The effect of climate change on Arcto-Tertiary Mexican beech forests: Exploring their past, present, and future distribution.

Fagus mexicana Martínez (Mexican beech) is an endangered Arcto-Tertiary Geoflora tree species that inhabit isolated and fragmented tropical montane cloud forests in eastern Mexico. Exploring past, present, and future climate change effects on the distribution of Mexican beech involves the study of spatial ecology and temporal patterns to develop conservation plans. These are key to understanding the niche conservatism of other forest communities with similar environmental requirements. For this study, we used species distribution models by combining occurrence records, to assess the distribution patterns and changes of the past (Last Glacial Maximum), present (1981-2010), and future (2040-2070) periods under two climate scenarios (SSP 3-7.0 & SSP 5-8.5). Next, we determined the habitat suitability and priority conservation areas of Mexican beech as associated with topography, land cover use, distance to the nearest town, and environmental variables. By considering the distribution of Mexican beech during different periods and under different climate scenarios, our study estimated that high-impact areas of Mexican beech forests were restricted to specific areas of the Sierra Madre Oriental that constitute refugia from the Last Glacial Maximum. Regrettably, our results exhibited that Mexican beech distribution has decreased 71.3% since the Last Glacial Maximum and this trend will for the next 50 years, migrating to specific refugia at higher altitudes. This suggests that the states of Hidalgo, Veracruz, and Puebla will preserve the habitat suitability features as ecological refugia, related to high moisture and north-facing slopes. For isolated and difficult-to-access areas, the proposed methods are powerful tools for relict-tree species, which deserve further conservation.

Ecological relationship between floral thermogenesis and pollination in Nelumbo lutea (Nelumbonaceae).

PREMISE OF STUDY: Floral thermogenesis is an unusual floral trait with a well-documented physiological process, and yet, there is limited understanding of how this trait influences plant reproduction. The current study was undertaken to gain a better understanding of how floral thermogenesis in Nelumbo lutea impacts pollinator attraction and consequent plant reproduction. METHODS: We conducted field studies on floral thermogenesis and thermoregulation, flower sexual development, floral visitation patterns, breeding system, pollen transfer dynamics, and floral scent production. KEY RESULTS: The most abundant visitors to the thermoregulatory flowers included the Phoridae (Diptera), Chrysomelidae (Coleoptera), and Hymenoptera. Chrysomelid beetles, particularly Diabrotica, were frequent visitors to both first-day female- and second-day bisexual-phase flowers, while phorid flies were most common in bisexual-phase flowers. Pollen transfer experiments indicated that Diabrotica was equally effective in depositing pollen on stigmas, as were the less frequent, but pollen-loaded halictid bees. CONCLUSIONS: Flowers received a taxonomically wide assemblage of floral visitors and appear adapted to attract beetles, primarily Chrysomelidae and medium-sized bees. This study is the first to provide strong support that beetles can comprise the dominant portion of floral visitors and are as effective in pollen transfer as bees. Thermogenesis aids in dispersing the main floral scent component-1,4-dimethoxybenzene-attracting both chrysomelids and bees, while thermoregulation causes chrysomelid beetles to actively seek out new flowers for evening residence. This search behavior likely results in chrysomelids affecting cross-pollination.

The interaction between pollinator size and the bristle staminode of Penstemon digitalis (Scrophulariaceae).

Penstemon digitalis, a prairie species whose flowers possess a large bristle staminode, is visited by eight bee species of varying size. Two sets of field experiments involving staminode removal were performed to test pollination efficiency in relation to bee size. Our data indicate that bristle staminode presence and function are influenced by size-dependent selection on bee body size and associated pollen transporting attributes. The first experiment compared staminode presence and removal in open-pollinated flowers. Staminode removal significantly reduced total pollen deposition but had no effect on total pollen removal. The second experiment utilized single bee visits to assess the interaction between pollinator size and staminode presence on the rate of pollen deposition and removal. This experiment indicated that staminode removal resulted in fewer pollen grains deposited on stigmas and less pollen removed from anthers for both large and small bees (the contrary was true for medium bees). Although the number of pollen grains deposited was greatly reduced for large bees, staminode removal reduced deposition efficiency most notably for small bees by 41.3%, reducing female reproductive success. Staminode removal increased pollen removal efficiency most notably for medium bees by 22.7%, reducing male reproductive success. Mechanisms of staminode function are discussed.