Simulating small‐scale climate change effects–lessons from a short‐term field manipulation experiment on grassland arthropods

Climate change is expected to cause major consequences on biodiversity. Understanding species‐specific reactions, such as species shifts, species declines, and changes in population dynamics is a key issue to quantify large‐scale impacts of climate change on biotic communities. As it is often impossible or at least impracticable to conduct large‐scale experiments on biotic responses to climate change, studies at a smaller scale may be a useful alternative. In our study, we therefore tested responses of grassland arthropods (carabid beetles, spiders, grasshoppers) to simulated climate change in terms of species activity densities and diversity. We conducted a controlled field experiment by changing water and microclimatic conditions at a small scale (16 m²). Roof constructions were used to increase drought‐like conditions, whereas water supply was enhanced by irrigation. In all, 2 038 carabid beetles (36 species), 4 893 spiders (65 species), and 303 Orthoptera (4 species) were caught using pitfall traps from May to August, 2010. During our experiment, we created an artificial small‐scale climate change; and statistics revealed that these changes had short‐term effects on the total number of individuals and Simpson diversity of the studied arthropod groups. Moreover, our results showed that certain species might react very quickly to climate change in terms of activity densities, which in turn might influence diversity due to shifts in abundance patterns. Finally, we devised methodological improvements that may further enhance the validity of future studies.     

A Novel Putative Transporter Maps to the Osteosclerosis (oc) Mutation and Is Not Expressed in theocMutant Mouse

The phenotype of mice homozygous for the osteosclerosis (oc) mutation includes osteopetrosis, and a variety of studies demonstrate that osteoclasts in these mice are present but nonfunctional. We have identified a novel gene that has homology to a family of 12-transmembrane domain proteins with transport functions and maps to proximal mouse chromosome 19, in a region to which theocmutation has been previously assigned. The putative transporter is abundant in normal kidney, but its expression is markedly reduced in kidneys fromoc/ocmice when tested using Northern and Western analyses. Southern analysis of this gene, which we callRoct(reduced inoctransporter), demonstrates that it is intact and unrearranged inoc/ocmice.In situstudies show thatRoctis expressed in developing bone. We propose that the absence ofRoctexpression results in an osteopetrosis phenotype in mice.     

Oxygen Affects Gut Bacterial Colonization and Metabolic Activities in a Gnotobiotic Cockroach Model

The gut microbiota of termites and cockroaches represents complex metabolic networks of many diverse microbial populations. The distinct microenvironmental conditions within the gut and possible interactions among the microorganisms make it essential to investigate how far the metabolic properties of pure cultures reflect their activities in their natural environment. We established the cockroach Shelfordella lateralis as a gnotobiotic model and inoculated germfree nymphs with two bacterial strains isolated from the guts of conventional cockroaches. Fluorescence microscopy revealed that both strains specifically colonized the germfree hindgut. In diassociated cockroaches, the facultatively anaerobic strain EbSL (a new species of Enterobacteriaceae) always outnumbered the obligately anaerobic strain FuSL (a close relative of Fusobacterium varium), irrespective of the sequence of inoculation, which showed that precolonization by facultatively anaerobic bacteria does not necessarily favor colonization by obligate anaerobes. Comparison of the fermentation products of the cultures formed in vitro with those accumulated in situ indicated that the gut environment strongly affected the metabolic activities of both strains. The pure cultures formed the typical products of mixed-acid or butyrate fermentation, whereas the guts of gnotobiotic cockroaches accumulated mostly lactate and acetate. Similar shifts toward more-oxidized products were observed when the pure cultures were exposed to oxygen, which corroborated the strong effects of oxygen on the metabolic fluxes previously observed in termite guts. Oxygen microsensor profiles of the guts of germfree, gnotobiotic, and conventional cockroaches indicated that both gut tissue and microbiota contribute to oxygen consumption and suggest that the oxygen status influences the colonization success.     

Benzpyrene-Induced sister chromatid exchanges in lymphocytes of patients with lung cancer

Summary The effect of benzpyrene on sister chromatid exchange was determined in PHA-stimulated lymphocytes of 18 patients with lung cancer and 11 controls without cancer or bronchopulmonary diseases. Patients and controls did not differ either with respect to the spontaneous rate of sister chromatid exchanges or in their response to the carcinogen. We conclude that individual susceptibility to lung cancer cannot be detected by an individual response to benzpyrene, at least in lymphocytes and at the chromosomal level.     

Dipeptidyl peptidase IV (DP IV) and superoxide dismutase activity in thymus-derived lymphocytes: effects of inhibitory peptides and Zn2+ in vitro

DP IV and superoxide dismutase (SOD) activity in thymus-derived lymphocytes of rats was assayed in vitro. The DP IV activity was measured fluorimetrically by hydrolysis of Leu-Pro-AMC, and the SOD activity by the inhibition of autooxidation of L-adrenaline. In order of their competitive inhibitory potency the following peptides were tested against DP IV and SOD activity: Ile-Pro-Ile (diprotin A), Val-Pro-Leu (diprotin B), Ile-Pro, Leu-Pro, Val-Pro, Tyr-D--Ala-Ala-Pro, Phe-Pro, Tyr-Pro, Ala-Ala-Pro and Gly-Pro. The peptides, in the order of their potency against DP IV, were effective to inhibit the SOD activity in T lymphocytes. Zn2+ ions exerted an inhibition on both DP IV and SOD activity in a near equimolar concentration. The involvement of Zn2+ as well as the peptides liberated by hydrolysis of polypeptides in regulation of cell-mediated immune responses has been discussed.     

Ecological,evolutionary, and conservation implications of incubation temperature‐dependent phenotypes in birds

Incubation is a vital component of reproduction and parental care in birds. Maintaining temperatures within a narrow range is necessary for embryonic development and hatching of young, and exposure to both high and low temperatures can be lethal to embryos. Although it is widely recognized that temperature is important for hatching success, little is known about how variation in incubation temperature influences the post‐hatching phenotypes of avian offspring. However, among reptiles it is well known that incubation temperature affects many phenotypic traits of offspring with implications for their future survival and reproduction. Although most birds, unlike reptiles, physically incubate their eggs, and thus behaviourally control nest temperatures, variation in temperature that influences embryonic development still occurs among nests within a population. Recent research in birds has primarily been limited to populations of megapodes and waterfowl; in each group, incubation temperature has substantial effects on hatchling phenotypic traits important for future development, survival, and reproduction. Such observations suggest that incubation temperature (and incubation behaviours of parents) is an important but underappreciated parental effect in birds and may represent a selective force instrumental in shaping avian reproductive ecology and life‐history traits. However, much more research is needed to understand how pervasive phenotypic effects of incubation temperature are among birds, the sources of variation in incubation temperature, and how effects on phenotype arise. Such insights will not only provide foundational information regarding avian evolution and ecology, but also contribute to avian conservation.