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The primary objective of this study was to elucidate gene organization and to integrate the genetic linkage map for barley (Hordeum vulgare L.) with a physical map using ultrasensitive fluorescence in situ hybridization (FISH) techniques for detecting signals from restriction fragment length polymorphism (RFLP) clones. In the process, a single landmark plasmid, p18S5Shor, was constructed that identified and oriented all seven of the chromosome pairs. Plasmid p18S5Shor was used in all hybridizations. Fourteen cDNA probes selected from the linkage map for barley H. vulgare 'Steptoe' x H. vulgare 'Morex' (Kleinhofs et al. 1993) were mapped using an indirect tyramide signal amplification technique and assigned to a physical location on one or more chromosomes. The haploid barley genome is large and a complete physical map of the genome is not yet available; however, it was possible to integrate the linkage map and the physical locations of these cDNAs. An estimate of the ratio of base pairs to centimorgans was an average of 1.5 Mb/cM in the distal portions of the chromosome arms and 89 Mb/cM near the centromere. Furthermore, while it appears that the current linkage maps are well covered with markers along the length of each arm, the physical map showed that there are large areas of the genome that have yet to be mapped.

The Class II transposable element, piggyBac, was used to transform the yellow fever mosquito, Aedes aegypti. In two transformed lines only 15-30% of progeny inherited the transgene, with these individuals displaying mosaic expression of the EGFP marker gene. Southern analyses, gene amplification of genomic DNA, and plasmid rescue experiments provided evidence that these lines contained a high copy number of piggyBac transformation constructs and that much of this DNA consisted of both donor and helper plasmids. A detailed analysis of one line showed that the majority of piggyBac sequences were unit-length donor or helper plasmids arranged in a large tandem array that could be lost en masse in a single generation. Despite the presence of a transposase source and many intact donor elements, no conservative (cut and paste) transposition of piggyBac was observed in these lines. These results reveal one possible outcome of uncontrolled and/or unexpected recombination in this mosquito, and support the conclusion that further investigation is necessary before transposable elements such as piggyBac can be used as genetic drive mechanisms to move pathogen-resistance genes into mosquito populations.

A polymerase chain reaction (PCR) assay was developed for detecting duck plague virus. A 765-hp EcoRI fragment cloned from the genome of the duck plague vaccine (DP-VAC) virus was sequenced for PCR primer development. The fragment sequence was found by GenBank alignment searches to be similar to the 3' ends of an undefined open reading frame and the gene for DNA polymerase protein in other herpesviruses. Three of four primer sets were found to be specific for the DP-VAC virus and 100% (7/7) of field isolates but did not amplify DNA from inclusion body disease of cranes virus. The specificity of one primer set was tested with genome templates from other avian herpesviruses, including those from a golden eagle, bald eagle, great horned owl, snowy owl, peregrine falcon, prairie falcon, pigeon, psittacine, and chicken (infectious laryngotracheitis), but amplicons were not produced. Hence, this PCR test is highly specific for duck plague virus DNA. Two primer sets were able to detect 1 fg of DNA from the duck plague vaccine strain, equivalent to five genome copies. In addition, the ratio of tissue culture infectious doses to genome copies of duck plague vaccine virus from infected duck embryo cells was determined to be 1:100, making the PCR assay 20 times more sensitive than tissue culture for detecting duck plague virus. The speed, sensitivity, and specificity of this PCR provide a greatly improved diagnostic and research tool for studying the epizootiology of duck plague.

Barley metaphase chromosomes (2n = 14) can be identified by fluorescence in situ hybridization (FISH) and digital imaging microscopy using heterologous 18S rDNA and 5S rDNA probe sequences. When these sequences are used together, FISH landmark signals were seen so that all 7 chromosomes were uniquely identified and unambiguously oriented. The chromosomal location of the landmark signals was determined by FISH to a barley trisomic series using the 18S and 5S probes labeled with different fluorophores. The utility of these FISH landmarks for barley physical mapping was also demonstrated when an Amy-2 cDNA clone and a BAC clone were hybridized with the FISH landmark probes.

The usefulness of isozyme patterns for distinguishing 14 lepidopteran and 2 dipteran cell lines was evaluated. The lepidopteran cell lines used in this study represent eight taxonomic families with one family, Noctuidae, having five representatives. Cell extracts were examined for 18 isozymes using a starch gel electrophoretic system. Ten isozymes proved to be suitable because their isozyme patterns permitted the allocation of the cell lines into distinct groups. Furthermore, four isozymes (isocitrate dehydrogenase, malic enzyme, phosphoglucoisomerase, and phosphoglucomutase) were found to be adequate to distinguish the cell lines. The isozyme patterns observed for the two dipteran and one of the lepidopteran cell lines were analogous to the profiles found using the intact insect. Isozyme analyses differentiated the cell lines and may prove useful for identifications of species of origin. The use of this technique as a criterion for identification of invertebrate cell lines is proposed.

The chromosomal distribution, copy numbers, and nucleotide sequences were determined for four repetitive DNA clones, pSB1 and pSB7 of Solanum brevidens and pST3 and pST10 of Solanum tuberosum. Using fluorescence in situ hybridization (FISH), pSB1 and pSB7 were localized near the telomeres and in some centromeric and interstitial sites of S. brevidens chromosomes, but not in S. tuberosum chromosomes, after high stringency washes. The clone pST3 showed signals in the telomeric areas of a few chromosomes in S. tuberosum, but signals were not detected in S. brevidens. All three repeated sequences (pSB1, pSB7, and pST3) were detected in chromosomal areas that are typically known to contain tandemly repeated sequences. The S. tuberosum clone pST10 did not show signals in either species even at low stringency conditions. The estimated copy numbers of the four clones were 1500, 6750, 300, and 400 for pSB1, pSB7, pST3, and pST10, respectively, in the corresponding haploid genomes (S. brevidens and S. tuberosum). The inserts of the four clones pSB1, pSB7, pST3, and pST10 were 322, 167, 845, and 121 bp, respectively. After sequencing, no significant sequence homologies were found among the four clones. A homology search in sequence data bases showed that pSB7 has variable homology (78-100%) with another repetitive sequence of S. brevidens Sb4/2 depending on its subrepeat. It also showed some homology with one repeat of tomato (pLEG15) and one repeat of Solanum circaeifolium (pSC15).

isozyme analyses of acarine (Rhipicephalus appendiculatus) and dipteran cell lines used in study of arboviruses, usefulness of this characterization technique in identifying potentially mislabeled cell lines

The usefulness of four serologic techniques for distinguishing five selected lepidopteran cell lines was evaluated; the techniques included complement fixation, hemagglutination, immunodiffusion, and immunoelectrophoresis. The five selected lepidopteran cell lines represent three taxonomic families of Lepidoptera with one family, Noctuidae, containing two cell lines derived from insects within the same genus. The five cell lines were cross-reactive in complement-fixation tests, but the lines were distinguishable at a familic level when two units of antigens were used in the test. Agglutination of goose erythrocytes was not observed with the antigens over a pH range of 5.8 to 7.2 at 4° C or ambient temperature. Immunodiffusion tests demonstrated a common cross-reactive antigen(s), but spurs of partial identity and the presence of extra precipitin bands were indicative that differentiation at a familic level was possible. Immunoelectrophoresis of the cellular antigens also revealed common cross-reactive precipitin arcs, but the number and clarity of arcs in homologous systems was increased such that four of the five cell lines were distinguishable. A basic protein was consistently seen in the homologous system, but it was absent in the heterologous systems. Although these data suggest that immunoelectrophoresis was the best serologic technique for distinguishing the five lepidopteran cell lines, the shortcomings of this approach are also discussed.