Moose (Alces alces) reacts to high summer temperatures by utilizing thermal shelters in boreal forests – an analysis based on airborne laser scanning of the canopy structure at moose locations

The adaptation of different species to warming temperatures has been increasingly studied. Moose (Alces alces) is the largest of the ungulate species occupying the northern latitudes across the globe, and in Finland it is the most important game species. It is very well adapted to severe cold temperatures, but has a relatively low tolerance to warm temperatures. Previous studies have documented changes in habitat use by moose due to high temperatures. In many of these studies, the used areas have been classified according to how much thermal cover they were assumed to offer based on satellite/aerial imagery data. Here, we identified the vegetation structure in the areas used by moose under different thermal conditions. For this purpose, we used airborne laser scanning (ALS) data extracted from the locations of GPS‐collared moose. This provided us with detailed information about the relationships between moose and the structure of forests it uses in different thermal conditions and we were therefore able to determine and differentiate between the canopy structures at locations occupied by moose during different thermal conditions. We also discovered a threshold beyond which moose behaviour began to change significantly: as day temperatures began to reach 20 °C and higher, the search for areas with higher and denser canopies during daytime became evident. The difference was clear when compared to habitat use at lower temperatures, and was so strong that it provides supporting evidence to previous studies, suggesting that moose are able to modify their behaviour to cope with high temperatures, but also that the species is likely to be affected by warming climate.     

An easy ratiometric compensation for the extracellular Ca indicator-caused fluorescence artifact

Measurement of intracellular Ca²⁺ dynamics is one of the most central real-time assays for cellular signaling. Ratiometric methods reduce the need for internal calibration and also effectively compensate for most artifacts when used in imaging. However, ratiometric calculation cannot compensate for extracellularly leaked (and fluorescent) Ca²⁺ indicator and will instead indicate erroneous Ca²⁺ concentration. This frequently occurs in systems where extracellular indicator is accumulated such as fluorescence spectrophotometers and plate readers. Here I present a method that, for the first time, fully compensates for this phenomenon. The method uses a single-step internal calibration together with a predefined ratiometric calibration protocol.     

<Emphasis Type="Italic">Methylophilaceae</Emphasis> and <Emphasis Type="Italic">Hyphomicrobium</Emphasis> as target taxonomic groups in monitoring the function of methanol-fed denitrification biofilters in municipal wastewater treatment plants

Molecular monitoring of bacterial communities can explain and predict the stability of bioprocesses in varying physicochemical conditions. To study methanol-fed denitrification biofilters of municipal wastewater treatment plants, bacterial communities of two full-scale biofilters were compared through fingerprinting and sequencing of the 16S rRNA genes. Additionally, 16S rRNA gene fingerprinting was used for 10-week temporal monitoring of the bacterial community in one of the biofilters. Combining the data with previous study results, the family Methylophilaceae and genus Hyphomicrobium were determined as suitable target groups for monitoring. An increase in the relative abundance of Hyphomicrobium-related biomarkers occurred simultaneously with increases in water flow, NO _x ^? load, and methanol addition, as well as a higher denitrification rate, although the dominating biomarkers linked to Methylophilaceae showed an opposite pattern. The results indicate that during increased loading, stability of the bioprocess is maintained by selection of more efficient denitrifier populations, and this progress can be analyzed using simple molecular fingerprinting.     

The molecular phylogeny of the Miarus campanulae (Coleoptera: Curculionidae) species group inferred from CO1 and ITS2 sequences

Miarus is a Holarctic weevil genus with morphologically very similar species, all breeding on Campanula plants or their close relatives. Two European members of this genus, Miarus campanulae (L.), the type species, and Miarus graminis (Bohemann) have recently been split into several new species on the basis of slight external variations. The separation of these new forms has proved impossible and new data was needed. Molecular data were gathered from specimens from a number of locations in Finland, Estonia, Denmark and Sweden. The regions sequenced were mitochondrial CO1 and nuclear ITS2. Both combined and separate datasets were analyzed using the optimization alignment program POY, with parsimony as the optimality criterion. The recently separated Miarus species was found to be indistinguishable from the traditionally recognized form on the basis of this sequence data. On the other hand, the traditionally recognized species were characterized by numerous synapomorphies. Our data suggest that recent studies have underestimated the morphological variation in this genus. We propose that this may also be true for many taxonomically problematic beetle complexes in well‐studied European regions. The idea that molecular evidence will inevitably reveal unnoticed cryptic variation may only apply to poorly known regions. Miarus fennicus Kangas, 1978 is placed as a junior synonym of Miarus campanulae (Linnaeus, 1767) syn. nov . © The Willi Hennig Society 2006.     

Effects of temporal variation in the risk of predation by least weasel (Mustela nivalis) on feeding behavior of field vole (Microtus agrestis)

Predation risk tends to vary in time. Thus prey animals face a problem of allocating feeding and antipredator effort across different risk situations. A recent model of Lima and Bednekoff (1999) predicts that a prey should allocate more feeding effort to low risk situations and more antipredator effort to high risk situations with increasing relative degree of risk in high risk situations (attack ratio). Furthermore when the proportion of time the prey spends in the high risk situation (p) increases, the prey have to eventually feed also in the high risk situations. However the increase in feeding effort in low risk situations should clearly exceed that in high risk situations as p increases. To test these predictions we measured feeding effort of field voles (Microtus agrestis) exposed to varying presence of least weasel (Mustela nivalis) and its feces in laboratory conditions. We generated quantitative predictions by estimating attack ratios from results of a pilot experiment. The model explained 15% of the observed variation in feeding effort of voles. Further analyses indicated that feeding effort was lower in high risk situations than in low risk situations at high attack ratio, but not at a lower one. Voles exposed to a presence of a weasel for extended periods showed signs of nutritional stress. Still we did not find any increase in feeding effort with increasing p. This was obviously due to the relatively low maximal p we used as we included only conditions likely to occur in nature.     

Phylogeny of Syrphidae (Diptera) inferred from combined analysis of molecular and morphological characters

Abstract.  Syrphidae (Diptera) commonly called hoverflies, includes more than 5000 species world-wide. The aim of this study was to address the systematic position of the disputed elements in the intrafamilial classification of Syrphidae, namely the monophyly of Eristalinae and the placement of Microdontini and Pipizini, as well as the position of particular genera ( Nausigaster , Alipumilio , Spheginobaccha ). Sequence data from nuclear 28S rRNA and mitochondrial COI genes in conjunction with larval and adult morphological characters of fifty-one syrphid taxa were analysed using optimization alignment to explore phylogenetic relationships among included taxa. A species of Platypezidae, Agathomyia unicolor , was used as outgroup, and also including one representative ( Jassidophaga villosa ) of the sister-group of Syrphidae, Pipunculidae. Sensitivity of the data was assessed under six different parameter values. A stability tree summarized the results. Microdontini, including Spheginobaccha , was placed basally, and Pipizini appeared as the sister-group to subfamily Syrphinae. The monophyly of subfamily Eristalinae was supported. The results support at least two independent origins of entomophagy in syrphids, and frequent shifts between larval feeding habitats within the saprophagous eristalines.