Microsatellite standardization and evaluation of genotyping error in a large multi-partner research programme for conservation of Atlantic salmon (Salmo salar L.).

Microsatellite genotyping is a common DNA characterization technique in population, ecological and evolutionary genetics research. Since different alleles are sized relative to internal size-standards, different laboratories must calibrate and standardize allelic designations when exchanging data. This interchange of microsatellite data can often prove problematic. Here, 16 microsatellite loci were calibrated and standardized for the Atlantic salmon, Salmo salar, across 12 laboratories. Although inconsistencies were observed, particularly due to differences between migration of DNA fragments and actual allelic size ('size shifts'), inter-laboratory calibration was successful. Standardization also allowed an assessment of the degree and partitioning of genotyping error. Notably, the global allelic error rate was reduced from 0.05 ± 0.01 prior to calibration to 0.01 ± 0.002 post-calibration. Most errors were found to occur during analysis (i.e. when size-calling alleles; the mean proportion of all errors that were analytical errors across loci was 0.58 after calibration). No evidence was found of an association between the degree of error and allelic size range of a locus, number of alleles, nor repeat type, nor was there evidence that genotyping errors were more prevalent when a laboratory analyzed samples outside of the usual geographic area they encounter. The microsatellite calibration between laboratories presented here will be especially important for genetic assignment of marine-caught Atlantic salmon, enabling analysis of marine mortality, a major factor in the observed declines of this highly valued species.

A retrospective approach to fractionize variation in body mass of Atlantic cod Gadus morhua.

Eggs of a single spawning batch from wild-caught Norwegian Atlantic cod Gadus morhua were hatched and first fed on either natural zooplankton or enriched rotifers Brachionus plicatilis during the larval period. Juvenile G. morhua (initial mass 14·2 g) from the two first-feeding groups were then reared for 3 months under a variety of temperature (10 and 14° C) and salinity (15 and 32) combinations. All fish were individually tagged and microsatellite markers were used in a multiplex to trace the pedigree of all fish and body mass variation analysed according to different environmental and genetic sources. After the termination of the laboratory trial, the fish were transferred to land-based tanks and later to sea pens and reared at ambient conditions for 26 months until they were harvested in March 2009. Growth gain from the larval and juvenile periods was persistent during the 26 months of sea pen ongrowing. The final mass of the zooplankton group was 12% higher compared to the B. plicatilis group. Similarly, rearing under a temperature of 14° C and salinity of 15 during the initial 3 month period during the early juvenile stage resulted in 7-13% larger size at harvesting compared to the other three temperature and salinity combinations. The study indicates that the first-feeding method and temperature and salinity manipulation explain nearly 90% of the body mass variation explained by the model. The genetic effect (measured as body mass variation within the families studied) only accounted for c. 2% during the initial rearing period, whereas it has a large effect on growth variation (30%) during the long-term rearing at ambient conditions. Sex proportion and final maturation did not differ between family groups, and no interaction between sex and family group was seen.

Permanent Genetic Resources added to the Molecular Ecology Resources Database 1 February 2010-31 March 2010.

This article documents the addition of 228 microsatellite marker loci to the Molecular Ecology Resources Database. Loci were developed for the following species: Anser cygnoides, Apodemus flavicollis, Athene noctua, Cercis canadensis, Glis glis, Gubernatrix cristata, Haliotis tuberculata, Helianthus maximiliani, Laricobius nigrinus, Laricobius rubidus, Neoheligmonella granjoni, Nephrops norvegicus, Oenanthe javanica, Paramuricea clavata, Pyrrhura orcesi and Samanea saman. These loci were cross-tested on the following species: Apodemus sylvaticus, Laricobius laticollis and Laricobius osakensis (a proposed new species currently being described).

DNA microarrays for identifying fishes.

In many cases marine organisms and especially their diverse developmental stages are difficult to identify by morphological characters. DNA-based identification methods offer an analytically powerful addition or even an alternative. In this study, a DNA microarray has been developed to be able to investigate its potential as a tool for the identification of fish species from European seas based on mitochondrial 16S rDNA sequences. Eleven commercially important fish species were selected for a first prototype. Oligonucleotide probes were designed based on the 16S rDNA sequences obtained from 230 individuals of 27 fish species. In addition, more than 1200 sequences of 380 species served as sequence background against which the specificity of the probes was tested in silico. Single target hybridisations with Cy5-labelled, PCR-amplified 16S rDNA fragments from each of the 11 species on microarrays containing the complete set of probes confirmed their suitability. True-positive, fluorescence signals obtained were at least one order of magnitude stronger than false-positive cross-hybridisations. Single nontarget hybridisations resulted in cross-hybridisation signals at approximately 27% of the cases tested, but all of them were at least one order of magnitude lower than true-positive signals. This study demonstrates that the 16S rDNA gene is suitable for designing oligonucleotide probes, which can be used to differentiate 11 fish species. These data are a solid basis for the second step to create a "Fish Chip" for approximately 50 fish species relevant in marine environmental and fisheries research, as well as control of fisheries products.

Cloning, sequence analysis and functional characterization of DNA polymerase I from the thermophilic eubacterium Rhodothermus marinus.

A gene encoding a DNA polymerase I from the thermophilic eubacterium Rhodothermus marinus was identified. The gene was cloned, sequenced and expressed in Escherichia coli. The gene is 2772 bp long and encodes a protein of 924 amino acids with a calculated molecular mass of 104.8 kDa. Sequence analysis showed that a generally conserved Phe residue in the O-helix is substituted by a Tyr (position 756) in the R. marinus enzyme. A Tyr in this position decreases the discrimination against dideoxynucleotides which is a major advantage in DNA sequencing. The protein was purified, characterized and showed to contain specific DNA-polymerization activity of 3100 units/mg of protein, 5'-->3' exonuclease activity and a 3'-->5' proofreading activity. Its optimum activity was at 55 degrees C and it had a half-life of 2 min at 90 degrees C. A truncated form of the enzyme lacking the 5'-->3' exonuclease domain was also expressed in E. coli. It had a specific DNA-polymerization activity of 5000 units/mg of protein and lacked the 5'-->3' exonuclease activity. Its optimum activity was at 65 degrees C and it had a half-life of 11 min at 90 degrees C. It was usable for DNA sequencing. This is the first thermostable DNA polymerase described with the O-helix Phe-->Tyr substitution.

Species Composition of Cultivated and Noncultivated Bacteria from Short Filaments in an Icelandic Hot Spring at 88 degrees C.

Samples of short pink-grayish filaments were collected from a hot spring in the Hengill area in southwestern Iceland at 85-88 degrees C, pH 6.9 and 1.7 mg/L sulfide. The species composition was studied by cloning and sequencing small subunit rRNA genes obtained by PCR amplifications from mat DNA. Using 98% sequence similarity as a cutoff value, a total of 5 bacterial operational taxonomic units (OTUs) and 6 archaeal OTUs were detected among 68 bacterial clones and 97 archaeal clones. Database matching showed that 80.5% of the archaeal sequences were 99% similar to Pyrobaculum islandicum and 14.5% were closest to the Korarchaeota clone sequence SRI306. About 87% of the bacterial sequences had the closest database match (99%) to the clone sequence SRI48 but were also found to be 99% identical with hydrogen-oxidizing strains previously isolated in this laboratory from hot springs in the same region. Out of 7 Thermus sequences, 4 were 100% identical to T. scotoductus NMX2 A.1 but 3 represented a new uncultivated Thermus species. Four different media, varying in organic nutrients and phosphate composition were used to isolate 81 aerobic thermophilic heterotrophs. Four isolates were Bacillus spp; but out of 77 Thermus isolates, 42 belonged to T. scotoductus and 35 to T. brockianus. T. scotoductus seemed to be preferably isolated on media low in nutrients and phosphate, whereas for T. brockianus it was the opposite. The T. scotoductus clones and isolates had 99-100% sequence similarity to each other. No T. brockianus sequences were found in the bacterial clone library.

Influence of sulfide and temperature on species composition and community structure of hot spring microbial mats.

In solfataric fields in southwestern Iceland, neutral and sulfide-rich hot springs are characterized by thick bacterial mats at 60 to 80 degrees C that are white or yellow from precipitated sulfur (sulfur mats). In low-sulfide hot springs in the same area, grey or pink streamers are formed at 80 to 90 degrees C, and a Chloroflexus mat is formed at 65 to 70 degrees C. We have studied the microbial diversity of one sulfur mat (high-sulfide) hot spring and one Chloroflexus mat (low-sulfide) hot spring by cloning and sequencing of small-subunit rRNA genes obtained by PCR amplification from mat DNA. Using 98% sequence identity as a cutoff value, a total of 14 bacterial operational taxonomic units (OTUs) and 5 archaeal OTUs were detected in the sulfur mat; 18 bacterial OTUs were detected in the Chloroflexus mat. Although representatives of novel divisions were found, the majority of the sequences were >95% related to currently known sequences. The molecular diversity analysis showed that Chloroflexus was the dominant mat organism in the low-sulfide spring (1 mg liter(-1)) below 70 degrees C, whereas Aquificales were dominant in the high-sulfide spring (12 mg liter(-1)) at the same temperature. Comparison of the present data to published data indicated that there is a relationship between mat type and composition of Aquificales on the one hand and temperature and sulfide concentration on the other hand.

Cloning, sequence analysis and overexpression of a rhodothermus marinus gene encoding a thermostable thymidine kinase.

Thymidine kinase type II is an important part of the pyrimidine salvage pathway. The thymidine kinase gene from the thermophilic eubacterium Rhodothermus marinus was cloned, sequenced and overexpressed. The gene is 639 bp and encodes a protein of 213 amino acids with a calculated molecular mass of 23.6 kDa. It shows homology to other thymidine kinase proteins from eukaryotic and prokaryotic organisms. The recombinant protein is inhibited by dNTPs but not by dNDPs. It is a tetramer in its native state. Its optimum temperature of activity is 65 degrees C and it has a half life of 15 min at 90 degrees C. This is the first thymidine kinase to be described from a thermophilic bacterium.