Explore the vast range of titles available.

Defoliation, often caused by herbivory, is a common cause of biomass loss for plants that can affect current and future growth and reproduction. There are three models that predict contrasting compensatory growth responses of plants to herbivory and resource availability: (1) Growth rate model, (2) Compensatory continuum hypothesis and (3) Limiting resource model. The predictions of these three models were tested on the tree Brosimum alicastrum and the liana Vitis tiliifolia. Seedlings were subjected to three levels of experimental defoliation (0%, 50% and 90% leaf removal) along a light resource gradient (1%, 9% and 65% of full sun). In both species, defoliation significantly increased leaf production rate and relative growth rate of leaf area, but not of biomass. Net assimilation rate was the strongest driver of biomass growth in both species, but leaf area ratio and specific leaf area were also important in B. alicastrum. Compensatory responses of leaf area growth in B. alicastrum were significantly greater in higher than lower light availability, consistent with the compensatory continuum hypothesis predictions, but in contrast to the growth rate model predictions. The limiting resource model offered an explanation for all possible experimental outcomes by directly considering the effects of environmental differences in resource availability. La defoliación ocasionada por herbivoría causa pérdida de biomasa que puede afectar el crecimiento y la reproducción en plantas. Tres modelos que predicen respuestas contrastantes del crecimiento compensatorio de plantas a la herbivoría y a la disponibilidad de recursos son: (1) Modelo de la tasa de crecimiento, (2) Hipótesis de la compensación continua, y (3) Modelo del recurso limitante. Se examinaron las predicciones a estos tres modelos en la especie arbórea Brosimum alicastrum y en la liana Vitis tiliifolia. Las plántulas se sometieron a tres niveles de defoliación experimental (0, 50 y 90% de defoliación total) a lo largo de un gradiente de luz (1, 9 y 65% de luz total). En ambas especies, la defoliación afectó de manera positiva y significativa la tasa de producción foliar y la tasa relativa de crecimiento en área foliar, pero no afectó la biomasa. La tasa de asimilación neta fué el parámetro que mejor explicó las diferencias en la tasa relativa de crecimiento en biomasa en ambas especies, pero en B. alicastrum la relación foliar y el área específica foliar también fueron factores importantes. Las respuestas compensatorias de B. alicastrum en la tasa de producción foliar fueron significativamente mayores en alta disponibilidad de luz comparadas con baja disponibilidad de luz, consistente con la hipótesis de la compensación continua pero contrario a las predicciones esperadas por el modelo de la tasa de crecimiento. El modelo del recurso limitante ofrece la mejor explicación para todos los posibles resultados experimentales, ya que considera directamente los efectos de diferencias ambientales en la disponibilidad de recursos.

Plant-growth-promoting rhizobacteria (PGPR) influence soil fertility, plant growth, tolerance to abiotic stress, resistance to herbivorous insects, and plant interactions with other organisms. While the effects of PGPR on plant growth, fruit yield, and induced defense responses have been extensively studied, the consistent positive outcomes have fueled rapid expansion in this research field. To evaluate PGPR impacts on plant growth and interactions with phytophagous insects, we conducted a systematic meta-analysis using publications from electronic databases (e.g., PubMed, Web of Science) that reported PGPR effects on plants and insects. Effects were categorized by plant family, PGPR genus, insect feeding guild, and insect–host specialization. Our analysis revealed that PGPR generally enhanced plant growth across most plant families; however, the magnitude and direction of these effects varied significantly among PGPR genera, indicating genus-specific interactions with host plants. When assessing PGPR-mediated reductions in phytophagous insects, we found that Pseudomonas, Rhizobium, and Bacillus exhibited the weakest negative effects on insect populations. PGPR significantly reduced both monophagous and polyphagous insects, with the most pronounced negative impacts on sucking insects (e.g., aphids, whiteflies). This study highlights critical patterns in PGPR-mediated plant growth promotion across taxa and the related differential effects on phytophagous insect activity. These insights advance our understanding of PGPR applications in agroecological production systems, particularly for integrated pest management and sustainable crop productivity.

In the search for environmentally friendly options to manage plant pests and enhance productivity with fewer external inputs in agriculture, the screening of landraces has gained importance. The aims of this study were to characterize functional leaf traits in maize landraces, including morphological traits such as leaf toughness, thickness, specific leaf area (SLA), and number of trichomes, as well as physiological leaf traits such as photosynthesis, transpiration rate, and stomatal conductance. We aimed to determine the association of these traits with leaf damage caused by Spodoptera frugiperda across 24 maize landraces. Relationships of dependence among leaf traits and leaf damage were determined using principal component analysis, multiple regression analysis and sequential path analyses. All morphological leaf traits showed differences among maize landraces mainly at 20 and 30 days after emerge (DAE) whereas at 40 DAE the differences decreased. By the contrast, physiological leaf traits had high variation at 40 DAE among maize landraces. We found a negative dependency of principal component conformed by photosynthesis, transpiration rate, and stomatal conductance over leaf damage. Based on the level of leaf damage, we categorized maize landraces into two groups with low and high susceptibility. Surprisingly, we observed that in the former group, physiological leaf traits affected the number of trichomes, whereas in the latter group, they influenced leaf thickness. This finding highlights the necessity of detailed assessments of foliage properties to understand the impact of S. frugiperda infestations. Such an analytical approach is crucial in scientific research, providing deeper insights into the underlying mechanisms of interaction between the pest and its host plants.

Plant-insect interactions are a determining factor for sustainable crop production. Although plants can resist or tolerate herbivorous insects to varying degrees, even with the use of pesticides, insects can reduce plant net productivity by as much as 20%, so sustainable strategies for pest control with less dependence on chemicals are needed. Selecting plants with optimal resistance and photosynthetic traits can help minimize damage and maintain productivity. Here, 27 landrace accessions of lima beans, Phaseolus lunatus L., from the Yucatan Peninsula were evaluated in the field for morphological resistance traits, photosynthetic characteristics, insect damage and seed yield. Variation was found in physical leaf traits (number, area, and dry mass of leaves; trichome density, specific leaf thickness and hardness) and in physiological traits (photosynthetic rate, stomatal conductance, intercellular carbon, water-use efficiency, and transpiration). Five accessions (JMC1325, JMC1288, JMC1339, JMC1208 and JMC1264) had the lowest index for cumulative damage with the highest seed yield, although RDA analysis uncovered two accessions (JMC1339, JMC1288) with strong positive association of seed yield and the cumulative damage index with leaf production, specific leaf area (SLA) and total leaf area. Leaf traits, including SLA and total leaf area are important drivers for optimizing seed yield. This study identified 12 important morphological and physiological leaf traits for selecting landrace accessions of P. lunatus for high yields (regardless of damage level) to achieve sustainable, environmentally safe crop production.

Las plantas responden a cambios bióticos y abióticos acorde a su plasticidad fenotípica. Estas variaciones pueden expresarse en características relacionadas a la morfología foliar, crecimiento y defoliación. Este estudio evalúa la influencia de la edad de las plantas y de hojas sobre las características foliares, y su relación con la defoliación en tres especies forrajeras, Tithonia diversifolia, Morus alba y Moringa oleifera. M. oleifera mostró hojas con mayores valores de grosor, peso seco, asimetría y área; M. alba hojas más duras y con mayor área foliar especifica. M. oleifera el área foliar, peso seco, grosor y dureza incrementaron en plantas de 30 días. En tanto, que en M. alba las hojas intermedias tuvieron mayor área; y, las plantas de 90 días mayores valores de SLA, grosor y dureza. El área foliar y peso seco fueron mayores a los 60 y 30 días, respectivamente. En T. diversifolia las hojas intermedias presentaron mayor peso seco y grosor, las plantas de 30 días mayor área foliar y peso seco; y, las de 90 días, mayor grosor. Se encontraron relaciones negativas en hojas jóvenes con el grosor, dureza y peso seco. La defoliación mostró asociaciones positivas con el SLA y la dureza; y, negativas con el grosor, peso seco, asimetría y área. Subrayamos la importancia de realizar estudios que contribuyan al entendimiento de interrelaciones entre la estructura de la hoja, su función y sus relaciones con la expresión de los rasgos morfológicos de resistencia y tolerancia en especies tropicales de importancia económica y ecológica.

In order to identify the role played by plant species as a food source in the fruit election of dispersing agents (Alouatta pigra Lawrence 1933, Ateles geoffroyi Kuhl 1820 and frugivorous bats), we developed a study in dry tropical forests in Yucatan, Mexico. We recorded the fruits consumed by frugivorous bats using collectors and, for monkeys, we implemented the focal animal method. The number of fruits consumed by primates (A. pigra and A. geoffroyi) and bats were recorded, 342 and 386, respectively. It was determined that bats deposited fruits with some percentage of pulp, while monkeys contributed more with a fruits without pulp (pairwise LSD contrast p < 0.05). Among the variety of fruit species in the diet of primates, we detected that A. pigra chose mostly not an abundant species such as Enterolobium cyclocarpum Jacq. Griseb. (1860) instead of those more abundant (Manilkara zapota (L.) P. Royen (1953) and Brosimum alicastrum Sw. subsp. alicastrum C.C. Berg (1972)). The type of fruit and seed handling caused by primates would be more beneficial to seed germination than those applied by bats. Moreover, this election and fruit handling could depend on the characteristics of fruits and space-temporal availability of plant species as a food source.

Se reportan los primeros registros de dos especies de hormigas, i.e., Hypoponera opacior y Pseudomyrmex seminole y dos géneros, i.e., Acanthosticus y Mycetosoritis (Hymenoptera: Formicidae), asociados a etapas de descomposición de necrotrampas colocadas en una zona semiurbana del estado de Yucatán, México.

El crecimiento compensatorio y las defensas vegetales son respuestas para lidiar con la herbivoría y la luz. El estudio de la influencia de los componentes morfo-fisiológicos, de la asignación de biomasa y de la defensa vegetal podría arrojar información que ayude a entender estas respuestas. Se evaluaron los efectos de la herbivoría y la apertura de claros sobre el crecimiento, los componentes morfo-fisiológicos, la asignación de biomasa y las defensas químicas y físicas en plántulas de Brosimum alicastrum en una selva mediana subcaducifolia. Se utilizó un diseño anidado con sitios de sotobosque y claros (n = 3 en cada uno) y dentro de ellos plántulas sometidas a tres tratamientos de herbivoría: control (n = 10), simulada (n = 10) y natural (n = 10). Se registró a lo largo de seis meses la influencia de la herbivoría sobre el crecimiento (biomasa, área foliar, altura, diámetro y producción de hojas), la producción de fenoles y la dureza foliar. Se halló un crecimiento compensatorio (todas las variables de crecimiento) con la herbivoría natural, subcompensatorio (biomasa, altura y diámetro) con la simulada, y sobrecompensatorio (producción de hojas) con la herbivoría natural sólo en claros. Los componentes morfológicos como el cociente del área foliar (LAR) y el área foliar específica (SLA) fueron mayores bajo claros y el fisiológico, como la tasa de asimilación neta (NAR), en sotobosque. La proporción de biomasa en sotobosque fue mayor hacia hojas y tallos y en claros más alta hacia raíces. La herbivoría fue mayor en claros y los fenoles foliares en sotobosque. No se encontró una relación (compromiso) entre las defensas y el crecimiento, sólo una tendencia negativa con los fenoles bajo condiciones limitantes de recursos, como ocurre en el sotobosque.

The effect of the parent tree on seedling recruitment has been studied in various research studies. The Janzen–Connell (JC) hypothesis states that the closer the seedlings are to the source tree, the greater the risk of mortality and/or impact from pathogens and herbivores. Despite the extensive existing literature, there are not many studies that evaluate the influence of crown area, as well as the effects on leaf asymmetry, an important measure of biotic and abiotic stress. (1) This study evaluates the effect of distance from the parent tree and the crown’s area of influence on mortality, growth, and leaf asymmetry of Manilkara zapota seedlings, as well as insect herbivory and damage from leaf pathogens in a Mexican neotropical forest. (2) We selected 10 reproductive adult trees (Diameter at breast height, DBH ~ 10–25 cm) and established four 10 m × 1 m transects around each tree in four directions (north, south, east, and west). Each transect produced 10 quadrants of 1 m², and the quadrant where the shadow of the parent tree extended was marked as either under crown or crown-free. All M. zapota seedlings were counted in each quadrant. For one seedling in each quadrant, we recorded height, leaf asymmetry (LA), insect herbivory, and damage from leaf pathogens. Herbivory by insects, damage from leaf pathogens, and LA were only measured on the newest leaves. Mortality was determined after 9 months per quadrant, as well as light availability (photosynthetic photon flux density), temperature, and relative humidity. (3) We found that mortality and relative growth rate (RGRHeight) increased near and under the parent tree. Furthermore, LA decreased at greater distances from the parent tree and only outside the crown’s influence. Additionally, LA had a strong positive influence on damage caused by insect herbivory and leaf pathogens, impacting both more strongly under the crown. A high dependency of leaf pathogens on damage from insect herbivory was also recorded. Finally, the most frequent type of herbivory was that caused by chewing insects. (4) To our knowledge, we present one of the few studies that has addressed the JC hypothesis, considering not only the distance from the parent tree and seedling density but also the influence of the crown on the performance of M. zapota seedlings. Studies that consider the influence of the microenvironment are of fundamental importance for a comprehensive understanding of the JC hypothesis.

Las plantas responden a cambios bióticos y abióticos acorde a su plasticidad fenotípica. Estas variaciones pueden expresarse en características relacionadas a la morfología foliar, crecimiento y defoliación. Este estudio evalúa la influencia de la edad de las plantas y de hojas sobre las características foliares, y su relación con la defoliación en tres especies forrajeras, Tithonia diversifolia, Morus alba y Moringa oleifera. M. oleifera mostró hojas con mayores valores de grosor, peso seco, asimetría y área; M. alba hojas más duras y con mayor área foliar especifica. M. oleifera el área foliar, peso seco, grosor y dureza incrementaron en plantas de 30 días. En tanto, que en M. alba las hojas intermedias tuvieron mayor área; y, las plantas de 90 días mayores valores de SLA, grosor y dureza. El área foliar y peso seco fueron mayores a los 60 y 30 días, respectivamente. En T. diversifolia las hojas intermedias presentaron mayor peso seco y grosor, las plantas de 30 días mayor área foliar y peso seco; y, las de 90 días, mayor grosor. Se encontraron relaciones negativas en hojas jóvenes con el grosor, dureza y peso seco. La defoliación mostró asociaciones positivas con el SLA y la dureza; y, negativas con el grosor, peso seco, asimetría y área. Subrayamos la importancia de realizar estudios que contribuyan al entendimiento de interrelaciones entre la estructura de la hoja, su función y sus relaciones con la expresión de los rasgos morfológicos de resistencia y tolerancia en especies tropicales de importancia económica y ecológica.