Search Results (162)

Sweet sorghum, a high-quality forage and energy crop, is significantly affected by drought, the primary abiotic stress impacting its growth. Melatonin (MT) has emerged as a crucial signaling molecule in plant responses to abiotic stress. This study investigates the role of melatonin in enhancing drought tolerance in sweet sorghum, specifically using the ‘Dali Shi’ variety under polyethylene glycol (PEG)-induced drought conditions. Our findings demonstrate that exogenous melatonin application significantly increased proline content (by 27.76% and 5.95% under mild and moderate drought, respectively) while decreasing malondialdehyde (MDA) levels (by 18.33% and 35.18%, respectively). Melatonin also enhanced the accumulation of photosynthetic pigments, including chlorophyll b and total chlorophyll, and improved photosynthetic fluorescence parameters (Fv/Fm and ETR). Additionally, melatonin treatment improved root vitality, stimulated carbon and nitrogen metabolism, and increased antioxidant enzyme activity. Transcriptomic analysis revealed that differentially expressed genes were enriched in pathways related to carbon fixation, glycolysis/gluconeogenesis, nitrogen metabolism, antioxidant defense, and plant hormone signaling. Notably, melatonin upregulated key genes associated with these pathways and activated bHLH and MYB transcription factors. In conclusion, this study elucidates the mechanisms by which melatonin enhances sweet sorghum’s drought tolerance, highlighting its potential as a practical approach for improving drought resistance in this crop. Full article

Sorghum halepense is widely recognised as one of the most aggressive invasive perennial grasses affecting agricultural ecosystems worldwide. This systematic review synthesises existing scientific evidence on the ecological invasion dynamics, origin, distribution patterns, impacts on both biodiversity and livestock, and management strategies. A systematic literature review approach was employed to identify and evaluate peer-reviewed and grey literature. Relevant studies were retrieved from major scientific databases, including Google Scholar, PubMed, and ResearchGate, using predefined search terms related to S. halepense, invasion, impact on native plants and livestock, and possible control measures. Articles were screened based on relevance, methodological quality, and thematic alignment with the objectives of the review. The results showed that Johnsongrass is making a gradual invasion in South Africa through seed production and rhizome systems. Sorghum halepense alters native species composition, subsequently reduces biodiversity, and outcompetes native species. Although it may provide forage under certain conditions, its accumulation of cyanogenic compounds and nitrates poses serious poisoning risks to herbivores. Management strategies such as mechanical, burning, and chemical methods vary in terms of effectiveness. Some of these measures are influenced by the genetic make-up of the plant, costs associated with each control measure and other environmental factors. This review highlights the need for integrated management approaches that balance invasive weed control with sustainable forage production. This review emphasises the importance of adopting integrated management strategies that effectively control both seed production and underground stems. Future research should prioritise climate-responsive management approaches, improved understanding of invasion ecology, and the development of cost-effective control measures. Bringing together policy makers and specialists in weed science, natural conservation science, and animal health will be essential for reaching consensus on the actions required to curb the expansion and reduce the economic losses associated with the abundance of Sorghum halepense in our ecosystems. Full article

Brown midrib (bmr) mutants are frequently associated with unfavorable agronomic traits. In this study, we identified a novel brown midrib mutant, bmr34, which exhibited distinct brown coloration in roots, stems, and leaf midribs. Although most classic bmr mutants show undesirable agronomic performance, this mutant displays altered lignin accumulation and has important potential for forage quality and biomass utilization, providing a key genetic resource for lignin regulatory research in sorghum. Compared to the wild-type, bmr34 showed no significant differences in five major agronomic traits; however, lignin content was significantly reduced. Bulked segregant analysis (BSA) using an F₂ population derived from a cross between bmr34 and the wild type Tx623 mapped the candidate region to chromosome 4. Further sequencing analysis identified a single nucleotide substitution (C → T; reverse strand G → A) at position 5,731,348 within the 5′ splice site of the third intron of Sobic.004G071000 in the mapping interval. KASP marker analysis demonstrated complete co-segregation between the mutation site and the bmr phenotype. Sequence analysis also revealed that this G → A substitution resulted in aberrant splicing and a 33-bp insertion in the third exon, which introduced a premature stop codon. Notably, the normally spliced transcript still accounted for approximately 36.2% of total transcripts in bmr34, indicating partial retention of wild-type transcript processing. These results demonstrate that bmr34 represents a novel weak allele of Bmr6, providing new insights into splice-site mutations and their contribution to lignin biosynthesis regulation in sorghum. Full article

Photoperiod-sensitive sweet sorghum (Sorghum bicolor L. Moench) accumulates biomass and sugars during vegetative growth, making it a silage candidate where water limits maize production. This study examined how harvest date and nitrogen (N) rate affect its forage quality and in vitro rumen gas production under rain-fed conditions. In a randomized complete block design with three replications, we evaluated dry matter (DM) yield, morphology, and chemical composition of sweet sorghum harvested at 80 and 110 days after planting (DAP) under five N rates (0, 75, 150, 225, and 300 kg N/ha). Each treatment was ensiled in laboratory-scale bag silos for 90 days. Silage was analyzed for silage quality and 48-h in vitro rumen gas production and fermentation parameters. Delaying harvest from 80 to 110 DAP increased DM yield and fiber fractions (NDF, ADF, lignin), but reduced crude protein (CP), water-soluble carbohydrates (WSC), and in vitro dry matter digestibility (IVDMD) in fresh forage (p < 0.001). Increasing the N rate up to 225 kg N/ha enhanced DM yield, CP, and WSC at both harvest dates. A harvest date × N rate interaction occurred for WSC (p < 0.05). After ensiling, CP and IVDMD were higher in 80-DAP silage. Butyric acid (BA) and ammonia-N (NH₃-N) increased with N rate, but at ≥225 kg N/ha both were lower in 80 DAP silage. The highest 48-h gas production (71.2 and 61.0 mL/200 mg DM) occurred in forage and silage from 110 DAP with 150 kg N/ha. Ruminal pH remained optimal range (6.2–6.8) across treatments. Harvest date and N rate interactively influence sweet sorghum silage quality and rumen fermentability. Under rain-fed conditions, 80 DAP with 225 kg N/ha optimizes silage quality, while 110 DAP with 150 kg N/ha maximizes rumen fermentation potential. These findings support sweet sorghum as a viable silage option where maize production is constrained by water availability. Full article

Sorghum (Sorghum bicolor (L.) Moench) is an essential food, forage, and bioenergy crop that plays an irreplaceable role in modern agricultural supply systems and daily life. However, the traditional cultivation varieties, characterized by tall stems, low planting density and large panicles, are incompatible with the requirements of modern intensive agriculture for high-density planting, mechanized harvesting, and efficient resource utilization. Therefore, cultivating an ideotype suitable for mechanized harvesting is the most urgent and practical need for sorghum breeding. This paper systematically reviews the key components of the sorghum ideotype and their physiological basis, focusing on traits such as canopy structure, stalk characteristics, panicle traits, and root systems. Then, the major genes and molecular mechanisms that regulate plant height, stem strength, leaf morphology, and panicle type are described in detail. Additionally, current breeding challenges, including gene pleiotropy, trade-offs among traits, narrow genetic diversity, and limitations in phenotypic identification techniques, are summarized. Finally, we propose modern breeding strategies involving multi-omics approaches, high-throughput phenotyping, gene editing, and computational modeling to advance sorghum breeding into the design era. This will enable the simultaneous improvement in light use efficiency, lodging resistance, and adaptation to mechanized production. Full article

Intensive monoculture exacerbates soil compaction and sodification in the West Liao River Plain. This study evaluated legacy effects of diversified 3-year rotations on sodic soil health (ESP > 15%, ECe < 4 dS m⁻¹) during two subsequent maize seasons. Rotations incorporating salt-tolerant forages and deep-rooted crops (sugar beet–Echinochloa–sorghum and Echinochloa–tall fescue–silage corn) significantly reduced bulk density (8.6–13.1%) and exchangeable sodium percentage (up to 14.1 percentage points) relative to continuous monoculture. Treatments with maximum desalination (22.6% reduction) enhanced fungal α-diversity by 98.0%, while forage-dominated systems enriched Acidobacteriota by 35.2%, shifting bacterial communities toward oligotrophic dominance. Structural equation modeling confirmed that rotation effects on enzyme activity were mediated through reduced bulk density and ESP. These systems provide effective biological models for sustainable maize cultivation in sodic soils via synergistic physical-chemical-biological amelioration. Full article

Intercropping systems involving sorghum, grasses, and legumes can enhance forage production and improve sustainability under no-tillage systems. In the context of agricultural systems, the effective selection of rotational species is essential, as they contribute to soil system dynamics and provide feed for livestock. In this study, the dry matter production of grain sorghum (GS: cultivar A 9902), forage sorghum (FS: cultivar Volumax), and dual-purpose sorghum (DPS: cultivar Rancheiro) intercropped with Urochloa brizantha and dwarf pigeon pea was evaluated at five sowing densities (0 to 24 seeds m⁻¹) over two growing seasons (2018 and 2019), conducted in a randomized complete block design under autumn growing conditions. Biometric and productive traits of sorghum were assessed, as well as the dry matter production of the companion species, in order to understand interspecific interactions within the system. Sorghum dry matter yield was not affected by pigeon pea density, indicating high stability of the main crop. Grain sorghum (GS) and forage sorghum (FS) showed higher production in the first season (20,428 and 18,210 kg ha⁻¹, respectively), whereas dual-purpose sorghum (DPS) performed best in the second season (25,388 kg ha⁻¹). GS exhibited the highest panicle production, exceeding the other cultivars by up to 55%. Increasing pigeon pea density enhanced its biomass production but reduced Urochloa production by up to 50%; however, Urochloa showed better performance when intercropped with GS and FS. Sorghum morphological traits were not affected, and overall, the intercropping system maintained sorghum productivity while increasing total biomass, demonstrating potential for silage production and pasture establishment. Full article

This study examined the distribution and feeding ecology of Grey Crowned Cranes (GCCs) (Balearica regulorum gibbericeps) in the Rushebeya–Kanyabaha wetland watershed in southwestern Uganda, focusing on changes in land use and land cover (LULC) between 1986 and 2022. We documented crane distribution and foraging behaviors through field surveys and analyzed Landsat data of 1986, 1998, 2010, and 2022 using supervised classification. The findings revealed significant changes in LULC, with an increase in built-up areas and subsistence farms, while grassland, bushland, and wetland coverage steadily declined. As the human population increased, leading to a demand for food, subsistence farming emerged as the predominant land use starting in 1998. Data on crane distribution indicates that wetlands are a vital habitat for roosting and breeding; nests are typically located within 140 m of water, along the edges of wetlands, and in vegetation that averages 2.6 m in height. Subsistence farmland, primarily growing beans, potatoes, and sorghum, serves as a key food source for the cranes. The study highlights that while agricultural landscapes provide important foraging sites, crane populations are at risk due to ongoing habitat degradation and disturbances. To effectively conserve these populations, strategies that integrate sustainable land use planning within the catchment area and wetland protection will be essential. Full article

Sorghum (Sorghum bicolor) is a key cereal for food and forage security in arid and semi-arid regions, where climate change is intensifying drought stress and threatening sustainable crop production. Intercropping cereals with legumes is widely promoted as a nature-based solution to improve resource-use efficiency, nitrogen (N) cycling, and drylands’ resilience. We evaluated the performance and interactions of a novel sorghum–legume combination by intercropping sorghum with the drought-tolerant legume serradella (Ornithopus sativus) in a 10-week mesocosm experiment. Cropping systems (sorghum monocrop, serradella monocrop, and strip intercropping) were subjected to moderate or severe water stress, with or without frequent cutting. We investigated how intercropping influenced individual crop growth, N accumulation, and survival, and whether benefits at the plant level translated to the system level. Under severe water stress, sorghum maintained higher biomass and survival than serradella. Intercropping did not increase aboveground biomass or N content at the mesocosm level. However, individual sorghum plants in intercrops accumulated up to 80% more biomass and 100% more aboveground N than in monocropping. In contrast, serradella experienced reduced growth, N accumulation, and survival in intercrops. Our results reveal trade-offs in this intercrop under dryland stress, where individual crop benefits do not translate into system-level gains. Although limited to early growth and controlled conditions, the results provide valuable insights for designing resilient sorghum–legume systems, including optimizing species density, intercrop configuration, and cutting regimes in drought-prone agroecosystems. Full article

This study evaluated the effects of increasing proportions of sudangrass sorghum forage in ruminant diets, with or without polyethylene glycol (PEG), on rumen fermentation, gas and methane production, nutrient digestibility, and protein fermentation metabolites. Three experimental diets containing 20%, 40%, or 60% sorghum forage (S20, S40, and S60) were incubated in vitro with cattle rumen fluid. Incubations were performed with or without PEG used as a tannin-binding agent. After 24 h of incubation, gas and methane production, in vitro dry matter digestibility (DMD), neutral detergent fiber digestibility (NDFD), ammonia nitrogen concentration (N-NH₃), and volatile fatty acid (VFA) production and profiles were measured. Increasing sorghum inclusion resulted in a significant reduction in DMD (p = 0.0012). In contrast, NDFD increased (p = 0.0005), likely due to differences in lignin content among diets. Methane production was unaffected by the proportion of sorghum, despite the increasing tannin content. PEG supplementation significantly increased N-NH₃ concentration (p = 0.042) and isobutyric molar proportion (p < 0.0001), indicating enhanced rumen protein degradation following tannin neutralization. The total VFA concentration was not influenced by either sorghum level or PEG treatment. However, higher sorghum inclusion was associated with shifts in the VFA profiles toward higher acetate (p = 0.0023) and lower butyrate proportions (p = 0.0114). Overall, the results suggest that moderate levels of condensed tannins (CTs) in sorghum forage may alter rumen fermentation patterns without markedly reducing methane production. PEG supplementation further confirmed the biological activity of tannins, especially regarding protein metabolism. Therefore, sudangrass sorghum may be considered a viable forage option for ruminant diets, provided its inclusion level and tannin effects are carefully managed. Full article

Water and nitrogen (N) are the most critical limiting factors for sudangrass (Sorghum sudanense (Piper) Stapf) growth under drip irrigation in arid oases of southern Xinjiang, yet the quantitative interaction mechanism governing yield–quality–efficiency trade-offs remains unclear. This study employed a quadratic orthogonal regression design to generate 11 water–nitrogen treatment combinations (irrigation: 1800–4200 m³·ha⁻¹; nitrogen: 240–720 kg·ha⁻¹). Agronomic traits, dry matter yield, nutritional quality, and nitrogen use efficiency (NUE) were measured through field experiments in 2023–2024, and quadratic models were fitted to identify optimal water–nitrogen bundles maximizing multi-objective performance. Irrigation volume was the dominant factor controlling the plant height, SPAD index, and stem–leaf ratio, whereas stem diameter depended on the water × N interaction (p < 0.01). The “medium-water × moderate-nitrogen” regime (3000 m³·ha⁻¹ + 480 kg·ha⁻¹) maximized dry matter yield (~28 t·ha⁻¹), NUE (~44%) and forage quality (Relative Feed Value > 135, crude protein ≥ 8.8%). This climate-adaptive precision strategy reduces water use by 30% and nitrogen by 20% while increasing yield by 15% and quality by 15%, providing a sustainable production framework for arid and semi-arid regions of Xinjiang. Full article

The high cost of nitrogen (N) fertilizers has increased interest in sustainable alternatives, such as inoculation with Azospirillum brasilense, to improve forage production. This study evaluated the agronomic performance, yield, nutritional composition, and fermentation profile of giant sorghum silage from crops inoculated with A. brasilense under different N rates. A randomized block design was adopted in a 5 × 2 factorial arrangement, with five N rates (0, 50, 100, 200, and 400 kg ha⁻¹) and the presence or absence of A. brasilense inoculation, with four replicates. Nitrogen rates significantly affected plant height and stem diameter, with maximum values observed at 200 kg ha⁻¹ N. An interaction between inoculation and N rates was detected for first-cycle yield, in which inoculated plants showed reduced productivity at 200 and 400 kg ha⁻¹ N. Total yield was higher in non-inoculated treatments and was maximized at 200 kg ha⁻¹ N, representing a 29.42% increase compared with the unfertilized control. Crude protein concentration increased with increasing N rates, while in vitro dry matter digestibility was influenced only by N fertilization. Inoculation did not improve agronomic performance and negatively affected yield at higher N rates, although both inoculation and N fertilization influenced protein and fiber contents of sorghum silage. Under the edaphoclimatic conditions of the Brazilian Amazon, A. brasilense inoculation is not recommended for giant sorghum cultivation, whereas the application of 200 kg ha⁻¹ N was the most effective strategy to maximize yield. Full article

Sorghum (Sorghum bicolor L.) is a vital crop for both grain production and forage, playing a critical role in ensuring global food security and sustainable livestock production. Drought stress represents one of the most severe abiotic constraints in sorghum cultivation, adversely affecting plant growth and development, and ultimately leading to significant reductions in yield and quality. Melatonin has emerged as a multifaceted plant growth regulator that enhances plant growth and confers tolerance to various abiotic stresses. It actively participates in regulating key physiological processes, including seed germination, seedling establishment, cellular development, and metabolic homeostasis. This review synthesizes current knowledge on the impacts of drought stress on sorghum growth and physiological metabolism, with a specific focus on the protective role of melatonin under water-deficit conditions. The underlying physiological and molecular mechanisms are comprehensively discussed, encompassing ion homeostasis, nutrient metabolism, reactive oxygen species (ROS) scavenging, photosynthetic efficiency, energy metabolism, phytohormone crosstalk, signal transduction, and associated gene expression. Finally, we outline future research directions to advance our understanding of melatonin-mediated drought tolerance in sorghum, providing insights for breeding drought-resilient varieties and developing high-yielding cultivation strategies. Full article

Agriculture in semi-arid regions faces challenges, such as water scarcity and low soil fertility, making the forage cactus a highly important crop due to its crassulacean acid metabolism (CAM) pathway. The productivity of the forage cactus, however, depends on proper water and nutrient management, especially nitrogen. Despite its importance, there is little research into the effects of nitrogen fertilisation on productive, photochemical, physiological and biochemical parameters, or on intercropping systems. Increasing doses of nitrogen are assumed to enhance CAM pathway, improving productivity, gas exchange, photochemical efficiency and antioxidant accumulation, in addition to mitigating the effects of oxidative stress under adverse conditions. The experiment was conducted in Serra Talhada, Pernambuco, Brazil, in a randomised block design with four replications. Changes in the biometric, productive, photochemical, physiological and biochemical parameters were evaluated in forage cactus intercropped with sorghum (Sorghum bicolor) or pigeon pea (Cajanus cajan) subjected to different doses of nitrogen (0, 75, 150, 300 and 450 kg ha⁻¹). The results showed that nitrogen fertilisation promoted a higher photosynthetic rate and greater stomatal conductance, increased transpiration, and higher levels of pigment and soluble proteins, in addition to reducing lipid peroxidation. Our findings revealed that the cactus—pigeon pea intercropping system has better photosynthetic, enzymatic and productive performance at a dose of 150 kg N ha⁻¹, whereas the cactus—sorghum intercropping system required 450 kg N ha⁻¹ to achieve similar results. Overall, proper nitrogen management in intercropping systems can optimise the physiological performance and productivity of the forage cactus in semi-arid environments. Full article

In the present context of climate changes, multipurpose and stress-resistant crops tend to be widely grown in areas with severe environmental conditions, such as drought and saline-alkali land. Due to its effective adaptation to high-temperature dry conditions, Sorghum bicolor (L.) Moench is a highly resistant and versatile crop. Sorghum is cultivated as a grain, sweet stem, forage material, and broomcorn, and is a source of fuel, alcoholic and non-alcoholic beverages, and building materials. Sorghum could be part of an integrated circular economy due to its special manufacturing possibilities. Despite having plenty of beneficial properties, sorghum is not very popular all over the world. Thus, the main purpose of our study is to reveal its benefits and various manufacturing possibilities. Currently known more for being used as animal feed and for biofuel production, once popularized, sorghum could become an important vector of food security. The present study reviews the latest data, highlighting the potential of sorghum to develop new food products, noting the functional and health properties of sorghum in foods and the processing possibilities of sorghum-based products. Full article