(T2AG3)n Telomeric Sequence Hybridization Suggestive of Centric Fusion in Karyotype Marsupials Evolution

It has been suggested that the karyotype of the marsupials derived from a low diploid number (2n = 14) which originated, through fissions of biarmed chromosomes, the karyotypes with a higher 2n. The telomeric sequence (T₂AG₃)_nwas in situhybridized to the chromosomes of Gracilinanus microtarsusand G. emiliae, Micoureus demeraraeand Marmosa murina, species with 2n = 14, in Monodelphissp., M. domestica, M. kunsiand M. brevicaudatawith 2n = 18, and in Lutreolina crassicaudata, Didelphis albiventris, Chironectes minimus, Philander opossumand P. frenata, all of them with 2n = 22. The probe hybridization occurred in the telomeric regions of both arms, short and long, of all chromosomes of the complement of all individuals of all species analysed. However, in some pairs of the karyotypes of Gracilinanus microtarsusand Micoureus demerarae(with 2n = 14), and in Monodelphissp., M. domestica, M. kunsiand M. brevicaudata(2n = 18) ectopic signs of hybridization were detected proximal to the centromeres, suggesting the retention of this telomeric sequence in the centromeric regions of some chromosomes of these species. Based on these results, it is proposed that the karyotype of marsupials evolved from a 2n = 22 to a 2n = 14, by means of chromosomal fusions. This revised version was published online in July 2006 with corrections to the Cover Date.     

Chromium determinations in blood cells: clinical relevance demonstrated in patients with diabetes mellitus type 2

As an essential nutrient involved in carbohydrate and lipid metabolism, chromium is of extraordinary importance for patients with diabetes. Plasma concentrations do not reflect the chromium supply; thus, we determined the element’s content in blood cells in order to evaluate the body status. We investigated 86 blood donors (C) and 35 diabetics type 2 (Dm2). After the isolation of the blood cells by using a density centrifugation, the chromium concentrations were determined by electrothermal atomic absorption spectrometry. Compared to C, Dm2 had higher values in plasma, erythrocytes, and platelets (248%, 61%, and 91%, respectively) and lower contents in polymorphonuclear and mononuclear leukocytes (each −35%, age- and sex-matched groups with n=35, each p<0.01). The poorer the metabolic control assessed by HbA1c, the higher were the chromium concentrations in plasma (r=+0.46, n=33, p=0.007, increase 11.1% per %HbA1c) and the lower were the values in mononuclear leukocytes (r=−0.45, n=33, p=0.008, decrease 17.8% per %HbA1c). The changed amounts in plasma and in mononuclear cells in increasing hyperglycemia could be the result of an intracellular/extracellular redistribution of the element. High plasma levels might explain the renal chromium losses of diabetics, whereas the lymphocytes could reflect a decreasing chromium body state.     

Exploring the active site of yeast xylose reductase by site-directed mutagenesis of sequence motifs characteristic of two dehydrogenase/reductase family types

Starting from a common tyrosine, yeast xylose reductases (XRs) contain two conserved sequence motifs corresponding to the catalytic signatures of single-domain reductases/epimerases/dehydrogenases (Tyrⁿ-(X)₃-Lysⁿ⁺⁴) and aldo/keto reductases (AKRs) (Tyrⁿ-(X)₂₈-Lysⁿ⁺²⁹). Tyr⁵¹, Lys⁵⁵ and Lys⁸⁰ of XR from Candida tenuis were replaced by site-directed mutagenesis. The purified Tyr⁵¹→ Phe and Lys⁸⁰→Ala mutants showed turnover numbers and catalytic efficiencies for NADH-dependent reduction of -xylose between 2500- and 5000-fold below wild-type levels, suggesting a catalytic role of both residues. Replacing Lys⁵⁵ by Asn, a substitution found in other AKRs, did not detectably affect binding of coenzymes, and enzymatic catalysis to carbonyl/alcohol interconversion. The contribution of Tyr⁵¹ to rate enhancement of aldehyde reduction conforms with expectations for the general acid catalyst of the enzymatic reaction.     

Towards Antiviral shRNAs Based on the AgoshRNA Design

RNA interference (RNAi) can be induced by intracellular expression of a short hairpin RNA (shRNA). Processing of the shRNA requires the RNaseIII-like Dicer enzyme to remove the loop and to release the biologically active small interfering RNA (siRNA). Dicer is also involved in microRNA (miRNA) processing to liberate the mature miRNA duplex, but recent studies indicate that miR-451 is not processed by Dicer. Instead, this miRNA is processed by the Argonaute 2 (Ago2) protein, which also executes the subsequent cleavage of a complementary mRNA target. Interestingly, shRNAs that structurally resemble miR-451 can also be processed by Ago2 instead of Dicer. The key determinant of these “AgoshRNA” molecules is a relatively short basepaired stem, which avoids Dicer recognition and consequently allows alternative processing by Ago2. AgoshRNA processing yields a single active RNA strand, whereas standard shRNAs produce a duplex with guide and passenger strands and the latter may cause adverse off-target effects. In this study, we converted previously tested active anti-HIV-1 shRNA molecules into AgoshRNA. We tested several designs that could potentially improve AgoshRNA activity, including extension of the complementarity between the guide strand and the mRNA target and reduction of the thermodynamic stability of the hairpins. We demonstrate that active AgoshRNAs can be generated. However, the RNAi activity is reduced compared to the matching shRNAs. Despite reduced RNAi activity, comparison of an active AgoshRNA and the matching shRNA in a sensitive cell toxicity assay revealed that the AgoshRNA is much less toxic.     

Genome scans for transmission ratio distortion regions in mice

Transmission ratio distortion (TRD) is the departure from the expected genotypic frequencies under Mendelian inheritance. This departure can be due to multiple physiological mechanisms during gametogenesis, fertilization, fetal and embryonic development, and early neonatal life. Although a few TRD loci have been reported in mouse, inheritance patterns have never been evaluated for TRD. In this article, we developed a Bayesian binomial model accounting for additive and dominant deviation TRD mechanisms. Moreover, this model was used to perform genome-wide scans for TRD quantitative trait loci (QTL) on six F2 mouse crosses involving between 296 and 541 mice and between 72 and 1854 genetic markers. Statistical significance of each model was checked at each genetic marker with Bayes factors. Genome scans revealed overdominance TRD QTL located in mouse chromosomes 1, 2, 12, 13, and 14 and additive TRD QTL in mouse chromosomes 2, 3, and 15, although these results did not replicate across mouse crosses. This research contributes new statistical tools for the analysis of specific genetic patterns involved in TRD in F2 populations, our results suggesting a relevant incidence of TRD phenomena in mouse with important implications for both statistical analyses and biological research.     

Chloroplasts as source and target of cellular redox regulation: a discussion on chloroplast redox signals in the context of plant physiology

During the evolution of plants, chloroplasts have lost the exclusive genetic control over redox regulation and antioxidant gene expression. Together with many other genes, all genes encoding antioxidant enzymes and enzymes involved in the biosynthesis of low molecular weight antioxidants were transferred to the nucleus. On the other hand, photosynthesis bears a high risk for photo-oxidative damage. Concomitantly, an intricate network for mutual regulation by anthero- and retrograde signals has emerged to co-ordinate the activities of the different genetic and metabolic compartments. A major focus of recent research in chloroplast regulation addressed the mechanisms of redox sensing and signal transmission, the identification of regulatory targets, and the understanding of adaptation mechanisms. In addition to redox signals communicated through signalling cascades also used in pathogen and wounding responses, specific chloroplast signals control nuclear gene expression. Signalling pathways are triggered by the redox state of the plastoquinone pool, the thioredoxin system, and the acceptor availability at photosystem I, in addition to control by oxolipins, tetrapyrroles, carbohydrates, and abscisic acid. The signalling function is discussed in the context of regulatory circuitries that control the expression of antioxidant enzymes and redox modulators, demonstrating the principal role of chloroplasts as the source and target of redox regulation.