Tissue factor deficiency increases alveolar hemorrhage and death in influenza A virus-infected mice.

UNLABELLED: Essentials H1N1 Influenza A virus (IAV) infection is a hemostatic challenge for the lung. Tissue factor (TF) on lung epithelial cells maintains lung hemostasis after IAV infection. Reduced TF-dependent activation of coagulation leads to alveolar hemorrhage. Anticoagulation might increase the risk for hemorrhages into the lung during severe IAV infection. SUMMARY: Background Influenza A virus (IAV) infection is a common respiratory tract infection that causes considerable morbidity and mortality worldwide. Objective To investigate the effect of genetic deficiency of tissue factor (TF) in a mouse model of IAV infection. Methods Wild-type mice, low-TF (LTF) mice and mice with the TF gene deleted in different cell types were infected with a mouse-adapted A/Puerto Rico/8/34 H1N1 strain of IAV. TF expression was measured in the lungs, and bronchoalveolar lavage fluid (BALF) was collected to measure extracellular vesicle TF, activation of coagulation, alveolar hemorrhage, and inflammation. Results IAV infection of wild-type mice increased lung TF expression, activation of coagulation and inflammation in BALF, but also led to alveolar hemorrhage. LTF mice and mice with selective deficiency of TF in lung epithelial cells had low basal levels of TF and failed to increase TF expression after infection; these two strains of mice had more alveolar hemorrhage and death than controls. In contrast, deletion of TF in either myeloid cells or endothelial cells and hematopoietic cells did not increase alveolar hemorrhage or death after IAV infection. These results indicate that TF expression in the lung, particularly in epithelial cells, is required to maintain alveolar hemostasis after IAV infection. Conclusion Our study indicates that TF-dependent activation of coagulation is required to limit alveolar hemorrhage and death after IAV infection.

A fast, streaming SIMD Extensions 2, logistic squashing function.

Schraudolph proposed an excellent exponential approximation providing increased performance particularly suited to the logistic squashing function used within many neural networking applications. This note applies Intel's streaming SIMD Extensions 2 (SSE2), where SIMD is single instruction multiple data, of the Pentium IV class processor to Schraudolph's technique, further increasing the performance of the logistic squashing function. It was found that the calculation of the new 32-bit SSE2 logistic squashing function described here was up to 38 times faster than the conventional exponential function and up to 16 times faster than a Schraudolph-style 32-bit method on an Intel Pentium D 3.6 GHz CPU.

Dielectric spectroscopy of Tobacco Mosaic Virus.

The dielectric properties of the Tobacco Mosaic Virus (TMV) have been measured using time domain dielectric spectroscopy (TDDS) in the temperature range from 1 to 40 degrees C. A single dielectric dispersion is observed in the MHz range. The activation energy of the process is found to be in the range 1-2 kcal/mol. The experimental data could not be completely accounted for by current theoretical models, but evidence indicates that the dielectric loss arises from polarisation of charge on and around the virus.

Pararetrovirus-crucifer interactions: attack and defence or modus vivendi?

Abstract The compatible infection of plants by viruses usually leads to the development of systemic symptoms. Symptom expression of this kind is generally understood to be a host response that indicates an inability of the host to defend itself from attack. We have been studying compatible interactions between the plant pararetrovirus cauliflower mosaic virus (CaMV) and its crucifer hosts in order to understand the relationship between viral activity, symptom expression and plant defence. A CaMV protein (P6) appears to play a major role in eliciting symptom expression. This host response leads to a regulation of the viral multiplication cycle that is associated with leaf mosaics. The host regulation of CaMV appears to operate at the transcriptional level through an effect on the 35S promoter, or at the post-transcriptional level by a process that is akin to gene silencing, and can lead to host recovery depending upon the genetic background of the host. The plant apex is a focus for antiviral defence mechanisms, presumably because viral infection of the apical meristem would rapidly compromise the ability of the plant to generate new leaves and flowers for reproduction. The balance of interactions between CaMV and crucifers can provide a sustainable source of host plants to ensure viral propagation and viral exposure allows the host to adapt and develop its repertoire of defence mechanisms.

Altered patterns of gene expression in Arabidopsis elicited by cauliflower mosaic virus (CaMV) infection and by a CaMV gene VI transgene.

Cauliflower mosaic virus (CaMV) gene VI protein (P6) is an important determinant of symptom expression. Differential display polymerase chain reaction (PCR) was used to identify changes in gene expression in Arabidopsis elicited by a P6 transgene that causes a symptomatic phenotype. We used slot blot hybridization to measure the abundance of mRNAs complementary to 66 candidate PCR products in transgenic, CaMV-infected, and uninfected Arabidopsis plants. CaMV-infected and P6 transgenic plants showed broadly similar changes in abundance of mRNA species. In P6 transgenic plants we detected 18 PCR products that showed unambiguous changes in abundance plus another 15 that showed more limited changes (approximately twofold). CaMV-infected plants showed 17 unambiguous and 13 limited changes. Down-regulated species include those encoding a novel, phenol-like sulfotransferase, and a glycine-rich, RNA-binding protein. Up-regulated species included ones encoding an myb protein, glycine-rich and stress-inducible proteins, and a member of a previously unreported gene family. CaMV infection causes alterations in expression of many Arabidopsis genes. Transgene-mediated expression of P6 mimics virus infection in its effect on host gene expression, providing a potential mechanism for this process.

Characterization of gamma irradiation-induced deletion mutations at a selectable locus in Arabidopsis.

Seeds of transgenic Arabidopsis, containing a negatively selectable suicide marker, a 35Stms2 construct introduced as a transgene, were gamma-irradiated at a range of doses from 20-120 krad. Batches of M2 seeds, from M1 plants irradiated at doses of 40, 45 and 60 krad, were screened by germinating them on medium containing NAM under conditions that selectively inhibited growth of plants expressing the tms2 gene product. Nine candidate loss-of-transgene mutants were isolated. The frequency of such mutations (0.0125 to 0.025%) did not vary significantly with irradiation dose or M1 pool size. DNA from the mutants and the parent was hybridized in Southern blots, using probes complementary to various regions of the transgene. All nine mutants were null for both the tms2 coding sequence and the 35S promoter. Six of the nine mutants were null for the entire transgene construct of 9 kbp. DNA from one mutant contained one of the T-DNA borders and gave a hybridization pattern consistent with a deletion at least 5 kbp. The two remaining mutant lines gave identical patterns of hybridization, consistent with a 5.6-kbp internal deletion within the transgene. From the Southern blots, and on the basis of lineage, the nine lines represent the progeny of either seven or eight independent mutations. We have established conditions capable of producing deletion mutations of at least 5 kbp, but without apparently introducing small deletions or rearrangements. Such deletion mutations are ideally suited for cloning by subtractive hybridization, and should also be readily detectable by RFLP analysis, facilitating map-based cloning procedures.

Transgenic Arabidopsis lines expressing gene VI from cauliflower mosaic virus variants exhibit a range of symptom-like phenotypes and accumulate inclusion bodies.

Gene VI of cauliflower mosaic virus (CaMV) is an important determinant of symptom expression during infection. We have constructed a series of transgenic Arabidopsis lines that express gene VI protein (P6) from two CaMV isolates (Bari-1 and Cabb B-JI) that cause mild and severe symptoms, respectively, in Arabidopsis, and from a recombinant virus (Baji-31) with a hybrid gene VI that causes very severe symptoms. From 41 transgenic lines analyzed, 17 showed symptom-like phenotypes that ranged from mild vein chlorosis to severe chlorosis and stunting. P6 levels in transgenic lines varied from undetectable in the lowest expressors to levels greater than those in CaMV-infected plants. There was a strong correlation between phenotype severity and the level of P6, and with the gene VI origin in the order, Baji-31 > B-JI > Bari-1. This was similar to symptom severity in Arabidopsis infected with the respective CaMV variant. We also found that transgenic P6 accumulated in inclusion bodies that were similar to those found in infected plants but lacking virions. We conclude that expression of P6, in the absence of virus replication, elicits a subset of the host symptom responses normally observed during infection and that the level, sequence, and possibly the form of P6 are important in potentiating the process.

Manipulation and trapping of sub-micron bioparticles using dielectrophoresis.

A non-uniform alternating electric field induces motion in polarisable particles called dielectrophoresis. The effect is governed by the relative magnitudes of the dielectric properties of the medium and the particles. The technology has been used to manipulate particles for biotechnological applications, including purification, fractionation and concentration of cells and microorganisms. However, the lower size limit for the dielectrophoretic manipulation of particles was believed to be about 1 micron, but recent work has proved otherwise. The dielectrophoretic movement and properties of latex beads and a simple rod-shaped virus, tobacco mosaic virus (TMV), have been measured using microfabricated electrode structures. Measurements have been made over a range of suspending medium conductivities, applied frequencies and electric field strengths. It is shown that under appropriate conditions both latex beads and tobacco mosaic virus particles can be selectively attracted to regions of high electric field strength located at the tips of microfabricated electrode structures. The ability to selectively trap and separate bio-particles has many potential applications in the area of biotechnology.

A kinetic model for subtractive hybridization.

Nucleic acid sequences that differ in abundance between two populations (target sequences) can be cloned by multiple rounds of subtractive hybridization and amplification by PCR. These sequences can be cDNAs representing up-regulated mRNAs, or genomic DNAs from deletion mutants. We have derived an equation that describes the recovery of such sequences, and have used this to simulate the outcome of up to 10 rounds of subtractive hybridization and PCR amplification. When the model was tested by comparing its predictions with the published results from genomic and cDNA subtractions, the predictions of the model were generally in good agreement with the published data. We have modelled the outcomes of genomic subtractions, for a variety of genomes, and have used it to compare various strategies for enriching targets. The model predicts that for genomes of less than 5 x 10(8) bp, deletions of as small as 1 kbp should represent > 99% of the DNA after three to six rounds of hybridization (depending on the enrichment procedure). As genomes increase in size, the kinetics of hybridization become an important limiting factor. However, even for genomes as large as 3 x 10(9) bp, it should be possible to isolate deletions of 5 kbp using the appropriate conditions. These simulations suggest that such methods offer a realistic alternative to chromosome walking for identifying genomic deletions for which there are known phenotypes, thereby considerably reducing time and effort. For cDNA subtractive hybridization, the model predicts that after six rounds of hybridization, sequences that do not differ in abundance between the tester and driver populations (the background) will represent < 1% of the subtracted population, and even quite modestly upregulated cDNAs should be successfully enriched. Where several up-regulated cDNAs are present, the predicted final representation is dependent on both the initial abundance and the degree of up-regulation.

Identification of genes up-regulated in dedifferentiating Nicotania glauca pith tissue, using an improved method for constructing a subtractive cDNA library.

Pith explants of Nicotiana glauca grown in vitro in synthetic medium supplemented with 2,4 dichlorophenoxyacetic acid (2, 4 D), are induced to dedifferentiate. Treatment with actinomycin D within the first 4-8 h of culture (but not later) is lethal and the explants die, implying a requirement for de novo transcription. The genes expressed during the initial period of culture are presumably critical for subsequent cell survival and proliferation, but so far their identity is unknown. We have constructed a subtractive cDNA library, enriched in sequences more abundant in dedifferentiating tissue than in pith. The subtractive library contains approximately seven major species, two of which, NGSUB7 and NGSUB8, are highly abundant. In Northern blots, these two hybridized to mRNA species whose abundance increased significantly but transiently during the first 4 to 8 h of culture. The sequence of NGSUB7 showed no significant homology at a nucleotide or derived amino acid level with any previously reported sequence. NGSUB8 however, showed significant homology over part of the derived amino acid sequence to several yeast and bacterial proteins with DNA binding function. We propose that the two recombinants represent transcripts from two novel genes edeA and edeB, which are expressed early in dedifferentiation.

Size and complexity of polyadenylated RNAs induced in tobacco infected with sonchus yellow net virus.

Hybridization of 32P-labeled sonchus yellow net virus (SYNV) RNA to polyadenylated (poly A+) RNA from infected tobacco reveals the presence of four electrophoretically distinct components. These components probably represent five discrete RNA species complementary to SYNV RNA (scRNAs). The scRNAs are smaller than the 13,000 nucleotide (NT) SYNV genome and range in size from 1200 to 6600 NT. Individual recombinant DNA clones derived from SYNV RNA hybridize to at least three and probably four of the scRNAs. These results suggest that each of the scRNAs contains unique sequences with a combined size representing more than 90% of the viral genome. Therefore, the size range and sequence complexity of the scRNAs are as expected for messenger RNAs encoding the four major SYNV polypeptides and the minor "L-protein."

Investigation of the complexity of barley stripe mosaic virus RNAs with recombinant dna clones.

RNA isolated from the Type, ND18, and Norwich strains of barley stripe mosaic virus (BSMV) was electrophoresed in agarose gels, transferred to nitrocellulose, and hybridized with BSMV-specific complementary DNA (cDNA) or recombinant DNA clones derived from ND18 RNA. Genomic RNA components 1 (Mr = 1.43 x 10(6)) and 2 (Mr = 1.24 x 10(6)) were resolved in all three strains, but RNA 3 (Mr = 1.1 x 10(6)) was seen only in the ND18 and Norwich strains. A low-molecular-weight RNA (Mr = 0.27 x 10(6)), thought to be a subgenomic (SG) RNA, was also detected in RNA preparations from all three strains by staining with toluidine blue or ethidium bromide and by hybridizing with cDNA or selected recombinant DNA probes. Three classes of recombinant DNA clones, designated pBSM1, pBSM2, and pBSM3, were identified by hybridization of nick-translated recombinant DNA to electrophoretically separated viral RNAs. Clones in the pBSM1 class hybridized only to RNA 1 of all three strains and class pBSM2 clones hybridized only to RNA 2 of all three strains. Class pBSM3 clones hybridized to RNA 3 of the ND18 and Norwich strains and to RNA 2 of the Type strain, but not to RNA 2 of ND18 or Norwich. Based on the sizes of the BSMV-specified inserts in clones designated pBSM1a, pBSM2a, and pBSM3a, we estimate that a minimum of 44, 63, and 63% of the nucleotide sequences of ND18 and Norwich RNAs 1, 2, and 3, respectively, are unique. Furthermore, because the combined size of the inserts in pBSM2a and pBSM3a is approximately 15% greater than the estimated size of RNA 2, it is probable that the second RNA component of the Type strain actually consists of two RNA species which are similar in size but have different sequences. The SG RNA component is viral specific and contains sequences common to clones derived from RNA 3.

Euglena gracilis Chloroplast DNA Codes for Polyadenylated RNA.

Polyadenylated RNA, isolated from total cellular RNA of photoautotrophically grown Euglena gracilis, comprised 2.1% of the total cellular RNA and contained 6.2% polyadenylic acid. Polyadenylated RNA, labeled in vitro with (125)I, hybridized at saturating levels to an average 7.7% of the chloroplast DNA. In the presence of excess chloroplast rRNA, hybridization of polyadenylated RNA was reduced, but was still observed at a level corresponding to 2.8% of the chloroplast DNA. Polyadenylic acid was not detected in mRNA prepared from chloroplast polyribosomes, indicating a level of less than 0.1% polyadenylic acid in mature chloroplast mRNA. Of the total RNA isolated from cytoplasmic polyribosomes, 2.0% contained polyadenylic acid. This latter polyadenylated RNA did not hybridize to chloroplast DNA.

Subcellular distribution of RNA sequences complementary to sonchus yellow net virus RNA.

RNA isolated from free and membrane-bound polyribosomes of sonchus yellow net virus (SYNV)-infected tobacco was hybridized to SYNV RNA. RNA from free polyribosomes was shown to be complementary to nearly 100% of the SYNV genome, whereas RNA from membrane-bound polyribosomes was complementary to only 40% of the SYNV RNA. When RNA derived from the two classes of polyribosomes was fractionated by chromatography on oligo(dT)-cellulose, sequences complementary to SYNV RNA were present in both bound and unbound fractions. Neither nuclear RNA nor poly(A)-containing nuclear RNA from SYNV-infected plants hybridized to SYNV RNA. The results suggest that SYNV messenger RNAs are selectively partitioned in the cytoplasm and that hybridizing sequences are not abundant in the nuclei of infected cells.

Sequence complementarity of sonchus yellow net virus RNA with RNA isolated from the polysomes of infected tobacco.

Polyribosomal RNA from tobacco infected with sonchus yellow net virus (SYNV) contained sequences which hybridized to 125I-labeled SYNV RNA and which were complementary to 80 to 100% of the viral RNA genome. The poly(A)-containing RNA from polyribosomes was complementary to over 90% of the viral genome but the polyribosomal RNA lacking poly(A) hybridized to approximately 40-60% of the genome. The kinetics of hybridization of all three fractions are best explained by the presence of a single abundance class of viral-complementary RNA. However, titration hybridization of poly(A)+ RNA to an excess of SYNV RNA suggested that viral-complementary sequences which contain poly(A) may vary in concentration over a factor of about fivefold. About 1.5 to 4.6% of the fraction containing poly(A), 0.02 to 0.06% of the fraction lacking poly(A) and 0.04 to 0.18% of the total polyribosomal RNA was complementary to viral RNA as estimated from the kinetics of hybridization. The viral complementary RNA(vcRNA) was heterogeneous in size with a modal sedimentation coefficient of 12 S and a profile in sucrose density gradients similar to the polyadenylated polyribosomal RNA.

Analysis of Euglena gracilis chloroplast deoxyribonucleic acid with a restriction endonuclease, EcoRI.

Cleavage of chloroplast deoxyribonucleic acid (DNA) of Euglena gracilis Z with restriction endonuclease RI from Escherichia coli (EcoRI) yielded 23 bands upon electrophoresis in gels of agarose. Four of the bands contained twice the stoichiometric amount of DNA. One of these bands contained two similarly sized fragments. The sum of the molecular weight of the 24 different fragments equaled the molecular weight of the circular molecule. The restriction fragments had different buoyant densities, with four having distinctly heavy densities in CsCl. Restriction fragments with a high buoyant density were preferentially lost when broken chloroplast DNA was purified by equilibrium density gradient centrifugation. Hybridization of chloroplast ribosomal ribonucleic acid to intact chloroplast DNA determined that there are two cistrons for 16S and 23S ribosomal ribonucleic acid. These two cistrons are located on six restriction fragments, all of which have buoyant densities greater than the intact molecule of chloroplast DNA.

The conformation of 16S RNA in the 30S ribosomal subunit from Escherichia coli.

The digestion of E. coli 16S RNA with a single-strand-specific nuclease produced two fractions separable by gel filtration. One fraction was small oligonucleotides, the other, comprising 67.5% of the total RNA, was highly structured double helical fragments of mol. wt. 7,600. There are thus about 44 helical loops of average size corresponding to 12 base pairs in each 16S RNA. 10% of the RNA could be digested from native 30S subunits. Nuclease attack was primarily in the intraloop single-stranded region but two major sites of attack were located in the interloop single-stranded regions. Nuclease digestion of unfolded subunits produced three classes of fragments, two of which, comprising 80% of the total RNA, were identical to fragments from 16S RNA. The third, consisting of 20% RNA, together with an equal weight of peotein, was a resistant core (sedimentation coefficient 7S).