Your search keyword '"Reichwald, K"' showing total 10 results

1. The age related markers lipofuscin and apoptosis show different genetic architecture by QTL mapping in short-lived Nothobranchius fish.

Author

Ng'oma E, Reichwald K, Dorn A, Wittig M, Balschun T, Franke A, Platzer M, and Cellerino A

Subjects

Animals, Biomarkers analysis, In Situ Nick-End Labeling, Lipofuscin metabolism, Longevity genetics, Quantitative Trait Loci, Aging genetics, Apoptosis genetics, Cyprinodontiformes genetics, Lipofuscin analysis

Abstract

Annual fish of the genus Nothobranchius show large variations in lifespan and expression of age-related phenotypes between closely related populations. We studied N. kadleci and its sister species N. furzeri GRZ strain, and found that N.kadleci is longer-lived than the N. furzeri. Lipofuscin and apoptosis measured in the liver increased with age in N. kadleci with different profiles: lipofuscin increased linearly, while apoptosis declined in the oldest animals. More lipofuscin (P<0.001) and apoptosis (P<0.001) was observed in N. furzeri than in N. kadleci at 16w age. Lipofuscin and apoptotic cells were then quantified in hybrids from the mating of N. furzeri to N. kadleci. F₁individuals showed heterosis for lipofuscin but additive effects for apoptosis. These two age-related phenotypes were not correlated in F₂ hybrids. Quantitative trait loci analysis of 287 F₂ fish using 237 markers identified two QTL accounting for 10% of lipofuscin variance (P<0.001) with overdominance effect. Apoptotic cells revealed three significant- and two suggestive QTL explaining 19% of variance (P<0.001), showing additive and dominance effects, and two interacting loci. Our results show that lipofuscin and apoptosis are markers of different age-dependent biological processes controlled by different genetic mechanisms.

Published

2014

2. Parallel evolution of senescence in annual fishes in response to extrinsic mortality.

Author

Tozzini ET, Dorn A, Ng'oma E, Polačik M, Blažek R, Reichwald K, Petzold A, Watters B, Reichard M, and Cellerino A

Subjects

Animals, Climate, Ecosystem, Lipofuscin analysis, Smegmamorpha physiology, Aging, Longevity, Smegmamorpha classification, Smegmamorpha genetics

Abstract

Background: Early evolutionary theories of aging predict that populations which experience low extrinsic mortality evolve a retarded onset of senescence. Experimental support for this theory in vertebrates is scarce, in part for the difficulty of quantifying extrinsic mortality and its condition- and density-dependent components that -when considered- can lead to predictions markedly different to those of the "classical" theories. Here, we study annual fish of the genus Nothobranchius whose maximum lifespan is dictated by the duration of the water bodies they inhabit. Different populations of annual fish do not experience different strengths of extrinsic mortality throughout their life span, but are subject to differential timing (and predictability) of a sudden habitat cessation. In this respect, our study allows testing how aging evolves in natural environments when populations vary in the prospect of survival, but condition-dependent survival has a limited effect. We use 10 Nothobranchius populations from seasonal pools that differ in their duration to test how this parameter affects longevity and aging in two independent clades of these annual fishes., Results: We found that replicated populations from a dry region showed markedly shorter captive lifespan than populations from a humid region. Shorter lifespan correlated with accelerated accumulation of lipofuscin (an established age marker) in both clades. Analysis of wild individuals confirmed that fish from drier habitats accumulate lipofuscin faster also under natural conditions. This indicates faster physiological deterioration in shorter-lived populations., Conclusions: Our data provide a strong quantitative example of how extrinsic mortality can shape evolution of senescence in a vertebrate clade. Nothobranchius is emerging as a genomic model species. The characterization of pairs of closely related species with different longevities should provide a powerful paradigm for the identification of genetic variations responsible for evolution of senescence in natural populations.

Published

2013

3. The transcript catalogue of the short-lived fish Nothobranchius furzeri provides insights into age-dependent changes of mRNA levels.

Author

Petzold A, Reichwald K, Groth M, Taudien S, Hartmann N, Priebe S, Shagin D, Englert C, and Platzer M

Subjects

Animals, Cyprinodontiformes physiology, Gene Expression Profiling, Gene Expression Regulation, Developmental, Gene Library, High-Throughput Nucleotide Sequencing, Molecular Sequence Annotation, RNA, Messenger physiology, Zebrafish genetics, Zebrafish growth & development, Aging genetics, Cyprinodontiformes genetics, RNA, Messenger genetics

Abstract

Background: The African annual fish Nothobranchius furzeri has over recent years been established as a model species for ageing-related studies. This is mainly based on its exceptionally short lifespan and the presence of typical characteristics of vertebrate ageing. To substantiate its role as an alternative vertebrate ageing model, a transcript catalogue is needed, which can serve e.g. as basis for identifying ageing-related genes., Results: To build the N. furzeri transcript catalogue, thirteen cDNA libraries were sequenced using Sanger, 454/Roche and Solexa/Illumina technologies yielding about 39 Gb. In total, 19,875 protein-coding genes were identified and annotated. Of these, 71% are represented by at least one transcript contig with a complete coding sequence. Further, transcript levels of young and old fish of the strains GRZ and MZM-0403, which differ in lifespan by twofold, were studied by RNA-seq. In skin and brain, 85 differentially expressed genes were detected; these have a role in cell cycle control and proliferation, inflammation and tissue maintenance. An RNA-seq experiment for zebrafish skin confirmed the ageing-related relevance of the findings in N. furzeri. Notably, analyses of transcript levels between zebrafish and N. furzeri but also between N. furzeri strains differed largely, suggesting that ageing is accelerated in the short-lived N. furzeri strain GRZ compared to the longer-lived strain MZM-0403., Conclusions: We provide a comprehensive, annotated N. furzeri transcript catalogue and a first transcriptome-wide insight into N. furzeri ageing. This data will serve as a basis for future functional studies of ageing-related genes.

Published

2013

4. Mapping of quantitative trait loci controlling lifespan in the short-lived fish Nothobranchius furzeri--a new vertebrate model for age research.

Author

Kirschner J, Weber D, Neuschl C, Franke A, Böttger M, Zielke L, Powalsky E, Groth M, Shagin D, Petzold A, Hartmann N, Englert C, Brockmann GA, Platzer M, Cellerino A, and Reichwald K

Subjects

Alleles, Animals, Chromosomes genetics, Female, Genome-Wide Association Study, Male, Models, Biological, Aging, Fishes genetics, Quantitative Trait Loci

Abstract

The African annual fish Nothobranchius furzeri emerged as a new model for age research over recent years. Nothobranchius furzeri show an exceptionally short lifespan, age-dependent cognitive/behavioral decline, expression of age-related biomarkers, and susceptibility to lifespan manipulation. In addition, laboratory strains differ largely in lifespan. Here, we set out to study the genetics of lifespan determination. We crossed a short- to a long-lived strain, recorded lifespan, and established polymorphic markers. On the basis of genotypes of 411 marker loci in 404 F(2) progeny, we built a genetic map comprising 355 markers at an average spacing of 5.5 cM, 22 linkage groups (LGs) and 1965 cM. By combining marker data with lifespan values, we identified one genome-wide highly significant quantitative trait locus (QTL) on LG 9 (P < 0.01), which explained 11.3% of the F(2) lifespan variance, and three suggestive QTLs on LG 11, 14, and 17. We characterized the highly significant QTL by synteny analysis, because a genome sequence of N. furzeri was not available. We located the syntenic region on medaka chromosome 5, identified candidate genes, and performed fine mapping, resulting in a c. 40% reduction of the initial 95% confidence interval. We show both that lifespan determination in N. furzeri is polygenic, and that candidate gene detection is easily feasible by cross-species analysis. Our work provides first results on the way to identify loci controlling lifespan in N. furzeri and illustrates the potential of this vertebrate species as a genetic model for age research., (© 2011 The Authors. Aging Cell © 2011 Blackwell Publishing Ltd/Anatomical Society of Great Britain and Ireland.)

Published

2012

5. Allele-specific, age-dependent and BMI-associated DNA methylation of human MCHR1.

Author

Stepanow S, Reichwald K, Huse K, Gausmann U, Nebel A, Rosenstiel P, Wabitsch M, Fischer-Posovszky P, and Platzer M

Subjects

Adult, Aged, Aging drug effects, Azacitidine pharmacology, Cell Line, CpG Islands genetics, DNA Methylation drug effects, Gene Expression Regulation drug effects, Genome, Human genetics, Humans, Male, Middle Aged, RNA, Messenger genetics, RNA, Messenger metabolism, Receptors, Somatostatin metabolism, Young Adult, Aging genetics, Alleles, Body Mass Index, DNA Methylation genetics, Receptors, Somatostatin genetics

Abstract

Background: Melanin-concentrating hormone receptor 1 (MCHR1) plays a significant role in regulation of energy balance, food intake, physical activity and body weight in humans and rodents. Several association studies for human obesity showed contrary results concerning the SNPs rs133072 (G/A) and rs133073 (T/C), which localize to the first exon of MCHR1. The variations constitute two main haplotypes (GT, AC). Both SNPs affect CpG dinucleotides, whereby each haplotype contains a potential methylation site at one of the two SNP positions. In addition, 15 CpGs in close vicinity of these SNPs constitute a weak CpG island. Here, we studied whether DNA methylation in this sequence context may contribute to population- and age-specific effects of MCHR1 alleles in obesity., Principal Findings: We analyzed DNA methylation of a 315 bp region of MCHR1 encompassing rs133072 and rs133073 and the CpG island in blood samples of 49 individuals by bisulfite sequencing. The AC haplotype shows a significantly higher methylation level than the GT haplotype. This allele-specific methylation is age-dependent. In young individuals (20-30 years) the difference in DNA methylation between haplotypes is significant; whereas in individuals older than 60 years it is not detectable. Interestingly, the GT allele shows a decrease in methylation status with increasing BMI, whereas the methylation of the AC allele is not associated with this phenotype. Heterozygous lymphoblastoid cell lines show the same pattern of allele-specific DNA methylation. The cell line, which exhibits the highest difference in methylation levels between both haplotypes, also shows allele-specific transcription of MCHR1, which can be abolished by treatment with the DNA methylase inhibitor 5-aza-2'-deoxycytidine., Conclusions: We show that DNA methylation at MCHR1 is allele-specific, age-dependent, BMI-associated and affects transcription. Conceivably, this epigenetic regulation contributes to the age- and/or population specific effects reported for MCHR1 in several human obesity studies.

Published

2011

6. High tandem repeat content in the genome of the short-lived annual fish Nothobranchius furzeri: a new vertebrate model for aging research.

Author

Reichwald K, Lauber C, Nanda I, Kirschner J, Hartmann N, Schories S, Gausmann U, Taudien S, Schilhabel MB, Szafranski K, Glöckner G, Schmid M, Cellerino A, Schartl M, Englert C, and Platzer M

Subjects

Animals, Antioxidants pharmacology, Cold Temperature, Fishes, Genetic Markers, Models, Animal, Phylogeny, Resveratrol, Stilbenes pharmacology, Aging genetics, Genome genetics, Longevity genetics, Tandem Repeat Sequences

Abstract

Background: The annual fish Nothobranchius furzeri is the vertebrate with the shortest known life span in captivity. Fish of the GRZ strain live only three to four months under optimal laboratory conditions, show explosive growth, early sexual maturation and age-dependent physiological and behavioral decline, and express aging related biomarkers. Treatment with resveratrol and low temperature significantly extends the maximum life span. These features make N. furzeri a promising new vertebrate model for age research., Results: To contribute to establishing N. furzeri as a new model organism, we provide a first insight into its genome and a comparison to medaka, stickleback, tetraodon and zebrafish. The N. furzeri genome contains 19 chromosomes (2n = 38). Its genome of between 1.6 and 1.9 Gb is the largest among the analyzed fish species and has, at 45%, the highest repeat content. Remarkably, tandem repeats comprise 21%, which is 4-12 times more than in the other four fish species. In addition, G+C-rich tandem repeats preferentially localize to centromeric regions. Phylogenetic analysis based on coding sequences identifies medaka as the closest relative. Genotyping of an initial set of 27 markers and multi-locus fingerprinting of one microsatellite provides the first molecular evidence that the GRZ strain is highly inbred., Conclusions: Our work presents a first basis for systematic genomic and genetic analyses aimed at understanding the mechanisms of life span determination in N. furzeri.

Published

2009

7. Telomeres shorten while Tert expression increases during ageing of the short-lived fish Nothobranchius furzeri

Author

Alexander Dorn, Jeanette Kirschner, André Lechel, Kathrin Reichwald, Alessandro Cellerino, Nils Hartmann, Eva Terzibasi, Christoph Englert, Matthias Platzer, Karl Lenhard Rudolph, Juliane Wellner, Michael Graf, Hartmann, N, Reichwald, K, Lechel, A, Graf, M, Kirschner, J, Dorn, A, Terzibasi, Eva, Wellner, J, Platzer, M, Rudolph, K. L., Cellerino, Alessandro, and Englert, C.

Subjects

Genetics, Senescence, Aging, Telomerase, Base Sequence, biology, media_common.quotation_subject, Longevity, Telomere, biology.organism_classification, Gene Expression Regulation, Enzymologic, Cell biology, Nothobranchius furzeri, Cyprinodontiformes, Nothobranchius, Ageing, Animals, Killifish, Conserved Sequence, Developmental Biology, media_common

Abstract

Age research in vertebrates is often limited by the longevity of available models. The teleost fish Nothobranchius furzeri has an exceptionally short lifespan with 3.5 months for the laboratory strain GRZ and about 6 months for the wild-derived strain MZM-0403. Here we have investigated telomere length in muscle and skin tissue of young and old fish of both strains using different methods. We found age-dependent telomere shortening in the MZM-0403 strain with the longer lifespan, whereas the short-lived GRZ strain showed no significant telomere shortening with advanced age. Sequencing of the two main telomerase genes Tert and Terc revealed that both genes are highly conserved between the N. furzeri strains while there is little conservation to other fish species and humans. Both genes are ubiquitously expressed in N. furzeri and expression levels of Tert and Terc correlate with telomerase activity in a tissue-specific manner. Unexpectedly, the expression level of Tert is increased in aged muscle and skin tissue of MZM-0403 suggesting that telomeres shorten upon ageing despite increased Tert expression and hence high telomerase activity. We further conclude that the extremely short lifespan of the GRZ strain is not caused by diminished telomerase activity or accelerated telomere shortening.

Published

2009

8. The age related markers lipofuscin and apoptosis show different genetic architecture by QTL mapping in short-lived Nothobranchius fish

Author

Michael Wittig, Tobias Balschun, Enoch Ng'oma, Alexander Dorn, Allesandro Cellerino, Kathrin Reichwald, Andre Franke, Matthias Platzer, Ng'Oma, E, Reichwald, K, Dorn, A, Wittig, M, Balschun, T, Franke, A, Platzer, M, and Cellerino, Alessandro

Subjects

Genetics, Aging, Heterosis, Longevity, Quantitative Trait Loci, apoptosis, Overdominance, Cell Biology, Biology, Quantitative trait locus, biology.organism_classification, Phenotype, Genetic architecture, Lipofuscin, Cyprinodontiformes, Nothobranchius, In Situ Nick-End Labeling, Animals, Biomarkers, lifespan, Research Paper

Abstract

Annual fish of the genus Nothobranchius show large variations in lifespan and expression of age-related phenotypes between closely related populations. We studied N. kadleci and its sister species N. furzeri GRZ strain, and found that N.kadleci is longer-lived than the N. furzeri. Lipofuscin and apoptosis measured in the liver increased with age in N. kadleci with different profiles: lipofuscin increased linearly, while apoptosis declined in the oldest animals. More lipofuscin (P < 0.001) and apoptosis (P < 0.001) was observed in N. furzeri than in N. kadleci at 16w age. Lipofuscin and apoptotic cells were then quantified in hybrids from the mating of N. furzeri to N. kadleci. F1 individuals showed heterosis for lipofuscin but additive effects for apoptosis. These two age-related phenotypes were not correlated in F2 hybrids. Quantitative trait loci analysis of 287 F2 fish using 237 markers identified two QTL accounting for 10% of lipofuscin variance (P < 0.001) with overdominance effect. Apoptotic cells revealed three significant- and two suggestive QTL explaining 19% of variance (P < 0.001), showing additive and dominance effects, and two interacting loci. Our results show that lipofuscin and apoptosis are markers of different age-dependent biological processes controlled by different genetic mechanisms.

Published

2014

9. Parallel evolution of senescence in annual fishes in response to extrinsic mortality

Author

Andreas Petzold, Enoch Ng'oma, Matej Polačik, Alessandro Cellerino, Martin Reichard, Eva Terzibasi Tozzini, Kathrin Reichwald, Alexander Dorn, Radim Blažek, Brian R. Watters, Terzibasi, Eva, Dorn, A, Ng'Oma, E, Polačik, M, Blažek, R, Reichwald, K, Petzold, A, Watters, B, Reichard, M, and Cellerino, Alessandro

Subjects

Senescence, Aging, Trade off, media_common.quotation_subject, Climate, Longevity, Zoology, Biology, Trade-off, Settore BIO/09 - Fisiologia, Lipofuscin, Nothobranchiu, Nothobranchius furzeri, biology.animal, Genetic variation, Animals, Life history, Ecosystem, Ecology, Evolution, Behavior and Systematics, media_common, Ageing theory, Vertebrate, biology.organism_classification, Smegmamorpha, Nothobranchius, Evolutionary biology, Parallel evolution, Research Article

Abstract

Background Early evolutionary theories of aging predict that populations which experience low extrinsic mortality evolve a retarded onset of senescence. Experimental support for this theory in vertebrates is scarce, in part for the difficulty of quantifying extrinsic mortality and its condition- and density-dependent components that –when considered- can lead to predictions markedly different to those of the “classical” theories. Here, we study annual fish of the genus Nothobranchius whose maximum lifespan is dictated by the duration of the water bodies they inhabit. Different populations of annual fish do not experience different strengths of extrinsic mortality throughout their life span, but are subject to differential timing (and predictability) of a sudden habitat cessation. In this respect, our study allows testing how aging evolves in natural environments when populations vary in the prospect of survival, but condition-dependent survival has a limited effect. We use 10 Nothobranchius populations from seasonal pools that differ in their duration to test how this parameter affects longevity and aging in two independent clades of these annual fishes. Results We found that replicated populations from a dry region showed markedly shorter captive lifespan than populations from a humid region. Shorter lifespan correlated with accelerated accumulation of lipofuscin (an established age marker) in both clades. Analysis of wild individuals confirmed that fish from drier habitats accumulate lipofuscin faster also under natural conditions. This indicates faster physiological deterioration in shorter-lived populations. Conclusions Our data provide a strong quantitative example of how extrinsic mortality can shape evolution of senescence in a vertebrate clade. Nothobranchius is emerging as a genomic model species. The characterization of pairs of closely related species with different longevities should provide a powerful paradigm for the identification of genetic variations responsible for evolution of senescence in natural populations.

Published

2013

10. High tandem repeat content in the genome of the short-lived annual fish Nothobranchius furzeri: a new vertebrate model for aging research

Author

Gernot Glöckner, Chris Lauber, Karol Szafranski, Kathrin Reichwald, Susanne Schories, Alessandro Cellerino, Ulrike Gausmann, Christoph Englert, Nils Hartmann, Stefan Taudien, Indrajit Nanda, Michael Schmid, Jeanette Kirschner, Manfred Schartl, Matthias Platzer, Markus Schilhabel, Reichwald, K, Lauber, C, Nanda, I, Kirschner, J, Hartmann, N, Schories, S, Gausmann, U, Taudien, S, Schilhabel, Mb, Szafranski, K, Glockner, G, Schmid, M, Cellerino, Alessandro, Schartl, M, Englert, C, and Platzer, M.

Subjects

Genetic Markers, Aging, Longevity, Genome, Antioxidants, Nothobranchius furzeri, Tandem repeat, biology.animal, Stilbenes, Animals, Tetraodon, Zebrafish, Maximum life span, Phylogeny, Genetics, biology, Research, Fishes, Vertebrate, biology.organism_classification, Cold Temperature, Evolutionary biology, Resveratrol, Tandem Repeat Sequences, Models, Animal, Microsatellite

Abstract

A genomic analysis of the annual fish Nothobranchius furzeri, a vertebrate with the shortest known life span in captivity and which may provide a new model organism for aging research., Background The annual fish Nothobranchius furzeri is the vertebrate with the shortest known life span in captivity. Fish of the GRZ strain live only three to four months under optimal laboratory conditions, show explosive growth, early sexual maturation and age-dependent physiological and behavioral decline, and express aging related biomarkers. Treatment with resveratrol and low temperature significantly extends the maximum life span. These features make N. furzeri a promising new vertebrate model for age research. Results To contribute to establishing N. furzeri as a new model organism, we provide a first insight into its genome and a comparison to medaka, stickleback, tetraodon and zebrafish. The N. furzeri genome contains 19 chromosomes (2n = 38). Its genome of between 1.6 and 1.9 Gb is the largest among the analyzed fish species and has, at 45%, the highest repeat content. Remarkably, tandem repeats comprise 21%, which is 4-12 times more than in the other four fish species. In addition, G+C-rich tandem repeats preferentially localize to centromeric regions. Phylogenetic analysis based on coding sequences identifies medaka as the closest relative. Genotyping of an initial set of 27 markers and multi-locus fingerprinting of one microsatellite provides the first molecular evidence that the GRZ strain is highly inbred. Conclusions Our work presents a first basis for systematic genomic and genetic analyses aimed at understanding the mechanisms of life span determination in N. furzeri.

Published

2009