Direct autoradiography of cylindrical gels--introducing a simple longitudinal gel slicer.

A simple, easy-to-make gel slicer for slicing cylindrical gel longitudinally is described. Agarose gel of 2–5% and acrylamide gel of 2 to 20% can all be sliced successfully into three pieces: two half curved outer slices and one flat-faced center slice of 1 to 2 mm thick, without requiring freezing of the gel. The flat-faced center slice is particularly suitable for autoradiography.     

A longitudinal slicer for obtaining multiple uniform slices from cylindrical polyacrylamide gels

Construction of a longitudinal gel slicer for polyacrylamide gels is described. The apparatus produces intact, undamaged, and identical slices with rectangular cross section from gels of different thicknesses and different concentrations of acrylamide. When an extract containing brain proteins was electrophoresed on a cylindrical gel and then sliced and colored by Coomassie blue, an identical band pattern was obtained in all slices, indicating the absence of any gel distortion during cutting.     

Functional replacement of Trypanosoma brucei Argonaute by the human slicer Argonaute2

RNA interference (RNAi) is widespread throughout the eukaryotic lineage, from protozoa to man. Central to all RNAi phenomena is a member of the Argonaute protein family, and, in the case of dsRNA-triggered mRNA cleavage, the Ago protein functions as the RNAi endonuclease or slicer. However, at present there is no definite experimental evidence that slicer Argonautes can be interchanged between distantly related organisms. Here, we show that the human slicer Argonaute2 (HsAgo2), but not HsAgo1, functions in RNAi in the early divergent protozoan Trypanosoma brucei, thus mimicking the situation in mammalian cells. This finding indicates that the basic features of the RNAi mechanism are conserved from T. brucei to man.     

Simple radioassay for uridine phosphorylase and 5'-nucleotidase

A method is described whereby a large number of chromatographic fractions containing protein or enzyme components may be run on a single-starch gel. A multiple punch for making the sample holes, gel slab support, and a gel slicer used to cut several slices from the one gel for staining for the various enzyme or protien constituents are described. An example is given of a run using fractions obtained from a Sephadex G-200 column chromatography run of a herring muscle extract. Densitometry may be used to assay the stained gels. In another example a commercially obtained muscle lactate dehydrogenase preparation was chromatographed on a Sephadex G-200 column. The electrophoretic run of the fractions revealed the presence of both heart-type A and muscle-type B lactate dehydrogenase subunits and showed that the column run had effected a partial separation of the various tetramers.     

PRMT1 methylates the single Argonaute of Toxoplasma gondii and is important for the recruitment of Tudor nuclease for target RNA cleavage by antisense guide RNA

Argonaute (Ago) plays a central role in RNA interference in metazoans, but its status in lower organisms remains ill-defined. We report on the Ago complex of the unicellular protozoan, Toxoplasma gondii (Tg), an obligatory pathogen of mammalian hosts. The PIWI-like domain of TgAgo lacked the canonical DDE/H catalytic triad, explaining its weak target RNA cleavage activity. However, TgAgo associated with a stronger RNA slicer, a Tudor staphylococcal nuclease (TSN), and with a protein Arg methyl transferase, PRMT1. Mutational analysis suggested that the N-terminal RGG-repeat domain of TgAgo was methylated by PRMT1, correlating with the recruitment of TSN. The slicer activity of TgAgo was Mg(2+)-dependent and required perfect complementarity between the guide RNA and the target. In contrast, the TSN activity was Ca(2+) -dependent and required an imperfectly paired guide RNA. Ago knockout parasites showed essentially normal growth, but in contrast, the PRMT1 knockouts grew abnormally. Chemical inhibition of Arg-methylation also had an anti-parasitic effect. These results suggest that the parasitic PRMT1 plays multiple roles, and its loss affects the recruitment of a more potent second slicer to the parasitic RNA silencing complex, the exact mechanism of which remains to be determined.     

Horizontal slice preparation of the retina

Traditionally the vertical slice and the whole-mount preparation of the retina have been used to study the function of retinal circuits. However, many of retinal neurons, such as amacrine cells, expand their dendrites horizontally, so that the morphology of the cells is supposed to be severely damaged in the vertical slices. In the whole-mount preparation, especially for patch-clamp recordings, retinal neurons in the middle layer are not easily accessible due to the extensive coverage of glial cell (Mueller cell) s endfeets. Here, we describe the novel slicing method to preserve the dendritic morphology of retinal neurons intact. The slice was made horizontally at the inner layer of the retina using a vibratome slicer after the retina was embedded in the low-temperature melting agarose gel. In this horizontal slice preparation of the retina, we studied the function of retinal neurons compared with their morphology, by using patch-clamp recording, calcium imaging technique, immunocytochemistry, and single-cell RT-PCR.     

Single-cell viability assessment with a novel spectro-imaging system

Single-cell viability assessment by means of plural dye probes require the spectral and temporal analysis of microscopic images of the test cells. To meet this requirement, we have developed a simple and compact spectro-imaging system using an image slicer and a grism. The image slicer was made of a bundle of 100 optical fibers. The field of view is divided into 10 x 10 sections. The spectral data of each section could be recorded every 5 s in the range from 400 to 800 nm at 5 nm resolution. The viability changes of yeast or tobacco single-cells were measured with this system. Using BY-2 cells, for example, the response to a chemical stress of saponin was measured by means of two fluorescent probes. The spectral-spatial-temporal data of fluorescein and DNA bound ethidium bromide provided us with useful information about the dynamic change of cell membrane permeability from which the cell viability was assessed.     

Development of motility in cultures of the cyanobacterium Mastigocladus laminosus

Abstract The time course for the development of motility in cultures of the cyanobacterium Mastigocladus laminosus was established quantitatively using a slicer tool as described here. The slicer tool produces samples of trichomes from centrifuged pellets that, under identical conditions, shed comparable numbers of hormogonia. The number of hormogonia formed in liquid culture rises steeply between 24 and 31 h of incubation, returning to essentially zero in the next 24 h. The initial lag may be devoted to the cell divisions needed to form the cells of the hormogonium. The drop in motility could be due to one or more heat-stable substance(s) accumulated in the medium, since used media inhibited motility and the effect resisted autoclaving. The fact that the inoculum needed to be ground in order for motility to occur suggests that the structure of the clump inhibits the shedding of hormogonia. Some ecological implications are proposed, assuming that the clump structure interferes with light and mass transfer.     

Novel Drosophila Viruses Encode Host-Specific Suppressors of RNAi

The ongoing conflict between viruses and their hosts can drive the co-evolution between host immune genes and viral suppressors of immunity. It has been suggested that an evolutionary ‘arms race’ may occur between rapidly evolving components of the antiviral RNAi pathway of Drosophila and viral genes that antagonize it. We have recently shown that viral protein 1 (VP1) of Drosophila melanogaster Nora virus (DmelNV) suppresses Argonaute-2 (AGO2)-mediated target RNA cleavage (slicer activity) to antagonize antiviral RNAi. Here we show that viral AGO2 antagonists of divergent Nora-like viruses can have host specific activities. We have identified novel Nora-like viruses in wild-caught populations of D. immigrans (DimmNV) and D. subobscura (DsubNV) that are 36% and 26% divergent from DmelNV at the amino acid level. We show that DimmNV and DsubNV VP1 are unable to suppress RNAi in D. melanogaster S2 cells, whereas DmelNV VP1 potently suppresses RNAi in this host species. Moreover, we show that the RNAi suppressor activity of DimmNV VP1 is restricted to its natural host species, D. immigrans. Specifically, we find that DimmNV VP1 interacts with D. immigrans AGO2, but not with D. melanogaster AGO2, and that it suppresses slicer activity in embryo lysates from D. immigrans, but not in lysates from D. melanogaster. This species-specific interaction is reflected in the ability of DimmNV VP1 to enhance RNA production by a recombinant Sindbis virus in a host-specific manner. Our results emphasize the importance of analyzing viral RNAi suppressor activity in the relevant host species. We suggest that rapid co-evolution between RNA viruses and their hosts may result in host species-specific activities of RNAi suppressor proteins, and therefore that viral RNAi suppressors could be host-specificity factors.     

Cucumber mosaic virus suppressor 2b binds to AGO4-related small RNAs and impairs AGO4 activities

Cucumber mosaic virus suppressor 2b (CMV2b) is a nuclear viral suppressor that interferes with local and systemic silencing and inhibits AGO1 slicer activity. CMV2b-mediated transgene hypomethylation and its localization in Cajal bodies suggests a role of CMV2b in RNA-directed DNA methylation (RdDM). However, its direct involvement in RdDM, or its binding with small RNAs (sRNAs) in vivo is not yet established. Here, we show that CMV2b binds both microRNAs (miRNAs) and small interfering RNAs (siRNAs) in vivo. sRNA sequencing data from the CMV2b immunocomplex revealed its preferential binding with 24-nt repeat-associated siRNAs. We provide evidence that CMV2b also has direct interaction with the AGO4 protein by recognizing its PAZ and PIWI domains. Subsequent analysis of AGO4 functions revealed that CMV2b reduced AGO4 slicer activity and the methylation of several loci, accompanied by the augmented accumulation of 24-nt siRNAs in Arabidopsis inflorescences. Intriguingly, CMV2b also regulated an AGO4-related epiallele independently of its catalytic potential, which further reinforces the repressive effects of CMV2b on AGO4 activity. Collectively, our results demonstrate that CMV2b can counteract AGO4-related functions. We propose that by adopting novel counter-host defense strategies against AGO1 and AGO4 proteins, CMV creates a favorable cellular niche for its proliferation.     

An on-line realtime cardiotachograph]

A realtime cardiotachogram was devised to detect fluctuation of cardiac rhythm. The apparatus is composed of five parts; (1) a "preamplifier" for recording electrical and/or mechanical cardiac activities, (2) a "slicer" to obtain sampling pulses from cardiac activity at a certain trigger level, (3) a "trigger pulse generator" to monitor sampling pulse, (4) an "oscillator" whose output is fed to a pulse counter, and (5) a "pulse counter" which counts the outputs of the oscillator during the gating period determined by the sampling pulses. The count numbers are converted to analog output, thus we can get sawtooth wave whose amplitude is directly proportional to the cardiac interval. The cardiac intervals between 100 ms and 5 seconds can be recorded by this tachograph.     

Renewable enzyme reactors based on beds of artificial gel antibodies

A novel approach is described for the synthesis of beds for enzyme reactors. The method is based on the use of artificial antibodies in the form of polyacrylamide gel particles with diameters around 0.1–0.3 mm. These gel particles mimic protein antibodies, raised in experimental animals, in the sense that they selectively recognize and adsorb only the protein present during the preparation of the “antibodies”. The gel antibodies have several advantages over conventional protein antibodies, which can be taken advantage of in the design of enzyme reactors; for instance, if upon prolonged use the immobilized enzyme loses its activity it can easily be replaced by an active enzyme, which is not possible when the enzyme is immobilized via a conventional protein antibody (a new bed with immobilized protein antibodies must be prepared); and equally or more remarkable: the enzyme can be applied in the form of a non-purified extract since the selectivity of the artificial gel antibodies is so high that they will “fish-out” the enzyme, but no other proteins in the extract. In addition, no preconcentration of the enzyme solution is required prior to the immobilization, since the enzyme is enriched at the top of the column upon the application. These unique properties make enzyme reactors based on artificial gel antibodies very attractive, also in process chromatography. The potential application range of the artificial gel antibodies is enormous since the same method for their synthesis can be used independent of the structure and the size of the “antigen”; for instance, renewable biosensors based on gel antibodies for the selective detection of protein biomarkers, as well as pathogenic viruses, bacteria, and spores (for instance Anthrax) should not be difficult to design.     

Sequence- and structure-based analysis of proteins involved in miRNA biogenesis

miRNA biogenesis is a multistage process for the generation of a mature miRNA and involves several different proteins. In this work, we have carried out both sequence- and structure-based analysis for crucial proteins involved in miRNA biogenesis, namely Dicer, Drosha, Argonaute (Ago), and Exportin-5 to understand evolution of these proteins in animal kingdom and also to identify key sequence and structural features that are determinants of their function. Our analysis reveals that in animals the miRNA biogenesis pathway first originated in molluscs. The phylogeny of Dicer and Ago indicated evolution through gene duplication followed by sequence divergence that resulted in functional divergence. Our detailed structural analysis also revealed that RIIIDb domains of Drosha and Dicer, share significant similarity in sequence, structure, and substrate-binding pocket. On the other hand, PAZ domains of Dicer and Ago show only conservation of the substrate-binding pockets in the catalytic sites despite significant divergence in sequence and overall structure. Based on a comparative structural analysis of all four human Ago proteins (hAgo1–4) and their known biochemical activity, we have also attempted to identify key residues in Ago2 which are responsible for the unique slicer activity of hAgo2 among all isoforms. We have identified six key residues in N domain of hAgo2, which are located far away from the catalytic pocket, but might be playing a major role in slicer activity of hAgo2 protein because of their involvement in mRNA binding.     

Elsie 4: quantitative computer analysis of sets of two-dimensional gel electrophoretograms

We have developed and refined a system for quantitative computer analysis of two-dimensional polyacrylamide gel electrophoretograms. The system, named Elsie 4, is based on one described by Vo et al. (Anal. Biochem. 112, 258 (1981]. It is highly automated. Elsie 4 can find, and measure the intensity of, almost any spot resolvable on two-dimensional gels, including spots visible only as shoulders off larger spots and spots so close together that there is no "valley" between them. It can automatically match the spot patterns of different gels, potentially without the need for a user to provide landmark matches. The matches between paired gels let us follow the synthesis of any spot through a set of gels. Information about a group of matched spots can be obtained by referring to any spot in the group. There is generally no need for a standard or reference gel. Data for two experiments can be combined and compared by matching any gel in one experiment with any gel in the other. There are ways to automatically find possible mismatches in sets of gels. Scans and the results of the analysis can be shown on an image displayer. The programs use function libraries; this helps ensure consistency and increase portability. The programs and functions can be linked together in many ways; this lets users build custom programs for analysis of specific experiments.     

Analysis of glycopeptides as borate complexes by polyacrylamide gel electrophoresis

A new method using polyacrylamide gel electrophoresis in a Tris-borate buffer to analyze Pronase-derived glycopeptides is described. Examination of immunoglobulin, Sindbis virus, and ovalbumin-radiolabeled glycopeptides by this system demonstrates a pattern similar to that seen after Bio-Gel-P-6 chromatography and, in addition, exposes a heterogeneity in the immunoglobulin and Sindbis virus glycopeptides not apparent after gel filtration. The resolution of glycopeptides by gel electrophoresis depends on the inclusion of borate ions in the sample, the gel, and the electrophoresis buffer. The borate ions react with neutral sugars, converting them to charged complexes which migrate during electrophoresis. The number of borate ions bound to a glycopeptide is a function of the composition, sequence, and linkages of the carbohydrates. Gel electrophoresis of glycopeptides in a borate buffer has several advantages: (1) The method requires no new equipment or special skills beyond those necessary for conventional polyacrylamide gel electrophoresis; (2) when performed on a slab gel, up to 24 samples can be analyzed simultaneously; and (3) since detection is by radio-autography, small amounts of radiolabeled glycopeptides can be visualized by prolonging the exposure time. These characteristics are advantageous for studies of glycopeptides based on digestion products resulting from incubations with specific exo- and endo-glycosidases. Untreated glycopeptides have been compared on the same gel with glycopeptides sequentially treated with different glycosidases to gain structural information.     

Human fibrinogen gel formed by the action of a cell surface polysaccharide obtained from a Staphylococcus

An alkali-stable polysaccharide (called compact-colony forming active substance; substance 1) obtained from the cell surface of a strain of Staphylococcus epidermidis caused gel formation of human fibronogen, with no release of fibrinopeptides. Substance 1 possessed neither esterase nor caseinolytic activities; no inhibition of gel formation was shown by dinitrofluorophosphate. Heparin and galactose prevented gel formation of fibrinogen with substance 1. With the addition of early- and late-fibrinogen or fibrin degradation products into the fibrinogen sample, no prolongation of the gel formation time was observed. This substance is, therefore, assumed to nonenzymatically induce gel formation with fibrinogen, a process resembling paracoagulation.     

Quantitative aspects of mercurial-agarose gel electrophoresis

Single-stranded nucleic acids are capable of extensive intramolecular base pairing as well as intermolecular aggregation. Consequently, electrophoretic studies of single-stranded nucleic acids are most effective when conducted under denaturing conditions. A number of techniques are available for nucleic acid denaturing gel electrophoresis (1–3). In this paper we describe certain quantitative features of one of these techniques, mercurial-agarose gel electrophoresis (4–7). Specifically, we address the questions of resolution and base composition dependence and we introduce a new mercurial for agarose gel electrophoresis, p-chloromercuriphenyl-sulfonic acid.In a previous publication we demonstrated that methylmercury was an effective denaturant in an agarose gel (4). The mechanism of denaturation is presumably the disruption of hydrogen bonding by the reversible binding of methylmercury to uridine and guanosine imino nitrogens. At saturating mercurial concentrations accurate molecular weights can be determined, free of conformation effects. The presence of methylmercury has no observable effect on the mechanical properties of the gel. Hence the denaturing power of the gel can be readily varied. The strength and rigidity of agarose gels make them considerably easier to handle than acrylamide gels, and the large pore size ensures a system compatible with high molecular weight RNA.     

Purification of Pregnancy Zone Protein and Its Receptor Binding Domain from Human Plasma

A new significantly improved method for purification of pregnancy zone protein (PZP), α₂-macroglobulin (α₂M), and the C-terminal PZP receptor binding domain is presented. Several steps in an earlier procedure have been deleted, and modifications in the gradients in the DEAE step leave most of the contaminants bound to a DEAE-Sephacel gel. This procedure makes possible the rapid, simultaneous purification of both of these closely related unstable proteins in native form from human plasma, with no thiolester cleavage or formation of tetrameric PZP. The final preparations of both α₂M and PZP are pure as determined by nonreducing and reducing polyacrylamide gel electrophoresis following silver staining and no cross-contamination can be observed. The yield has been significantly improved and typically more than 500 mg PZP can be obtained from 1 liter pregnancy plasma. Furthermore, the stability of PZP at different temperatures on storage was studied. In liquid nitrogen PZP can be maintained in native dimeric form with intact thiolester for many years. The storage of native PZP with intact functional properties during and after purification is an obligatory prerequisite to elucidate the biological role of PZP. The receptor binding domain of PZP can be cleaved from the PZP–methylamine complex by papain and isolated from the other peptides by S-200 gel filtration. The cleavage site was determined and the C-terminal fragment was identified with several site-specific monoclonal antibodies against PZP.