From core/shell to hollow Fe/γ-Fe2O3 nanoparticles: evolution of the magnetic behavior.

High quality Fe/γ-Fe2O3 core/shell, core/void/shell, and hollow nanoparticles with two different sizes of 8 and 12 nm were synthesized, and the effect of morphology, surface and finite-size effects on their magnetic properties including the exchange bias (EB) effect were systematically investigated. We find a general trend for both systems that as the morphology changes from core/shell to core/void/shell, the magnetization of the system decays and inter-particle interactions become weaker, while the effective anisotropy and the EB effect increase. The changes are more drastic when the nanoparticles become completely hollow. Noticeably, the morphological change from core/shell to hollow increases the mean blocking temperature for the 12 nm particles but decreases for the 8 nm particles. The low-temperature magnetic behavior of the 12 nm particles changes from a collective super-spin-glass system mediated by dipolar interactions for the core/shell nanoparticles to a frustrated cluster glass-like state for the shell nanograins in the hollow morphology. On the other hand for the 8 nm nanoparticles core/shell and hollow particles the magnetic behavior is more similar, and a conventional spin glass-like transition is obtained at low temperatures. In the case of the hollow nanoparticles, the coupling between the inner and outer spin layers in the shell gives rise to an enhanced EB effect, which increases with increasing shell thickness. This indicates that the morphology of the shell plays a crucial role in this kind of exchange-biased systems.

Polymorphisms in GDF9 and BMP15 associated with fertility and ovulation rate in Moghani and Ghezel sheep in Iran.

The genetic base of fertility and ovulation rate in Moghani and Ghezel sheep in northwestern Iran and northeastern Turkey is important because of their fat-tailed meat and carpet quality wool. The genes encoding bone morphogenetic (BM) protein 15 and growth differentiation (GD) factor 9, respectively BMP15 and GDF9 have been shown to affect female productivity in domesticated sheep. Recently, numerous investigations have been performed on a variety of breeds to determine the association between mutations in these genes and fertility. Thus, in this study, we assessed such mutations in the Moghani and Ghezel breeds using polymerase chain reaction (PCR)-based restriction fragment length polymorphism (RFLP) with appropriate enzymes. Our data were similar to those of the previous studies showing that the genotypes were heterozygous for GD (G -->A) and BM (C -->T) mutations. These heterozygous genotypes resulted in higher ovulation rates, illustrating that one copy of each of the BMP15 and GDF9 mutations had equivalent effects on the ovulation rate. We demonstrate for the first time that the BM variant may not be sufficient on its own for infertility. In addition, although the previous studies have shown no notable relationship between the GD variant, known as the non-effecting mutation and sterility, we report that this mutation has an important role in the Moghani and Ghezel breeds.

Mutation of Streptomyces griseoflavus in order to obtain high yield desferrioxamine producing fused cells.

Streptomyces griseoflavus PTCC 1130 was mutated by UV irradiation. Two mutants were obtained (C7031 and S7011). These two mutants were able to produce desferioxamine. Desferrioxamine was extracted from the culture broth of the two mutated strains and the thin layer chromatogram of the products showed the R(F) values of 0.461, 0.463 and 0.456 for S7011, C7031 and the standard, respectively. The protoplasts of mutated Streptomyces griseoflavus were isolated and fused together. Total numbers of 58 fusions were obtained and only 17 fusions showed significant resistance to sodium azide and crystal violet. In terms of production of desferrioxamine only fusion PF9 and PF10 increased 68.3 and 81.8% desferrioxamine production as compared to parent strain (PTCC 1130), respectively.