The collective participation in Belt and Road Initiative expects to forego unequal integration and to start inclusive and fair development. Nepal also participates in this initiative with similar aspirations. China has linked her West Development Strategy with BRI. Nepal’s connectivity is now through Western the autonomous region of Tibet, which comes in the form of bilateral cooperation. What kind of participation in Belt and Road Initiative will give best economic benefits to Nepal? As an answer to this question, this paper proposes and argues for two distinct features: Regionality and Specificity. Regionality refers to priority concentration on the directly connected Tibet and associated role of adjoining provinces like Sichuan, Yunnan and Xinjiang. Specificity refers to the study of specific sectors like agriculture, industry, finance, tourism of these regions. The study of comparative requirement of these regions (regionality) in specific sectors (specificity) is paramount to get benefits from BRI.
3.4.Number of wireworms found in different regions of soil from plastic pots sown with wheat and trap crops in the bioassay on ten days after sowing. Chi-square values are at α 0.
Compositional dependence of optical band gap and refractive index in lead and bismuth borate glasses
A B S T R A C TWe prepared a series of lead and bismuth borate glasses by varying PbO/Bi 2 O 3 content and studied refractive index and optical band gap as a function of glass composition. Refractive indices were measured very accurately using a Brewster's angle set up while the optical band gaps were determined by analyzing the optical absorption edge using the Mott-Davis model. Using the Lorentz-Lorentz method and the effective medium theory, we calculated the refractive indices and then compared them with the measured values. Bismuth borate glasses show better agreement between the calculated values of the refractive index and experimental values. We used a differential method based on Mott-Davis model to obtain the type of transition and optical band gap (E opt ) which in turn was compared with the value of E opt obtained using the extinction coefficient. Our analysis shows that in both lead and bismuth borate glasses, the optical band gap arises due to direct forbidden transition. With increasing PbO/Bi 2 O 3 content, the absorption edge shifts toward longer wavelengths and the optical band gap decreases. This behavior can be explained in terms of changes to the Pb-O/Bi-O chemical bonds with glass composition. We obtained a new empirical relation between the optical band gap and the refractive index which can be used to accurately determine the electronic oxide polarizability in lead and bismuth oxide glasses.
Plant litter can alter ecosystems and promote plant invasions by altering resource availability, depositing phytotoxins, and transmitting microorganisms to living plants. Transmission of microorganisms from invasive plant litter to live plants may gain importance as invasive plants, which often escape pathogens upon introduction to a new range, acquire new pathogens over time. It is unclear, however, if invasive plant litter affects native plant communities by promoting disease. Microstegium vimineum is an invasive grass that suppresses native populations, in part through litter production, and has acquired new fungal leaf spot diseases since its introduction to the United States. In a greenhouse experiment, we evaluated how M. vimineum litter and its pathogens mediated competition with the native grass Elymus virginicus. M. vimineum litter promoted disease on E. virginicus and suppressed establishment and biomass of both species. Litter had stronger negative effects on E. virginicus than M. vimineum, increasing the relative biomass of M. vimineum. Live plant competition reduced biomass of both species and live M. vimineum increased disease incidence on E. virginicus. Altogether, invasive grass litter suppressed both species, ultimately favoring the invasive species in competition, and increased disease incidence on the native species.
Non-native invasive plants can establish in natural areas, where they can be ecologically damaging and costly to manage. Like cultivated plants, invasive plants can experience a relatively disease-free period upon introduction and accumulate pathogens over time. Diseases of invasive plant populations are infrequently studied compared to diseases of agriculture, forestry, and even native plant populations. We evaluated similarities and differences in the processes that are likely to affect pathogen accumulation and disease in invasive plants compared to cultivated plants, which are the dominant focus of the field of plant pathology. Invasive plants experience more genetic, biotic, and abiotic variation across space and over time than cultivated plants, which is expected to stabilize the ecological and evolutionary dynamics of interactions with pathogens and possibly weaken the efficacy of infectious disease in their control. Although disease is expected to be context dependent, the widespread distribution of invasive plants makes them important pathogen reservoirs. Research on invasive plant diseases can both protect crops and help manage invasive plant populations. Expected final online publication date for the Annual Review of Phytopathology, Volume 58 is August 25, 2020. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.
Infectious diseases and invasive species can be strong drivers of biological systems that may interact to shift plant community composition. For example, disease can modify resource competition between invasive and native species. Invasive species tend to interact with a diversity of native species, and it is unclear how native species differ in response to disease-mediated competition with invasive species. Here, we quantified the biomass responses of three native North American grass species (Dichanthelium clandestinum, Elymus virginicus, and Eragrostis spectabilis) to disease-mediated competition with the non-native invasive grass Microstegium vimineum. The foliar fungal pathogen Bipolaris gigantea has recently emerged in Microstegium populations, causing a leaf spot disease that reduces Microstegium biomass and seed production. In a greenhouse experiment, we examined the effects of B. gigantea inoculation on two components of competitive ability for each native species: growth in the absence of competition and biomass responses to increasing densities of Microstegium. Bipolaris gigantea inoculation affected each of the three native species in unique ways, by increasing (Dichanthelium), decreasing (Elymus), or not changing (Eragrostis) their growth in the absence of competition relative to mock inoculation. Bipolaris gigantea inoculation did not, however, affect Microstegium biomass or mediate the effect of Microstegium density on native plant biomass. Thus, B. gigantea had species-specific effects on native plant competition with Microstegium through species-specific biomass responses to B. gigantea inoculation, but not through modified responses to Microstegium density. Our results suggest that disease may uniquely modify competitive interactions between invasive and native plants for different native plant species.
Guinea grass is an invasive perennial C4 grass and is a common weed around agricultural crops in Louisiana, Texas, and Hawaii, USA (Overholt and Franck 2019). In November 2018, leaf spots were observed on Guinea grass occurring in an organic garden located in Gainesville, Florida, USA. Lesions were oblong to irregular, dark grey to brownish center with pale-yellow to brownish black margin. Lesions had coalesced, forming necrotic margins that spread from the leaf tip, resulting in leaf blight and collapse of the canopy. Pieces of symptomatic leaf blades (5 sq cm) were surface sterilized (1 min), washed with sterile distilled water and plated onto water agar media plates. Plates were incubated at 27°C under 12-h light/dark for 3 to 5 days. Grey to black cottony mycelium was consistent on all plates and produced conidia characteristic of Bipolaris spp. Conidia were transferred to potato dextrose agar (PDA) plates with a 0.5 mm diameter sterile needle. Three isolates GG1, GG2 and GG3 were successfully grown on PDA. Conidia were black to brown colored, distoseptate with 3 to 8 septa and measured from (60.6- )70-105(-139.8) × (16.0-)17-23(-25.9) μm (avg: 93.3 μm, n=35, SD = 20.6; avg = 21.3 μm, n = 35, SD = 2.89). Conidiophores were in groups or single, brown, smooth and straight, septate and swollen at upper tip. Sigma Extract-N-Amp was used for genomic DNA extraction. Primers ITS1/ITS4 and GPD1/GPD2 (Berbee et al. 1999) were used to amplify and sequence the internal transcribed spacer region (ITS) and partial glyceraldehyde-3-phosphate dehydrogenase (GPDH) gene, respectively. Sequences were aligned using MUSCLE and alignment was trimmed for length. Maximum likelihood phylogenetic trees were constructed with 1,000 bootstrap samples based on the K2+G substitution model, selected by BIC for these two loci using Mega X (Kumar et al. 2018). The ITS and GPDH sequences of GG1, GG2 and GG3 (Genbank accessions MT514518-20, MT576654-56), grouped with B. yamadae isolates CPC_28807 and CBS_202.29 in phylogenetic trees (Marin-Felix et al. 2017). All three isolates from Guinea grass were inoculated on Sach’s agar (Luttrell 1958) at 27°C under 12-h light/dark for a week, but no sexual morph was observed, and consistent for two repeated inoculations. To fulfill Koch’s postulates, one isolate, GG1, was used. Conidia were harvested from a one-week-old colony grown on PDA incubated at 27°C and 12-h light/dark cycle. The concentration of the conidial suspension was adjusted to 105 conidia/ml using a hemocytometer. Using a Passche H-202S airbrush sprayer, five-week-old seedlings of Guinea grass were sprayed until runoff with the conidia suspension or 0.5% tween water only. Each treatment included four replicates and the experiment was repeated. Leaf spot symptoms were observed on the seedlings inoculated with conidia, whereas seedlings sprayed with water were asymptomatic. Cultures with the expected morphology were isolated from symptomatic leaf blades and absent from control plants. To our knowledge, this is the first report of leaf spot on Guinea grass caused by B. yamadae in Florida, USA. B. yamadae was previously reported from Guinea grass in India, and from other Panicum species in the northern USA (Farr and Rossman 2019). B. yamadae was also isolated from sugarcane in Cuba and China, and corn in Japan (Manamgoda et al. 2014, Raza et al. 2019), which suggests that it has the potential to impact agronomic crops in Florida, such as sugarcane and corn.
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