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Selection Lines (selection + line)

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Life Sciences	77%

Selected Abstracts

RELATIVE CONTRIBUTION OF ADDITIVE, DOMINANCE, AND IMPRINTING EFFECTS TO PHENOTYPIC VARIATION IN BODY SIZE AND GROWTH BETWEEN DIVERGENT SELECTION LINES OF MICE

EVOLUTION, Issue 5 2009
Reinmar Hager
Epigenetic effects attributed to genomic imprinting are increasingly recognized as an important source of variation in quantitative traits. However, little is known about their relative contribution to phenotypic variation compared to those of additive and dominance effects, and almost nothing about their role in phenotypic evolution. Here we address these questions by investigating the relative contribution of additive, dominance, and imprinting effects of quantitative trait loci (QTL) to variation in "early" and "late" body weight in an intercross of mice selected for divergent adult body weight. We identified 18 loci on 13 chromosomes; additive effects accounted for most of the phenotypic variation throughout development, and imprinting effects were always small. Genetic effects on early weight showed more dominance, less additive, and, surprisingly, less imprinting variation than that of late weight. The predominance of additivity of QTL effects on body weight follows the expectation that additive effects account for the evolutionary divergence between selection lines. We hypothesize that the appearance of more imprinting effects on late body weight may be a consequence of divergent selection on adult body weight, which may have indirectly selected for alleles showing partial imprinting effects due to their associated additive effects, highlighting a potential role of genomic imprinting in the response to selection. [source]

Serum insulin-like growth factor-1 concentration in pigs divergently selected for daily food intake or lean growth rate

JOURNAL OF ANIMAL BREEDING AND GENETICS, Issue 4 2003
N. D. Cameron
Summary Divergent selection over seven generations for daily food intake (DFI) and for two lean growth rate (LGA and LGS) selection objectives in pigs produced correlated responses in serum insulin-like growth factor-1 (IGF-1) concentration. The LGA and LGS selection objectives were for lean growth, but with performance testing on ad libitum (LGA) or on restricted (LGS) feeding regimes. There were 342 animals in the study, with an average of 46 pigs in each selection line and 72 pigs in the control line. All animals were performance-tested from 30 to 90 kg on an ad libitum feeding regime. Selection on DFI increased IGF-1 at 6 weeks of age (158 versus 104 ,g/l, SED 21; control 136 ,g/l) and selection for high LGA increased IGF-1 at 30 kg liveweight (202 versus 161 ,g/l, SED 14; control 185 ,g/l). At 6 weeks of age and at 30 kg of weight, there was no response in IGF-1 with selection on LGS (128 versus 129 and 167 versus 153 ,g/l, respectively) suggesting that IGF-1 may not be a reliable physiological predictor of genetic merit for such a selection objective, which combined rate and efficiency of lean growth. IGF-1 measured immediately prior to the start of performance test may be useful in determining which animals to performance test for a lean growth selection objective, whereas IGF-1 measured at 6 weeks of age may be a useful physiological predictor of genetic merit for daily food intake during performance test. Zusammenfassung Serumkonzentrationen des insulinähnlichen Wachstumsfaktors-1 bei Schweinen, die entweder auf tägliche Futteraufnahme oder auf hohe Wachstumsrate für Magerfleischanteil selektiert wurden Die Selektion von Schweinen über sieben Generationen einerseits auf tägliche Futteraufnahme (DFI) und andererseits auf zwei Wachstumsraten für Magerfleischanteil (LGA, ad-libitum -Fütterung; LGS, rationierte Fütterung) ergab korrelierende Konzentrationen am insulinähnlichen Wachstumsfaktor (IGF-1). An der Studie waren 342 Tiere mit einer durchschnittlichen Tierzahl von 46 Schweinen pro Selektionsgruppe und 72 Schweinen als Kontrollgruppe beteiligt. Alle Tiere wurden zwischen 30 und 90 kg bei der ad-libitum Fütterung leistungsgeprüft. Die Selektion auf tägliche Futteraufnahme (DFI) erhöhte die IGF-1 Konzentrationen in der 6. Lebenswoche von 104 ,g/l auf 158 ,g/l (Kontrollgruppe 136 ,g/l) und die Selektion auf LGA bei der ad-libitum -Fütterung bei einem Lebendgewicht von 30 kg von 161 ,g/l auf 202 ,g/l (Kontrollgruppe 185 ,g/l). In der 6. Lebenswoche und bei 30 kg Lebendgewicht gab es keinen Anstieg der IGF-1 Konzentrationen in der Selektionsgruppe LGS mit rationierter Fütterung (128 ,g/l bzw. 129 ,fg/l in der 6. Lebenswoche; 167 ,g/l bzw. 153 ,g/l bei 30 kg),was darauf hinweisen könnte, dass IGF-1 wahrscheinlich kein verlässlicher, physiologischer Marker für den genetischen Erfolg für ein solches Selektionsziel, welches die Wachstumsrate und die Effizienz beim Magerfleischwachstum kombiniert, darstellt. Die direkt vor Prüfungsbeginn ermittelten IGF-1 Konzentrationen könnten bei der Auswahl der Tiere, die an einer Leistungsprüfung für die Wachstumsrate des Magerfleischanteils als Selektionsziel herangezogen werden sollten, hilfreich sein. Die IGF-1 Konzentrationen, die in der 6. Lebenswoche gemessen werden, sind wahrscheinlich ein hilfreicher physiologischer Marker für den genetischen Erfolg für DFI während einer Leistungsprüfung. [source]

Identification of chromosomal regions associated with growth and carcass traits in an F3 full sib intercross line originating from a cross of chicken lines divergently selected on body weight

ANIMAL GENETICS, Issue 5 2009
D. Ter
Summary An F3 resource population originating from a cross between two divergently selected lines for high (D+ line) or low (D, line) body weight at 8-weeks of age (BW55) was generated and used for Quantitative Trait Locus (QTL) mapping. From an initial cross of two founder F0 animals from D(+) and D(,) lines, progeny were randomly intercrossed over two generations following a full sib intercross line (FSIL) design. One hundred and seventy-five genome-wide polymorphic markers were employed in the DNA pooling and selective genotyping of F3 to identify markers with significant effects on BW55. Fifty-three markers on GGA2, 5 and 11 were then genotyped in the whole F3 population of 503 birds, where interval mapping with GridQTL software was employed. Eighteen QTL for body weight, carcass traits and some internal organ weights were identified. On GGA2, a comparison between 2-QTL vs. 1-QTL analysis revealed two separate QTL regions for body, feet, breast muscle and carcass weight. Given co-localization of QTL for some highly correlated traits, we concluded that there were 11 distinct QTL mapped. Four QTL localized to already mapped QTL from other studies, but seven QTL have not been previously reported and are hence novel and unique to our selection line. This study provides a low resolution QTL map for various traits and establishes a genetic resource for future fine-mapping and positional cloning in the advanced FSIL generations. [source]

Size-Dependent Mating Success at Various Nutritional States in the Yellow Dung Fly

ETHOLOGY, Issue 8 2008
Wolf U. Blanckenhorn
Mating success not only depends on genetic quality, but also equally on environmental factors, most prominently food availability. We investigated the interactive effects of nutritional state and body size on mating success and copula duration in yellow dung fly males (Scathophaga stercoraria; Diptera: Scathophagidae) of three body size selection lines in the laboratory in both non-competitive (single) and competitive (group) situations. Adults require protein and lipids from prey to reproduce, as well as sugars as an energy source for reproductive activity. We expected mating success to decrease with time because of sperm depletion (sugar treatment) and/or energy shortage (water treatment) relative to the control, prey plus sugar treatment. Based on physiological scaling, we also expected large-line males to become depleted either sooner because of their higher energy and sperm demands, or later because of their more efficient energy use. Average mating success indeed declined over a period of 5,7 d (or 5,15 potential copulations per male), but equally for all food treatments and body size classes. Surprisingly, water-fed and small-line males had the highest mating probability in the non-competitive setting, while in the competitive setting large-line males had the highest success. Energy-depleted males showed apparent terminal investment. Small males acquired females more readily but eventually lost them to larger males in the competitive situation. As shown before, copula duration was inversely related to body size and increased with copulation number, independent of food treatment. We conclude that sugar or prey shortage has little effect on mating success in the short term, and does not differentially affect males of different sizes. [source]

RELATIVE CONTRIBUTION OF ADDITIVE, DOMINANCE, AND IMPRINTING EFFECTS TO PHENOTYPIC VARIATION IN BODY SIZE AND GROWTH BETWEEN DIVERGENT SELECTION LINES OF MICE

Adaptation, extinction and global change

EVOLUTIONARY APPLICATIONS (ELECTRONIC), Issue 1 2008
Graham Bell
Abstract We discuss three interlinked issues: the natural pace of environmental change and adaptation, the likelihood that a population will adapt to a potentially lethal change, and adaptation to elevated CO2, the prime mover of global change. 1.,Environmental variability is governed by power laws showing that ln difference in conditions increases with ln elapsed time at a rate of 0.3,0.4. This leads to strong but fluctuating selection in many natural populations. 2.,The effect of repeated adverse change on mean fitness depends on its frequency rather than its severity. If the depression of mean fitness leads to population decline, however, severe stress may cause extinction. Evolutionary rescue from extinction requires abundant genetic variation or a high mutation supply rate, and thus a large population size. Although natural populations can sustain quite intense selection, they often fail to adapt to anthropogenic stresses such as pollution and acidification and instead become extinct. 3.,Experimental selection lines of algae show no specific adaptation to elevated CO2, but instead lose their carbon-concentrating mechanism through mutational degradation. This is likely to reduce the effectiveness of the oceanic carbon pump. Elevated CO2 is also likely to lead to changes in phytoplankton community composition, although it is not yet clear what these will be. We emphasize the importance of experimental evolution in understanding and predicting the biological response to global change. This will be one of the main tasks of evolutionary biologists in the coming decade. [source]

Response of fluctuating and directional asymmetry to selection on wing shape in Drosophila melanogaster

JOURNAL OF EVOLUTIONARY BIOLOGY, Issue 3 2006
C. PÉLABON
Abstract We tested whether directional selection on an index-based wing character in Drosophila melanogaster affected developmental stability and patterns of directional asymmetry. We selected for both an increase (up selection) and a decrease (down selection) of the index value on the left wing and compared patterns of fluctuating and directional asymmetry in the selection index and other wing traits across selection lines. Changes in fluctuating asymmetry across selection lines were predominantly small, but we observed a tendency for fluctuating asymmetry to decrease in the up-selected lines in both replicates. Because changes in fluctuating asymmetry depended on the direction of selection, and were not related to changes in trait size, these results fail to support existing hypotheses linking directional selection and developmental stability. Selection also produced a pattern of directional asymmetry that was similar in all selected lines whatever the direction of selection. This result may be interpreted as a release of genetic variance in directional asymmetry under selection. [source]

Correlated responses to selection for stress resistance and longevity in a laboratory population of Drosophila melanogaster

JOURNAL OF EVOLUTIONARY BIOLOGY, Issue 4 2005
O. A. BUBLIY
Abstract Laboratory studies on Drosophila have revealed that resistance to one environmental stress often correlates with resistance to other stresses. There is also evidence on genetic correlations between stress resistance, longevity and other fitness-related traits. The present work investigates these associations using artificial selection in Drosophila melanogaster. Adult flies were selected for increased survival after severe cold, heat, desiccation and starvation stresses as well as increased heat-knockdown time and lifespan (CS, HS, DS, SS, KS and LS line sets, respectively). The number of selection generations was 11 for LS, 27 for SS and 21 for other lines, with selection intensity being around 0.80. For each set of lines, the five stress-resistance parameters mentioned above as well as longevity (in a nonstressful environment) were estimated. In addition, preadult developmental time, early age productivity and thorax length were examined in all lines reared under nonstressful conditions. Comparing the selection lines with unselected control revealed clear-cut direct selection responses for the stress-resistance traits. Starvation resistance increased as correlated response in all sets of selection lines, with the exception of HS. Positive correlated responses were also found for survival after cold shock (HS and DS) and heat shock (KS and DS). With regard to values of resistance across different stress assays, the HS and KS lines were most similar. The resistance values of the SS lines were close to those of the LS lines and tended to be the lowest among all selection lines. Developmental time was extended in the SS and KS lines, whereas the LS lines showed a reduction in thorax length. The results indicate a possibility of different multiple-stress-resistance mechanisms for the examined traits and fitness costs associated with stress resistance and longevity. [source]

Effects of assay conditions in life history experiments with Drosophila melanogaster

JOURNAL OF EVOLUTIONARY BIOLOGY, Issue 2 2001
M. Ackermann
Selection experiments with Drosophila have revealed constraints on the simultaneous evolution of life history traits. However, the responses to selection reported by different research groups have not been consistent. Two possible reasons for these inconsistencies are (i) that different groups used different environments for their experiments and (ii) that the selection environments were not identical to the assay environments in which the life history traits were measured. We tested for the effect of the assay environment in life history experiments by measuring a set of Drosophila selection lines in laboratories working on life history evolution with Drosophila in Basel, Groningen, Irvine and London. The lines measured came from selection experiments from each of these laboratories. In each assay environment, we measured fecundity, longevity, development time and body size. The results show that fecundity measurements were particularly sensitive to the assay environment. Differences between assay and selection environment in the same laboratory or differences between assay environments between laboratories could have contributed to the differences in the published results. The other traits measured were less sensitive to the assay environment. However, for all traits there were cases where the measurements in one laboratory suggested that selection had an effect on the trait, whereas in other laboratories no such conclusion would have been drawn. Moreover, we provide good evidence for local adaptation in early fecundity for lines from two laboratories. [source]