Development and evaluation of an experimental protocol for 3-D visualization and characterization of the structure of bacterial biofilms in porous media using laboratory X-ray tomography

The development of a reliable model allowing accurate predictions of biofilm growth in porous media relies on a good knowledge of the temporal evolution of biofilm structure within the porous network. Since little is known about the real 3-D structure of biofilms in porous media, this work was aimed at developing a new experimental protocol to visualize the 3-D microstructure of the inside of a porous medium using laboratory X-ray microtomography. A reliable and reproducible methodology is proposed for (1) growing a biofilm inside a porous medium, and (2) X-ray tomography-based characterization of the temporal development of the biofilm at the inlet of the biofilter. The statistical analysis proposed here also validates the results presented in the literature based on a biofilm structure single measurement.     

Coalescent-based DNA barcoding: multilocus analysis and robustness

DNA barcoding is the assignment of individuals to species using standardized mitochondrial sequences. Nuclear data are sometimes added to the mitochondrial data to increase power. A barcoding method for analysing mitochondrial and nuclear data is developed. It is a Bayesian method based on the coalescent model. Then this method is assessed using simulated and real data. It is found that adding nuclear data can reduce the number of ambiguous assignments. Finally, the robustness of coalescent-based barcoding to departures from model assumptions is studied using simulations. This method is found to be robust to past population size variations, to within-species population structures, and to designs that poorly sample populations within species. Supplementary Material is available online at www.liebertonline.com/cmb.     

Genomic approach to study floral development genes in Rosa sp

Cultivated for centuries, the varieties of rose have been selected based on a number of flower traits. Understanding the genetic and molecular basis that contributes to these traits will impact on future improvements for this economically important ornamental plant. In this study, we used scanning electron microscopy and sections of meristems and flowers to establish a precise morphological calendar from early rose flower development stages to senescing flowers. Global gene expression was investigated from floral meristem initiation up to flower senescence in three rose genotypes exhibiting contrasted floral traits including continuous versus once flowering and simple versus double flower architecture, using a newly developed Affymetrix microarray (Rosa1_Affyarray) tool containing sequences representing 4765 unigenes expressed during flower development. Data analyses permitted the identification of genes associated with floral transition, floral organs initiation up to flower senescence. Quantitative real time PCR analyses validated the mRNA accumulation changes observed in microarray hybridizations for a selection of 24 genes expressed at either high or low levels. Our data describe the early flower development stages in Rosa sp, the production of a rose microarray and demonstrate its usefulness and reliability to study gene expression during extensive development phases, from the vegetative meristem to the senescent flower.     

3-Keto-5-aminohexanoate cleavage enzyme: a common fold for an uncommon Claisen-type condensation

The exponential increase in genome sequencing output has led to the accumulation of thousands of predicted genes lacking a proper functional annotation. Among this mass of hypothetical proteins, enzymes catalyzing new reactions or using novel ways to catalyze already known reactions might still wait to be identified. Here, we provide a structural and biochemical characterization of the 3-keto-5-aminohexanoate cleavage enzyme (Kce), an enzymatic activity long known as being involved in the anaerobic fermentation of lysine but whose catalytic mechanism has remained elusive so far. Although the enzyme shows the ubiquitous triose phosphate isomerase (TIM) barrel fold and a Zn(2+) cation reminiscent of metal-dependent class II aldolases, our results based on a combination of x-ray snapshots and molecular modeling point to an unprecedented mechanism that proceeds through deprotonation of the 3-keto-5-aminohexanoate substrate, nucleophilic addition onto an incoming acetyl-CoA, intramolecular transfer of the CoA moiety, and final retro-Claisen reaction leading to acetoacetate and 3-aminobutyryl-CoA. This model also accounts for earlier observations showing the origin of carbon atoms in the products, as well as the absence of detection of any covalent acyl-enzyme intermediate. Kce is the first representative of a large family of prokaryotic hypothetical proteins, currently annotated as the "domain of unknown function" DUF849.     

Deep,subsurface microflora after excavation respiration and biomass and its potential role in degradation of fossil organic matter

Three types of Miocene claystones (amorphous, lamellar, and transitional) were aseptically sampled from depths of 30 m and 150 m below the soil surface. Respiration of these sediments was measured under conditions that prevented inoculation by other microorganisms not indigenous to the claystones in situ. Microbial respiration was higher in lamellar than amorphous claystones and was not affected by sampling depth. During cultivation, microbial biomass (as indicated by PLFA) significantly increased. Microbial biomass after cultivation was significantly higher in sediments from 30 m than from 150 m depth. Both microbial respiration and biomass increased after glucose addition.     

Facial Expression Wrinkles and Their Relaxation by a Synthetic Peptide

International Journal of Peptide Research and Therapeutics - Expression wrinkles form over time due to repeated facial movements such as smiling and frowning. They have an imprint on facial skin in...     

Hydrostatic and osmotic pressure study of the hairpin ribozyme

The recent discovery of numerous catalytically active RNAs in various living species as well as the in vitro selection of a large series of RNA aptamers able to bind specifically various molecules such as metabolites and co-factors, emphasize the adaptability of RNAs through the plasticity of their secondary structure. Furthermore, all these observations give support to the "RNA world" hypothesis as a step in the primitive development of life on Earth. On this background, we used high pressure to study the mechanism of action of a model hairpin ribozyme which exhibits self-cleavage and ligation. The activation volume (DeltaV( not equal)) of the cleavage reaction (34+/-4 ml/mol) indicates that an important compaction of the RNA molecule occurs during the reaction and must be accompanied by a significant movement of water molecules . Indeed, such a release of 78+/-4 water molecules per RNA molecule could be measured by complementary osmotic shock experiments. These results are consistent with the information provided by the structural studies which indicate that two loops of the RNA molecule should come into contact for the reaction to occur .The high pressure study of a modified form of the ribozyme whose activity is strictly dependent on the presence of adenine as a co-factor should bring some information about the structural significance of this important DeltaV( not equal) of activation.     

A Conserved Gene Cluster Rules Anaerobic Oxidative Degradation of l-Ornithine

For the ornithine fermentation pathway, described more than 70 years ago, genetic and biochemical information are still incomplete. We present here the experimental identification of the last four missing genes of this metabolic pathway. They encode l-ornithine racemase, (2R,4S)-2,4-diaminopentanoate dehydrogenase, and the two subunits of 2-amino-4-ketopentanoate thiolase. While described only for the Clostridiaceae to date, this pathway is shown to be more widespread.The catabolism of ornithine by anaerobic bacteria can be accomplished through the Stickland reaction, the main chemical reaction by which Clostridium sporogenes obtains its energy (16, 17). The Stickland reaction usually involves one amino acid which acts as an electron donor while another acts as an electron acceptor, as described for Clostridium sporogenes (16, 20), Clostridium botulinum (4, 5), and Clostridium sticklandii (6, 7). However, l-ornithine, as a single substrate, is converted into both an electron donor and acceptor and metabolized in a way similar to the Stickland reaction: it is oxidized to acetate, alanine, and ammonia (oxidative pathway) and reduced to 5-aminovalerate through the formation of proline (reductive pathway) (Fig. ​(Fig.1).1). This study focuses on the oxidative degradation pathway, starting with the conversion of l-ornithine to the d isomer by ornithine racemase (OR) (EC 5.1.1.12) (Fig. ​(Fig.1,1, step 1) (2). d-Ornithine is next converted to (2R,4S)-2,4-diaminopentanoate (DAP) through the action of d-ornithine aminomutase (OA) (EC 5.4.3.5) (Fig. ​(Fig.1,1, step 2), an adenosylcobalamine and pyridoxal phosphate (PLP)-dependent enzyme (3, 14). DAP then undergoes a NAD⁺- or NADP⁺-dependent oxidative deamination by DAP dehydrogenase (DAPDH) (EC 1.4.1.12) (Fig. ​(Fig.1,1, step 3), leading to 2-amino-4-ketopentanoate (AKP) (13, 18). This compound is metabolized by AKP thiolase (AKPT), a PLP-dependent enzyme, through a thiolytic cleavage with coenzyme A (CoA) to form acetyl-CoA and alanine (Fig. ​(Fig.1,1, step 4) (9).Open in a separate windowFIG. 1.The ornithine fermentation pathway. Enzymes involved are OR (encoded by or-5) (EC 5.1.1.12) in step 1, OA (encoded by oraS and oraE) (EC 5.4.3.5) in step 2, DAPDH (encoded by or-1) (EC 1.4.1.12) in step 3, AKPT (encoded by or-2 and or-3) in step 4, ornithine transaminase (EC 2.6.1.13) in step 5, spontaneous in step 6, pyrroline-5-carboxylate reductase (EC 1.5.1.2) in step 7, proline racemase (EC 5.1.1.4) in step 8, d-proline reductase (EC 1.21.4.1) in step 9, and ornithine cyclodeaminase (EC 4.3.1.12) in step 10.Although the proteins of this oxidative pathway were characterized biochemically 30 years ago for C. sticklandii, only the genes corresponding to the two subunits of OA (oraS and oraE) have been identified to date (3). In this article, we present the analysis of genes which are colocalized with oraS and oraE and which are hypothesized to be involved in the conversion of l-ornithine to d-ornithine, the oxidative deamination of DAP, and the thiolytic cleavage of AKP. The proteins encoded by these genes were purified and their enzymatic activity characterized, which made it possible to reconstitute the whole oxidative branch of the l-ornithine fermentation pathway in vitro. The occurrence of this oxidative metabolic pathway in bacterial genomes which have been sequenced to date is discussed.     

Human IRGM regulates autophagy and cell-autonomous immunity functions through mitochondria

IRGM, a human immunity-related GTPase, confers autophagic defence against intracellular pathogens by an unknown mechanism. Here, we report an unexpected mode of IRGM action. IRGM demonstrated differential affinity for the mitochondrial lipid cardiolipin, translocated to mitochondria, affected mitochondrial fission and induced autophagy. Mitochondrial fission was necessary for autophagic control of intracellular mycobacteria by IRGM. IRGM influenced mitochondrial membrane polarization and cell death. Overexpression of IRGMd, but not IRGMb splice isoforms, caused mitochondrial depolarization and autophagy-independent, but Bax/Bak-dependent, cell death. By acting on mitochondria, IRGM confers autophagic protection or cell death, explaining IRGM action both in defence against tuberculosis and in the damaging inflammation caused by Crohn's disease.