Predicting Biological Invasions

There are various approaches to explain the mechanisms of biological invasions. It is possible (1) to focus on the characteristics of invading species and (2) on those of the ecosystems invaded, (3) to investigate the relationship between these two factors (key–lock approach), or (4) to differentiate the invasion process in time. Each of these approaches may serve to improve the understanding of some aspects of biological invasions, and each of them is in some way suitable for the purpose of predicting invasions. We discuss the usefulness and the limitations of these approaches, focusing on case studies from central Europe. An example of the fourth approach, a model of steps and stages of plant invasions that describes the invasion process in greater detail, illustrates some general limitations in predicting biological invasions. This revised version was published online in July 2006 with corrections to the Cover Date.     

Using molecular genetics to identify immature specimens of the weevil Ceratapion basicorne (Coleoptera: Apionidae)

Molecular analyses can play a primary role in the process of host specificity evaluation at species and population levels. Here we present an example of their application with a promising candidate biological control agent for yellow starthistle, Centaurea solstitialis L. Although it is highly host specific, Ceratapion basicorne (Coleoptera: Apionidae) can develop on safflower in laboratory tests. A field experiment was conducted to further evaluate host plant specificity; however, it was not possible to rear all larvae to the adult stage, which was necessary for species determination. Therefore molecular genetic methods were used to identify immature specimens. A 731 bp fragment of mtDNA cytochrome C oxidase I gene (COI) was sequenced from 41 individuals of C. basicorne and four congeners: Ceratapion orientale, Ceratapion onopordi, Ceratapion penetrans and Ceratapion scalptum. Intraspecific variability ranged from 0.0% to 0.2%, and interspecific divergences ranged from 1.7% to 17.6%. All larvae that were sequenced from the field study, clearly matched one of the five species, enabling us to unambiguously identify them. Use of molecular genetics to identify larvae should also help the process of foreign exploration, enabling the identification of field-collected larvae, which often provide more reliable host plant associations than field collected adults.     

A new lotic species of the genus Leptocerus Leach (Trichoptera, Leptoceridae) from Japan

A new lotic species of leptocerid caddisfly, Leptocerus fluminalis sp. nov., is described based on adult and immature stages from Japan. The habitat and gut contents of this species are noted.     

长江口日本鳗鲡幼体色素发育时相及其体型变化

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Future warmer seas: increased stress and susceptibility to grazing in seedlings of a marine habitat‐forming species

Increases in seawater temperature are expected to have negative consequences for marine organisms. Beyond individual effects, species‐specific differences in thermal tolerance are predicted to modify species interactions and increase the strength of top‐down effects, particularly in plant–herbivore interactions. Shifts in trophic interactions will be especially important when affecting habitat‐forming species such as seagrasses, as the consequences on their abundance will cascade throughout the food web. Seagrasses are a major component of coastal ecosystems offering important ecosystem services, but are threatened by multiple anthropogenic stressors, including warming. The mechanistic understanding of seagrass responses to warming at multiple scales of organization remains largely unexplored, especially in early‐life stages such as seedlings. Yet, these early‐life stages are critical for seagrass expansion processes and adaptation to climate change. In this study, we determined the effects of a 3 month experimental exposure to present and predicted mean summer SST of the Mediterranean Sea (25°C, 27°C, and 29°C) on the photophysiology, size, and ecology (i.e., plant‐herbivore interactions) of seedlings of the seagrass Posidonia oceanica. Warming resulted in increased mortality, leaf necrosis, and respiration as well as lower carbohydrate reserves in the seed, the main storage organ in seedlings. Aboveground biomass and root growth were also limited with warming, which could hamper seedling establishment success. Furthermore, warming increased the susceptibility to consumption by grazers, likely due to lower leaf fiber content and thickness. Our results indicate that warming will negatively affect seagrass seedlings through multiple direct and indirect pathways: increased stress, reduced establishment potential, lower storage of carbohydrate reserves, and increased susceptibly to consumption. This work provides a significant step forward in understanding the major mechanisms that will drive the capacity of seagrass seedlings to adapt and survive to warming, highlighting the potential additive effects that herbivory will have on ultimately determining seedling success.     

Beetles and flies collected on pig carrion in an experimental setting in Thuringia and their forensic implications

Decomposition processes and insect succession were analysed on a total of eight pig (Sus scrofa) carcasses. The survey was carried out in four different periods between November 2007 and August 2008 and on two different substrates (meadow, concrete floor close to a building). The experiments were placed in a rural site in the surroundings of Jena, Thuringia. The duration and specificity of the different decomposition stages were dependent on season, weather and quality and quantity of insect colonization. Whereas the carrion maintained a bloated appearance even after 133 days in winter, it reached the dry stage within 8 days in the summer months. The type of substrate had few effects on the decaying process, but the insects were generally more abundant on the meadow. In total, more than 57 species of Diptera belonging to 17 families and 48 species of Coleoptera belonging to 14 families were identified. Dominant species belonged to the families of Calliphoridae (n = 11 spp.), Sarcophagidae (n = 8), Muscidae (n = 9), Piophilidae (n = 3), Silphidae (n = 6), Dermestidae (n = 3), Nitidulidae (n = 4), Cleridae (n = 3) and Histeridae (n = 2). Remarkably, the rather common Nicrophorus species were completely absent, whereas the usually rare Necrodes littoralis (L.) was present in larger numbers. No distinct coincidence between the occurrence of a single species and a certain decomposition stage could be confirmed. A main objective of the study is the establishment of a forensic entomological database for Central Europe, especially Thuringia.     

Census of orthologous genes and self-organizing maps of biologically relevant transcriptional patterns in chickens (Gallus gallus)

The launch of large-scale chicken expressed sequence tags (EST) projects has placed the chicken in the lead for the number of EST sequences in agriculturally important animals. More than 451,000 chicken ESTs derived from over 158 libraries have been deposited in the NCBI dbEST database as of December 2003. But how many genes these ESTs represent and how they are expressed in different chicken tissues/organs remain undetermined. In the present research, we developed a human gene-based strategy for census of chicken orthologous genes and identification of their expression patterns. Among 34,157 human coding genes used in the study, BLAST analysis revealed that 11,066 genes provisionally matched 248,628 chicken ESTs. Based on the average EST abundance of the orthologous genes, the current public repository of chicken ESTs could represent 20,000 provisional genes. Analysis of gene expression in 14 single tissues/organs showed that approximately 15% of genes were expressed exclusively in single tissue/organ whereas the remaining 85% of genes were co-expressed in two or more tissues/organs. A majority (91.15%) of genes expressed in chicken embryos were also expressed at post-hatch stages, indicating that most genes activated in chicken embryos could serve housekeeping functions. Self-organizing maps (SOM) analysis organized 8807 provisional genes in selected chicken tissues into 98 clusters with each cluster being indicative of common regulatory factors and pathways. A total of 969 provisional orthologous genes were identified as preferentially expressed genes (PEGs) in various chicken tissues/organs (LOD>3.0). No doubt, the present study on gene expression patterns will provide insight into dynamics of metabolic pathways and tissue/organ programming and reprogramming in chickens.