Thermal time models are useful to determine the thermal and temporal requirements for seed germination. This information may be used as a criterion for species distribution in projected scenarios of climate change, especially in threatened species like red cedar. The objectives of this work were to determine the cardinal temperatures and thermal time for seeds of Cedrela odorata and to predict the effect of increasing temperature in two scenarios of climate change. Seeds were placed in germination chambers at constant temperatures ranging from 5 ± 2 to 45 ± 2 °C. Germination rate was analyzed in order to calculate cardinal temperatures and thermal time. The time required for germination of 50% of population was estimated for the current climate, as well as under the A2 and B2 scenarios for the year 2050. The results showed that base, optimal and maximal temperatures were −0.5 ± 0.09, 38 ± 1.6 and 53.3 ± 2.1 °C, respectively. Thermal time (θ1(50)) was 132.74 ± 2.60 °Cd, which in the current climate scenario accumulates after 5.5 days. Under the A2 scenario using the English model, this time is shortened to 4.5 days, while under scenario B2, the time is only 10 hours shorter than the current scenario. Under the German model, the accumulation of thermal time occurs 10 and 6.5 hours sooner than in the current climate under the A2 and B2 models, respectively. The seeds showed a wide range of temperatures for germination, and according to the climate change scenarios, the thermal time accumulates over a shorter period, accelerating the germination of seeds in the understory. This is the first report of a threshold model for C. odorata, one of the most important forest species in tropical environments.
Thermal Niche for Seed Germination and Species Distribution Modelling of Swietenia macrophylla King (Mahogany) under Climate Change Scenarios
Swietenia macrophylla is an economically important tree species propagated by seeds that lose their viability in a short time, making seed germination a key stage for the species recruitment. The objective of this study was to determine the cardinal temperatures and thermal time for seed germination of S. macrophylla; and its potential distribution under different climate change scenarios. Seeds were placed in germination chambers at constant temperatures from 5 to 45 °C and their thermal responses modelled using a thermal time approach. In addition, the potential biogeographic distribution was projected according to the Community Climate System Model version 4 (CCSM4). Germination rate reached its maximum at 37.3 ± 1.3 °C (To); seed germination decreased to near zero at 52.7 ± 2.2 °C (ceiling temperature, Tc) and at 12.8 ± 2.4 °C (base temperature, Tb). The suboptimal thermal time θ150 needed for 50% germination was ca. 190 °Cd, which in the current scenario is accumulated in 20 days. The CCSM4 model estimates an increase of the potential distribution of the species of 12.3 to 18.3% compared to the current scenario. The temperature had an important effect on the physiological processes of the seeds. With the increase in temperature, the thermal needs for germination are completed in less time, so the species will not be affected in its distribution. Although the distribution of the species may not be affected, it is crucial to generate sustainable management strategies to ensure its long-term conservation.
Chia (Salvia hispanica L.) Seed Soaking, Germination, and Fatty Acid Behavior at Different Temperatures
The temperature reduces the viability and seed vigor; however, the effect of temperature on imbibition and fatty acid profile has not been studied. Chia (Salvia hispanica L.) seeds have a substantial quantity of oil, making them a potential study model for fatty acid metabolism. Therefore, we explore the effect of temperature (10, 20, and 30 °C) on chia seed imbibition, germination, and fatty acid profile by GC-MS. Imbibition FI occurs within the first hour in all the treatments; while FII and FIIend elapse with an hour of difference at 20 °C and 30 °C. The highest viability and germination rate were observed at 30 °C; while the highest concentrations of all fatty acids, except oleic acid, were observed at 20 °C. Maximum fatty acid concentrations were detected at FI and FIIend; while at 30 °C, different patterns for saturated and unsaturated fatty acids and three linolenic acid isomers were observed. A shorter FII is associated with earlier germination; the increase in concentration in fatty acids after 3 h and a negative correlation between linoleic and linolenic acid observed at 20 °C were related to a higher germination efficiency. At 30 °C, isomer formation is related to homeoviscous cell membrane adaptation.
Quantifying Cardinal Temperatures of Chia (Salvia hispanica L.) Using Non-Linear Regression Models
Temperature is the main factor that impacts germination and therefore the success of annual crops, such as chia (Salvia hispanica L.), whose seeds are known for their high nutritional value related to its oil. The effect of temperature on germination is related to cardinal-temperature concepts that describe the range of temperature over which seeds of a particular species can germinate. Therefore, in this study, in addition to calculated germinative parameters such as total germination and germination rate of S. hispanica seeds, the effectiveness of non-linear models for estimating the cardinal temperatures of chia seeds was also determined. We observed that germination of S. hispanica occurred in cold to moderate-high temperatures (10–35 °C), having an optimal range between 25 and 35 °C, with the highest GR and t50 at 30 °C. Temperatures higher than 35 °C significantly reduced germination. Output parameters of the different non-linear models showed that the response of chia germination to temperature was best explained by beta models (B). Cardinal temperatures calculated by the B1 model for chia germination were: 2.52 ± 6.82 °C for the base, 30.45 ± 0.32 °C for the optimum, and 48.58 ± 2.93 °C for the ceiling temperature.
Diversidad y estructura del bosque de galería del río Fuerte, Sinaloa, México
El río Fuerte es la corriente hidrológica más importante del norte de Sinaloa, su riqueza biológica forma parte del patrimonio biocultural del pueblo Yoreme-Mayo y es fundamental para su bienestar. Sin embargo, la contaminación, fragmentación y pérdida de biodiversidad están impactando de forma negativa su funcionalidad. Por lo anterior, el objetivo fue evaluar y describir la diversidad y la estructura de la vegetación asociada al bosque de galería del río Fuerte. Se establecieron 41 parcelas circulares de 0.1 ha, en las que se tomaron datos dasométricos (altura, diámetro normal y cobertura de la copa). La estructura se caracterizó mediante la distribución diamétrica y la altura, empleando el índice de valor de importancia. La diversidad se evaluó con los índices de Equidad (E), Margalef (DMg), Simpson (D) y Shannon-Wiener (H’). Se registraron 27 especies de las que 16 son nativas. La familia Fabaceae fue la más representada con 11 especies, seguida de Salicaceae con dos. El estrato arbóreo tuvo un valor de importancia del 79.18% y de 14.11% para el arbustivo. El 60% de los árboles se agrupó en la categoría diamétrica de 5 y el 74% en las categorías de 5 y 10 dealtura. Las especies de mayor importancia ecológica para el ecosistema ribereño fueron Populus mexicana, Pithecellobium dulce y Prosopis juliflora. El río Fuerte presentó una diversidad alta con dominancia del estrato arbóreo y una población con estructura juvenil, característica de un ecosistema con presencia de disturbios por actividades humanas.
Potential Distribution of Cedrela odorata L. in Mexico according to Its Optimal Thermal Range for Seed Germination under Different Climate Change Scenarios
Cedrela odorata is a native tree of economic importance, as its wood is highly demanded in the international market. In this work, the current and future distributions of C. odorata in Mexico under climate change scenarios were analyzed according to their optimal temperature ranges for seed germination. For the present distribution, 256 localities of the species’ presence were obtained from the Global Biodiversity Information Facility (GBIF) database and modelled with MaxEnt. For the potential distribution, the National Center for Atmospheric Research model (CCSM4) was used under conservative and drastic scenarios (RCP2.6 and RCP8.5 Watts/m2, respectively) for the intermediate future (2050) and far future (2070). Potential distribution models were built from occurrence data within the optimum germination temperature range of the species. The potential distribution expanded by 5 and 7.8% in the intermediate and far future, respectively, compared with the current distribution. With the increase in temperature, adequate environmental conditions for the species distribution should be met in the central Mexican state of Guanajuato. The states of Chihuahua, Mexico, Morelos, Guerrero, and Durango presented a negative trend in potential distribution. Additionally, in the far future, the state of Chihuahua it is likely to not have adequate conditions for the presence of the species. For the prediction of the models, the precipitation variable during the driest month presented the greatest contribution. When the humidity is not limiting, the thermal climatic variables are the most important ones. Models based on its thermal niche for seed germination allowed for the identification of areas where temperature will positively affect seed germination, which will help maximize the establishment of plant populations and adaptation to different climate change scenarios.
Potencial de los aceites esenciales en el control de Phytophthora cinnamomi Rands y Fusarium sp. in vitro en Cinnamomum verum
La canela (Cinnamomum sp.) es una especie con algunas limitantes sanitarias pero significativas, siendo Phytophthora cinnamomi y Fusarium sp. las de mayor importancia que afectan la raíz. Su control con fungicidas sintéticos ha favorecido el desarrollo de resistencia debido a su mal manejo, por lo que su control con aceites esenciales es una alternativa viable. El objetivo fue determinar el potencial antifúngico de los aceites esenciales de tomillo y clavo para el control de P. cinnamomi y Fusarium sp. aislados de Cinnamomum verum. Se evaluaron concentraciones de 60, 120 y 300 µL L-1 para los dos aceites esenciales. Los datos registrados sobre la tasa de crecimiento radial micelial de los patógenos después de la incubación de Fusarium sp. a 25 ± 1 °C y 28 ± 1 °C tuvo diferencia significativa en las concentraciones ensayadas. P. cinnamomi, no creció radialmente con la concentración de 300 µL L‑1, mientras que con 120 µL L-1 la tasa de crecimiento fue de 0.06 mm por día. En tanto, con Fusarium sp. se inhibe por completo el crecimiento micelial con las dosis de 120 y 300 µL L-1 de aceites esenciales. Con el aceite de tomillo se observó una tendencia similar en las concentraciones 120 y 300 µL L-1 con mayor efecto de inhibición de los dos patógenos. La dosis de 300 µL L-1 de los dos aceites esenciales son capaces de inhibir en su totalidad (P ≤ 0.05) el crecimiento de ambos patógenos. En una concentración máxima de 280 esporas de ambos patógenos; se observó que, el número de esporas se reduce hasta 73 esporas con 300 µL L-1 de aceite de tomillo. Por tanto, pueden ser una alternativa preventiva en el control de enfermedades de la raíz en canela.
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