilizer) reduced soil pH by 2.58%, significantly outperforming other treatments. It also markedly increased the contents of soil organic matter, available phosphorus, available potassium, and alkali-hydrolyzable nitrogen, indicating that the amendments significantly improved soil physicochemical conditions. Regarding plant growth parameters, the AT treatment significantly enhanced plant height (+36.40%), stem diameter (+49.50%), aboveground biomass (+68.67%), and belowground biomass (+89.29%), representing the highest increases among all treatments. Physiological and biochemical analyses revealed that T, AT, and MT treatments significantly increased the activities of superoxide dismutase (SOD), peroxidase (POD), and catalase (CAT) in cotton leaves, while reducing the levels of malondialdehyde (MDA), soluble protein, and proline, indicating enhanced stress resistance. Correlation analysis further demonstrated significant relationships between soil properties and cotton growth indicators, providing a scientific basis for optimizing soil amendment strategies. In conclusion, the combination of T. harzianum and organic fertilizer (AT treatment) was most effective in improving soil quality and promoting cotton growth. These findings offer scientific support and practical guidance for the efficient utilization of saline-alkali soils and the sustainable production of high-quality cotton in Xinjiang.
This paper delineated the integrated technological work process (encompassing cultivar selection, soil amelioration and cultivation management) developed for drought-alkali wheat expansion on saline soils in Cangzhou. It reviewed the consecutive growth trajectory in which the cropped area rose from 5.9×104 hm2 in 2020 to 1.2×105 hm2 in 2024, and the grain yield increased from 3.1×103 to 4.3×103 kg/hm2. The inhibitory effects exerted by drought, high salinity-alkalinity and low temperature-low light stresses during the growing season on seed germination, tiller formation and grain filling were summarized. The latest mechanisms of exogenous abscisic acid (ABA), silicon formulations and cerium oxide nanoparticles in enhancing root Na+ exclusion, maintaining foliar K+ homeostasis and scavenging reactive oxygen species were analyzed. A full-cycle, targeted green-regulation technical system centered on a framework of ‘seed treatment for stress-resilient germination and tillering stem-strengthening chemical regulation at jointing; culm-strengthening chemical regulation at jointing to improve lodging resistance and stress resilience; flag-leaf-sustaining and grain-filling-promoting regulation during the grain-filling stage’ was proposed, offering a replicable technological route for yield enhancement and green, efficient production of drought-alkali wheat.
Facility agriculture is an effective way to efficiently utilize saline-alkali land. This paper conducts an in-depth analysis of the conditions and current situation of developing facility agriculture in the coastal heavy saline-alkali land around Bohai Sea, which clarifies three favorable factors ("not competing with grain for land and water", "safe production environment and good light and heat conditions", and "collaborative development assistance and mature technical models") and three disadvantageous factors ("small research and development platform", "weak demonstration and promotion effect", and "limited policy and financial support"). The main modes of developing facility agriculture in heavy saline-alkali land around Bohai Sea are summarized as follows: the production mode of fruits and vegetables in heavy saline-alkali area, the matrix cultivation mode of saline soil, the safe utilization mode of salt water in facility vegetables in fresh water-deficient saline-alkali area, and the high-quality production and cultivation mode of water and salt regulation of fruits and vegetables in saline soil. It proposes suggestions such as strengthening scientific and technological support, strengthening dry-alkali agriculture, and enhancing policy support, with the aim of providing references for the high-quality development of facility agriculture in the saline-alkali areas around Bohai Sea.
