Flow cytometric and karyological analyses of Calendula species from Iberian Peninsula

Calendula L. (Asteraceae) is a taxonomically and cytologically complex genus due to its high morphological and karyological variation. To gather consistent cytological information aiming to consolidate the existing knowledge, sustain the taxonomic revision of the genus and explore the evolutionary relationships among species, the genome size and chromosome number of the Iberian Peninsula representatives of this genus were assessed. The study included 11 taxa that occur in the Iberian Peninsula, one in Madeira and two from Morocco. Chromosome counts were made using the squash technique in root tips and flower buds, while nuclear DNA contents were assessed using propidium iodide flow cytometry. The following chromosome numbers are reported: 2n = 44 for C. arvensis, 2n = 30 for C. tripterocarpa, and 2n = 32 for the remaining Iberian taxa. The genome size of Calendula species was assessed for the first time and ranged from 1.75 pg/2C in C. maroccana to 5.41 pg/2C in C. arvensis. Within the complex formed by C. incana and C. suffruticosa, a gradient of genome size values was obtained. Intraspecific variation in genome size was detected in some taxa. The obtained genome size values and their variation are discussed in the light of the theories proposed for the speciation of the genus, with events of hybridization, genome duplication and dysploidy being hypothesized to play a major role in the evolution of this genus.     

The PrPC C1 fragment derived from the ovine A136R154R171 PRNP allele is highly abundant in sheep brain and inhibits fibrillisation of full-length PrPC protein in vitro

Expression of the cellular prion protein (PrP^C) is crucial for the development of prion diseases. Resistance to prion diseases can result from reduced availability of the prion protein or from amino acid changes in the prion protein sequence. We propose here that increased production of a natural PrP α-cleavage fragment, C1, is also associated with resistance to disease. We show, in brain tissue, that ARR homozygous sheep, associated with resistance to disease, produced PrP^C comprised of 25% more C1 fragment than PrP^C from the disease-susceptible ARQ homozygous and highly susceptible VRQ homozygous animals. Only the C1 fragment derived from the ARR allele inhibits in-vitro fibrillisation of other allelic PrP^C variants. We propose that the increased α-cleavage of ovine ARR PrP^C contributes to a dominant negative effect of this polymorphism on disease susceptibility. Furthermore, the significant reduction in PrP^C β-cleavage product C2 in sheep of the ARR/ARR genotype compared to ARQ/ARQ and VRQ/VRQ genotypes, may add to the complexity of genetic determinants of prion disease susceptibility.     

No evidence of interaction between known lipid-associated genetic variants and smoking in the multi-ethnic PAGE population

Genome-wide association studies (GWAS) have identified many variants that influence high-density lipoprotein cholesterol, low-density lipoprotein cholesterol, and/or triglycerides. However, environmental modifiers, such as smoking, of these known genotype–phenotype associations are just recently emerging in the literature. We have tested for interactions between smoking and 49 GWAS-identified variants in over 41,000 racially/ethnically diverse samples with lipid levels from the Population Architecture Using Genomics and Epidemiology (PAGE) study. Despite their biological plausibility, we were unable to detect significant SNP × smoking interactions.     

Complete genome sequence of the marine methyl-halide oxidizing Leisingera methylohalidivorans type strain (DSM 14336T), a representative of the Roseobacter clade

Leisingera methylohalidivorans Schaefer et al. 2002 emend. Vandecandelaere et al. 2008 is the type species of the genus Leisingera. The genus belongs to the Roseobacter clade (Rhodobacteraceae, Alphaproteobacteria), a widely distributed lineage in marine environments. Leisingera and particularly L. methylohalidivorans strain MB2^T is of special interest due to its methylotrophy. Here we describe the complete genome sequence and annotation of this bacterium together with previously unreported aspects of its phenotype. The 4,650,996 bp long genome with its 4,515 protein-coding and 81 RNA genes consists of three replicons, a single chromosome and two extrachromosomal elements with sizes of 221 kb and 285 kb.     

Overexpression and loss-of-function at <Emphasis Type="Italic">TIME FOR COFFEE</Emphasis> results in similar phenotypes in diverse growth and physiological responses

Plant experience diurnal changes in their environment that can be anticipated and responded to via the circadian clock. Integration of external signals by this clock ensures metabolic homeostasis and ultimately enhances fitness. TIME FOR COFFEE (TIC) is known to be associated to the circadian clock, being required to maintain rhythmic period and amplitude, and to regulate clock-driven physiological responses. The molecular function of TIC has so far only been studied with loss-of-function mutants. The biochemical activity of TIC remains elusive. To learn more about TIC in diverse physiological processes, here we generated TIC overexpressing plants (TICox) and characterized their impact on plant growth, development, and circadianclock activity. TICox plants displayed phenotypic similarity with tic mutants. This included defects in leaf morphology, the developmental transition from the vegetative to reproductive phase, and circadian-clock function. These observations allowed us to hypothesize that TIC is an element of protein complexes that are involved in global biological processes.     

Biodegradation of the herbicide propanil, and its 3,4-dichloroaniline by-product in a continuously operated biofilm reactor

The persistence of propanil in soil and aquatic environments along with the possible accumulation of toxic degradation products, such as chloroanilines, is of environmental concern. In this work, a continuous small-scale bioprocess to degrade the herbicide propanil, its main catabolic by-product, 3,4-dichloroaniline (3,4-DCA), and the herbicide adjuvants is carried out. A microbial consortium, constituted by nine bacterial genera, was selected. The isolated strains, identified by amplification and sequencing of their 16S rDNA, were: Acidovorax sp., Luteibacter (rhizovicinus), Xanthomonas sp., Flavobacterium sp., Variovorax sp., Acinetobacter (calcoaceticus), Pseudomonas sp., Rhodococcus sp., and Kocuria sp. The ability of the microbial consortium to degrade the herbicide was evaluated in a biofilm reactor at propanil loading rates ranging from 1.9 to 36.8 mg L^?1 h^?1. Complete removal of propanil, 3,4-DCA, chemical oxygen demand and total organic carbon was obtained at propanil loading rates up to 24.9 mg L^?1 h^?1. At higher loading rates, the removal efficiencies decayed. Four of the identified strains could grow individually in propanil, and 3,4-DCA: Pseudomonas sp., Acinetobacter calcoaceticus, Rhodococcus sp., and Xanthomonas sp. The Kokuria strain grew on 3,4-DCA, but not on propanil. The first three bacteria have been related to biodegradation of phenyl urea herbicides or chlorinated anilines. Although some strains of the genera Xanthomonas and Kocuria have a role in the biodegradation of several xenobiotic compounds, as far as we know, there are no reports about degradation of propanil by Xanthomonas or 3,4-DCA by Kocuria species.     

Defining the roles of Asn-128, Glu-129 and Phe-130 in loop A of the 5-HT3 receptor

The ligand binding pocket of Cys-loop receptors consists of a number of binding loops termed A–F. Here we examine the 5-HT₃ receptor loop A residues Asn-128, Glu-129 and Phe-130 using modelling, mutagenesis, radioligand binding and functional studies on HEK 293 cells. Replacement of Asn-128 results in receptors that have wild type [³H]granisetron binding characteristics but large changes (ranging from a five-fold decrease to a 1500-fold increase) in the 5-HT EC₅₀ when compared to wild type receptors. Phe-130 mutant receptors show both increases and decreases in K_d and EC₅₀ values, depending on the amino acid substituted. The most critical of these residues appears to be Glu-129; its replacement with a range of other amino acids results in non-binding and non-functional receptors. Lack of binding and function in some, but not all, of these receptors is due to poor membrane expression. These data suggest that Glu-129 is important primarily for receptor expression, although it may also play a role in ligand binding; Phe-130 is important for both ligand binding and receptor function, and Asn-128 plays a larger role in receptor function than ligand binding. In light of these results, we have created two new homology models of the 5-HT₃ receptor, with alternative positions of loop A. In our preferred model Glu-129 and Phe-130 contribute to the binding site, while the location of Asn-128 immediately behind the binding pocket could contribute to the conformation changes that result in receptor gating. This study provides a new model of the 5-HT₃ receptor binding pocket, and also highlights the importance of experimental data to support modelling studies.     

New enzymes,new pathways and an alternative view on starch biosynthesis in both photosynthetic and heterotrophic tissues of plants

Since the initial discovery showing that ADPglucose (ADPG) serves as the universal glucosyl donor in the reaction catalyzed by starch synthase, the mechanism of starch biosynthesis in both leaves and heterotrophic organs has generally been considered to be an unidirectional process wherein ADPG pyrophosphorylase (AGPase) exclusively catalyzes the synthesis of ADPG and acts as the major limiting step of the gluconeogenic process. There is however mounting evidence that ADPG linked to starch biosynthesis is produced de novo in the cytosol by means of sucrose synthase (SuSy). In this review we show and discuss the numerous pitfalls of the ‘classic’ view of starch biosynthesis. In addition, we describe many overlooked aspects of both ADPG and starch metabolism. With the overall data we propose an ‘alternative’ model of starch biosynthesis, applicable to both photosynthetic and heterotrophic tissues, according to which both sucrose and starch biosynthetic processes are tightly interconnected by means of an ADPG synthesizing SuSy activity. According to this new view, starch metabolism embodies catabolic and anabolic reactions taking place simultaneously in which AGPase plays a vital role in the scavenging of starch breakdown products.