Francine Krieg
Institut national de la recherche agronomique
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Featured researches published by Francine Krieg.
Heredity | 1993
Arnaud Estoup; Pablo Presa; Francine Krieg; Daniel Vaiman; René Guyomard
Thirteen (GT)n and four (CT)n microsatellite loci (n = 10 or more and n = 20 or more, respectively) have been isolated from a partial genomic library of brown trout and sequenced. On average, a (GT)n repeat sequence occurs approximately every 23 kb and a (CT)n repeat sequence every 76 kb in brown trout genome. Primers for DNA amplifications using the polymerase chain reaction (PCR) were synthesized for three single locus microsatellites. Mendelian inheritance of the observed polymorphisms was confirmed in full-sib families. Four brown trout populations (10 unrelated individuals per population) were screened for polymorphism with these three microsatellite loci. The total number of alleles detected in the four populations is five at one locus, six at the other two microsatellite loci and is three, on average, per population. Heterozygosities range from 0.18 to 0.74. The largest differences in allelic frequencies occurred between the Mediterranean and the Atlantic populations: this result is congruent with previous allozymic data. The gene-centromere distances of the three microsatellite markers were determined on gynogenetic lines: post-reduction rates range from 0.17 to 0.60. For all the three microsatellite loci, the primers designed from brown trout sequences can be used in another closely related species of salmonid, the rainbow trout (Oncorhynchus mykiss). This last aspect supports the view that microsatellite markers may have wide application in genetic studies in salmonid species and fishes in general.
Genetics | 2005
Karim Gharbi; Angélique Gautier; Roy G. Danzmann; Sonia Gharbi; Takashi Sakamoto; Bjørn Høyheim; John B. Taggart; Margaret Cairney; Richard Powell; Francine Krieg; Nobuaki Okamoto; Moira M. Ferguson; Lars-Erik Holm; René Guyomard
We report on the construction of a linkage map for brown trout (Salmo trutta) and its comparison with those of other tetraploid-derivative fish in the family Salmonidae, including Atlantic salmon (Salmo salar), rainbow trout (Oncorhynchus mykiss), and Arctic char (Salvelinus alpinus). Overall, we identified 37 linkage groups (2n = 80) from the analysis of 288 microsatellite polymorphisms, 13 allozyme markers, and phenotypic sex in four backcross families. Additionally, we used gene–centromere analysis to approximate the position of the centromere for 20 linkage groups and thus relate linkage arrangements to the physical morphology of chromosomes. Sex-specific maps derived from multiple parents were estimated to cover 346.4 and 912.5 cM of the male and female genomes, respectively. As previously observed in other salmonids, recombination rates showed large sex differences (average female-to-male ratio was 6.4), with male crossovers generally localized toward the distal end of linkage groups. Putative homeologous regions inherited from the salmonid tetraploid ancestor were identified for 10 pairs of linkage groups, including five chromosomes showing evidence of residual tetrasomy (pseudolinkage). Map alignments with orthologous regions in Atlantic salmon, rainbow trout, and Arctic char also revealed extensive conservation of syntenic blocks across species, which was generally consistent with chromosome divergence through Robertsonian translocations.
Genetics Selection Evolution | 1985
Francine Krieg; René Guyomard
The genetic variability of 7 fish-farm strains and 14 wild populations of brown trout was studied by electrophoretic analysis of 23 enzyme systems coded for by 52 loci. The total gene diversity was high (0.112) as compared to other salmonid species, but only 45 p. 100 was found within the populations, indicating an extreme genetic differentiation in brown trout. UrcNtn clustering analysis subdivided the populations into 4 major groups, i.e. 2 in Corsica, 1 in Brittany and a 4 th one closely clustering the Norman wild anadromous populations with the hatchery strains. These results suggest that Breton and Corsican samples represent native stocks, but that some hatchery introgression or contamination is possible in Norman rivers. This last assumption could explain the coexistence of 2 electrophoretically differentiated ecotypes in one Norman drainage. The genetic distances between Corsican and continental samples are consistent with previous meristic studies reporting the occurrence of a differentiated form in Corsica.
BMC Genomics | 2006
René Guyomard; Stéphane Mauger; Kamila Tabet-Canale; Sylvain Martineau; Carine Genet; Francine Krieg; Edwige Quillet
BackgroundThe development of large genomic resources has become a prerequisite to elucidate the wide-scale evolution of genomes and the molecular basis of complex traits. Linkage maps represent a first level of integration and utilization of such resources and the primary framework for molecular analyses of quantitative traits. Previously published linkage maps have already outlined the main peculiarities of the rainbow trout meiosis and a correspondance between linkage groups and chromosome arms has been recently established using fluorescent in situ hybridization. The number of chromosome arms which were covered by these maps remained unknown.ResultsWe report an updated linkage map based on segregation analysis of more than nine hundred microsatellite markers in two doubled haploid gynogenetic lines. These markers segregated into 31 linkage groups spanning an approximate total map length of 2750 cM. Centromeres were mapped for all the linkage groups using meiogenetic lines. For each of the 31 linkage groups, the meta or acrocentric structure infered from centromere mapping was identical with those recently found with fluorescent in situ hybridization results. The present map is therefore assumed to cover the 52 chromosome arms which constitute the rainbow trout karyotype. Our data confirm the occurrence of a high interference level in this species. Homeologous regions were identified in eleven linkage groups, reflecting the tetraploid nature of the salmonid genome. The data supported the assumption that gene orders are conserved between duplicated groups and that each group is located on a single chromosome arm. Overall, a high congruence with already published rainbow trout linkage maps was found for both gene syntenies and orders.ConclusionThis new map is likely to cover the whole set of chromosome arms and should provide a useful framework to integrate existing or forthcoming rainbow trout linkage maps and other genomic resources. Since very large numbers of EST containing microsatellite sequences are available in databases, it becomes feasible to construct high-density linkage maps localizing known genes. This will facilitate comparative mapping and, eventually, identification of candidate genes in QTL studies.
BMC Genetics | 2012
René Guyomard; Mekki Boussaha; Francine Krieg; Caroline Hervet; Edwige Quillet
BackgroundRainbow trout is an economically important fish and a suitable experimental organism in many fields of biology including genome evolution, owing to the occurrence of a salmonid specific whole-genome duplication (4th WGD). Rainbow trout is among some of the most studied teleosts and has benefited from substantial efforts to develop genomic resources (e.g., linkage maps. Here, we first generated a synthetic map by merging segregation data files derived from three independent linkage maps. Then, we used it to evaluate genome conservation between rainbow trout and three teleost models, medaka, stickleback and zebrafish and to further investigate the extent of the 4th WGD in trout genome.ResultsThe INRA linkage map was updated by adding 211 new markers. After standardization of marker names, consistency of marker assignment to linkage groups and marker orders was checked across the three different data sets and only loci showing consistent location over all or almost all of the data sets were kept. This resulted in a synthetic map consisting of 2226 markers and 29 linkage groups spanning over 3600 cM. Blastn searches against medaka, stickleback, and zebrafish genomic databases resulted in 778, 824 and 730 significant hits respectively while blastx searches yielded 505, 513 and 510 significant hits. Homology search results revealed that, for most rainbow trout chromosomes, large syntenic regions encompassing nearly whole chromosome arms have been conserved between rainbow trout and its closest models, medaka and stickleback. Large conserved syntenies were also found between the genomes of rainbow trout and the reconstructed teleost ancestor. These syntenies consolidated the known homeologous affinities between rainbow trout chromosomes due to the 4th WGD and suggested new ones.ConclusionsThe synthetic map constructed herein further highlights the stability of the teleost genome over long evolutionary time scales. This map can be easily extended by incorporating new data sets and should help future rainbow trout whole genome sequence assembly. Finally, the persistence of large conserved syntenies across teleosts should facilitate the identification of candidate genes through comparative mapping, even if the occurrence of intra-chromosomal micro-rearrangement may hinder the accurate prediction their genomic location.
BMC Genomics | 2011
Yniv Palti; Carine Genet; Ming-Cheng Luo; Aurélie Charlet; Guangtu Gao; Yuqin Hu; Cecilia Castaño-Sánchez; Kamila Tabet-Canale; Francine Krieg; Jianbo Yao; Roger L. Vallejo; Caird E. Rexroad
BackgroundRainbow trout (Oncorhynchus mykiss) are the most-widely cultivated cold freshwater fish in the world and an important model species for many research areas. Coupling great interest in this species as a research model with the need for genetic improvement of aquaculture production efficiency traits justifies the continued development of genomics research resources. Many quantitative trait loci (QTL) have been identified for production and life-history traits in rainbow trout. An integrated physical and genetic map is needed to facilitate fine mapping of QTL and the selection of positional candidate genes for incorporation in marker-assisted selection (MAS) programs for improving rainbow trout aquaculture production.ResultsThe first generation integrated map of the rainbow trout genome is composed of 238 BAC contigs anchored to chromosomes of the genetic map. It covers more than 10% of the genome across segments from all 29 chromosomes. Anchoring of 203 contigs to chromosomes of the National Center for Cool and Cold Water Aquaculture (NCCCWA) genetic map was achieved through mapping of 288 genetic markers derived from BAC end sequences (BES), screening of the BAC library with previously mapped markers and matching of SNPs with BES reads. In addition, 35 contigs were anchored to linkage groups of the INRA (French National Institute of Agricultural Research) genetic map through markers that were not informative for linkage analysis in the NCCCWA mapping panel. The ratio of physical to genetic linkage distances varied substantially among chromosomes and BAC contigs with an average of 3,033 Kb/cM.ConclusionsThe integrated map described here provides a framework for a robust composite genome map for rainbow trout. This resource is needed for genomic analyses in this research model and economically important species and will facilitate comparative genome mapping with other salmonids and with model fish species. This resource will also facilitate efforts to assemble a whole-genome reference sequence for rainbow trout.
Genetics Selection Evolution | 1994
P Presa; Francine Krieg; A Estoup; René Guyomard
Résumé Nous avons examiné le polymorphisme électrophorétique de 47 locus enzymatiques dans 24 populations naturelles et domestiques de truite commune de France ainsi que la variabilité à 5 locus microsatellites dans 4 de ces populations. La proportion de locus enzymatiques polymorphes sur l’ensemble des échantillons est de 57% et varie de 0 à 37% entre populations. Ce polymorphisme permet de distinguer 2 sous-espèces distinctes occupant respectivement les bassins atlantique et méditerranéen et dont la distance génétique standard (Nei) s’établit, en moyenne, à 0,10. La variabilité des populations atlantiques s’avère nettement plus élevée que celle des populations méditerranéennes et présente un certain degré de structuration géographique. Toutes les souches domestiques étudiées ont
Genetics Selection Evolution | 2004
Bernard Chevassus; Edwige Quillet; Francine Krieg; Marie-Gwénola Hollebecq; Muriel Mambrini; André Fauré; Laurent Labbé; Jean-Pierre Hiseux; Marc Vandeputte
Growth rate is the main breeding goal of fish breeders, but individual selection has often shown poor responses in fish species. The PROSPER method was developed to overcome possible factors that may contribute to this low success, using (1) a variable base population and high number of breeders (Ne > 100), (2) selection within groups with low non-genetic effects and (3) repeated growth challenges. Using calculations, we show that individual selection within groups, with appropriate management of maternal effects, can be superior to mass selection as soon as the maternal effect ratio exceeds 0.15, when heritability is 0.25. Practically, brown trout were selected on length at the age of one year with the PROSPER method. The genetic gain was evaluated against an unselected control line. After four generations, the mean response per generation in length at one year was 6.2% of the control mean, while the mean correlated response in weight was 21.5% of the control mean per generation. At the 4th generation, selected fish also appeared to be leaner than control fish when compared at the same size, and the response on weight was maximal (≈130% of the control mean) between 386 and 470 days post fertilisation. This high response is promising, however, the key points of the method have to be investigated in more detail.
BMC Genetics | 2011
Yvan Le Bras; Nicolas Dechamp; Francine Krieg; Olivier Filangi; René Guyomard; Mekki Boussaha; H. Bovenhuis; Tom G. Pottinger; Patrick Prunet; Pascale Le Roy; Edwige Quillet
BackgroundThere is increasing evidence that the ability to adapt to seawater in teleost fish is modulated by genetic factors. Most studies have involved the comparison of species or strains and little is known about the genetic architecture of the trait. To address this question, we searched for QTL affecting osmoregulation capacities after transfer to saline water in a nonmigratory captive-bred population of rainbow trout.ResultsA QTL design (5 full-sib families, about 200 F2 progeny each) was produced from a cross between F0 grand-parents previously selected during two generations for a high or a low cortisol response after a standardized confinement stress. When fish were about 18 months old (near 204 g body weight), individual progeny were submitted to two successive hyper-osmotic challenges (30 ppt salinity) 14 days apart. Plasma chloride and sodium concentrations were recorded 24 h after each transfer. After the second challenge, fish were sacrificed and a gill index (weight of total gill arches corrected for body weight) was recorded. The genome scan was performed with 196 microsatellites and 85 SNP markers. Unitrait and multiple-trait QTL analyses were carried out on the whole dataset (5 families) through interval mapping methods with the QTLMap software. For post-challenge plasma ion concentrations, significant QTL (P < 0.05) were found on six different linkage groups and highly suggestive ones (P < 0.10) on two additional linkage groups. Most QTL affected concentrations of both chloride and sodium during both challenges, but some were specific to either chloride (2 QTL) or sodium (1 QTL) concentrations. Six QTL (4 significant, 2 suggestive) affecting gill index were discovered. Two were specific to the trait, while the others were also identified as QTL for post-challenge ion concentrations. Altogether, allelic effects were consistent for QTL affecting chloride and sodium concentrations but inconsistent for QTL affecting ion concentrations and gill morphology. There was no systematic lineage effect (grand-parental origin of QTL alleles) on the recorded traits.ConclusionsFor the first time, genomic loci associated with effects on major physiological components of osmotic adaptation to seawater in a nonmigratory fish were revealed. The results pave the way for further deciphering of the complex regulatory mechanisms underlying seawater adaptation and genes involved in osmoregulatory physiology in rainbow trout and other euryhaline fishes.
Aquaculture | 1987
Jean-Marie Blanc; Daniel Chourrout; Francine Krieg
Abstract Five diploid and eight first-generation tetraploid males were mated with a pool of diploid females, with and without retention of the second polar body by heat shock, and the progenies were studied up to the sixth month after hatching. Apart from the poor fertilizing capacity of the tetraploid sires inducing low hatching rates, further survival and growth of the second-generation triploids were similar to those of the triploids obtained from diploid sires and heat shock. Second-generation tetraploids obtained from tetraploid sires and heat shock were inferior to the other ploidy types in post-hatching survival and growth. These characters were affected by a large variation of paternal origin, suggesting that genetic improvement would be possible.