Your search keyword '"Nederbragt A"' showing total 14 results

1. A genome-wide analysis of nonribosomal peptide synthetase gene clusters and their peptides in a Planktothrix rubescens strain

Author

Nederbragt Alexander J, Rohrlack Thomas, Rounge Trine B, Kristensen Tom, and Jakobsen Kjetill S

Subjects

Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Cyanobacteria often produce several different oligopeptides, with unknown biological functions, by nonribosomal peptide synthetases (NRPS). Although some cyanobacterial NRPS gene cluster types are well described, the entire NRPS genomic content within a single cyanobacterial strain has never been investigated. Here we have combined a genome-wide analysis using massive parallel pyrosequencing ("454") and mass spectrometry screening of oligopeptides produced in the strain Planktothrix rubescens NIVA CYA 98 in order to identify all putative gene clusters for oligopeptides. Results Thirteen types of oligopeptides were uncovered by mass spectrometry (MS) analyses. Microcystin, cyanopeptolin and aeruginosin synthetases, highly similar to already characterized NRPS, were present in the genome. Two novel NRPS gene clusters were associated with production of anabaenopeptins and microginins, respectively. Sequence-depth of the genome and real-time PCR data revealed three copies of the microginin gene cluster. Since NRPS gene cluster candidates for microviridin and oscillatorin synthesis could not be found, putative (gene encoded) precursor peptide sequences to microviridin and oscillatorin were found in the genes mdnA and oscA, respectively. The genes flanking the microviridin and oscillatorin precursor genes encode putative modifying enzymes of the precursor oligopeptides. We therefore propose ribosomal pathways involving modifications and cyclisation for microviridin and oscillatorin. The microviridin, anabaenopeptin and cyanopeptolin gene clusters are situated in close proximity to each other, constituting an oligopeptide island. Conclusion Altogether seven nonribosomal peptide synthetase (NRPS) gene clusters and two gene clusters putatively encoding ribosomal oligopeptide biosynthetic pathways were revealed. Our results demonstrate that whole genome shotgun sequencing combined with MS-directed determination of oligopeptides successfully can identify NRPS gene clusters and the corresponding oligopeptides. The analyses suggest independent evolution of all NRPS gene clusters as functional units. Our data indicate that the Planktothrix genome displays evolution of dual pathways (NRPS and ribosomal) for production of oligopeptides in order to maximize the diversity of oligopeptides with similar but functional discrete bioactivities.

Published

2009

2. Assessing graph-based read mappers against a baseline approach highlights strengths and weaknesses of current methods

Author

Grytten, Ivar, Rand, Knut D., Nederbragt, Alexander J., and Sandve, Geir K.

Published

2020

3. Genomic architecture of haddock (Melanogrammus aeglefinus) shows expansions of innate immune genes and short tandem repeats

Author

Tørresen, Ole K., Brieuc, Marine S. O., Solbakken, Monica H., Sørhus, Elin, Nederbragt, Alexander J., Jakobsen, Kjetill S., Meier, Sonnich, Edvardsen, Rolf B., and Jentoft, Sissel

Published

2018

4. Loss of stomach, loss of appetite? Sequencing of the ballan wrasse (Labrus bergylta) genome and intestinal transcriptomic profiling illuminate the evolution of loss of stomach function in fish

Author

Lie, Kai K., Tørresen, Ole K., Solbakken, Monica Hongrø, Rønnestad, Ivar, Tooming-Klunderud, Ave, Nederbragt, Alexander J., Jentoft, Sissel, and Sæle, Øystein

Published

2018

5. Assessing graph-based read mappers against a baseline approach highlights strengths and weaknesses of current methods

Author

Geir Kjetil Sandve, Ivar Grytten, Alexander J. Nederbragt, and Knut Dagestad Rand

Subjects

Current generation, Theoretical computer science, Pan-genomics, lcsh:QH426-470, lcsh:Biotechnology, Graph-based references, Biology, computer.software_genre, 03 medical and health sciences, 0302 clinical medicine, Sequence alignment, lcsh:TP248.13-248.65, Genetics, Humans, 030304 developmental biology, 0303 health sciences, Genome, Human, Methodology Article, Graph based, Computational Biology, High-Throughput Nucleotide Sequencing, Graph genomes, lcsh:Genetics, Reference genomes, Scripting language, Graph (abstract data type), Read mapping, computer, 030217 neurology & neurosurgery, Combinatorial explosion, Strengths and weaknesses, Biotechnology

Abstract

Background Graph-based reference genomes have become popular as they allow read mapping and follow-up analyses in settings where the exact haplotypes underlying a high-throughput sequencing experiment are not precisely known. Two recent papers show that mapping to graph-based reference genomes can improve accuracy as compared to methods using linear references. Both of these methods index the sequences for most paths up to a certain length in the graph in order to enable direct mapping of reads containing common variants. However, the combinatorial explosion of possible paths through nearby variants also leads to a huge search space and an increased chance of false positive alignments to highly variable regions. Results We here assess three prominent graph-based read mappers against a hybrid baseline approach that combines an initial path determination with a tuned linear read mapping method. We show, using a previously proposed benchmark, that this simple approach is able to improve overall accuracy of read-mapping to graph-based reference genomes. Conclusions Our method is implemented in a tool Two-step Graph Mapper, which is available at https://github.com/uio-bmi/two_step_graph_mapperalong with data and scripts for reproducing the experiments. Our method highlights characteristics of the current generation of graph-based read mappers and shows potential for improvement for future graph-based read mappers.

Published

2020

6. Genomic architecture of haddock (Melanogrammus aeglefinus) shows expansions of innate immune genes and short tandem repeats

Author

Elin Sørhus, Alexander J. Nederbragt, Monica Hongrø Solbakken, Sissel Jentoft, Marine S. O. Brieuc, Ole K. Tørresen, Kjetill S. Jakobsen, Rolf B. Edvardsen, and Sonnich Meier

Subjects

Fish Proteins, 0301 basic medicine, lcsh:QH426-470, lcsh:Biotechnology, NLR Proteins, Genomics, Genome, 03 medical and health sciences, Tandem repeat, NOD-like receptors, lcsh:TP248.13-248.65, Genetics, Animals, Gene family, Gadus, Microsatellites, Population Density, Genome assembly, biology, Gadiformes, Histocompatibility Antigens Class I, Toll-Like Receptors, Genetic Variation, Haddock, biology.organism_classification, Immunity, Innate, lcsh:Genetics, STRs, 030104 developmental biology, Evolutionary biology, Atlantic cod, Research Article, Microsatellite Repeats, Biotechnology

Abstract

Background Increased availability of genome assemblies for non-model organisms has resulted in invaluable biological and genomic insight into numerous vertebrates, including teleosts. Sequencing of the Atlantic cod (Gadus morhua) genome and the genomes of many of its relatives (Gadiformes) demonstrated a shared loss of the major histocompatibility complex (MHC) II genes 100 million years ago. An improved version of the Atlantic cod genome assembly shows an extreme density of tandem repeats compared to other vertebrate genome assemblies. Highly contiguous assemblies are therefore needed to further investigate the unusual immune system of the Gadiformes, and whether the high density of tandem repeats found in Atlantic cod is a shared trait in this group. Results Here, we have sequenced and assembled the genome of haddock (Melanogrammus aeglefinus) – a relative of Atlantic cod – using a combination of PacBio and Illumina reads. Comparative analyses reveal that the haddock genome contains an even higher density of tandem repeats outside and within protein coding sequences than Atlantic cod. Further, both species show an elevated number of tandem repeats in genes mainly involved in signal transduction compared to other teleosts. A characterization of the immune gene repertoire demonstrates a substantial expansion of MCHI in Atlantic cod compared to haddock. In contrast, the Toll-like receptors show a similar pattern of gene losses and expansions. For the NOD-like receptors (NLRs), another gene family associated with the innate immune system, we find a large expansion common to all teleosts, with possible lineage-specific expansions in zebrafish, stickleback and the codfishes. Conclusions The generation of a highly contiguous genome assembly of haddock revealed that the high density of short tandem repeats as well as expanded immune gene families is not unique to Atlantic cod – but possibly a feature common to all, or most, codfishes. A shared expansion of NLR genes in teleosts suggests that the NLRs have a more substantial role in the innate immunity of teleosts than other vertebrates. Moreover, we find that high copy number genes combined with variable genome assembly qualities may impede complete characterization of these genes, i.e. the number of NLRs in different teleost species might be underestimates. Electronic supplementary material The online version of this article (10.1186/s12864-018-4616-y) contains supplementary material, which is available to authorized users.

Published

2018

7. An improved genome assembly uncovers prolific tandem repeats in Atlantic cod

Author

Tørresen, Ole K., primary, Star, Bastiaan, additional, Jentoft, Sissel, additional, Reinar, William B., additional, Grove, Harald, additional, Miller, Jason R., additional, Walenz, Brian P., additional, Knight, James, additional, Ekholm, Jenny M., additional, Peluso, Paul, additional, Edvardsen, Rolf B., additional, Tooming-Klunderud, Ave, additional, Skage, Morten, additional, Lien, Sigbjørn, additional, Jakobsen, Kjetill S., additional, and Nederbragt, Alexander J., additional

Published

2017

8. Genomic architecture of haddock (<italic>Melanogrammus aeglefinus)</italic> shows expansions of innate immune genes and short tandem repeats.

Author

Tørresen, Ole K., Brieuc, Marine S. O., Solbakken, Monica H., Sørhus, Elin, Nederbragt, Alexander J., Jakobsen, Kjetill S., Meier, Sonnich, Edvardsen, Rolf B., and Jentoft, Sissel

Subjects

HADDOCK, FISH genomes, NATURAL immunity, TANDEM repeats, TOLL-like receptors, MICROSATELLITE repeats

Abstract

Background: Increased availability of genome assemblies for non-model organisms has resulted in invaluable biological and genomic insight into numerous vertebrates, including teleosts. Sequencing of the Atlantic cod (Gadus morhua) genome and the genomes of many of its relatives (Gadiformes) demonstrated a shared loss of the major histocompatibility complex (MHC) II genes 100 million years ago. An improved version of the Atlantic cod genome assembly shows an extreme density of tandem repeats compared to other vertebrate genome assemblies. Highly contiguous assemblies are therefore needed to further investigate the unusual immune system of the Gadiformes, and whether the high density of tandem repeats found in Atlantic cod is a shared trait in this group. Results: Here, we have sequenced and assembled the genome of haddock (Melanogrammus aeglefinus) – a relative of Atlantic cod – using a combination of PacBio and Illumina reads. Comparative analyses reveal that the haddock genome contains an even higher density of tandem repeats outside and within protein coding sequences than Atlantic cod. Further, both species show an elevated number of tandem repeats in genes mainly involved in signal transduction compared to other teleosts. A characterization of the immune gene repertoire demonstrates a substantial expansion of MCHI in Atlantic cod compared to haddock. In contrast, the Toll-like receptors show a similar pattern of gene losses and expansions. For the NOD-like receptors (NLRs), another gene family associated with the innate immune system, we find a large expansion common to all teleosts, with possible lineage-specific expansions in zebrafish, stickleback and the codfishes. Conclusions: The generation of a highly contiguous genome assembly of haddock revealed that the high density of short tandem repeats as well as expanded immune gene families is not unique to Atlantic cod – but possibly a feature common to all, or most, codfishes. A shared expansion of NLR genes in teleosts suggests that the NLRs have a more substantial role in the innate immunity of teleosts than other vertebrates. Moreover, we find that high copy number genes combined with variable genome assembly qualities may impede complete characterization of these genes, i.e. the number of NLRs in different teleost species might be underestimates. [ABSTRACT FROM AUTHOR]

Published

2018

9. A genome-wide analysis of nonribosomal peptide synthetase gene clusters and their peptides in a Planktothrix rubescens strain

Author

Trine B. Rounge, Kjetill S. Jakobsen, Thomas Rohrlack, Alexander J. Nederbragt, and Tom Kristensen

Subjects

DNA, Bacterial, Cyanobacteria, lcsh:QH426-470, lcsh:Biotechnology, Biology, Proteomics, Evolution, Molecular, Nonribosomal peptide, Putative gene, lcsh:TP248.13-248.65, Gene cluster, Genetics, Peptide Synthases, Gene, Phylogeny, chemistry.chemical_classification, Oligopeptide, Computational Biology, Sequence Analysis, DNA, biology.organism_classification, lcsh:Genetics, chemistry, Genes, Bacterial, Multigene Family, DNA microarray, Oligopeptides, Genome, Bacterial, Genome-Wide Association Study, Research Article, Biotechnology

Abstract

Background Cyanobacteria often produce several different oligopeptides, with unknown biological functions, by nonribosomal peptide synthetases (NRPS). Although some cyanobacterial NRPS gene cluster types are well described, the entire NRPS genomic content within a single cyanobacterial strain has never been investigated. Here we have combined a genome-wide analysis using massive parallel pyrosequencing ("454") and mass spectrometry screening of oligopeptides produced in the strain Planktothrix rubescens NIVA CYA 98 in order to identify all putative gene clusters for oligopeptides. Results Thirteen types of oligopeptides were uncovered by mass spectrometry (MS) analyses. Microcystin, cyanopeptolin and aeruginosin synthetases, highly similar to already characterized NRPS, were present in the genome. Two novel NRPS gene clusters were associated with production of anabaenopeptins and microginins, respectively. Sequence-depth of the genome and real-time PCR data revealed three copies of the microginin gene cluster. Since NRPS gene cluster candidates for microviridin and oscillatorin synthesis could not be found, putative (gene encoded) precursor peptide sequences to microviridin and oscillatorin were found in the genes mdn A and osc A, respectively. The genes flanking the microviridin and oscillatorin precursor genes encode putative modifying enzymes of the precursor oligopeptides. We therefore propose ribosomal pathways involving modifications and cyclisation for microviridin and oscillatorin. The microviridin, anabaenopeptin and cyanopeptolin gene clusters are situated in close proximity to each other, constituting an oligopeptide island. Conclusion Altogether seven nonribosomal peptide synthetase (NRPS) gene clusters and two gene clusters putatively encoding ribosomal oligopeptide biosynthetic pathways were revealed. Our results demonstrate that whole genome shotgun sequencing combined with MS-directed determination of oligopeptides successfully can identify NRPS gene clusters and the corresponding oligopeptides. The analyses suggest independent evolution of all NRPS gene clusters as functional units. Our data indicate that the Planktothrix genome displays evolution of dual pathways (NRPS and ribosomal) for production of oligopeptides in order to maximize the diversity of oligopeptides with similar but functional discrete bioactivities.

Published

2009

10. A genome-wide analysis of nonribosomal peptide synthetase gene clusters and their peptides in a Planktothrix rubescens strain

Author

Rounge, Trine B, primary, Rohrlack, Thomas, additional, Nederbragt, Alexander J, additional, Kristensen, Tom, additional, and Jakobsen, Kjetill S, additional

Published

2009

11. Loss of stomach, loss of appetite? Sequencing of the ballan wrasse (<italic>Labrus bergylta</italic>) genome and intestinal transcriptomic profiling illuminate the evolution of loss of stomach function in fish.

Author

Lie, Kai K., Tørresen, Ole K., Solbakken, Monica Hongrø, Rønnestad, Ivar, Tooming-Klunderud, Ave, Nederbragt, Alexander J., Jentoft, Sissel, and Sæle, Øystein

Subjects

APPETITE loss, BALLAN wrasse, FISH physiology, INTERSEXUALITY, FISH phylogeny, FISHES

Abstract

Background: The ballan wrasse (Labrus bergylta) belongs to a large teleost family containing more than 600 species showing several unique evolutionary traits such as lack of stomach and hermaphroditism. Agastric fish are found throughout the teleost phylogeny, in quite diverse and unrelated lineages, indicating stomach loss has occurred independently multiple times in the course of evolution. By assembling the ballan wrasse genome and transcriptome we aimed to determine the genetic basis for its digestive system function and appetite regulation. Among other, this knowledge will aid the formulation of aquaculture diets that meet the nutritional needs of agastric species. Results: Long and short read sequencing technologies were combined to generate a ballan wrasse genome of 805 Mbp. Analysis of the genome and transcriptome assemblies confirmed the absence of genes that code for proteins involved in gastric function. The gene coding for the appetite stimulating protein ghrelin was also absent in wrasse. Gene synteny mapping identified several appetite-controlling genes and their paralogs previously undescribed in fish. Transcriptome profiling along the length of the intestine found a declining expression gradient from the anterior to the posterior, and a distinct expression profile in the hind gut. Conclusions: We showed gene loss has occurred for all known genes related to stomach function in the ballan wrasse, while the remaining functions of the digestive tract appear intact. The results also show appetite control in ballan wrasse has undergone substantial changes. The loss of ghrelin suggests that other genes, such as motilin, may play a ghrelin like role. The wrasse genome offers novel insight in to the evolutionary traits of this large family. As the stomach plays a major role in protein digestion, the lack of genes related to stomach digestion in wrasse suggests it requires formulated diets with higher levels of readily digestible protein than those for gastric species. [ABSTRACT FROM AUTHOR]

Published

2018

12. Assessing graph-based read mappers against a baseline approach highlights strengths and weaknesses of current methods

Author

Ivar Grytten, Knut D. Rand, Alexander J. Nederbragt, and Geir K. Sandve

Subjects

Graph genomes, Read mapping, Pan-genomics, Reference genomes, Graph-based references, Sequence alignment, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Graph-based reference genomes have become popular as they allow read mapping and follow-up analyses in settings where the exact haplotypes underlying a high-throughput sequencing experiment are not precisely known. Two recent papers show that mapping to graph-based reference genomes can improve accuracy as compared to methods using linear references. Both of these methods index the sequences for most paths up to a certain length in the graph in order to enable direct mapping of reads containing common variants. However, the combinatorial explosion of possible paths through nearby variants also leads to a huge search space and an increased chance of false positive alignments to highly variable regions. Results We here assess three prominent graph-based read mappers against a hybrid baseline approach that combines an initial path determination with a tuned linear read mapping method. We show, using a previously proposed benchmark, that this simple approach is able to improve overall accuracy of read-mapping to graph-based reference genomes. Conclusions Our method is implemented in a tool Two-step Graph Mapper, which is available at https://github.com/uio-bmi/two_step_graph_mapperalong with data and scripts for reproducing the experiments. Our method highlights characteristics of the current generation of graph-based read mappers and shows potential for improvement for future graph-based read mappers.

Published

2020

13. Genomic architecture of haddock (Melanogrammus aeglefinus) shows expansions of innate immune genes and short tandem repeats

Author

Ole K. Tørresen, Marine S. O. Brieuc, Monica H. Solbakken, Elin Sørhus, Alexander J. Nederbragt, Kjetill S. Jakobsen, Sonnich Meier, Rolf B. Edvardsen, and Sissel Jentoft

Subjects

Haddock, Atlantic cod, STRs, Microsatellites, Genome assembly, NOD-like receptors, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Increased availability of genome assemblies for non-model organisms has resulted in invaluable biological and genomic insight into numerous vertebrates, including teleosts. Sequencing of the Atlantic cod (Gadus morhua) genome and the genomes of many of its relatives (Gadiformes) demonstrated a shared loss of the major histocompatibility complex (MHC) II genes 100 million years ago. An improved version of the Atlantic cod genome assembly shows an extreme density of tandem repeats compared to other vertebrate genome assemblies. Highly contiguous assemblies are therefore needed to further investigate the unusual immune system of the Gadiformes, and whether the high density of tandem repeats found in Atlantic cod is a shared trait in this group. Results Here, we have sequenced and assembled the genome of haddock (Melanogrammus aeglefinus) – a relative of Atlantic cod – using a combination of PacBio and Illumina reads. Comparative analyses reveal that the haddock genome contains an even higher density of tandem repeats outside and within protein coding sequences than Atlantic cod. Further, both species show an elevated number of tandem repeats in genes mainly involved in signal transduction compared to other teleosts. A characterization of the immune gene repertoire demonstrates a substantial expansion of MCHI in Atlantic cod compared to haddock. In contrast, the Toll-like receptors show a similar pattern of gene losses and expansions. For the NOD-like receptors (NLRs), another gene family associated with the innate immune system, we find a large expansion common to all teleosts, with possible lineage-specific expansions in zebrafish, stickleback and the codfishes. Conclusions The generation of a highly contiguous genome assembly of haddock revealed that the high density of short tandem repeats as well as expanded immune gene families is not unique to Atlantic cod – but possibly a feature common to all, or most, codfishes. A shared expansion of NLR genes in teleosts suggests that the NLRs have a more substantial role in the innate immunity of teleosts than other vertebrates. Moreover, we find that high copy number genes combined with variable genome assembly qualities may impede complete characterization of these genes, i.e. the number of NLRs in different teleost species might be underestimates.

Published

2018

14. Loss of stomach, loss of appetite? Sequencing of the ballan wrasse (Labrus bergylta) genome and intestinal transcriptomic profiling illuminate the evolution of loss of stomach function in fish

Author

Kai K. Lie, Ole K. Tørresen, Monica Hongrø Solbakken, Ivar Rønnestad, Ave Tooming-Klunderud, Alexander J. Nederbragt, Sissel Jentoft, and Øystein Sæle

Subjects

Ballan wrasse, Stomach, Intestine, Ghrelin, Labrid, Digestion, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background The ballan wrasse (Labrus bergylta) belongs to a large teleost family containing more than 600 species showing several unique evolutionary traits such as lack of stomach and hermaphroditism. Agastric fish are found throughout the teleost phylogeny, in quite diverse and unrelated lineages, indicating stomach loss has occurred independently multiple times in the course of evolution. By assembling the ballan wrasse genome and transcriptome we aimed to determine the genetic basis for its digestive system function and appetite regulation. Among other, this knowledge will aid the formulation of aquaculture diets that meet the nutritional needs of agastric species. Results Long and short read sequencing technologies were combined to generate a ballan wrasse genome of 805 Mbp. Analysis of the genome and transcriptome assemblies confirmed the absence of genes that code for proteins involved in gastric function. The gene coding for the appetite stimulating protein ghrelin was also absent in wrasse. Gene synteny mapping identified several appetite-controlling genes and their paralogs previously undescribed in fish. Transcriptome profiling along the length of the intestine found a declining expression gradient from the anterior to the posterior, and a distinct expression profile in the hind gut. Conclusions We showed gene loss has occurred for all known genes related to stomach function in the ballan wrasse, while the remaining functions of the digestive tract appear intact. The results also show appetite control in ballan wrasse has undergone substantial changes. The loss of ghrelin suggests that other genes, such as motilin, may play a ghrelin like role. The wrasse genome offers novel insight in to the evolutionary traits of this large family. As the stomach plays a major role in protein digestion, the lack of genes related to stomach digestion in wrasse suggests it requires formulated diets with higher levels of readily digestible protein than those for gastric species.

Published

2018