Your search keyword '"Tracheophyta physiology"' showing total 4 results

1. Temperature dependence of pollen germination and tube growth in conifers relates to their distribution along an elevational gradient in Washington State, USA.

Author

Hsu HW and Kim SH

Subjects

Washington, Pollen Tube growth & development, Pollen Tube physiology, Picea growth & development, Picea physiology, Climate Change, Tracheophyta physiology, Tracheophyta growth & development, Temperature, Altitude, Pinus growth & development, Pinus physiology, Germination physiology, Pollen growth & development, Pollen physiology

Abstract

Background and Aims: Pollen germination and tube growth are essential processes for successful fertilization. They are among the most temperature-vulnerable stages and subsequently affect seed production and determine population persistence and species distribution under climate change. Our study aims to investigate intra- and interspecific variations in the temperature dependence of pollen germination and tube length growth and to explore how these variations differ for pollen from elevational gradients., Methods: We focused on three conifer species, Pinus contorta, Picea engelmannii and Pinus ponderosa, with pollen collected from 350 to 2200 m elevation in Washington State, USA. We conducted pollen viability tests at temperatures from 5 to 40 °C in 5 °C intervals. After testing for 4 d, we took images of these samples under a microscope to monitor pollen germination percentage (GP) and tube length (TL). We applied the gamma function to describe the temperature dependence of GP and TL and estimated key parameters, including the optimal temperature for GP (Topt_GP) and TL (Topt_TL)., Key Results: Results showed that pollen from three species and different elevations within a species have different GP, TL, Topt_GP, and Topt_TL. The population with a higher Topt_GP would also have a higher Topt_TL, while Topt_TL was generally higher than Topt_GP, i.e. a positive but not one-to-one relationship. However, only Pinus contorta showed that populations from higher elevations have lower Topt_GP and Topt_TL and vice versa. The variability in GP increased at extreme temperatures, whereas the variability in TL was greatest near Topt_TL., Conclusions: Our study demonstrates the temperature dependences of three conifers across a wide range of temperatures. Pollen germination and tube growth are highly sensitive to temperature conditions and vary among species and elevations, affecting their reproduction success during warming. Our findings can provide valuable insights to advance our understanding of how conifer pollen responds to rising temperatures., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2025

2. Adaptive significance of age- and light-related variation in needle structure, photochemistry, and pigments in evergreen coniferous trees.

Author

Oluborode J, Chadzinikolau T, Formela-Luboińska M, Ye ZP, and Robakowski P

Subjects

Trees physiology, Trees metabolism, Photosystem II Protein Complex metabolism, Light, Tracheophyta physiology, Tracheophyta metabolism, Tracheophyta radiation effects, Picea physiology, Picea metabolism, Picea radiation effects, Chlorophyll A metabolism, Fluorescence, Adaptation, Physiological, Pigments, Biological metabolism, Photosynthesis physiology, Plant Leaves physiology, Plant Leaves radiation effects, Plant Leaves metabolism, Chlorophyll metabolism

Abstract

Evergreen conifers thrive in challenging environments by maintaining multiple sets of needles, optimizing photosynthesis even under harsh conditions. This study aimed to investigate the relationships between needle structure, photosynthetic parameters, and age along the light gradient in the crowns of Abies alba, Taxus baccata, and Picea abies. We hypothesized that: (1) Needle structure, photochemical parameters, and photosynthetic pigment content correlate with needle age and light levels in tree crowns. (2) The photosynthetic capacity of ageing needles would decline and adjust to the increasing self-shading of branches. Our results revealed a non-linear increase in the leaf mass-to-area ratio. The maximum quantum yield of photosystem II photochemistry decreased linearly with needle age without reaching levels indicative of photoinhibition. Decreased maximum electron transport rates (ETR max ) were linked to declining values of saturating photosynthetic photon flux density and increasing non-photochemical quenching of fluorescence (NPQ), indicating energy losses as heat. The chlorophyll a to chlorophyll b ratio linearly decreased, suggesting older needles sustain high light capture efficiency. These findings offer new insights into the combined effects of needle ageing and self-shading on photochemistry and pigment content. This functional needle balance highlights the trade-off between the costs of long-term needle retention and the benefits of efficient resource utilization. In environments where air temperature is less of a constraint on photosynthesis due to climate warming, evergreen coniferous trees could sustain or enhance their photosynthetic capacity. They can achieve this by shortening needle lifespan and retaining fewer cohorts of needles with higher ETR max and lower NPQ compared to older needles., Competing Interests: Declarations. Conflict of interest: The authors have no relevant financial or non-financial interests to disclose., (© 2024. The Author(s).)

Published

2025

3. Repeated fuel treatments fall short of fire-adapted regeneration objectives in a Sierra Nevada mixed conifer forest, USA.

Author

Nagelson PB, York RA, Shoemaker KT, Foster DE, Stephens SL, and Bisbing SM

Subjects

California, Tracheophyta physiology, Fires, Wildfires, Forestry methods, Trees, Conservation of Natural Resources methods, Forests

Abstract

Fire exclusion over the last two centuries has driven a significant fire deficit in the forests of western North America, leading to widespread changes in the composition and structure of these historically fire-adapted ecosystems. Fuel treatments have been increasingly applied over the last few decades to mitigate fire hazard, yet it is unclear whether these fuel-focused treatments restore the fire-adapted conditions and species that will allow forests to persist into the future. A vital prerequisite of restoring fire-adaptedness is ongoing establishment of fire-tolerant tree species, and both the type and reoccurrence of fuel treatments are likely to strongly influence stand trajectories. Here, we leveraged a long-term study of repeated fuel treatments in a Sierra Nevada mixed-conifer forest to examine the regeneration response of six native tree species to the repeated application of common fuel treatments: prescribed fire, mechanical, mechanical plus fire, and untreated controls. Our objectives were to (1) quantify differences in forest structure and composition following the repeated application of alternative fuel treatments that may influence the establishment environment and then (2) identify the stand structure and climate conditions influencing seedling dynamics. We found that both treatment type and intensity are highly influential in shifting forests toward more fire-adapted conditions and determining species-specific regeneration dynamics. Specifically, the conifer species tracked here increased in either colonization or persistence potential following repeated applications of fire, indicating fire may be most effective for restoring regeneration conditions broadly across species. Fire alone, however, was not enough to promote fire-adapted composition, with concurrent mechanical treatments creating more favorable conditions for promoting colonization and increasing abundances of fire-tolerant ponderosa pine. Yet, even with repeated fuel treatment application, establishment of fire-intolerant species far exceeded that of fire-tolerant species over this 20-year study period. Moreover, increasing growing season water stress negatively impacted seedling dynamics across all species regardless of treatment type and intensity, an important consideration for ongoing management under heightened climatic stress. While repeated treatments are waypoints in restoring fire-adapted conditions, more intense treatments via gap-creation or hotter prescribed fires targeting removal of fire-intolerant species will be necessary to sustain recruitment of fire-tolerant species., (© 2024 The Ecological Society of America.)

Published

2025

4. Fire in the tree: The origin and distribution of fire-adapted traits within conifers and their influence on speciation rates across the conifer phylogeny.

Author

Turck DF, Schwery O, Harmon LJ, and Tank DC

Subjects

Biological Evolution, Genetic Speciation, Adaptation, Physiological, Climate, Trees physiology, Tracheophyta physiology, Tracheophyta genetics, Phylogeny, Fires

Abstract

Premise: Considering rapidly changing fire regimes due to anthropogenic disturbances to climate and fuel loads, it is crucial to understand the underpinnings driving fire-adapted trait evolution. Among the oldest lineages affected by fire is Coniferae. This lineage occupies a variety of fire prone and non-fire prone habitats across all hemispheres and has four fire-adapted traits: (1) thick bark; (2) serotiny; (3) seedling grass stage; and (4) resprouting ability. We seek to determine the historic origins of these traits, the degree of convergent evolution among species, how fire adaptations affect diversification rates in conifers, and if there is a link between climate and the evolution of fire adaptations., Methods: To investigate these questions, we use a combination of ancestral state reconstructions, multiple diversification analyses, and Pagel trait correlations., Results: Our results point to multiple evolutionary origins of fire adaptations. We find certain climates, particularly Subtropical and Mediterranean, are highly correlated with species possessing fire adaptations. Several lineages evolved fire adaptations after the Mid-Miocene Climactic Optimum, which coincides with the expansion of the then novel Mediterranean Climate type. Generally possessing a fire adaptation does not increase diversification rates, with the possible exceptions of Pinus subsections Australes and Ponderosae., Conclusions: The appearance of novel climates and associated fire regimes seem to have been the primary drivers of fire adaptation evolution in conifers. However, most increases in diversification rates are within clades that responded favorably to cooler drier climates post Mid-Miocene Climactic Optimum, regardless of whether the clade is fire adapted., (© 2025 Botanical Society of America.)

Published

2025