Your search keyword '"Derakhshifar I"' showing total 10 results

1. Association of Institutes for Bee Research Report of the 55th Seminar in Hohen Neuendorf 11–13March 2008

Author

Scheiner, R., Alkattea, R., Steidle, H., Rosenkranz, P., Grünewald, B., Bartsch, C., Giurfa, M., Devaud, J. -M., Lein, J., Becher, M., Moritz, R. F. A., Fuchs, S., Riessberger-Gallé, U., Vollmann, J., Brodschneider, R., Aupinel, P., Crailsheim, K., Elmi, M. Pour, Haddad, N., de Miranda, J. R., Siede, R., König, M., Büchler, R., Thiel, H. -J., Gisder, S., Aumeier, P., Yue, C., Genersch, E., Šekulja, D., Garrido, C., Bienefeld, K., Ehrhardt, K., Ziegelmann, B., Steidle, J., Joachimsmeier, I., Kirchner, W. H., Ashiralieva, A., Fünfhaus, A., Borriss, R., Randolt, K., Gimple, O., Gätschenberger, H., Beier, H., Tautz, J., Loncaric, I., Derakhshifar, I., Köglberger, H., Moosbeckhofer, R., Oberlerchner, J., Riedel, M., Yue, D., Nordhoff, M., Wieler, L. H., Harz, M., Rademacher, E., Berg, S., Schürzinger, F., Illies, I., Radtke, J., Neuberger, P., Kovac, H., Bartzsch, C., Trompelt, J., Feller, K. -H., Schmidt, W., and Etzold, E.

Published

2008

2. Association of Institutes for Bee Research Report of the 54th seminar in Veitshöchheim 27–29 March 2007

Author

Radtke, J., Etzold, E., Iilies, I., Siede, Reinhold, Büchler, R., Wegener, J., Huang, Z., Bienefeld, K., Kleinhenz, M., Bujok, B., Fuchs, S., Tautz, J., Knauer, U., Meffert, B., Heimken, Ch., Kirchner, W. H., Brodschneider, R., Hrassnigg, N., Vollmann, J., Petz, M., Riessberger-Gallé, U., Crailsheim, K., Thenius, R., Uhl, K., Krainer, S., Kovac, H., Siede, R., König, M., Thiel, H. -J., Schlesinger, A., Almanza, M. T., Wittmann, D., Makert, G. R., Paxton, R. J., Hartfelder, K., Muffert, A. M., Trein, L., Schindler, M., Hamm, A., Schumacher, W., Ruoff, K., Schroeder, A., von der Ohe, K., von der Ohe, W., Smanalieva, J., Lichtenberg-Kraag, B., Senge, B., Fritz, B., Weber, D., Wallner, K., Kasina, M., Martius, Ch., Illies, I., Kühn, J., Schneider, K., Forchmann, K., Friedrichs, K., Haas, E. M., Interthal, M., Jänicke, K., Kühn, T., Mergler, B., Mertens, E., Raehse, J., Schrüffer, Y., Seelinger, N., Sölch, K., Weißenborn, C., Hoffmann, I., Peruquetti, R. C., Peruquetti, R. C., Berg, S., Färber, C., Koeniger, N., Moritz, R. F. A., Spiewok, S., Schmolz, E., Ruther, J., Alkattea, R., Steidle, H., Rosenkranz, P., Aumeier, P., Lipka, J., Liebig, G., Frey, E., Yue, D., Ashiralieva, A., Hedtke, K., Genersch, E., Nordhoff, N., Wieler, L., Yue, C., Schröder, M., Loncaric, I., Derakhshifar, I., Köglberger, H., Moosbeckhofer, R., Martín, R., Higes, M., and Meana, A.

Published

2007

3. 54. Zum Vorkommen von Bacillus larvae-Sporen in österreichischen Honigen

Author

Derakhshifar, I and Revues Inra, Import

Subjects

[SDV.BA.ZI]Life Sciences [q-bio]/Animal biology/Invertebrate Zoology, [SDV.EE]Life Sciences [q-bio]/Ecology, environment, [SDV.EE] Life Sciences [q-bio]/Ecology, environment, [SDV.SA.SPA]Life Sciences [q-bio]/Agricultural sciences/Animal production studies, [SDV.BA.ZI] Life Sciences [q-bio]/Animal biology/Invertebrate Zoology, [SDV.BID]Life Sciences [q-bio]/Biodiversity, [SDV.SA.SPA] Life Sciences [q-bio]/Agricultural sciences/Animal production studies, ComputingMilieux_MISCELLANEOUS, [SDV.BID] Life Sciences [q-bio]/Biodiversity

Abstract

International audience

Published

1994

4. Sacbrood virus of the honeybee (Apis mellifera): rapid identification and phylogenetic analysis using reverse transcription-PCR.

Author

Grabensteiner, E, Ritter, W, Carter, M J, Davison, S, Pechhacker, H, Kolodziejek, J, Boecking, O, Derakhshifar, I, Moosbeckhofer, R, Licek, E, and Nowotny, N

Abstract

Sacbrood virus (SBV) infects larvae of the honeybee (Apis mellifera), resulting in failure to pupate and death. Until now, identification of viruses in honeybee infections has been based on traditional methods such as electron microscopy, immunodiffusion, and enzyme-linked immunosorbent assay. Culture cannot be used because no honeybee cell lines are available. These techniques are low in sensitivity and specificity. However, the complete nucleotide sequence of SBV has recently been determined, and with these data, we now report a reverse transcription-PCR (RT-PCR) test for the direct, rapid, and sensitive detection of these viruses. RT-PCR was used to target five different areas of the SBV genome using infected honeybees and larvae originating from geographically distinct regions. The RT-PCR assay proved to be a rapid, specific, and sensitive diagnostic tool for the direct detection of SBV nucleic acid in samples of infected honeybees and brood regardless of geographic origin. The amplification products were sequenced, and phylogenetic analysis suggested the existence of at least three distinct genotypes of SBV.

Published

2001

5. Health status of honey bee colonies (Apis mellifera) and disease-related risk factors for colony losses in Austria.

Author

Morawetz L, Köglberger H, Griesbacher A, Derakhshifar I, Crailsheim K, Brodschneider R, and Moosbeckhofer R

Subjects

Animal Husbandry trends, Animals, Austria, Beekeeping methods, Bees, Conservation of Natural Resources, Health Status, Honey, Risk Factors, Varroidae pathogenicity, Animal Husbandry methods, Beekeeping trends, Mite Infestations economics

Abstract

Austrian beekeepers frequently suffered severe colony losses during the last decade similar to trends all over Europe. This first surveillance study aimed to describe the health status of Austrian bee colonies and to analyze the reasons for losses for both the summer and winter season in Austria. In this study 189 apiaries all over Austria were selected using a stratified random sampling approach and inspected three times between July 2015 and spring 2016 by trained bee inspectors. The inspectors made interviews with the beekeepers about their beekeeping practice and the history of the involved colonies. They inspected a total of 1596 colonies for symptoms of nine bee pests and diseases (four of them notifiable diseases) and took bee samples for varroa mite infestation analysis. The most frequently detected diseases were three brood diseases: Varroosis, Chalkbrood and Sacbrood. The notifiable bee pests Aethina tumida and Tropilaelaps spp. were not detected. During the study period 10.8% of the 1596 observed colonies died. Winter proved to be the most critical season, in which 75% of the reported colony losses happened. Risks for suffering summer losses increased significantly, when colonies were weak in July, had queen problems or a high varroa mite infestation level on bees in July. Risks for suffering winter losses increased significantly, when the colonies had a high varroa mite infestation level on bees in September, were weak in September, had a queen older than one year or the beekeeper had few years of beekeeping experience. However, the effect of a high varroa mite infestation level in September had by far the greatest potential to raise the winter losses compared to the other significant factors., Competing Interests: LM, HK, AG, ID and RM are employees of the Austrian Agency for Health and Food Safety Ldt. (AGES). AGES is a limited liability company governed by private law which is wholly owned by the Republic of Austria. Due to the special ownership structure and the lack of self-interest of AGES, the particular working relationship is no circumstance that would call into question the author‘s impartiality or might give rise to a conflict of interest. This does not alter our adherence to PLOS ONE policies on sharing data and materials’.

Published

2019

6. Genetic diversity among isolates of Paenibacillus larvae from Austria.

Author

Loncaric I, Derakhshifar I, Oberlerchner JT, Köglberger H, and Moosbeckhofer R

Subjects

Austria, Bacteria classification, Bacteria isolation & purification, Bacterial Typing Techniques, Polymerase Chain Reaction, Bacteria genetics, Genotype

Abstract

Genetic diversity of 214 Paenibacillus larvae strains from Austria was studied. Genotyping of isolates was performed by polymerase chain reaction (PCR) with primers corresponding to enterobacterial repetitive intergenic consensus (ERIC), BOX repetitive and extragenic palindromic (REP) elements (collectively known as rep-PCR) using ERIC primers, BOX A1R and MBO REP1 primers. Using ERIC-PCR technique two genotypes could be differentiated (ERIC I and II), whereas using combined typing by BOX- and REP-PCR, five different genotypes were detected (ab, aB, Ab, AB and alphab). Genotypes aB and alphab are new and have not been reported in other studies using the same techniques.

Published

2009

7. Phylogenetic analysis of deformed wing virus genotypes from diverse geographic origins indicates recent global distribution of the virus.

Author

Berényi O, Bakonyi T, Derakhshifar I, Köglberger H, Topolska G, Ritter W, Pechhacker H, and Nowotny N

Subjects

Animals, Conserved Sequence genetics, Evolution, Molecular, Genome, Viral genetics, Genotype, Molecular Sequence Data, Point Mutation genetics, RNA Helicases genetics, RNA Viruses classification, RNA Viruses isolation & purification, Reverse Transcriptase Polymerase Chain Reaction, Sequence Analysis, DNA, Sequence Homology, Viral Nonstructural Proteins genetics, Viral Structural Proteins genetics, Bees virology, Phylogeny, RNA Viruses genetics, RNA, Viral genetics

Abstract

Honeybees originating from 10 different countries (Austria, Poland, Germany, Hungary, Slovenia, Nepal, Sri Lanka, the United Arab Emirates, Canada, and New Zealand) located on four continents were analyzed for the presence of deformed wing virus (DWV) nucleic acid by reverse transcription-PCR. Two target regions within the DWV genome were selected for PCR amplification and subsequent sequencing, i.e., a region within the putative VP2 and VP4 structural-protein genes and a region within the RNA helicase enzyme gene. DWV nucleic acid was amplified from 34 honeybee samples representing all the above-mentioned countries with the notable exception of New Zealand. The amplification products were sequenced, and phylogenetic analyses of both genomic regions were performed independently. The phylogenetic analyses included all sequences determined in this study as well as previously published DWV sequences and the sequences of two closely related viruses, Kakugo virus (KGV) and Varroa destructor virus 1 (VDV-1). In the sequenced regions, the DWV genome turned out to be highly conserved, independent of the geographic origins of the honeybee samples: the partial sequences exhibited 98 to 99% nucleotide sequence identity. Substitutions were most frequently observed at the same positions in the various DWV sequences. Due to the high level of sequence conservation, no significant clustering of the samples in the phylogenetic trees could be identified. On the other hand, the phylogenetic analyses support a genetic segregation of KGV and VDV-1 from DWV.

Published

2007

8. Occurrence of six honeybee viruses in diseased Austrian apiaries.

Author

Berényi O, Bakonyi T, Derakhshifar I, Köglberger H, and Nowotny N

Subjects

Animals, Austria epidemiology, Insect Viruses classification, Insect Viruses genetics, Insect Viruses isolation & purification, Prevalence, RNA Viruses classification, RNA Viruses genetics, RNA, Viral analysis, RNA, Viral isolation & purification, Reverse Transcriptase Polymerase Chain Reaction, Animal Husbandry, Bees virology, RNA Viruses isolation & purification

Abstract

The occurrence, prevalence, and distribution patterns of acute bee paralysis virus (ABPV), black queen cell virus (BQCV), chronic bee paralysis virus (CBPV), deformed wing virus (DWV), Kashmir bee virus (KBV), and sacbrood virus (SBV) were investigated in 90 Austrian honeybee colonies suffering from symptoms of depopulation, sudden collapse, paralysis, or dark coloring by employing reverse transcription-PCR. Infestation with parasites was also recorded. The samples originated from all parts of Austria. The most prevalent virus was DWV, present in 91% of samples, followed by ABPV, SBV, and BQCV (68%, 49%, and 30%, respectively). CBPV was detected in 10% of colonies, while KBV was not present in any sample. In most samples, more than one virus was identified. The distribution pattern of ABPV, BQCV, CBPV, and SBV varied considerably in the different geographic regions investigated, while DWV was widespread in all Austrian federal states. In bees that showed dark coloring and disorientation, CBPV was always detected. Simultaneous infections of DWV and ABPV were most frequently observed in colonies suffering from weakness, depopulation, and sudden collapse. Bees obtained from apparently healthy colonies within the same apiaries showed a similar distribution pattern of viruses; however, the relative virus load was 10 to 126 times lower than in bees from diseased colonies. A limited number of bee samples from surrounding central European countries (Germany, Poland, Hungary, and Slovenia) were also tested for the presence of the above viruses. Variances were found in the distribution of BQCV and SBV.

Published

2006

9. Development and evaluation of PCR assays for the detection of Paenibacillus larvae in honey samples: comparison with isolation and biochemical characterization.

Author

Bakonyi T, Derakhshifar I, Grabensteiner E, and Nowotny N

Subjects

Animals, Bacillus classification, Bacillus genetics, Bees growth & development, Culture Media, DNA Primers, DNA, Bacterial analysis, DNA, Bacterial genetics, DNA, Bacterial isolation & purification, Sensitivity and Specificity, Sequence Analysis, DNA, Bacillus isolation & purification, Bees microbiology, Honey microbiology, Polymerase Chain Reaction methods

Abstract

PCR assays were developed for the direct detection of Paenibacillus larvae in honey samples and compared with isolation and biochemical characterization procedures. Different primer pairs, designed from the 16S rRNA and the metalloproteinase precursor gene regions, and different DNA extraction methods were tested and compared. The sensitivity of the reactions was evaluated by serial dilutions of DNA extracts obtained from P. larvae cultures. The specificity of the primers was assessed by analyzing related Paenibacillus and Bacillus strains isolated from honey. The PCR assays also amplified these related bacteria, but at lower sensitivity. In the next step, the PCR assays were applied to contaminated honey and other bee products originating from 15 countries. Lysozyme treatment followed by proteinase K digestion was determined to be the best DNA extraction method for P. larvae spores. The most sensitive primer pair detected P. larvae in 18 of 23 contaminated honey samples, as well as in pollen, wax, and brood. Honey specimens containing saprophyte bacilli and paenibacilli, but not P. larvae, were PCR negative. Although the isolation and biochemical identification method (BioLog) showed higher sensitivity and specificity, PCR proved to be a valuable technique for large-scale screening of honey samples for American foulbrood, especially considering its rapidity and moderate costs.

Published

2003

10. Sacbrood virus of the honeybee (Apis mellifera): rapid identification and phylogenetic analysis using reverse transcription-PCR.

Author

Grabensteiner E, Ritter W, Carter MJ, Davison S, Pechhacker H, Kolodziejek J, Boecking O, Derakhshifar I, Moosbeckhofer R, Licek E, and Nowotny N

Subjects

Amino Acid Sequence, Animals, Base Sequence, DNA, Viral, Molecular Sequence Data, Phylogeny, Picornaviridae genetics, Reverse Transcriptase Polymerase Chain Reaction, Sequence Analysis, DNA methods, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, Time Factors, Bees virology, Picornaviridae classification

Abstract

Sacbrood virus (SBV) infects larvae of the honeybee (Apis mellifera), resulting in failure to pupate and death. Until now, identification of viruses in honeybee infections has been based on traditional methods such as electron microscopy, immunodiffusion, and enzyme-linked immunosorbent assay. Culture cannot be used because no honeybee cell lines are available. These techniques are low in sensitivity and specificity. However, the complete nucleotide sequence of SBV has recently been determined, and with these data, we now report a reverse transcription-PCR (RT-PCR) test for the direct, rapid, and sensitive detection of these viruses. RT-PCR was used to target five different areas of the SBV genome using infected honeybees and larvae originating from geographically distinct regions. The RT-PCR assay proved to be a rapid, specific, and sensitive diagnostic tool for the direct detection of SBV nucleic acid in samples of infected honeybees and brood regardless of geographic origin. The amplification products were sequenced, and phylogenetic analysis suggested the existence of at least three distinct genotypes of SBV.

Published

2001