Phylogenetic consideration of two scuticociliate genera, Philasterides and Boveria (Protozoa, Ciliophora) based on 18 S rRNA gene sequences

Many scuticociliates are facultative parasites of aquatic organisms and are among the most problematic ciliate taxa regarding their systematic relationships. The main reason is that most species, especially taxa in the order Thigmotrichida have similar morphology and have not been studied yet using molecular methods. In the present work, two scuticociliate genera, represented by two rare parasitic species, Philasterides armatalis (order Philasterida) and Boveria subcylindrica (order Thigmotrichida), were studied, and phylogenetic trees concerning these two genera were constructed based on their 18 S rRNA gene sequences. The results indicate that: 1) Philasterides forms a sister group with Philaster, supporting the classification that these two genera belong to the family Philasteridae; 2) it is confirmed that the nominal species, Philasterides dicentrarchi Dragesco et al., 1995 should be a junior synonym of Miamiensis avidus as revealed by both previous investigations and the data revealed in the present work; and 3) the poorly known form B. subcylindrica, the only member in the order Thigmotrichida, of which molecular data are available so far, always clusters with Cyclidium glaucoma, a highly specialized scuticociliate, indicating a sister relationship between the orders Thigmotrichida and Pleuronematida.     

Propensities of Aromatic Amino Acids versus Leucine and Proline to Induce Residual Structure in the Denatured-State Ensemble of Iso-1-cytochrome c

Histidine-heme loop formation in the denatured state of a protein is a sensitive means for probing residual structure under unfolding conditions. In this study, we use a host-guest approach to investigate the relative tendencies of different amino acids to promote residual structure under denaturing conditions. The host for this work is a 6-amino-acid insert of five alanines, followed by a lysine engineered immediately following a unique histidine near the N-terminus of yeast iso-1-cytochrome c. We substitute the fourth alanine in this sequence HAAAXAK (with X = Trp, Phe, Tyr, and Leu). The effects of proline are tested with substitutions at positions 1 and 5 in the insert (HPAAAAK and HAAAAPK, respectively). Thermodynamic studies on His-heme loop formation in 3 M guanidine hydrochloride reveal significant stabilization of residual structure by aromatic amino acids, particularly Trp and Phe, and minimal stabilization of residual structure by Leu. Prolines slightly disfavor His-heme loop formation, presumably due to enhanced chain stiffness. Kinetic studies reveal that much of the change in His-heme loop stability for the aromatic amino acids is caused by a slowdown in the rate of His-heme loop breakage, indicating that residual structure is preferentially stabilized in the closed-loop form of the denatured state.     

SplicerAV: a tool for mining microarray expression data for changes in RNA processing

Background  

Over the past two decades more than fifty thousand unique clinical and biological samples have been assayed using the Affymetrix HG-U133 and HG-U95 GeneChip microarray platforms. This substantial repository has been used extensively to characterize changes in gene expression between biological samples, but has not been previously mined en masse for changes in mRNA processing. We explored the possibility of using HG-U133 microarray data to identify changes in alternative mRNA processing in several available archival datasets.     

Formation of conjugated linoleic acid metabolites in human vascular endothelial cells

Conjugated linoleic acids (CLAs) are bioactive lipid compounds showing anti-atherogenic actions in cell culture experiments and animal models of atherosclerosis without exact knowledge about the underlying mechanisms. CLAs were recently reported to be further metabolized to bioactive conjugated metabolites indicating that these metabolites are possibly involved in mediating the anti-atherogenic actions of CLA. Regarding the lack of information with respect to the formation of CLA metabolites in the vascular endothelium, which is strongly involved in the process of atherosclerosis, the present study aimed to explore the potential formation of CLA metabolites in vascular endothelial cells. The results from the present study show for the first time that the CLA isomers cis-9, trans-11 CLA and trans-10, cis-12 CLA are metabolized within endothelial cells to beta-oxidation products such as CD16:2c7t9 and CD16:2t8c10 and elongation products such as CD20:2c11t13, CD20:2t12c14 as well as CD22:2c13t15 and CD22:2t14c16. Different CD16:2/CLA ratios observed between cells treated with different CLA isomers indicate that the metabolism of CLAs depends on the configuration of the conjugated double bonds. In conclusion, regarding the biological activity reported for CD20:2t12c14 and other metabolites of CLA, the present results indicate that metabolites of CLA are possibly also involved in mediating the anti-atherogenic actions of CLA.     

Characterization of human saposins by NMR spectroscopy

Saposins are lipid-binding and membrane-perturbing glycoproteins of the mammalian lysosomes involved in sphingolipid and membrane digestion. Although the four human saposins (Saps), A-D, are sequence-related, they are responsible for the activation of different steps in the cascade of lysosomal glycosphingolipid degradation. Saposin activity is maximal under acidic conditions, and the pH dependence of lipid and membrane binding has been assigned to conformational variability. We have employed solution NMR spectroscopy to all four (15)N-labeled human saposins at both neutral and acidic pH. Using backbone NOEs and residual dipolar couplings, the "saposin fold" comprising five alpha-helices was confirmed for Sap-A, Sap-C, and Sap-D. Structural variations within these proteins are in the order of variations between the known structures of Sap-C and NK-lysin. In contrast, Sap-B yielded spectra of very poor quality, presumably due to conformational heterogeneity and molecular association. Sap-D exists in a slow dynamic equilibrium of two conformational states with yet unknown function. At pH 4.0, where all saposins are highly unstable, Sap-C undergoes a transition to a specific dimeric state, which is likely to resemble the structure recently found in both Sap-C in a detergent environment and crystals of Sap-B.     

Cloning, Functional Identification and Sequence Analysis of Flavonoid 3′-hydroxylase and Flavonoid 3′,5′-hydroxylase cDNAs Reveals Independent Evolution of Flavonoid 3′,5′-hydroxylase in the Asteraceae Family

Flavonoids are ubiquitous secondary plant metabolites which function as protectants against UV light and pathogens and are involved in the attraction of pollinators as well as seed and fruit dispersers. The hydroxylation pattern of the B-ring of flavonoids is determined by the activity of two members of the vast and versatile cytochrome P450 protein (P450) family, the flavonoid 3′-hydroxylase (F3′H) and flavonoid 3′,5′-hydroxylase (F3′5′H). Phylogenetic analysis of known sequences of F3′H and F3′5′H indicated that F3′5′H was recruited from F3′H before the divergence of angiosperms and gymnosperms. Seven cDNAs were isolated from species of the Asteraceae family, all of which were predicted to code for F3′Hs based on their sequences. The recombinant proteins of four of the heterologously in yeast expressed cDNAs exhibited the expected F3′H activity but surprisingly, three recombinant proteins showed F3′5′H activity. Phylogenetic analyses indicated the independent evolution of an Asteraceae-specific F3′5′H. Furthermore, sequence analysis of these unusual F3′5′H cDNAs revealed an elevated rate of nonsynonymous substitutions as typically found for duplicated genes acquiring new functions. Since F3′5′H is necessary for the synthesis of 3′,4′,5′-hydroxylated delphinidin-derivatives, which normally provide the basis for purple to blue flower colours, the evolution of an Asteraceae-specific F3′5′H probably reflects the adaptive value of efficient attraction of insect pollinators.     

Ethanol is a better inducer of DNA guanine tetraplexes than potassium cations

Guanine tetraplexes are a biologically relevant alternative of the Watson and Crick duplex of DNA. It is thought that potassium or other cations present in the cavity between consecutive guanine tetrads are an integral part of the tetraplexes. Here we show using CD spectroscopy that ethanol induces the guanine tetraplexes like or even better than potassium cations. We present examples of ethanol stabilizing guanine tetraplexes even in cases when potassium cations fail to do so. Hence, besides the A-form or Z-form, ethanol stabilizes another conformation of DNA, i.e., the guanine tetraplexes. We discuss the mechanism of the stabilization. Use of ethanol will permit studies of guanine tetraplexes that cannot be induced by potassium cations or other tetraplex-promoting agents. This work demonstrates that a still broader spectrum of nucleotide sequences can fold into guanine tetraplexes than has previously been thought. Aqueous ethanol may better simulate conditions existing in vivo than the aqueous solutions.     

In vitro induction of micronuclei by monofunctional methanesulphonic acid esters: possible role of alkylation mechanisms

Six monofunctional alkylating methanesulphonates of widely varying structures were investigated in the in vitro micronucleus assay with Syrian hamster embryo fibroblast cells. The results were compared with the alkylating activities measured in the 4-(nitrobenzyl)pyridine test (NBP-test) and the N-methyl mercaptoimidazole (MMI-test) as measures for S(N)2 reactivity as well as in the triflouoroacetic acid (TFA) solvolysis and the hydrolysis reaction as measures for S(N)1 reactivity in order to provide insights into the role of alkylation mechanisms on induction of micronuclei. Moreover we compared the results of micronucleus assay with those of the Ames tests in strain TA 100 and TA1535 and with those of the SOS chromotest with the strains PQ37, PQ243, PM21 and GC 4798. The potency of methanesulphonates to induce micronuclei depended only to a certain degree, on the total alkylating activity (S(N)1 and S(N)2 reactivity). An inverse, significant correlation between the Ames test and the micronucleus assay was observed and an inverse correlation between the micronucleus assay and the SOS chromotest with the different strains. The results indicate that the primary mechanism leading to induction of micronuclei is not O-alkylation in DNA as it is the case in the Ames test with the hisG46 strains TA1535 and TA100 and not N-alkylation as with the SOS chromotest. There is evidence that protein alkylation, e.g. in the spindle apparatus in mitosis is decisive for induction of micronuclei by alkylating compounds. The structurally voluminous methanesulphonates 2-phenyl ethyl methanesulphonate and 1-phenyl-2-propyl methanesulphonate show a clear higher micronuclei inducing potency than the other tested though the bulky methanesulphonates possess a lower total alkylating activity than the others. This effect can be explained by a higher disturbance during mitosis after alkylation of the spindle apparatus with the structurally more bulky methanesulphonates.     

Dominant-negative Pes1 mutants inhibit ribosomal RNA processing and cell proliferation via incorporation into the PeBoW-complex

The nucleolar PeBoW-complex, consisting of Pes1, Bop1 and WDR12, is essential for cell proliferation and processing of ribosomal RNA in mammalian cells. Here we have analysed the physical and functional interactions of Pes1 deletion mutants with the PeBoW-complex. Pes1 mutants M1 and M5, with N- and C-terminal truncations, respectively, displayed a dominant-negative phenotype. Both mutants showed nucleolar localization, blocked processing of the 36S/32S precursors to mature 28S rRNA, inhibited cell proliferation, and induced high p53 levels in proliferating, but not in resting cells. Mutant M1 and M5 proteins associated with large pre-ribosomal complexes and co-immunoprecipitated Bop1 and WDR12 proteins indicating their proper incorporation into the PeBoW-complex. We conclude that the dominant-negative effect of the M1 and M5 mutants is mediated by the impaired function of the PeBoW-complex.