Variations and Trade‐offs in Functional Traits of Tree Seedlings during Secondary Succession in a Tropical Lowland Rain Forest

The seedling stage is generally the most important bottleneck for the successful regeneration of trees in forests. The traits of seedlings, particularly biomass allocation and root traits, are more easily quantified than the traits of adults. In this study, we tested the hypothesis that seedling traits vary and trade‐off tracking the changing environment during secondary succession. We measured the major morphological traits of 27 dominant species and the major environmental factors in a chronosequence (30‐yr‐old fallow, 60‐yr‐old fallow, and old growth forest) after shifting cultivation in a tropical lowland rain forest on Hainan Island, China. The 30‐yr‐old fallow had higher light and nutrient availability, and the older forests had higher soil water content. Redundancy analysis based on species abundance and environmental factors revealed groups of seedlings that dominate in different stages of succession. Seedlings in different stages of succession had different strategies of biomass allocation for harvesting resources that varied in availability. Species characteristic of younger forest had higher allocation to roots and higher specific leaf area, while species characteristic of older forest had higher allocation to leaves. Our study suggests that the variations and trade‐offs in the major functional traits of tree seedlings among successional classes may reflect changes in environmental conditions during succession.     

Altitudinal Patterns in Two Syntopic Species of Sturnira (Mammalia: Chiroptera: Phyllostomidae) in the Montane Rain Forests of Argentina

We evaluated altitudinal segregation in two Sturnira species as a mechanism allowing their coexistence. Tests were devised to discern between interspecific interactions and regional responses to geographic and environmental variables, using extensive capture data from 18 montane rain forest sites. No significant correlation between captures was found. Additionally and according to the hypothesis of historical occupation of highland versus lowland forests, each species has shown specificity in their response to the geographical and environmental variables. Our results indicated that abundance patterns in these bats likely result from the regional distribution of each species rather than local interactions between them, a pattern that may have ancient roots within the group.     

Application of the Kwei equation to model the Tg behavior of binary blends of sugars and salts

Vitrification of sugar-based solutions plays an important role in cryopreservation, lyophilization, and the emerging field of anhydrous preservation. An understanding of the glass transition characteristics of such formulations is essential for determining an appropriate storage temperature to ensure an extended shelf life of vitrified products. To better understand the effect of salts on the glass transition temperature (T_g) of glass-forming sugars, we investigated several data-fitting models (Fox, Gordon–Taylor and Kwei) for sugar–salt formulations using data from the literature, as well as new data generated on blends of trehalose and choline dihydrogen phosphate (CDHP). CDHP has recently been shown to have promise as a stabilizing agent for proteins and DNA. The Kwei equation, which has a specific parameter characterizing intermolecular interactions, provides good fits to the T_g data for sugar–salt blends, and complements other commonly used models that are frequently used to model T_g data.     

Temperature adaptation in Chrysomya megacephala and Chrysomya pinguis,two blow fly species of forensic significance

Chrysomya megacephala (Fabricius) (Diptera: Calliphoridae) is a common and forensically important blow fly species in the Oriental region. However, in the higher mountain regions and on winter days, its habitats are occupied by a closely related species, Chrysomya pinguis (Walker). The resources that the two species employ to survive are very similar and competition between the species may be one of the factors that trigger differentiation of their behaviors. We conducted experiments to examine how these two closely related species may have adapted to different temperature regimes to avoid competition. Several adult and immature parameters were assessed, such as fecundity, locomotor ability, hatching ratio, larval survivorship, and eclosion ratio. Results indicate that species show specific diapause at high temperature (38 °C), larval survivorship of Ch. megacephala was significantly better than that of Ch. pinguis. Conversely, at low temperature (15 °C), adult locomotor ability was better for Ch. pinguis than for Ch. megacephala. The results indicate that the two species may have evolved different temperature adaptation strategies to avoid competition. In mixed‐species larval rearing experiments, competition between Ch. pinguis and Ch. megacephala was observed: at higher temperature (30 °C), the immature performance index of Ch. megacephala was significantly increased when compared to that in single‐species culture, whereas the index of Ch. pinguis was decreased. These data are consistent with the idea that tolerance for higher temperature conditions would allow larvae of Ch. megacephala to gain a competitive advantage over Ch. pinguis in certain habitats. These results may help to explain their current distribution in the environment and provide more biological information on these forensically important species.     

Season-associated modifications in symplasmic organization of the cambium in Populus nigra

Background and Aims

Alterations of plasmodesma (PD) connectivity are likely to be very important for plant development. Here, the repetitive division pattern of cambial initials in Populus nigra ‘italica’ was studied to follow the development of the PD network during maturation. Furthermore, seasonal changes were investigated in order to trace indications for developmental and functional adaptations.

Methods

Cambium samples of P. nigra twigs, collected in summer, autumn and spring, were chemically fixed for transmission electron microscopy. The parameters, PD density (number of PDs per square micrometre cell-wall area) and PD frequency (total number of PDs per average cell-wall area), were determined for radial and tangential cell interfaces deposited in chronological order.

Key Results

Data sets, presented in plasmodesmograms, show a strong variability in the PD network throughout the year. In summer, high PD numbers occur at the division wall which, after PD doubling by longitudinal fission, decline with further development both at the xylem and the phloem side. In autumn, the number of PDs at the division wall is low as they are in subsequent tangential interfaces. In spring, the first cell division coincides with a massive increase in PD numbers, in particular at the division wall. Only the radial walls between initials maintain their PD equipment throughout the year. This feature can be exploited for identification of the initial layer.

Conclusions

PD networks in the cambium go through a strict developmental programme depending on the season, which is associated with changing functional requirements. For instance, PD numbers correlate with proliferative activity and potential pathways for intercellular signalling. Increases in PD numbers are ascribed to longitudinal fission as a major mechanism, whereas the decline in older derivatives is ascribed to PD degradation.     

Climate Change Implications for River Restoration in Global Biodiversity Hotspots

Global biodiversity hotspots contain exceptional concentrations of endemic species in areas of escalating habitat loss. However, most hotspots are geographically constrained and consequently vulnerable to climate change as there is limited ability for the movement of species to less hostile conditions. Predicted changes to rainfall and temperature will undoubtedly further impact on freshwater ecosystems in these hotspots. Southwestern Australia is a biodiversity hotspot and, as one of the first to experience significant climate change, is an example and potentially a global bellwether for issues associated with river restoration. In this hotspot, current and predicted water temperatures may exceed thermal tolerances of aquatic fauna. Gondwanic aquatic fauna, characteristic of southwestern Australia, are typically cold stenotherms and consequently intolerant of elevated temperatures. The hotspot in southwestern Australia is geographically restricted being surrounded by ocean and desert, and many important national parks are located on the extreme south coast, where the landscape is relatively flat. Consequently, fauna cannot change their distribution southwards or with altitude as a response to increasing temperatures. Therefore, any mitigation responses need to be in situ to produce a suitable biophysical envelope to enhance species' resilience. This could be through “over restoration” by increased riparian replanting at a catchment scale. A rule‐of‐thumb of a 10% increase in riparian cover would be required to reduce water temperatures by 1°C. These restoration techniques are considered applicable to other global biodiversity hotspots where geography constrains species' movement and the present condition is the desired restoration endpoint.     

Mechanism of low‐temperature‐induced pollen failure in rice

Low‐temperature stress during microspore development alters cellular organization in rice anthers. The major cellular damage includes unusual starch accumulation in the plastids of the endothecium in postmeiotic anthers, abnormal vacuolation and hypertrophy of the tapetum, premature callose (1,3‐β‐glucan) breakdown and lack of normal pollen wall formation. These cellular lesions arise from damage to critical biochemical processes that include sugar metabolism in the anthers and its use by the microspores. Failure of utilization of the callose breakdown product and other microspore wall components like sporopollenin can also be considered as critical. In recent years, considerable progress has been made in the understanding of major biochemical processes including the expression of critical genes that are sensitive to low temperature in rice and cause male sterility. This paper combines a discussion of cellular organization and associated biochemical processes that are sensitive to low temperatures and provides an overview of the potential mechanisms of low‐temperature‐induced male sterility in rice.     

Life‐cycle variation,including female production by virgin females in Frankliniella occidentalis (Thysanoptera: Thripidae)

The influence of three different temperatures on developmental time and sex ratio was investigated in the bisexual Thysanoptera species Frankliniella occidentalis. Increasing temperatures decreased developmental time and induced a more female biased sex ratio. Remarkably, there are second instars with a prolonged developmental time requiring the same number of hours as the shortest developmental time from egg to adult. Arrhenotokous reproduction in this species is based on haplodiploidy, with virgin females producing male offspring exclusively. However, at all three temperatures tested, about 0.5% of offspring from unfertilized eggs were females. The presence of Wolbachia could not be detected in Western flower thrips and can be excluded as influencing reproduction in this species.     

Mutations of the ER to plastid lipid transporters TGD1, 2, 3 and 4 and the ER oleate desaturase FAD2 suppress the low temperature‐induced phenotype of Arabidopsis tocopherol‐deficient mutant vte2

Previous studies with the tocopherol‐deficient Arabidopsis thaliana vte2 mutant demonstrated an important role for tocopherols in the development of transfer cell walls and maintenance of photoassimilate export capacity during low‐temperature (LT) adaptation. To further understand the processes linking tocopherol deficiency and the vte2 LT phenotypes, a genetic screen was performed for sve mutations (suppressor of the vte2 low temperature‐induced phenotype). The three strongest sve loci had differing impacts on LT‐induced sugar accumulation, photoassimilate export reduction and vascular‐specific callose deposition in vte2. sve1 completely suppressed all vte2 LT phenotypes and is a new allele of fad2, the endoplasmic reticulum‐localized oleate desaturase. sve2 showed partial suppression, and is a new allele of trigalactosyldiacylglycerol1 (tgd1), a component of the ER‐to‐plastid lipid ATP‐binding cassette (ABC) transporter. Introduction of tgd2, tgd3 and tgd4 mutations into the vte2 background similarly suppressed the vte2 LT phenotypes, indicating a key role for ER‐to‐plastid lipid transport in the vte2 LT phenotype. sve7 partially suppressed all vte2 LT phenotypes by affecting fatty acid and lipid metabolism at low temperatures only. Detailed analyses of acyl lipid composition indicated that all suppressors alleviated the increase in the level of linoleic acid esterified to phosphatidylcholine (PC‐18:2) in LT‐treated vte2, and this alleviation significantly correlated with their extent of suppression of photoassimilate export. Identification and characterization of the sve loci showed that the PC‐18:2 change is an early and key component in vte2 LT‐induced responses, and highlighted the interaction of tocopherols with non‐plastid lipid metabolism.