Apolygus lucorum is one of the most important piercing-sucking insect pests of tea plant. In this study, we assessed the impact of intercropping young tea plants with garden pea Pisum sativum on the populations of A. lucorum and natural enemies, tea plant growth and metabolites, and soil nutrient status of tea plantation. Intercropping with flowering P. sativum var. arvense reduced the population density of A. lucorum, particularly between June 1, 2020, and June 15, 2021, with a peak reduction of 90.87%. The percentage of A. lucorum-damaged tea leaves in the tea-pea intercropping was also reduced, with the maximum reduction of 8.96% observed on June 15, 2021, in the intercropping group compared to the control. The tea-P. arvense intercrop had a minor impact on the populations of natural enemies, such as coccinellids, parasitoids, and syrphids in the tea plantations. The tea-pea intercropping increased the contents of soluble sugar, tea polyphenols, caffeine, and anthocyanins, and decreased the contents of free amino acids and catechins of the tea plant leaves, and finally improved the quality of tea. Effective phosphorus and quick acting potassium decreased significantly in the plots intercropped. Our research indicated that tea-pea intercropping has the potential to manipulate the population of A. lucorum and tea leaf damage, and improve tea quality, while also enhancing soil fertility in tea plantations. The findings from this study offer important insights into the use of intercropping as a sustainable agricultural practice.

This research investigated the impact of various mixed sowing combinations on soil nutrients and grass yield within the rhizosphere across different seasons. Three varieties of leguminous forages-Medicago sativa 'Gannong No. 3' (GN3), M. sativa 'Gannong No. 9' (GN9), and M. sativa 'Juneng No. 7' (JN7)-as well as three varieties of grasses-Leymus chinensis 'Longmu No. 1' (LC), Agropyron mongolicum 'Mengnong No. 1' (AC), and Bromus inermis 'Yuanye' (BI)-were used as experimental materials for mixed sowing combinations; the monocultures of each material served as controls. We explored the seasonal effects of different legumes and grasses intercropping combinations on rhizosphere soil nutrients and grass yield in the Hexi Corridor region of China. The results indicated that the levels of soil enzyme activity, microbial biomass, and soil nutrients in the rhizosphere across the various treatments followed the following sequence: summer > spring > autumn. The soil enzyme activities and microbial biomass of various mixed sowing combinations were significantly higher than those of the monocultures within the same growing season (p < 0.05). Specifically, the activities of alkaline phosphatase (APA), catalase (CAT), soil microbial biomass carbon (SMBC), soil microbial biomass nitrogen (SMBN), soil microbial biomass phosphorus (SMBP), soil organic matter (SOM), available nitrogen (AN), available phosphorus (AP), and available potassium (AK) within the GN9+BI group were the highest among all treatments. The hay yields of GN3, GN9, and JN7 were markedly greater than those of their respective mixed sowing combinations (p < 0.05). Correlation analysis revealed a positive relationship between enzyme activities, microbial biomass, and soil nutrient levels. This comprehensive evaluation indicated that the mixed sowing combinations of GN9 + BI and GN9 + LC are particularly well suited for widespread adoption in the Hexi Oasis irrigation area.

Cover crops are increasingly recognized for their role in enhancing the multifunctionality and health of soil. Previous studies have focused largely on the effects of cover crop residues and have overlooked the impacts of living cover crops on the soil biochemical processes and nutrient cycling. The aim of this study is to bridge this gap by examining the effects of different types of living cover crops, such as legumes, grass, and their mixtures, on the soil nutrients and microbial communities. We conducted a field experiment in northeastern China using an Alfisol and intercropped cover crops with maize. During the growing season, we characterized microbial biomass and community structure using phospholipid fatty acid (PLFA) analysis and assessed microbial activity through enzyme activities related to carbon (C), nitrogen (N) and phosphorus (P). Additionally, we employed the enzyme vector model to evaluate potential microbial metabolic limitations. Compared with the control plots without cover crops, the legume treatment significantly increased dissolved organic carbon (DOC) and available nitrogen, particularly altering the microbial community structure during the maize growth stages. This change shifted the microbial functional group ratios towards enhanced C acquisition by soil microbes, indicating alleviated microbial C limitation in legume treatment. In contrast, the grass treatment maintained the soil organic carbon (SOC) and total nitrogen (TN) levels, and increased the total microbial biomass at the later growth stage. Compared with those in the other treatments, the biomass of bacterial groups in the grass treatment was more responsive, and the activities of the C, N and P enzymes were higher. Furthermore, the mixture treatment merged the benefits of both the legume and grass cover crops, enhancing both DOC and available N contents and maintaining SOC and TN levels. The mixture treatment significantly affected the microbial community structure without altering microbial nutrient limitations. Thus, the mixture treatment is recommended for application in cover crop-maize intercropping systems. In conclusion, our study captured the temporal dynamic shifts in the microbial functional groups associated with different microbial life strategies from intercropping different types of living cover crops with maize. This research refines our understanding of the role of cover crops in supporting belowground ecosystems and highlights the importance of living mulch in sustainable agricultural management.

Perennial planting of kiwifruit can easily lead to soil quality deterioration. To mitigate the negative effects of long-term kiwi cultivation on the soil, spring wheat straw is used to return to the field. The results showed that the longer the duration of straw returning to the field, the more pronounced the effect on soil quality improvement. The contents of SOM, AP, TN, and Alkaline-N were significantly higher in the Y10 plot (10-year-old kiwifruit plot) than in the Y1 plot (1-year-old kiwifruit plot) and the Y6 plot (6-year-old kiwifruit plot). The contents of these nutrients are 189.16%, 110.91%, 98.65% and 41.03% higher than Y1, respectively. Straw returning increased soil nutrients and enzyme activities (S-NP, S-SC and S-CL) and reduced soil acidification. Straw-returning treatment also enriched beneficial microbial groups (Ascomycota, Basidiomycota, Streptophyta, Mucoromycota, etc.) and changed functional groups and cellulolysis related to environmental stress. PLS-PM analysis showed that the years of straw returning to the field affected soil microorganisms' composition and functional adaptability by affecting soil nutrients and enzyme activities. These findings provide a feasible way to solve the problem of soil quality damage caused by long-term planting of kiwifruit.

Generally, with increasing elevation, there is a corresponding decrease in annual mean air and soil temperatures, resulting in an overall decrease in ecosystem carbon dioxide (CO2) exchange. However, there is a lack of knowledge on the variations in CO2 exchange along elevation gradients in tundra ecosystems. Aiming to quantify CO2 exchange along elevation gradients in tundra ecosystems, we measured ecosystem CO2 exchange in the peak growing season along an elevation gradient (9-387 m above sea level, m.a.s.l) in an arctic heath tundra, West Greenland. We also performed an ex-situ incubation experiment based on soil samples collected along the elevation gradient, to assess the sensitivity of soil respiration to changes in temperature and soil moisture. There was no apparent temperature gradient along the elevation gradient, with the lowest air and soil temperatures at the second lowest elevation site (83 m). The lowest elevation site exhibited the highest net ecosystem exchange (NEE), ecosystem respiration (ER) and gross ecosystem production (GEP) rates, while the other three sites generally showed intercomparable CO2 exchange rates. Topography aspect-induced soil microclimate differences rather than the elevation were the primary drivers for the soil nutrient status and ecosystem CO2 exchange. The temperature sensitivity of soil respiration above 0 degrees C increased with elevation, while elevation did not regulate the temperature sensitivity below 0 degrees C or the moisture sensitivity. Soil total nitrogen, carbon, and ammonium contents were the controls of temperature sensitivity below 0 degrees C. Overall, our results emphasize the significance of considering elevation and microclimate when predicting the response of CO2 balance to climate change or upscaling to regional scales, particularly during the growing season. However, outside the growing season, other factors such as soil nutrient dynamics, play a more influential role in driving ecosystem CO2 fluxes. To accurately upscale or predict annual CO2 fluxes in arctic tundra regions, it is crucial to incorporate elevation-specific microclimate conditions into ecosystem models.

Studies have reported the important role of soil properties in regulating insect herbivory under controlled conditions or at relatively large scales. However, whether fine-scale variation of soil properties affects insect herbivory under natural conditions in forests is still unclear. We selected a ca. 300 ha Quercus variabilis forest area where the leaf damage was mainly caused by Lampronadata cristata (Lepidoptera: Notodontidae) and set 200 10 x 10 m plots within the area. We examined insect herbivory (percent leaf area damaged) on Q. variabilis and correlated it to soil properties and tree characteristics. Insect herbivory decreased with soil sand percentage and bulk density and increased with DBH and tree height. Effects of soil sand percentage and bulk density on insect herbivory were partly mediated by DBH and tree height. Our results indicated that soil physical properties may have significant effects on insect herbivory by directly influencing insect herbivores that need to complete their life cycle in the soil, or by indirectly affecting insect herbivores through influencing DBH and tree height which reflects the total leaf biomass available to the insect herbivore. This study may help to understand the complex relationship between soil and plant-insect interactions in forest ecosystems.

Stress in plants denotes the detrimental impact of alterations in external environmental conditions on regular plant growth and development. Plants employ diverse mechanisms to mitigate or evade nutritional stress-induced damage. In order to investigate the physiological response mechanism of plants to nutritional stress and assess its impact on soil nutrient content and antioxidant enzyme activity in rice, a field experiment was conducted applying five treatments: control, nitrogen (N) deficiency, phosphorus (P) deficiency, potassium (K) deficiency, and full fertilization. Rice leaf and soil samples were concurrently gathered during both the vegetative and reproductive growth stages of rice. Analysis was conducted on soil N, P, and K levels, as well as leaf antioxidant enzyme activities, to investigate the impact of nutrient stress on rice antioxidant enzymes and soil fertility. The research findings indicate that full fertilization treatment enhanced the agronomic properties of the soil compared to the control treatment. In the N-deficiency treatment, reactive oxygen species (ROS) levels increased by 16.53-33.89% during the reproductive growth period compared to the vegetative growth period. The peroxidase (POD) activity decreased by 41.39% and superoxide dismutase (SOD) activity increased by 36.22% under K-deficiency treatment during the reproductive growth period compared to the vegetative growth period. Consequently, applying N and P fertilizer during the vegetative growth period can decrease membrane lipid peroxidation levels by 7.34-72.53%. The full fertilization treatment markedly enhanced rice yield compared to other treatments and increased the Nitrogen activation coefficient (NAC) and Phosphorus activation coefficient (PAC) in the soil, while decreasing the PAC. Elevating NAC levels can stimulate the activity or content of PRO, MDA, and RPS during the vegetative growth stage, whereas in the reproductive growth stage, it will decrease the content of ROS, PRO, and MDA. This data offers valuable insights and theoretical support for nutritional stress research.

The carbon stock stored within the biomass of tree species is vital in the forest ecosystem as it contributes significantly to the carbon balance. In addition, the physicochemical properties of soil play a critical role in influencing overall ecosystem health. In the present study the carbon stock and influence of seasonal change on soil physicochemical properties along soil depths in the Shivpuri Nagarjun National Park (SNNP), Nepal were analyzed. The above-ground biomass carbon stock was found to be 227.09 t/ha and below-ground stock was 45.42 t/ha. Tree species Castanopsis tribuloides exhibited the highest values of above and below-ground tree carbon stock. The soil of the study site was sandy loam and slightly acidic. High temperature and moisture in the monsoon season were followed by an increased bulk density during the pre-monsoon with deeper soil layers. The sand, silt, and clay contents did not differ significantly across the seasons and depths. The key soil nutrients, like carbon, total nitrogen, phosphorus, and potassium were high during the monsoon season at the topsoil layer, which gradually declined with increasing depth in all seasons. The study highlights that the total tree carbon stock in the study site is 272.51 t/ha, with significant seasonal and depth-related variations in soil attributes. The monsoon season, characterized by maximum soil moisture and higher concentrations of essential soil components, is crucial in influencing soil physicochemical properties and offers important insights for forest conservation and management.

Termite mounds are keystone structures in African savannas, affecting multiple ecosystem processes. Despite the large size of termite mounds having the potential to modify conditions around them, patterns of mound-induced ecosystem effects have been assumed to be isotropic, with little attention given to how effects might vary around mounds. We measured soil nitrogen content, grass species composition, and mammalian grazing on and off termite mounds in the four cardinal directions, and across wet and dry seasons at three savanna sites varying in mean annual rainfall in South Africa's Kruger National Park. Evidence of directional effects (anisotropy) on ecosystem properties around termite mounds varied with site. Grass species composition differed between north- and south-facing slopes at the two drier sites where mounds were taller. However, differences in grazing extent and soil nitrogen content around mounds were only present at the intermediate rainfall site where mammalian herbivore biomass was highest, and mounds were of medium height. Our results suggest that termite mound effects display significant variation with direction, but that the emergence of directional effects is context dependent. Our results further suggest that such context-dependent directional effects can lead to positive feedback loops between termites, abiotic conditions, and mammalian herbivores.

Sabina chinensis is a typically heteromorphic leaf evergreen tree worldwide with both ornamental and ecological value. However, the shaping mechanism of heteromorphic leaves of S. chinensis and its adaptability to environment are important factors determining its morphology. The morphological change of S. chinensis under different habitats (tree around) and treatments (light, pruning and nutrients) was investigated. Our findings suggested that the prickle leaves proportion was associated with low light intensity and soil nutrient scarcity. Stems and leaves are pruned together to form clusters of large prickle leaves, while only pruning leaves often form alternately growing small prickle leaves and scale leaves, and the length of the prickle leaves is between 0.5 cm and 1 cm. The gene expression of prickle leaves is higher than that of scale leaves under adverse environmental conditions, and the gene expression correlations between small prickle leaf and scale leaf were the highest. Homologous and heterologous mutants of gene structure in prickle leaves were larger than those in scale leaves. Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway showed that phenylpropanone and flavonoid biosynthesis were common enrichment pathways, and that the enrichment genes were mainly related to metabolism, genetic information processing and organismal systems. Therefore, we concluded that the occurrence of the heteromorphic leaf phenomenon was related to the changes in photosynthesis, mechanical damage and nutrient supplementation. The organic matter in the S. chinensis prickle leaves was reduced under environmental stresses, and it will be allocated to the expression of prickle leaf or protective cuticles formation.