Analysis of recombinant adenoviruses using an integrated microfluidic chip-based system.

The use of recombinant virus for gene therapy requires rigorous quality control methods to ensure that the viral vector preparations are functional and safe. A viral identity test is performed in which the viral payload, or transgene, is PCR amplified, followed by digestion with restriction enzymes that yields a characteristic "fingerprint." These DNA fragments are typically analyzed by agarose gel electrophoresis. The ethidium bromide-stained gels are photographed or scanned and the results are sufficient for a qualitative or semiquantitative identity confirmation of the viral product. We have investigated the use of an integrated microfluidic chip-based system as a new tool in the quality control testing of a recombinant, adenoviral, gene therapy product. The chip-based method was found to be very sensitive, requiring 100-fold less sample and only one-third the time compared to the agarose gel method. The automated data analysis sizes and quantitates the DNA fragments, thus yielding a more thorough, reproducible, sensitive, and rapid analysis.

Approaches to functional genomics: potential of matrix-assisted laser desorption ionization--time of flight mass spectrometry combined with separation methods for the analysis of DNA in biological samples.

MALDI-TOF MS has potential as a valuable technique in DNA mapping studies and may well be complementary to other approaches to DNA analysis such as gel electrophoresis and sequencing. This study used 2,6-dihydroxyacetophenone (DHAP) mixed with diammonium hydrogen citrate (DAHC) as the matrix. In addition, recent technical advances such as time lag focussing (TLF) and better selection of matrices (such as 3-hydroxypicolinic acid (3 HPA) and picolinic acid (PA)) extended the range of DNA fragments that can be studied by this approach. The following samples were investigated: Poly-T mixture (dT 15, 19, 20, 25, 74 and 75), plasmid pBR322 derived oligonucleotides (10, 11, 12, 13, 14, 15, 19, 20 and 50 nucleotides long) and DNA fragments of 25, 36 and 37 base pairs corresponding to a fragment in the restriction map for the gene corresponding to the hexon protein of Adenovirus 2 and 5. The results were contrasted with similar analyses performed by ion-paired reversed-phase HPLC coupled to on-line electrospray mass spectrometry.

Use of microphysiometry for analysis of heterologous ion channels expressed in yeast.

Measurement of extracellular acidification rates by microphysiometry provides a means to analyze the function of ion channels expressed in yeast cells. These measurements depend on the proton pumping action of the H(+)-ATPase, a central component of the yeast plasma membrane. We used microphysiometry to analyze the activity of two ion channels expressed in yeast. In one example, an inwardly rectifying K+ channel, gpIRK1, provides a potassium uptake function when expressed in a potassium transporter-defective yeast strain. Rates of acidification in gpIRK1-expressing cells directly reflect channel function. Addition of cesium, an inhibitor of gpIRK1 activity, results in an immediate reduction in acidification rates. In a second example, expression of a nonselective cation channel, the influenza virus M2 protein, is believed to interfere with the maintenance of the electrochemical proton gradient by the H(+)-ATPase. In cells expressing the M2 channel, addition of inhibitors increases the rate of proton extrusion. Moreover, functional differences between two M2 inhibitors, amantadine and BL-1743, are distinguished by the microphysiometer. This application demonstrates the utility of the microphysiometer for functional studies of ion channels; it is adaptable to a screening process for compounds that modulate ion channel activity.

Functional expression of the Schizosaccharomyces pombe Na+/H+ antiporter gene, sod2, in Saccharomyces cerevisiae.

In the fission yeast, Schizosaccharomyces pombe, tolerance to high sodium and lithium concentrations requires the functioning of the sod2, Na+/H+ antiporter. We have directly measured the activity of this antiporter and demonstrated reconstitution of the activity in gene deletion strains. In addition, we have shown that it can be transferred to, and its antiporter activity detected in, the budding yeast, Saccharomyces cerevisiae, where it also confers sodium and lithium tolerance. Proton flux through the S. pombe Na+/H+ antiporter was directly measured using microphysiometry. The direction of transmembrane proton flux mediated by this antiporter was reversible, with protons being imported or exported in response to the external concentration of sodium. This bidirectional activity was also detected in S. cerevisiae strains expressing sod2 and expression of this gene complemented the sodium and lithium sensitivity resulting from inactivation of the ENA1/PMR2 encoded Na+-exporting ATPases. This suggests that antiporters or sodium pumps can be utilized interchangeably by S. cerevisiae to regulate internal sodium concentration. Potent inhibitors of mammalian Na+/H+ exchangers were found to have no effect on sod2 activity. The proton flux mediated by sod2 was also found to be unaffected by perturbation of membrane potential or the plasma membrane proton gradient.

Growth impairment resulting from expression of influenza virus M2 protein in Saccharomyces cerevisiae: identification of a novel inhibitor of influenza virus.

The gene encoding M2, the ion channel-forming protein of influenza virus A, was expressed under the control of an inducible promoter in Saccharomyces cerevisiae. By using single and multicopy plasmids containing GAL promoter-M2 fusions, a correlation was observed between plasmid copy number and growth in medium inducing M2 expression. Cells expressing M2 from multicopy plasmids have reduced growth rates, suggesting that high levels of M2 are toxic to growth. The addition of amantadine, a compound known to block the ion channel activity of certain M2 alleles, restores the growth rates to wild-type levels in cells expressing an amantadine-susceptible allele of M2 but not an amantadine-resistant allele of M2, suggesting that M2 expression in S. cerevisiae results in the formation of functional M2 ion channels. Measurements of extracellular acidification by microphysiometry suggest that proton efflux in M2-expressing cells is altered and that the addition of amantadine permits the reestablishment of the proton gradient. The growth impairment phenotype resulting from M2 expression was used to develop a high-capacity screening assay which identified a novel inhibitor possessing an antiviral profile similar to that of amantadine.

Centromeres of the fission yeast Schizosaccharomyces pombe are highly variable genetic loci.

Gross variations in the structure of the centromere of Schizosaccharomyces pombe chromosome III (cen3) were apparent following characterization of this centromeric DNA in strain Sp223 and comparison of the structure with that of cen3 in three other commonly used laboratory strains. Further differences in centromere structure were revealed when the structure of the centromere of S. pombe chromosome II (cen2) was compared among common laboratory strains and when the structures of cen2 and cen3 from our laboratory strains were compared with those reported from other laboratories. Differences observed in cen3 structure include variations in the arrangement of the centromeric K repeats and an inverted orientation of the conserved centromeric central core. In addition, we have identified two laboratory strains that contain a minimal cen2 repeat structure that lacks the tandem copies of the cen2-specific block of K-L-B-J repeats characteristic of Sp223 cen2. We have also determined that certain centromeric DNA structural motifs are relatively conserved among the four laboratory strains and eight additional wild-type S. pombe strains isolated from various food and beverage sources. We conclude that in S. pombe, as in higher eukaryotes, the centromere of a particular chromosome is not a defined genetic locus but can contain significant variability. However, the basic DNA structural motif of a central core immediately flanked by inverted repeats is a common parameter of the S. pombe centromere.

Identification of DNA regions required for mitotic and meiotic functions within the centromere of Schizosaccharomyces pombe chromosome I.

We have determined the structural organization and functional roles of centromere-specific DNA sequence repeats in cen1, the centromere region from chromosome I of the fission yeast Schizosaccharomyces pombe. cen1 is composed of various classes of repeated sequences designated K', K"(dgl), L, and B', arranged in a 34-kb inverted repeat surrounding a 4- to 5-kb nonhomologous central core. Artificial chromosomes containing various portions of the cen1 region were constructed and assayed for mitotic and meiotic centromere function in S. pombe. Deleting K' and L from the distal portion of one arm of the inverted repeat had no effect on mitotic centromere function but resulted in greatly increased precocious sister chromatid separation in the first meiotic division. A centromere completely lacking K' and L, but containing the central core, one copy of B' and K" in one arm, and approximately 2.5 kb of the core-proximal portion of B' in the other arm, was also fully functional mitotically but again did not maintain sister chromatid attachment in meiosis I. However, deletion of K" from this minichromosome resulted in complete loss of centromere function. Thus, one copy of at least a portion of the K" (dgl) repeat is absolutely required but is not sufficient for S. pombe centromere function. The long centromeric inverted-repeat region must be relatively intact to maintain sister chromatid attachment in meiosis I.

Image reconstruction of the flagellar basal body of Caulobacter crescentus.

The bacterium Caulobacter crescentus has a single polar flagellum, which is present for only a portion of its cell cycle. The flagellum is ejected from the swarmer cell and then synthesized de novo later in the cell cycle. The flagellum is composed of a transmembrane basal body, a hook and a filament. Single-particle averaging and image reconstruction methods were applied to the electron micrographs of negatively stained basal bodies from C. crescentus. These basal bodies have five rings threaded on a rod. The L and P rings are connected by a bridge of material at their outer radii. The E ring is a thin, flat disk. The S ring has a triangular cross section, the sides of the triangle abutting the E ring, the rod and the M ring. The M ring, which is at the inner membrane of the cell, has a different structure depending on the method of preparation. With one method, the M ring makes a snug contact with the S ring and is often capped by an axial button, a new component apparently distinct from the M ring. With the other method, the M ring is similar to that of S. typhimurium; that is, it contacts the S ring only at an outer radius and lacks the button. Averages of the rod-hook-filament subassembly ejected by swarmer cells reveal that the rod consists of two parts with the E ring marking the approximate position of the break. The structures of basal bodies from two mutants defective in the hook assembly were found to be indistinguishable from wild-type basal bodies, suggesting that the assembly of the basal body is independent of the hook or filament assembly.

Construction of functional artificial minichromosomes in the fission yeast Schizosaccharomyces pombe.

The centromere DNAs from chromosomes I and III of Schizosaccharomyces pombe have been cloned in an artificial chromosome vector in both budding and fission yeasts. In S. pombe, synthetic linear and circular minichromosomes containing an intact centromere are stable mitotically and behave as independent genetic linkage groups that segregate properly through meiosis. These experiments present a general strategy for the isolation of centromeres from other organisms.

Organization and temporal expression of a flagellar basal body gene in Caulobacter crescentus.

Caulobacter crescentus assembles a single polar flagellum at a defined time in the cell cycle. The protein components of the flagellar hook and filament are synthesized just prior to their assembly. We demonstrated that the expression of a gene, flaD, that is involved in the formation of the flagellar basal body is under temporal control and is transcribed relatively early in the cell cycle, before the hook and flagellin genes are transcribed. Thus, the order of flagellar gene transcription reflects the order of assembly of the protein components. A mutation in the flaD gene results in the assembly of a partial basal body which is missing the outermost P and L rings as well as the external hook and filament (K.M. Hahnenberger and L. Shapiro, J. Mol. Biol. 194:91-103, 1987). The flaD gene was cloned and characterized by nucleotide sequencing and S1 nuclease protection assays. In contrast to the protein components of the hook and filament, the protein encoded by the flaD gene contains a hydrophobic leader peptide. The predicted amino acid sequence of the leader peptide of flaD is very similar to the leader peptide of the flagellar basal body P ring of Salmonella typhimurium (M. Homma, Y. Komeda, T. Iino, and R.M. Macnab, J. Bacteriol. 169:1493-1498, 1987).

Identification of a gene cluster involved in flagellar basal body biogenesis in Caulobacter crescentus.

The bacterial flagellum is a complex structure composed of a transmembrane basal body, a hook, and a filament. In Caulobacter crescentus the biosynthesis and assembly of this structure is under temporal and spatial control. To help to define the order of assembly of the flagellar components and to identify the genes involved in the early steps of basal body construction, mutants defective in basal body formation have been analyzed. Mutants in the flaD flaB flaC gene cluster were found to be unable to assemble a complete basal body. The flaD BC motC region was cloned and the genes were localized by subcloning and complementation analysis. A series of Tn5 insertion mutations in the flaD BC region were mapped. Complementation analysis of the Tn5 insertion mutants indicated the existence of at least four transcriptional units in the region and identified the presence of two new genes designated flbN and flbO. Mutants in flbN, flaB, flaC and flbO were unable to assemble any basal body structure and are likely to be involved in the early steps of basal body formation. The flaD mutant, however, was found to contain a partially assembled basal body consisting of the rod and three hook-distal rings. All of the mutants in this cluster exhibited pleiotropic effects on the expression of other flagellar and chemotaxis functions, including the level of synthesis of flagellins, the hook protein and hook protein precursor, and the level of chemotaxis methylation.

Pleiotropic mutations regulating resistance to glucose repression in Saccharomyces carlsbergensis are allelic to the structural gene for hexokinase B.

Previously, we described a mutation glr1-1 in Saccharomyces carlsbergensis which pleiotropically relieves the synthesis of the following enzymes from glucose repression: maltase, galactokinase, alpha-galactosidase, NADH:cytochrome c reductase, and cytochrome c oxidase (C. A. Michels and A. Romanowski, J. Bacteriol, 143:674-679, 1980.) In this report, we demonstrate that glr1-1 and two other alleles, glr1-3 and glr1-16, are also insensitive to the glucose repression of invertase synthesis. Determinations of the levels of hexokinase activity and the rate of glucose transport in these mutants show that both are reduced as compared with the parent strain. Complementation tests and genetic analysis indicate that the glr1 mutations are allelic to HXK2, the structural gene for hexokinase B. The significance of this result is discussed with regard to the mechanism of glucose repression in S. carlsbergensis.