Search Results (226)

Low solar radiation, caused by climate change or dense planting patterns, now limits wheat production. Although wheat breeding has increased lodging resistance and yield potential through the introduction of dwarfing genes, it still reduces wheat yields. Few studies have been conducted to clarify the lodging sensitivity to shading of different-era wheat cultivars in China’s Huang-Huai-Hai region, as well as the characteristics of lodging resistance as affected by paclobutrazol under shading stress. To address this gap, the experiment included two wheat cultivars released in different decades, grown under shade and treated with or without paclobutrazol. The results showed that reductions in filling degree and lignin content, together with increases in length of the basal internode and gravity center height, markedly reduced the section modulus and breaking strength of shaded wheat culms. These changes impaired lodging resistance and raised lodging risk. However, paclobutrazol application effectively reduced lodging incidence and increased wheat yield under shading stress. Furthermore, these responses were more pronounced in the old cultivar (YZM) than in the modern cultivar (S28). This indicates that the culm mechanical parameters of the old cultivar were more shade-sensitive than those of the modern cultivar. Moreover, shading downregulated the relative expression levels of key genes associated with lignin biosynthesis to decrease the activities of key enzymes, thereby inhibiting the biosynthesis and deposition of lignin in culms to increase the risk of wheat lodging. Paclobutrazol application alleviated the inhibitory effects of shading on lignin biosynthesis, thereby strengthening culms and enhancing lodging resistance. These findings may provide a basis for exploring cultivation regulation methods to enhance wheat lodging resistance under overcast and low-sunshine conditions, and to offer guidance for the breeding of wheat cultivars with lodging resistance and shade tolerance. Full article

Bamboo forests are among China’s key strategic forest resources, characterized by rapid growth and high carbon sequestration efficiency. Traditional management practices primarily aim to maximize economic benefits by regulating stand density to enhance yields of bamboo culms and shoots. However, the influence of density regulation on the growth and carbon accumulation of spring bamboo shoots remains insufficiently understood. Therefore, this study focuses on moso bamboo (Phyllostachys edulis (Carrière) J. Houzeau) stands and investigates shoot emergence during the shooting period across four stand density levels: D1 (1400 stems/ha), D2 (2000 stems/ha), D3 (2600 stems/ha), and D4 (3200 stems/ha). The study analyzes the dynamics of shoot emergence, height development, and morphological traits under varying stand densities, and explores patterns of carbon accumulation during the shooting period, thereby clarifying the effects of stand density on shoot quantity, growth quality, and carbon sequestration. The main findings are as follows: the number of emerging shoots decreased with increasing stand density, ranging from 2592 to 4634 shoots per hectare. The peak shoot emergence period in the D1 stand was extended by 3 days compared to D2 and D3, while the D4 stand entered the peak emergence period 6 days later than D2 and D3. The rapid height growth phase in D1 occurred 3 days earlier than in D2 and D3, and 6 days earlier than in D4. Results from the variable exponent taper equation indicated that spring shoots in the D2 and D4 stands had larger basal diameters, following the order D4 > D2 > D3 > D1. Shoots in the D2 stand exhibited the smallest taper, with the order being D2 < D3 < D1 < D4. During the late stage of shoot emergence (3 May to 9 May), all stands entered a period of rapid carbon accumulation per individual shoot. In the early stage, carbon accumulation followed the order D1 > D2 > D4 > D3; in the middle stage, the order shifted to D4 > D3 > D2 > D1; and in the final stage, the trend was D1 > D4 > D3 > D2. Within the 30-day investigation period, the carbon storage in spring shoots reached up to one-quarter or even one-third of the total accumulation during the growth period. The D1 stand exhibited the highest rate of increase in the proportion of individual shoot carbon storage. Full article

Phytoliths play a crucial role in plant growth and development. This paper analyzes the characterization of the culm sheath phytoliths of Bambusa vulgaris f.vittata across different geographic environments. The extraction of phytoliths was performed using microwave digestion, and the morphology of the phytolith was observed microscopically. The culm sheaths of Bambusa vulgaris f.vittata from GXNN, XSBN, GZGD, FJFZ, and FAFU Bambusa vulgaris f.vittata were selected for the study. The results indicated that the phytolith content and concentration were ranked as FJFZ > XSBN > GXNN > FAFU > GZHN, and the phytolith content and concentration were geographically significantly different. Saddle, Rondel, Silica stoma, and Scrobiculate (>70%) were observed in culm sheaths developed in different geographic environments, and phytolith morphology assemblages are largely homogeneous by genetic conservatism, but the proportion of each morphology varies across geographic environments. The main distribution of phytolith particle size ranges from 0 to 100 μm, with the highest peak in the 10–20 μm interval, followed by a decrease, and an elevation of up to 100–200 μm, followed by a significant reduction. The small size of the phytolith morphology was influenced by climatic factors. Specifically, the length, width, and area of XSBN increased with higher precipitation levels. Similarly, both the length and width of GDGZ also increased with increased precipitation. For FJFZ, the length increased with riding temperatures, while its width increased with higher precipitation. Additionally, the width of GXNN expanded with increasing temperatures. The present study supplemented the phytoliths analysis of the culm sheaths of Bambusa vulgaris f.vittata, which provided reference value for further research on the ability of Bambusa vulgaris f.vittata in carbon sequestration and other aspects, and contributed essential data for the robust development of the bamboo industry. Moreover, bamboo plants represent a significant natural solution to climate change, offering ecological, economic, and social benefits. This further encourages the protection of natural bamboo forests, the expansion of artificial cultivation, and the vigorous promotion of the bamboo industry and bamboo products. By maximizing their critical roles in forest carbon sequestration and climate regulation, bamboo plants provide a viable solution for global climate governance. Full article

Bamboo is widely distributed throughout the world, particularly in tropical and subtropical regions. This study aims to investigate the biomechanical properties of the root system of Bambusa pachinensis (Pachi bamboo). The root system of Pachi bamboo grows densely in clusters, with most roots growing vertically and potentially penetrating more than one meter into the soil after growing for several years. Owing to these characteristics, Pachi bamboo is considered a promising plant species for soil reinforcement. However, research on its root reinforcement capabilities remains limited. In situ shear and pullout tests were conducted to assess the root reinforcement of the fibrous root system. The root diameters of Pachi bamboo are typically less than 4 mm, and its tensile strength is notably lower than that of tree roots. This study establishes a method for estimating the root reinforcement of Pachi bamboo based on the number and cross-sectional area of the culms in a single bamboo cluster. The relationship between the maximum tensile force (F_ult) and root diameter (D) is F_ult = (3.65)D^2.59, where F_ult is in Newtons (N), and D is in millimeters (mm). The relationship between the pullout resistance (P_ult) and the shear resistance (S_ult) with the number of culms (SN) is P_ult = 46.5(SN) and S_ult = 0.53(SN) + 5, where P_ult is in Newtons (N), and S_ult is in kilopascals (kPa). These results suggest a positive contribution of the number of culms to mechanical resistance. Full article

UDP-glucose pyrophosphorylase (UGPase) is essential for carbohydrate metabolism, catalyzing UDP-glucose synthesis, a precursor for sucrose and cellulose biosynthesis. While UGP genes have been widely studied in plants, their functions in Dendrocalamus brandisii remain unclear. This study identified and characterized the DbUGP gene family using the whole genome and transcriptome data of D. brandisii, in conjunction with whole genome data from 10 additional species through sequence alignment, phylogenetic analysis, gene structure and motif exploration, protein structure prediction, and expression profiling. Phylogenetic analysis showed eight identified DbUGPs clustered with two OsUGPs in two clades. Gene structure, motif, and collinearity analyses indicate conservation with other bamboo UGPs. The gene family exhibited segmental duplications. Expression profiling revealed DbUGP1/5 were highly expressed in flowers, while others were enriched in shoots, buds, and culms. DbUGP1/4/8 were significantly downregulated during culm maturation. Protein structure prediction indicated two conformations with catalytic sites in disordered coil regions. WGCNA identified co-expression modules and protein interaction networks centered on DbUGP1/4, while KEGG enrichment indicated their functions in metabolism, signal transduction, and stress adaptation. Promoter analysis identified cis-regulatory elements responsive to light, MeJA, and ABA. This study suggests that the evolutionarily conserved DbUGPs exhibit mutual coordination and dynamic expression during D. brandisii growth, providing fresh insights into their functional roles. Full article

Bamboo is a green, renewable material with high strength and low cost, but raw bamboo has limited application in residential buildings due to its irregular shape and dry cracking. In this regard, this work proposed a novel ecological sandwich panel to explore the potential combination of engineered bamboo and raw bamboo culms. Face sheets made of glued laminated bamboo panels were bonded to the bamboo culm core via epoxy resin and mortise–tenon joints. Two groups of specimens with height-to-thickness ratios of 4.63 and 5.37 were tested through edgewise compression to investigate the failure modes, strength and rigidity. The results revealed that the specimens had no overall stability problem under axial loading, but exhibited delamination and local bulging to the face sheets. When the height-to-thickness ratio increased from 4.63 to 5.37, but still belonged to the short member range, the area of the adhesive interface increased by 16.13%, and the edgewise compressive strength and rigidity increased by 17.57% and 35.04%, respectively. This indicated that the capacity and rigidity were mainly determined by the connection strength, which was obviously affected by the manufacturing and assembly errors. Accordingly, increasing the connection strength could be helpful for improving the load-carrying capacity and ductility of such panels. Full article

This study focused on the phytolith characteristics of leaves and culm sheaths from nine bamboo species across three genera (Bambusa Schreb., Gigantochloa Nees, and Dendrocalamus Kurz ex Munro) in the Xishuangbanna Tropical Botanical Garden. By analyzing phytolith content, concentration, particle size distribution, morphometric parameters of elongated saddle-type phytoliths, and phytolith–assemblage composition, we aimed to elucidate the distribution patterns and morphological features of phytoliths in clumping bamboos, thereby providing morphological evidence for genus-level classification within the Bambusoideae. The results demonstrated the following. (1) Leaves exhibited significantly higher phytolith content and concentration than did culm sheaths across all genera, with Dendrocalamus being the sole exception, showing no significant intrageneric differences. (2) Distinct particle size distribution patterns were observed—leaves consistently peaked at 10–20 μm, whereas culm sheaths displayed triple peaks at 10–20 μm, 20–30 μm, and 900–1000 μm. (3) Morphometric analysis revealed that culm sheaths contained larger elongated saddle-type phytoliths (length, width, and area) compared to leaves across all genera. (4) Among the 37 identified phytolith morphotypes, culm sheaths exhibited greater diversity, with 35 types (dominated by rondel and elongate), while leaves contained 31 types primarily characterized by saddle and stomatal phytoliths, with elongated saddles being the most abundant. Collectively, our findings demonstrate significant morphological disparities between foliar and culm sheath phytoliths in sympodial bamboos (Bambusa), with culm sheath phytoliths exhibiting greater taxonomic potential for generic-level classification within the subfamily Bambusoideae. Full article

Phytoliths are widely used in plant taxonomy, paleoecology, soil silicon cycling, and agricultural archaeology. Bamboo has a strong capacity for silicon absorption, and there are some phytoliths in various organs. In this paper, the leaf organs (leaf blade, leaf sheath, culm sheath, and culm blade) of three kinds of bamboos [B. vulgaris (Bambusa vulgaris), B. tulda (Bambusa tulda), and B. dolichoclada (Bambusa dolichoclada)] were studied; the content, concentration, particle size distribution, and morphological characteristics of phytoliths in leaf organs were analyzed to explore the differences of phytoliths in different functional leaf organs of bamboo. The results showed that the content and concentration of phytoliths were the highest in the leaf sheath and the lowest in the culm sheath, and the content and concentration of phytoliths in the leaf blade and culm blade were between them. For different bamboo species, the order of phytolith content was B. dolichoclada > B. tulda > B. vulgaris, while the phytolith concentration was the opposite. The highest values of phytolith particle size peak distribution in the leaf sheaths were the opposite to those in leaf blades, culm sheaths, and culm blades. The particle sizes of phytoliths of the three bamboo species showed a similar trend. Only a few larger phytolith particle sizes were distributed in leaf blades and culm blades when they were larger than 400 μm. A total of 25 types of phytoliths were identified, and the leaf sheaths were mainly elongate and rondel phytoliths. The leaf blades are mainly saddle and rondel phytoliths with a unique phytolith morphology. Culm sheaths are dominated by rondel, scrobiculate, and acute phytoliths. Culm blades are similar to leaf blades but have a characteristic phytolith morphology. In addition, saddle phytoliths were the most abundant in the leaf blade and the least in the culm sheath, while rondel phytoliths were the most abundant in the culm blade and the least in the leaf sheath. The parameters of long-saddle phytoliths are different in different bamboo species and leaf organs. According to the long saddle phytolith parameters of different bamboo species, different bamboo species can be quantitatively distinguished to a certain extent. Therefore, this study not only helps to understand the differences in phytoliths in different bamboo species and leaf organs, but also provides a theoretical basis for bamboo species classification. Full article

Hydrogel-based adsorbents have gained increasing recognition in recent years due to their promising potential for pollutant removal. However, conventional hydrogels often suffer from low mechanical strength over prolonged use. Therefore, this study explores the incorporation of silica extracted from bamboo culm (Dendrocalamus asper) to enhance the mechanical stability of hydrogel beads composed from carboxymethyl cellulose (CMC), chitosan (CS), and magnetite ferrofluid (Fe₃O₄), through cross-linking. We hypothesize that silica enhances the mechanical properties of magnetite hydrogel beads without compromising their adsorption capacity. The extracted silica was confirmed with FTIR and EDS analysis. The synthesized CMC-CS-Fe₃O₄-Si hydrogel beads were characterized using FTIR and SEM. Its stability was assessed through dry weight loss measurements, while its adsorption efficiency was evaluated using batch adsorption experiments. The silica-incorporated hydrogel exhibited enhanced mechanical and thermal stability under various pH and temperature conditions, without negatively affecting its adsorption performance, achieving maximum adsorption capacities of 53.00 mg/g for Cr (VI) and 85.06 mg/g for Cu (II). Desorption and regeneration studies confirmed the reusability of the hydrogel for more than four cycles. Overall, the interaction between the hydrogel and silica resulted in excellent adsorption performance, improved mechanical properties, and long-term reusability, making this a promising hydrogel adsorbent for wastewater remediation. Full article

Timely harvest is pivotal for the pasture management of tall wheatgrass, which has recently been suggested for coastal saline and alkaline soils. In this work, different culm parts in the top three internodes of tall wheatgrass during various heading stages were investigated to explore the precise harvesting time for the first cut, factors influencing forage quality, and correlations between the expression levels of genes involved in cellulose and lignin biosynthesis and forage nutritive value. The results show that the culms clipped at the half heading stage produced the highest crude protein (CP) yield. The top three leaves contributed the greatest proportion of total culm CP yield, accounting for 49%, 40%, and 30% of total culm CP yield at the just, half, and full heading stages, respectively. By contrast, the leaves and spikes produced lower yields of neutral detergent fiber (NDF), acid detergent fiber (ADF), acid detergent lignin (ADL), crude cellulose (CC), and hemicellulose (HC) than leaf sheaths and stems, indicating that the leaf/stem ratio can be used as an index for the cultivation and genetic improvement of tall wheatgrass. The lignin and cellulose biosynthesis genes expressed differentially in different culm parts of tall wheatgrass in response to the heading stage. The expression levels of HCT, encoding a hydroxycinnamoyl CoA:shikimate hydroxycinnamoyl transferase, were negatively correlated with the CP content and relative feed value, but positively correlated with the yields of dry matter, NDF, ADF, CC, and HC, suggesting that it may be used as a marker gene linked to the forage quality of tall wheatgrass. Full article

Bamboo has recently garnered international recognition for its nutritional and medicinal properties, which contribute significantly to the culinary, pharmaceutical, and cosmeceutical sectors. Every component of the bamboo plant—rhizome, culm, bark shavings, shoots, leaves, roots, and seeds—possesses useful applications. Bamboo shoots, as a type of food, have been consumed for a long time due to their nutritional and edible qualities, as well as their economic value. Other parts of bamboo, such as leaves and culms, can also be used in food applications. Commercial markets in various countries offer a variety of bamboo-based products, including those that are dried, fermented, pickled, and thermally processed. This article provides an overview of the use of all edible bamboo parts as foods and related products as well as their nutritional benefits. A wide range of traditional food products derived from bamboo, including industrial products and some novel products, was investigated. It is possible that the promotion of bamboo as a staple food could offer substantial promise in addressing the worldwide concerns regarding hunger, food insecurity, and environmental degradation. Full article

The research on rice lodging resistance holds immeasurable value for achieving high yield, stable production, and superior quality of rice. To investigate the effects of mechanical properties and physicochemical characteristics of Japonica hybrid rice on its lodging resistance ability under natural field cultivation conditions, LY1052, LY9906, and GY1, which were mainly popularized in northern China, were selected as the experimental subjects, and NL313, Japonica hybrid rice prone to lodging, was taken as the control (NL313).The max bending force, breaking moment, bending section coefficient, single stem weight mass moment, bending strength, Young’s elastic modulus, inertia moment, and other mechanical indexes were measured by the bending test and tensile test, and the correlations between mechanical indexes, physicochemical indexes, and lodging index were studied. There was an extremely significant difference in the lodging index of experimental subjects and control (NL313) (p < 0.05). Therefore, it was concluded that the lower plant height and lighter panicle were not the stronger lodging resistance under appropriate cultivation conditions. Optimization of rice plant-type structure can achieve the unity of high culm and high yield. The lodging resistance of rice could be improved by shortening the internode length, increasing the tissue thickness and vascular bundle area, and increasing the content of cellulose and potassium in the stem. It was also found that the lodging resistance of rice plants was positively correlated with the maximum stem bending force, breaking moment, bending section coefficient, bending strength, and Young’s elastic modulus (p < 0.01) and negatively correlated with single stem weight mass moment and inertia moment (p < 0.01). It is feasible to select them as reference indexes of the lodging resistance of rice. The experimental results not only help to enrich the theoretical system of rice lodging resistance research but also provide an essential reference and basis for formulating scientific cultivation and management measures and breeding lodging-resistant rice varieties in practical production, which is of great significance for ensuring global food security and promoting sustainable agricultural development. Full article

Bamboo is an efficient silicon accumulator with diverse phytolith morphotypes and composition. The bamboo culm sheath, traditionally considered as a modified leaf, plays a key role in bamboo taxonomy and provides significant mechanical and physiological support for shoot development, but its silicon deposition and phytolith morphological variation remain underexplored. We investigated silicon variation and phytolith morphology in D. brandisii culm sheaths at different growth stages. The results showed that silicon deposition in D. brandisii culm sheaths at different growth stages was comparable to foliage leaves but significantly greater than branches as in previous research. Phytolith concentration in the culm sheath blades of D. brandisii was higher, associated with their greater silicon content than the sheath bodies. Silicon precipitated and phytoliths were produced as the culm sheath matured. Silicon and phytolith contents were significantly greater in upper culm sheath bodies. D. brandisii culm sheaths were characterized by a high proportion of rondel phytoliths, whereas bilobate and bulliform flabellate phytoliths were not observed. Circular and saddle phytoliths accounted for a very low proportion. Stomata phytoliths were abundant in culm sheaths at the shooting stage and increased with sheath maturation, which supported the transpiration, respiration and photosynthesis in culm sheaths of the shoots. Elongate and acute phytoliths were extremely abundant in D. brandisii culm sheaths and increased with sheath maturation, which enhanced the mechanical and protective role of the culm. The phytolith morphotypes in D. brandisii culm sheaths did not demonstrate a specific trend with sheath position. Saddle phytoliths showed insignificant variation in D. brandisii culm sheaths. Full article

The overuse of chemical fertilizers under adverse conditions endangers the sustainability of agriculture. A biological approach should be investigated to address this issue. Therefore, this study aimed to detect the potency of purple non-sulfur bacteria that can fix nitrogen (N) (PNSB-fN) Rhodobacter sphaeroides in soil N fertility, plant N uptake, growth, and rice yield. In brief, an experiment was conducted to check whether the biofertilizer containing PNSB-fN strains can improve rice yield and soil fertility under a highly saline acidic condition. A randomized complete block design was used with four replicates on saline soil in An Bien-Kien Giang, Vietnam. The first factor was the N fertilizer level, i.e., (i) 100%, (ii) 75%, (iii) 50%, and (iv) 0%; the second factor was the PNSB-fN (R. sphaeroides), i.e., (i) the control, (ii) S01, (iii) S06, and (iv) combined S01–S06. In the results, supplying PNSB-fN increased NH₄⁺ compared with the control, i.e., 104.7–112.0 mg NH₄⁺ kg⁻¹ compared with 94.0 mg NH₄⁺ kg⁻¹ in season 1 and 35.9–38.0 mg NH₄⁺ kg⁻¹ compared with 34.2 mg NH₄⁺ kg⁻¹ in season 2. Additionally, by supplying each PNSB-fN strain, the soil Na⁺ and plant Na in culm leaf and grain were decreased in comparison with those in treatments without PNSB-fN. The total N uptake was also enhanced by the PNSB-fN compared with the control. Moreover, supplying PNSB-fN improved the crop height, panicle length, panicle quantity pot⁻¹, grain quantity panicle⁻¹, filled spikelet rate, and grain yield compared with the control. Ultimately, in extremely saline soil, the mixture of PNSB-fN not only improved soil fertility and reduced soil salinity but also replaced 25% of chemical N fertilizer to ensure sustainable agriculture. This newly developed biofertilizer was potent in not only improving the rice and soil health in the locality but also performing the same under similar conditions around the globe. Full article

Bamboo forests with high potential carbon storage have been found worldwide. Makino bamboo is critical, with a broad area of plantations distributed around Taiwan. This study established a thinning trial to monitor aboveground carbon storage (AGCS) and aimed to develop a carbon yield model for this bamboo species based on the Weibull function. Four thinning treatments, each replicated four times, were applied in this study. We collected data in 2019 after thinning and in 2021. We used the allometric function to predict the AGCS and the Weibull function to quantify the diameter distribution for each record. The culm number (N) and the parameters of the Weibull function were employed as independent variables to develop the AGCS model. The results showed that using N as a variable had an 83.6% predictive capability (R_adj² = 0.836). When adding the parameters b and c of the Weibull function to the model, the predictive capability can improve to 93.9% (R_adj² = 0.939). This confirmed that adding the parameters of the Weibull function helped promote AGCS prediction for Makino bamboo. Moreover, the advantages of this model are that it not only shows AGCS but also displays the diameter distribution. Full article