Sequence-independent characterization of viruses based on the pattern of viral small RNAs produced by the host

Virus surveillance in vector insects is potentially of great benefit to public health. Large-scale sequencing of small and long RNAs has previously been used to detect viruses, but without any formal comparison of different strategies. Furthermore, the identification of viral sequences largely depends on similarity searches against reference databases. Here, we developed a sequence-independent strategy based on virus-derived small RNAs produced by the host response, such as the RNA interference pathway. In insects, we compared sequences of small and long RNAs, demonstrating that viral sequences are enriched in the small RNA fraction. We also noted that the small RNA size profile is a unique signature for each virus and can be used to identify novel viral sequences without known relatives in reference databases. Using this strategy, we characterized six novel viruses in the viromes of laboratory fruit flies and wild populations of two insect vectors: mosquitoes and sandflies. We also show that the small RNA profile could be used to infer viral tropism for ovaries among other aspects of virus biology. Additionally, our results suggest that virus detection utilizing small RNAs can also be applied to vertebrates, although not as efficiently as to plants and insects.     

AllR Controls the Expression of Streptomyces coelicolor Allantoin Pathway Genes

Streptomyces species are native inhabitants of soil, a natural environment where nutrients can be scarce and competition fierce. They have evolved ways to metabolize unusual nutrients, such as purines and its derivatives, which are highly abundant in soil. Catabolism of these uncommon carbon and nitrogen sources needs to be tightly regulated in response to nutrient availability and environmental stimulus. Recently, the allantoin degradation pathway was characterized in Streptomyces coelicolor. However, there are questions that remained unanswered, particularly regarding pathway regulation. Here, using a combination of proteomics and genetic approaches, we identified the negative regulator of the allantoin pathway, AllR. In vitro studies confirmed that AllR binds to the promoter regions of allantoin catabolic genes and determined the AllR DNA binding motif. In addition, effector studies showed that allantoic acid, and glyoxylate, to a lesser extent, inhibit the binding of AllR to the DNA. Inactivation of AllR repressor leads to the constitutive expression of the AllR regulated genes and intriguingly impairs actinorhodin and undecylprodigiosin production. Genetics and proteomics analysis revealed that among all genes from the allantoin pathway that are upregulated in the allR mutant, the hyi gene encoding a hydroxypyruvate isomerase (Hyi) is responsible of the impairment of antibiotic production.     

p73 is required for endothelial cell differentiation,migration and the formation of vascular networks regulating VEGF and TGFβ signaling

Vasculogenesis, the establishment of the vascular plexus and angiogenesis, branching of new vessels from the preexisting vasculature, involves coordinated endothelial differentiation, proliferation and migration. Disturbances in these coordinated processes may accompany diseases such as cancer. We hypothesized that the p53 family member p73, which regulates cell differentiation in several contexts, may be important in vascular development. We demonstrate that p73 deficiency perturbed vascular development in the mouse retina, decreasing vascular branching, density and stability. Furthermore, p73 deficiency could affect non endothelial cells (ECs) resulting in reduced in vivo proangiogenic milieu. Moreover, p73 functional inhibition, as well as p73 deficiency, hindered vessel sprouting, tubulogenesis and the assembly of vascular structures in mouse embryonic stem cell and induced pluripotent stem cell cultures. Therefore, p73 is necessary for EC biology and vasculogenesis and, in particular, that DNp73 regulates EC migration and tube formation capacity by regulation of expression of pro-angiogenic factors such as transforming growth factor-β and vascular endothelial growth factors. DNp73 expression is upregulated in the tumor environment, resulting in enhanced angiogenic potential of B16-F10 melanoma cells. Our results demonstrate, by the first time, that differential p73-isoform regulation is necessary for physiological vasculogenesis and angiogenesis and DNp73 overexpression becomes a positive advantage for tumor progression due to its pro-angiogenic capacity.Vascular system formation is one of the earliest events during organogenesis.¹ The original vascular plexus is established by vasculogenesis, through differentiation and assembly of mesodermal precursors.² The angiogenesis process allows the formation of new blood vessels from the existing vasculature and is perturbed in many diseases, including cancer.³ Although efforts have been made to identify factors that control vascular development, the understanding of the molecular networks remains incomplete.The formation of new capillaries and the remodeling of preexisting blood vessels is linked by signal transduction pathways.⁴ The members of the p53 family (p53, p73 and p63) coordinate cell proliferation, migration and differentiation, and could act as regulators of vascular development. TP73 function in angiogenesis is quite controversial,^{5, 6, 7} and it has never been addressed using developmental models.TP73 has a dual nature that resides in the existence of TA and DNp73 variants. TAp73 is capable of transactivating p53 targets^{8, 9, 10} whereas DNp73 can act as p53 and TAp73 repressor.^{11, 12, 13} TP73 final outcome will depend upon the differential expression of the TA/DNp73 isoforms in each cellular context, as they can execute synergic, as well as antagonist, functions.TP73 role during development is emphasized by the p73-knockout mice (Trp73−/−, p73KO from now on) multiple growth defects.¹⁴ These mice, which lack all p73 isoforms, exhibit gastrointestinal and cranial hemorrhages,¹⁴ suggestive of vascular fragility. Furthermore, TAp73 directly regulates GATA-1,⁸ which is essential for endothelial and hematopoietic differentiation.^{15, 16} This compounded information led us to hypothesize that p73 could be implicated in the regulation of vasculogenesis/angiogenesis.Regulation of these processes involves a broad range of signaling molecules essential for vascular growth and stability,¹⁷ such as vascular endothelial growth factor (VEGF)¹⁸ and transforming growth factor-β (TGF-β).¹⁹ TGF-β operates as a rheostat that controls endothelial cell (EC) differentiation, having an inhibitory effect on EC migration and proliferation by the TGF-β/TGFRI (ALK5)/Smad2/3 pathway, while the TβRII–ALK5/ALK1 complex activates Smad1/5/8, ID1 expression and a pro-angiogenic state.^{20, 21, 22}Regulation of the TGF-β and VEGF pathways by p53 family members has been documented.^{23, 24} However, p73''s function in these pathways during development remains largely unexplored. In this work, we have used mouse embryonic stem cells (mESC) and induced pluripotent stem cells (iPSCs) as models that recapitulate early vascular morphogenesis.^{25, 26, 27} ESC and iPSC form multi-cellular aggregates (embryoid bodies, EBs) that, under appropriate conditions, generate functional EC.²⁸ mESC and iPSC differentiation capacity into ECs has been fully addressed.^{29, 30} We have also performed retinal vascularization analysis to assess vascular processes in vivo.^{31, 32}We demonstrate that p73 deficiency perturbs density and stability of mouse retinal development by affecting VEGF and TGF-β signaling. Furthermore, p73 is necessary for the assembly of vascular structures under physiological conditions in mESC and iPSC. Moreover, DNp73 positively affects angiogenesis through regulation of the TGF-β pathway in human umbilical vein cells (HUVEC) and DNp73-overexpression results in enhanced angiogenic potential of B16-F10 melanoma cells.     

Simultaneous analysis of tramadol, O-desmethyltramadol, and N-desmethyltramadol enantiomers in rat plasma by high-performance liquid chromatography-tandem mass spectrometry: application to pharmacokinetics

Tramadol (T) is available as a racemic mixture of (+)‐trans‐T and (−)‐trans‐T. The main metabolic pathways are O‐demethylation and N‐demethylation, producing trans‐O‐desmethyltramadol ( M1 ) and trans‐N‐desmethyltramadol ( M2 ) enantiomers, respectively. The analgesic effect of T is related to the opioid activity of (+)‐trans‐T and (+)‐ M1 and to the monoaminergic action of (+/−)‐trans‐T. This is the first study using tandem mass spectrometry as a detection system for the simultaneous analysis of trans‐T, M1 , and M2 enantiomers. The analytes were resolved on a Chiralpak® AD column using hexane:ethanol (95.5:4.5, v/v) plus 0.1% diethylamine as the mobile phase. The quantitation limits were 0.5 ng/ml for trans‐T and M1 and 0.1 ng/ml for M2 . The method developed and validated here was applied to a pharmacokinetic study in rats. Male Wistar rats (n = 6 at each time point) received a single oral dose of 20 mg/kg racemic trans‐T. Blood samples were collected up to 12 h after drug administration. The kinetic disposition of trans‐T and M2 was enantioselective (AUC_(+)/(−) ratio = 4.16 and 6.36, respectively). The direction and extent of enantioselectivity in the pharmacokinetics of trans‐T and M2 in rats were comparable to data previously reported for healthy volunteers, suggesting that rats are a suitable model for enantioselective studies of trans‐T pharmacokinetics. Chirality, 2011. © 2010 Wiley‐Liss, Inc.     

Genetic Structure of the Population of Alternaria solani in Brazil

Understanding the genetic structure of the population of Alternaria solani (AS) is an important component of epidemiological studies of early blight, a severe disease that affects potato (Po) and tomato (To) worldwide. Up to 150 isolates obtained from both hosts were analysed with RAPD and AFLP markers to estimate the amount and distribution of genetic variability of AS in Brazil. Using RAPD, gene diversity (h = 0.20) and scaled indices of diversity of Shannon (H′ = 0.66) and Stoddart and Taylor’s (G = 0.31) for the Po population were higher than those of the To (h = 0.07, H′ = 0.34, G = 0.17). For AFLP, the statistics for the Po (h = 0.17, H′ = 0.86, G = 0.49) and To (h = 0.17, H′ = 0.85, G = 0.36) populations were similar. For each RAPD and AFLP locus, the allele frequency for the overall population ranged from 0.006 to 0.988, and 0.007 to 0.993, respectively. Genetic differentiation was high (G_ST = 0.41 and θ = 0.59) and moderately high (G_ST = 0.23 and θ = 0.37) when estimated with RAPD and AFLP, respectively. Based on cluster analyses, there was strong evidence of association of pathogen haplotypes with host species. The null hypothesis of random association of alleles was rejected in the analysis of both RAPD (I_A = 13.1, P < 0.001) and AFLP (I_A = 2.2, P < 0.001) markers. The average number of migrants was estimated to be around one and two individuals per generation, using RAPD and AFLP, respectively. There was no correlation between genetic distance and geographical origin of AS haplotypes for RAPD (r = ?0.07, P = 0.84) and AFLP (r = ?0.03, P = 0.70). The AS population is clonal with high genetic variability, and there is genetic differentiation between the populations that affect To and Po.