Histochemical Study of Photoperiodic and Low Temperature Effects on Floral Induction of Spinacia oleracea

Shoot apices of Spinacia oleracea plants have been induced toflower either by: (a) subjecting leaves to 24 h long day, or(b) exposure to a short photoperiod but displaced by 8 h (displacedshort day) in the usual 24 h short-day cycle, or (c) exposureto low temperature (5 °C) during the dark period of thenormal short day. A quantitative cytochemical assay of pentosephosphate pathway activity during floral induction indicatesan approximate doubling of the rate of activity when comparedto that of vegetative apices (short day) (21 °C). Exposure to either low temperature, or a displaced short photoperiodstimulates pentose phosphate pathway activity in the shoot apexin a manner similar to that seen by long-day induction. Thischange in metabolic activity is accompanied by changes in theshape of the shoot apex which resembles that seen at an earlystage during floral induction. Spinacia oleracea, pentose phosphate pathway, shoot apex, glucose-6-phosphate dehydrogenase, floral induction, chilling, displaced short day     

Remote control of neuronal activity with a light-gated glutamate receptor

The ability to stimulate select neurons in isolated tissue and in living animals is important for investigating their role in circuits and behavior. We show that the engineered light-gated ionotropic glutamate receptor (LiGluR), when introduced into neurons, enables remote control of their activity. Trains of action potentials are optimally evoked and extinguished by 380 nm and 500 nm light, respectively, while intermediate wavelengths provide graded control over the amplitude of depolarization. Light pulses of 1-5 ms in duration at approximately 380 nm trigger precisely timed action potentials and EPSP-like responses or can evoke sustained depolarizations that persist for minutes in the dark until extinguished by a short pulse of approximately 500 nm light. When introduced into sensory neurons in zebrafish larvae, activation of LiGluR reversibly blocks the escape response to touch. Our studies show that LiGluR provides robust control over neuronal activity, enabling the dissection and manipulation of neural circuitry in vivo.     

Direct visualization of single copy genes on banded metaphase chromosomes by nonisotopic in situ hybridization.

A rapid method is described for non isotopic in situ mapping of single copy genes directly on G-banded chromosomes by "one-step" regular light microscopy. It is based on hybridizing biotinylated probes to metaphase chromosomes. Biotin residues are detected by rabbit antibiotin antibody and anti-rabbit Ig labelled with peroxidase or colloidal gold. The peroxidase reaction product or colloidal gold signals are amplified by silver precipitation. The final product is a black silver dot at the gene locus on a purple G-banded chromosome. N-ras and alpha-1-antitrypsin genes have been mapped using plasmids with inserts of 1.5 and 1.3kb to 1p13.1 and the junction of 14q31/32 respectively. The signal to noise ratio in these experiments ranged from 32:1-46:1. This technology is at least as sensitive as radioisotopic in situ hybridization and gives results within 1 day of hybridization and has much better resolution. Additionally, genes are visualized by regular light microscopy without specialized techniques such as reflection contrast, fluorescence or phase microscopy. This methodology should facilitate more precise chromosomal gene localization.     

Naproxen and Cromolyn as New Glycogen Synthase Kinase 3β Inhibitors for Amelioration of Diabetes and Obesity: An Investigation by Docking Simulation and Subsequent In Vitro/In Vivo Biochemical Evaluation

Naproxen and cromolyn were investigated as new inhibitors of glycogen synthase kinase‐3β (GSK‐3β) in an attempt to explain their hypoglycemic properties. Study included simulated docking experiments, in vitro enzyme inhibition assay, and in vivo validations. Both drugs not only were optimally fitted within a GSK‐3β binding pocket via several attractive interactions with key amino acids but also exhibited potent in vitro enzymatic inhibitory activities of IC50 1.5 and 2.0 µM for naproxen and cromolyn, respectively. In vivo experiments illustrated that both drugs significantly reduced serum glucose and increased hepatic glycogen‐ and serum insulin levels in normal and type II diabetic Balb/c mice models. In obese animal model, both drugs exhibited significant reduction in mice weights, serum glucose, and resistin levels along with significant elevation in serum insulin, C‐peptide, and adiponectin values. It can be concluded that naproxen and cromolyn are novel GSK‐3β inhibitors and can help in management of diabetes and obesity. © 2013 Wiley Periodicals, Inc. J BiochemMol Toxicol 27:425–436, 2013; View this article online at wileyonlinelibrary.com . DOI 10.1002/jbt.21503     

Yellow Fever Outbreaks in Unvaccinated Populations,Brazil, 2008–2009

Due to the risk of severe vaccine-associated adverse events, yellow fever vaccination in Brazil is only recommended in areas considered at risk for disease. From September 2008 through June 2009, two outbreaks of yellow fever in previously unvaccinated populations resulted in 21 confirmed cases with 9 deaths (case-fatality, 43%) in the southern state of Rio Grande do Sul and 28 cases with 11 deaths (39%) in Sao Paulo state. Epizootic deaths of non-human primates were reported before and during the outbreak. Over 5.5 million doses of yellow fever vaccine were administered in the two most affected states. Vaccine-associated adverse events were associated with six deaths due to acute viscerotropic disease (0.8 deaths per million doses administered) and 45 cases of acute neurotropic disease (5.6 per million doses administered). Yellow fever vaccine recommendations were revised to include areas in Brazil previously not considered at risk for yellow fever.     

Clarin-1, Encoded by the Usher Syndrome III Causative Gene, Forms a Membranous Microdomain: POSSIBLE ROLE OF CLARIN-1 IN ORGANIZING THE ACTIN CYTOSKELETON*

Clarin-1 is the protein product encoded by the gene mutated in Usher syndrome III. Although the molecular function of clarin-1 is unknown, its primary structure predicts four transmembrane domains similar to a large family of membrane proteins that include tetraspanins. Here we investigated the role of clarin-1 by using heterologous expression and in vivo model systems. When expressed in HEK293 cells, clarin-1 localized to the plasma membrane and concentrated in low density compartments distinct from lipid rafts. Clarin-1 reorganized actin filament structures and induced lamellipodia. This actin-reorganizing function was absent in the modified protein encoded by the most prevalent North American Usher syndrome III mutation, the N48K form of clarin-1 deficient in N-linked glycosylation. Proteomics analyses revealed a number of clarin-1-interacting proteins involved in cell-cell adhesion, focal adhesions, cell migration, tight junctions, and regulation of the actin cytoskeleton. Consistent with the hypothesized role of clarin-1 in actin organization, F-actin-enriched stereocilia of auditory hair cells evidenced structural disorganization in Clrn1^−/− mice. These observations suggest a possible role for clarin-1 in the regulation and homeostasis of actin filaments, and link clarin-1 to the interactive network of Usher syndrome gene products.Usher syndrome is the most common cause of human inherited deafness and blindness, accounting for ∼50% of all cases (1). There are three clinical types of Usher syndrome, types I, II, and III (1–3). Usher type I is characterized by profound congenital deafness and vestibular dysfunction, and Usher type II is characterized by moderate to severe deafness. Usher type III is distinguished from types I and II by progressive (non-congenital) deafness together with variable impairment of vestibular function. All Usher types lead to progressive retinal degeneration with a retinitis pigmentosa-like appearance. Five causative genes have been identified for Usher syndrome type I, and three genes for type II (3). The protein products of Usher type I and II genes are functionally heterogeneous, including an unconventional myosin, scaffold proteins, G-protein-coupled receptor, and cadherins. Adding to this heterogeneity, the Usher syndrome type III gene encodes a novel transmembrane protein named clarin-1 (CLRN1)³ (4–6) with an unknown function. The heterogeneity of genes involved in Usher syndrome makes it extremely challenging to elucidate shared and distinctive disease mechanisms.CLRN1 belongs to a superfamily of four-transmembrane proteins that includes the tetraspanin and claudin families. CLRN1 and its paralogues, CLRN2 and CLRN3, form the Clarin family, which is conserved throughout vertebrate species and shows limited sequence homology to the tetraspanins (4). Tetraspanins are considered to be structural proteins that interact laterally with other membrane proteins such as ion channels, integrins, and other tetraspanins (7, 8) to form tetraspanin-enriched microdomains. Tetraspanin-enriched microdomains embody other proteins to allow localized transmission of signals, cell-cell adhesion/fusion, cell-matrix interactions, and/or formation of diffusion barriers against small molecules. Similar to tetraspanins, CLRN1 retains only limited hydrophilic regions exposed to cytoplasmic or extracellular aqueous phases (Fig. 1A) and, apparently, lacks any functional domains. Although CLRN1 is structurally related and similar to tetraspanins, it is currently unknown whether CLRN1 can form specific microdomains. The question also remains as to what one or more functions CLRN1 microdomains serve if indeed they do exist.Open in a separate windowFIGURE 1.CLRN1 is a plasma membrane protein localized at F-actin-enriched protrusions. A, the topology and transmembrane domains shown were predicted with the HMMTOP transmembrane topology prediction server (55). The possible N-linked glycosylation site is indicated. Also shown (red circle) is the previously predicted motif near the CLRN1 C-terminal tail that may serve as a PDZ-binding site (4). B, immunolocalization of Human WT CLRN1. C, immunolocalization of Na/K ATPase in HEK293 cells stably expressing CLRN1. D, merged image of B and C indicates that CLRN1 and Na/K ATPase co-localize. Images B–D are single optical sections of HEK293 cells. E, cell surface biotinylation was performed to separate cell surface proteins (avidin-bound) (AB) from intracellular proteins (flow-through) (FT). Immunoblots of both fractions reveal that most of the CLRN1 protein localized to the plasma membrane. HEK293 cells alone and HEK293 cells expressing CLRN1 were preincubated for 30 min with Sulfo-NHS-SS-Biotin to label cell surface proteins. After cells were harvested, biotin-labeled CLRN1 protein levels were measured by immunoblotting. F, localization of human WT CLRN1 in HEK293 cells stably expressing CLRN1. G, F-actin in HEK293 cells stably expressing CLRN1. F-actins were labeled with phalloidin-Alexa 488. H, merged image of F and G. CLRN1 localized at both microvilli (arrows) and lamellipodia (arrowheads). I–K, CLRN1 localization studied by immunofluorescence confocal microscopy after disruption of F-actin by cytochalasin D treatment. I, CLRN1 localized diffusely on the plasma membrane. J, F-actin localization is shown. K, merged image of I and J. After disruption of F-actin, CLRN1 and F-actin no longer co-localize. Images F–K were generated from multiple optical sections by a maximum intensity projection. Scale bars, 50 μm.CLRN1 is expressed in sensory hair cells (4) where it may interact with other co-existing Usher gene products or cellular machinery essential for the maintenance of these cells. Increasing evidence suggests that products of Usher type I and II genes form large networks of interacting proteins, and that F-actin plays a major role in organizing these networks (reviewed in Refs. 2, 9). The core of these networks is the Usher type IC gene product, Harmonin, which interacts directly with F-actin in vitro and stabilizes F-actin when it is expressed heterologously in HeLa cells (10). Harmonins retain multiple PDZ domains dedicated to interacting with products of Usher type I and type II genes (reviewed in Refs. 2, 9) and also serve as PDZ domain-based scaffolds to anchor Usher proteins to F-actin. A link between Usher gene products and actin-based organelles also has been established in vivo. In Usher syndrome I and II mouse models, the actin-enriched stereocilia are morphologically and functionally defective (11–14). Because the causative gene for Usher type III was identified more recently than those of Usher types I and II, little is known about the pathogenesis of Usher syndrome III. Epistatic interactions between Usher syndrome type IB and Usher syndrome III may suggest linkage among CLRN1, Myosin VIIa, and F-actin (15). Clinically, patients with the N48K CLRN1 mutation have a rod and cone degenerative phenotype similar to Usher type IIA patients (16), suggesting a common pathological pathway for Usher types IIA and III. Despite the genetic and phenotypic characterization in humans, the molecular function of CLRN1 remains elusive, as well as its relationship and interaction with other Usher gene products. Therefore, identifying possible interactive partners of CLRN1 should improve understanding of the function of CLRN1 and the common pathological pathways of progressive hearing and vision loss in the Usher syndromes.Here we investigated whether CLRN1 can form microdomains similar to the tetraspanin-enriched microdomain, and if so, what the function of such microdomains might be. Our studies indicate that CLRN1 forms membranous cholesterol-rich compartments on plasma membranes and interacts with and regulates the machinery involved in actin filament organization. To understand the pathogenesis of Usher syndrome, we asked whether and how the Usher syndrome III causative mutation, N48K, results in dysfunction of the clarin-1-enriched microdomains involved in organizing actin. To determine whether Clrn1 is involved in the regulation of actin cytoskeleton in vivo, we studied the structure of F-actin-enriched stereocilia bundles in Clrn1^−/− mouse. Because actin provides important scaffolds in Usher interactome, the observations described herein provide a novel molecular link between CLRN1 and the identified gene products of Usher types I and II.     

Development of a flow-through system to create occluding thrombus

Occlusive thrombosis accounts for many heart attacks and strokes. These acute events are difficult to catch in patients and animal test methods may be misleading because anti-thrombotic therapeutics often do not cross-react with different species. This paper presents a new flow-through system that leads to rapid occlusive thrombosis in arterial flow conditions. Whole porcine blood is perfused through a tubular test section. The growing thrombus is visualized in real time from early platelet attachment, through accumulation, to occlusion. The progression of flow rate reduction provides a clear distinguishing parameter between thrombus formation and embolization. Thrombus growth rate is a linear function of very high shear rate beyond 40,000 s(-1). The histology of the thrombus reveals predominantly platelet accumulation and growth as a rough surface with tendrils. This flow-through system may be useful for the economic testing of new anti-thrombosis therapies.