Anandamide induces sperm release from oviductal epithelia through nitric oxide pathway in bovines

Mammalian spermatozoa are not able to fertilize an egg immediately upon ejaculation. They acquire this ability during their transit through the female genital tract in a process known as capacitation. The mammalian oviduct acts as a functional sperm reservoir providing a suitable environment that allows the maintenance of sperm fertilization competence until ovulation occurs. After ovulation, spermatozoa are gradually released from the oviductal reservoir in the caudal isthmus and ascend to the site of fertilization. Capacitating-related changes in sperm plasma membrane seem to be responsible for sperm release from oviductal epithelium. Anandamide is a lipid mediator that participates in the regulation of several female and male reproductive functions. Previously we have demonstrated that anandamide was capable to release spermatozoa from oviductal epithelia by induction of sperm capacitation in bovines. In the present work we studied whether anandamide might exert its effect by activating the nitric oxide (NO) pathway since this molecule has been described as a capacitating agent in spermatozoa from different species. First, we demonstrated that 1 μM NOC-18, a NO donor, and 10 mM L-Arginine, NO synthase substrate, induced the release of spermatozoa from the oviductal epithelia. Then, we observed that the anandamide effect on sperm oviduct interaction was reversed by the addition of 1 μM L-NAME, a NO synthase inhibitor, or 30 μg/ml Hemoglobin, a NO scavenger. We also demonstrated that the induction of bull sperm capacitation by nanomolar concentrations of R(+)-methanandamide or anandamide was inhibited by adding L-NAME or Hemoglobin. To study whether anandamide is able to produce NO, we measured this compound in both sperm and oviductal cells. We observed that anandamide increased the levels of NO in spermatozoa, but not in oviductal cells. These findings suggest that anandamide regulates the sperm release from oviductal epithelia probably by activating the NO pathway during sperm capacitation.     

Spatial and Temporal Gene Expression Differences in Core and Periinfarct Areas in Experimental Stroke: A Microarray Analysis

Background

A large number of genes are regulated to promote brain repair following stroke. The thorough analysis of this process can help identify new markers and develop therapeutic strategies. This study analyzes gene expression following experimental stroke.

Methodology/Principal Findings

A microarray study of gene expression in the core, periinfarct and contralateral cortex was performed in adult Sprague-Dawley rats (n = 60) after 24 hours (acute phase) or 3 days (delayed stage) of permanent middle cerebral artery (MCA) occlusion. Independent qRT-PCR validation (n = 12) was performed for 22 of the genes. Functional data were evaluated by Ingenuity Pathway Analysis. The number of genes differentially expressed was 2,612 (24 h) and 5,717 (3 d) in the core; and 3,505 (24 h) and 1,686 (3 d) in the periinfarct area (logFC>|1|; adjP<0.05). Expression of many neurovascular unit development genes was altered at 24 h and 3 d including HES2, OLIG2, LINGO1 and NOGO-A; chemokines like CXCL1 and CXCL12, stress-response genes like HIF-1A, and trophic factors like BDNF or BMP4. Nearly half of the detected genes (43%) had not been associated with stroke previously.

Conclusions

This comprehensive study of gene regulation in the core and periinfarct areas at different times following permanent MCA occlusion provides new data that can be helpful in translational research.     

Application of Photochemical Trajectory Model to Evaluate OzoneFormation by Atmospheric Concentrations and Emissions of Propane andButane in Mexico City Metropolitan Zone

Molecular Engineering -     

Seasonal changes in energy allocation to somatic and reproductive body components of the common cold temperature sea urchin <Emphasis Type="Italic">Loxechinus albus</Emphasis> in a Sub-Antarctic environment

Monthly variations in the somatic indexes and energetic content of organs were investigated in Loxechinus albus from the Beagle Channel. Samples were collected monthly from May 2004 to May 2005. Lantern and test indexes did not vary significantly. A major peak of gonad index (GI) was observed in winter (sexual maturation period), with a strong declination in November suggesting a spawning period in spring. In coincidence a shortening of feeding activities was expressed by the lower values of gut index (Gut I), suggesting that the gut is a storage organ. The values of gonad energetic content (GEC) and total gonad energetic content (TGEC) showed minimum values in winter (ripe stage) and the maximum in spring (spawned stage). The TGEC reached higher monthly average values (50–200 kJ) than total gut energetic content (TGuEC) (20–40 kJ). These differences indicate that the gonads constitute the most important store organs in L. albus. Moreover, organic stores are built up in the gonads after spawning, and then utilized during gamete production.     

Investigation of the inclusion of the herbicide metobromuron in native cyclodextrins by powder X-ray diffraction and isothermal titration calorimetry

We report the formation of inclusion complexes between the phenylurea herbicide metobromuron [3-(p-bromophenyl)-1-methoxy-1-methylurea] and β- and γ-cyclodextrin in the solid state. Formation of crystalline inclusion complexes by the kneading method was confirmed by powder X-ray diffraction and further structural characterization using the principles of isostructurality followed. In addition, ΔH°, ΔS°, ΔG° and the association constants (K) at 298 K were determined for complex formation in solution using isothermal titration calorimetry. The magnitudes of K for the formation of 1:1 complexes between metobromuron and α-, β- and γ-CD were estimated as 598, 310 and 114, respectively.     

The global regulator LaeA controls penicillin biosynthesis, pigmentation and sporulation, but not roquefortine C synthesis in Penicillium chrysogenum

The biosynthesis of the beta-lactam antibiotic penicillin is an excellent model for the study of secondary metabolites produced by filamentous fungi due to the good background knowledge on the biochemistry and molecular genetics of the beta-lactam producing microorganisms. The three genes (pcbAB, pcbC, penDE) encoding enzymes of the penicillin pathway in Penicillium chrysogenum are clustered, but no penicillin pathway-specific regulators have been found in the genome region that contains the penicillin gene cluster. The biosynthesis of this beta-lactam is controlled by global regulators of secondary metabolism rather than by a pathway-specific regulator. In this work we have identified the gene encoding the secondary metabolism global regulator LaeA in P. chrysogenum (PcLaeA), a nuclear protein with a methyltransferase domain. The PclaeA gene is present as a single copy in the genome of low and high-penicillin producing strains and is not located in the 56.8-kb amplified region occurring in high-penicillin producing strains. Overexpression of the PclaeA gene gave rise to a 25% increase in penicillin production. PclaeA knock-down mutants exhibited drastically reduced levels of penicillin gene expression and antibiotic production and showed pigmentation and sporulation defects, but the levels of roquefortine C produced and the expression of the dmaW involved in roquefortine biosynthesis remained similar to those observed in the wild-type parental strain. The lack of effect on the synthesis of roquefortine is probably related to the chromatin arrangement in the low expression roquefortine promoters as compared to the bidirectional pbcAB-pcbC promoter region involved in penicillin biosynthesis. These results evidence that PcLaeA not only controls some secondary metabolism gene clusters, but also asexual differentiation in P. chrysogenum.     

Synthesis, Solution Structure, and Phylum Selectivity of a Spider ��-Toxin That Slows Inactivation of Specific Voltage-gated Sodium Channel Subtypes

Magi 4, now renamed δ-hexatoxin-Mg1a, is a 43-residue neurotoxic peptide from the venom of the hexathelid Japanese funnel-web spider (Macrothele gigas) with homology to δ-hexatoxins from Australian funnel-web spiders. It binds with high affinity to receptor site 3 on insect voltage-gated sodium (Na_V) channels but, unlike δ-hexatoxins, does not compete for the related site 3 in rat brain despite being previously shown to be lethal by intracranial injection. To elucidate differences in Na_V channel selectivity, we have undertaken the first characterization of a peptide toxin on a broad range of mammalian and insect Na_V channel subtypes showing that δ-hexatoxin-Mg1a selectively slows channel inactivation of mammalian Na_V1.1, Na_V1.3, and Na_V1.6 but more importantly shows higher affinity for insect Na_V1 (para) channels. Consequently, δ-hexatoxin-Mg1a induces tonic repetitive firing of nerve impulses in insect neurons accompanied by plateau potentials. In addition, we have chemically synthesized and folded δ-hexatoxin-Mg1a, ascertained the bonding pattern of the four disulfides, and determined its three-dimensional solution structure using NMR spectroscopy. Despite modest sequence homology, we show that key residues important for the activity of scorpion α-toxins and δ-hexatoxins are distributed in a topologically similar manner in δ-hexatoxin-Mg1a. However, subtle differences in the toxin surfaces are important for the novel selectivity of δ-hexatoxin-Mg1a for certain mammalian and insect Na_V channel subtypes. As such, δ-hexatoxin-Mg1a provides us with a specific tool with which to study channel structure and function and determinants for phylum- and tissue-specific activity.Voltage-gated sodium (Na_V)⁴ channels are responsible for the generation and propagation of electrical signals in excitable cells. At least nine different genes encoding distinct Na_V channels isoforms have been identified, and functionally expressed, in mammals (1). They are characterized by their sensitivity to TTX, with Na_V1.5, Na_V1.8, and Na_V1.9 being TTX-insensitive or TTX-resistant, and the remaining subtypes being sensitive to nanomolar concentrations of TTX. In addition, localization of the subtypes also varies, with Na_V1.1–1.3 mostly distributed in the central nervous system, Na_V1.6–1.9 principally located in the peripheral nervous system, and Na_V1.4 and Na_V1.5 found in skeletal and cardiac muscle, respectively. The structural diversity of Na_V channels also coincides with variations in physiological and pharmacological properties (2). In contrast, insects express only one gene (para) that undergoes extensive alternative splicing and RNA editing (3). The para-encoded Na_V channel is exceptionally well conserved across diverse orders of insects, with the level of identity ranging from 87 to 98% (3). This is one reason why insecticides that target insect Na_V channels have broad activity across many insect orders. In contrast, para-type Na_V channels have significantly lower levels of identity with the various types of mammalian Na_V channels with the level of identity typically around 50–60% (3). This explains why a high degree of phylogenetic specificity can be achieved with both Na_V channel toxins and insecticides that target the Na_V channel.At least seven distinct toxin-binding sites have been identified by radioligand binding and electrophysiological studies on vertebrate and insect Na_V channels (4, 5). Toxins interacting with these neurotoxin receptor sites have been instrumental in the study of Na_V channel topology, function, and pharmacology (6). In particular, a wide range of scorpion α-toxins, sea anemone toxins, and spider δ-hexatoxins (formerly δ-atracotoxins (7)) compete for binding to receptor site-3 on the extracellular surface of Na_V channels. These polypeptide toxins all inhibit the fast inactivation of Na_V channels to prolong Na⁺ currents (I_Na), despite huge diversity in primary and tertiary structures (8, 9). Nevertheless, receptor site-3 has not yet been fully characterized but is believed to involve domains DI/S5-S6, DIV/S5-S6, as well as DIV/S3-S4 (9). Most importantly, however, toxin characterization is often limited to studies using whole-cell I_Na or binding studies on neuronal membranes where there are mixed populations of Na_V channel subtypes. For all of these toxins, the precise pattern of Na_V channel subtype selectivity is either unknown or at best is incomplete.Recently, it was found that receptor site-3 was also recognized by a 43-residue spider toxin, originally named Magi 4, from the hexathelid spider Macrothele gigas (Iriomote, Japan). It binds with high affinity to insect Na_V channels but, similar to scorpion α-like toxins, does not compete for the related site-3 in rat brain synaptosomes, despite being lethal by intracranial injection (10). Magi 4 shares significant homology to four δ-hexatoxin (HXTX)-1 family peptides and δ-actinopoditoxin-Mb1a (formerly δ-missulenatoxin-Mb1a; Fig. 1) but no sequence homology to scorpion α-toxins. Neurochemical studies have shown that δ-HXTX-1 toxins compete at nanomolar concentrations with both anti-mammalian (e.g. Aah2 and Lqh2) and anti-insect (e.g. LqhαIT) scorpion toxins for site-3 (11–13). The three-dimensional structures of δ-HXTX-Ar1a and δ-HXTX-Hv1a peptides have been determined (14, 15) and possess core β regions stabilized by four disulfide bonds, placing them in the inhibitory cystine knot (ICK) structural family (16).Open in a separate windowFIGURE 1.Primary and secondary structure of δ-HXTX-Mg1a. A, comparison of the primary sequence of δ-HXTX-Mg1a and δ-HXTX-Mg1b (formerly Magi 14) with currently known members of the δ-HXTX-1 family and δ-AOTX-Mb1a (δ-actinopoditoxin-Mb1a, formerly δ-missulenatoxin-Mb1a). Homologies are shown relative to δ-HXTX-Mg1a; identities are boxed in gray, and conservative substitutions are in gray italic text. Gaps (dashes) have been inserted to maximize alignment. The disulfide bonding pattern for the strictly conserved cysteine residues determined for δ-HXTX-Mg1a (this study), δ-HXTX-Ar1a (55), and δ-HXTX-Hv1a (15) is indicated above the sequences; it is assumed that δ-AOTX-Mb1a (36), δ-HXTX-Hs20.1a (8), and δ-HXTX-Hv1b (56) have the same disulfide bonding pattern. The percentage identity and homology with δ-HXTX-Mg1a is shown to the right of the sequences. B, summary of δ-HXTX-Mg1a NMR data. Sequential NOEs, classified as very weak, weak, medium, and strong, are represented by the thickness of bars. Filled diamonds indicate backbone amide protons that form hydrogen bonds. ³J_NHCα coupling constants are indicated by ↑ (>8 Hz) and ↓ (<5.5 Hz). Secondary structure is shown at the bottom of the figure where rectangles represent β-turns (the type of turn is indicated in the rectangle) and arrows represent β-sheets.The aim of this study was to first determine the solution structure of Magi 4 and second to investigate the ability of Magi 4 to discriminate between different Na_V channels subtypes. Here we report the tertiary structure of Magi 4 by ¹H NMR and show its disulfide bonding pattern and three-dimensional structure are homologous to δ-HXTX-1 toxins. We highlight the key residues in Magi 4 that appear to be topologically similar to those residues known to be part of the pharmacophore for site-3 scorpion α-toxins, despite Magi 4 having a different overall structure to scorpion α-toxins (11). In addition, we provide a detailed characterization of the selectivity and mode of action of Magi 4 on nine cloned mammalian and insect Na_V channel subtypes, including a detailed characterization on insect neurotransmission. Given that the toxin potently slows the inactivation of Na_V channels, it should be renamed δ-hexatoxin-Mg1a (δ-HXTX-Mg1a) in accordance with the rational nomenclature recently proposed for naming spider peptide toxins (7) (see ArachnoServer spider toxin data base).     

Purification and characterization studies of a thermostable β-xylanase from <Emphasis Type="Italic">Aspergillus awamori</Emphasis>

This study presents data on the production, purification, and properties of a thermostable β-xylanase produced by an Aspergillus awamori 2B.361 U2/1 submerged culture using wheat bran as carbon source. Fractionation of the culture filtrate by membrane ultrafiltration followed by Sephacryl S-200 and Q-Sepharose chromatography allowed for the isolation of a homogeneous xylanase (PXII-1), which was 32.87 kDa according to MS analysis. The enzyme-specific activity towards soluble oat spelt xylan, which was found to be 490 IU/mg under optimum reaction conditions (50°C and pH 5.0–5.5), was 17-fold higher than that measured in the culture supernatant. Xylan reaction products were identified as xylobiose, xylotriose, and xylotetraose. K _m values (mg ml⁻¹) for soluble oat spelt and birchwood xylan were 11.8 and 9.45, respectively. Although PXII-1 showed 85% activity retention upon incubation at 50°C and pH 5.0 for 20 days, incubation at pH 7.0 resulted in 50% activity loss within 3 days. PXII-1 stability at pH 7.0 was improved in the presence of 20 mM cysteine, which allowed for 85% activity retention for 25 days. This study on the production in high yields of a remarkably thermostable xylanase is of significance due to the central role that this class of biocatalyst shares, along with cellulases, for the much needed enzymatic hydrolysis of biomass. Furthermore, stable xylanases are important for the manufacture of paper, animal feed, and xylooligosaccharides.