Doses from radon progeny as a source of external beta and gamma radiation

Great deal of work has been devoted to determine doses from alpha particles emitted by ²²²Rn and its progeny. In contrast, contribution of beta particles and following gamma radiation to total dose has mostly been neglected so far. The present work describes a study of the detriment of ²²²Rn progeny for humans due to external exposure. Doses and dose conversion factors (DCFs) were determined for beta and gamma radiation in main organs and remainder tissue of the Oak Ridge National Laboratory phantom, taking into account ²²²Rn progeny ²¹⁴Pb and ²¹⁴Bi distributed in the middle of a standard or typical room with dimensions 4?m?×?5?m?×?2.8?m. The DCF was found to be 7.37?μSv/WLM. Skin and muscle tissue from remainder tissue receives largest dose. Beta and gamma radiation doses from external exposure were compared with alpha, beta, and gamma doses from internal exposure where the source of radioactivity was the lungs. Total doses received in all main organs and remainder tissues were obtained by summing up the doses from external and internal exposure and the corresponding DCF was found to be 20.67?μSv/WLM.     

Purification and characterization of EpiA, the peptide substrate for post-translational modifications involved in epidermin biosynthesis

Abstract For the investigation of enzymes involved in epidermin biosynthesis it is necessary to produce sufficient amounts of preepidermin (EpiA) as a substrate and to design EpiA detection systems. Therefore, EpiA was expressed in Escherichia coli using a malE-epiA fusion. The identity of purified EpiA was confirmed by ion spray mass spectrometry and amino acid sequencing. For EpiA detection, anti-EpiA antisera were raised. Upon prolonged incubation, factor Xa not only cleaved EpiA from the fusion protein, but also less efficiently cleaved EpiA internally between R⁻¹ and I⁺¹. The internal factor Xa cleavage site of EpiA was masked by altering the sequence -A⁻⁴-E-P-R⁻¹- to -A⁻⁴-E-P-Q⁻¹- by site-directed mutagenesis.     

New insights into the origin and the genetic status of the Balkan donkey from Serbia

The Balkan donkey (Equus asinus L.) is commonly regarded as a large‐sized, unselected, unstructured and traditionally managed donkey breed. We assessed the current genetic status of the three largest E. asinus populations in the central Balkans (Serbia) by analysing the variability of nuclear microsatellites and the mitochondrial (mtDNA) control region of 77 and 49 individuals respectively. We further analysed our mtDNA dataset along with 209 published mtDNA sequences of ancient and modern individuals from 19 European and African populations to provide new insights into the origin and the history of the Balkan donkey. Serbian donkey populations are highly genetically diverse at both the nuclear and mtDNA levels despite severe population decline. Traditional Balkan donkeys in Serbia are rather heterogeneous; we found two groups of individuals with similar phenotypic features, somewhat distinct nuclear backgrounds and different proportions of mtDNA haplotypes belonging to matrilineal Clades 1 and 2. Another group, characterized by larger body size, different coat colour, distinct nuclear gene pool and predominantly Clade 2 haplotypes, was delineated as the Banat donkey breed. The maternal landscape of the large Balkan donkey population is highly heterogeneous and more complex than previously thought. Given the two independent domestication events in donkeys, multiple waves of introductions into the Balkans from Greece are hypothesized. Clade 2 donkeys probably appeared in Greece prior to those belonging to Clade 1, whereas expansion and diversification of Clade 1 donkeys within the Balkans predated that of Clade 2 donkeys.