Are Robertsonian variations a frequent phenomenon in mouse populations in Eurasia?

We examined the karyotypes of 212 specimens of the house mouse obtained from 44 localities in central and eastern Europe, and several regions of Asia. The Robertsonian chromosome fusion 5.12 was found in a population of Mus musculus musculus in Czechoslovakia. Two large HSRs on chromosome 1 were ascertained in four female mice from western Siberia. In most of the localities under study, the mice possessed a normal karyotype with 40 acrocentric chromosomes.     

High densities of leaf‐tiers in open habitats are explained by host plant architecture

1. Crown architecture remains one of the least studied plant traits that influence plant–herbivore interactions. The hypotheses that dense crown architecture of mountain birches from open habitats favours leaf‐tying caterpillars through bottom‐up and/or top‐down effects associated with high leaf connectivity were tested. 2. Population densities of leaf‐tying herbivores in open (industrial barren and seashore) habitats were three times as high as in the shaded (forest) habitats. An experimental increase in leaf density by branch binding did not affect foliar consumption by free‐living herbivores but increased consumption by leaf‐tiers. 3. The specific leaf weight was lower in shaded habitats and in bound branches, but branch binding did not influence either the foliar concentrations of carbon and nitrogen or the pupal weight of the most abundant leaf‐tier, Carpatolechia proximella Hbn. (Lepidoptera: Gelechiidae). 4. Caterpillars of C. proximella build several shelters during their lifetime and spend a considerable amount of time outside the shelter, where they excrete most of their faeces. In bound branches, caterpillars built new shelters more frequently than in control branches, and consumed less foliar biomass per shelter. 5. Mortality from parasitoids in bound branches was half that in the control, presumably because the complex environment disrupted parasitoid searching behaviour and/or because of lower damage to leaves from which the shelters were built. 6. It is concluded that the crown architecture associated with high leaf connectivity decreases mortality risks from natural enemies both outside and inside the shelter. Compact and dense crowns of host plants may at least partly explain high population densities of leaf‐tiers in open habitats.     

Mountain birch under multiple stressors – heavy metal‐resistant populations co‐resistant to biotic stress but maladapted to abiotic stress

Stress adaptations often include a trade‐off of weakened performance in nonlocal conditions, resulting in divergent selection, and potentially, genetic differentiation and evolutionary adaptation. Results of a two‐phase (greenhouse and field) common garden experiment demonstrated adaptation of mountain birch (Betula pubescens subsp. czerepanovii) populations from industrially polluted areas of the Kola Peninsula, north‐western Russia, to heavy metals (HM), whereas no adaptations to wind or drought stress were detected in populations from wind‐exposed sites. HM‐adapted seedlings were maladapted to drought but less palatable (co‐resistant) to insect herbivores, even under background HM concentrations. The absence of adaptations to harsh microclimate and the generally high adaptive potential of mountain birch, a critical forest forming tree in subarctic Europe, need to be accounted for in models predicting consequences of human‐driven environmental changes, including the projected climate change.     

Gene Correction by RNA‐DNA Oligonucleotides

An oligonucleotide composed of a contiguous stretch of RNA and DNA residues has been developed to facilitate the correction of single‐base mutations of episomal and chromosomal targets in mammalian cells. The design of the oligonucleotide exploited the highly recombinogenic RNA‐DNA hybrids and featured hairpin capped ends avoiding destruction by cellular helicases or exonucleases. The RNA‐DNA oligonucleotide (RDO) was designed to correct a point mutation in the tyrosinase gene and caused a permanent gene correction in mouse albino melanocytes, determined by clonal analysis at the level of genomic sequence, protein and phenotypic change. Recently, we demonstrated correction of the tyrosinase gene using the same RDO in vivo, as detected by dark pigmentation of several hairs and DOPA staining of hair follicles in the treated skin of albino mice. Such RDOs might hold a promise as a therapeutic method for the treatment of skin diseases. However, the frequency of gene correction varies among different cells, indicating that cellular activities, such as recombination and repair, may be important for gene conversion by RDOs. As this technology becomes more widely utilized in the scientific community, it will be important to understand the mechanism and to optimize the design of RDOs to improve their efficiency and general applicability.