The interaction between sire and f was a significant term when fitted in the MANOVA of the nine morphometric traits (Fthirty six,2208=1.451, P=0.041) but f fitted as a main effect was not (Fnine,549=0.903, P=0.523). MLH was not a significant term either as a main effect (F9,549=1.5, P=0.144) or as an interaction with sire (Fthirty six,2208=0.715, P=0.896). Note that f and MLH were not fitted in the same model for either the univariate or the multivariate analyses.
Forecasts for other vertebrate communities
And the Coopworth sheep population, bottom line analytics based on f and you can marker heterozygosity was basically built-up for 11 other populations. These types of studies was up coming always imagine the brand new correlation coefficient ranging from f and you may MLH (a) with the indicators which were typed in the analysis population at this point, and you will (b) in the event the 100 markers away from mean heterozygosity 0.seven were authored. Rates was shown from inside the Table 1. The population which MLH is actually the best predictor regarding f is actually Scandinavian wolves with an questioned r(H, f)=?0.71 when your 31 noted microsatellites was typed and you may a supposed r(H, f)= ?0.90 when the one hundred loci was in fact blogged. The people for which MLH is actually terrible in the forecasting f try the newest collared flycatchers (Ficedula albicollis) to your Swedish Island regarding Gotland, that have an expected r(H, f)=?0.08 in case the three recorded microsatellites was had written and an expected r(H, f)=?0.32 in the event that 100 loci were blogged. Basically, heterozygosity would not offer powerful where to find sugar daddies in Tucson AZ prices regarding f, although a hundred loci is actually wrote. Such, the fresh new requested roentgen(H, f) is weaker than –0.5 for five of your twelve communities and you may weakened than simply ?0.eight for 9 of communities.
In seven of the populations, r(H, f) had actually been estimated, enabling a comparison between expected and seen correlation coefficients (Table 1). In Scandinavian wolves and Large Ground Finches, the observed and expected correlation coefficients were almost identical. In four of the five other populations, r(H, f)observed was weaker than r(H, f)expected, perhaps due to errors in estimation of f (see Talk).
Discussion
The primary objective of this study was to establish if and when MLH can be used as a robust surrogate for individual f. A theoretical model and empirical data both suggest that the correlation between MLH and f is weak unless the study population exhibits unusually high variance in f. The Coopworth sheep data set used in this study comprised a considerably larger number of genotypes (590 individuals typed at 138 loci) than any similar study, yet MLH was only weakly correlated to individual f. Furthermore, f explained significant variation in a number of morphometric traits (typically 1–2% of the overall trait variance), but heterozygosity did not. From equation (5), it can be seen that the expected correlation between trait value and MLH is the product of the correlation coefficient between f and the trait (hereafter r(W, f)) and r(H, f). Estimates of the proportion of phenotypic trait variation explained by f are scarce, although from the limited available data 2% seems a typical value (see for example Kruuk et al, 2002; this paper, Table 2). Assuming r(W, f) 2 =0.02, and given the median value of r(H, f)=?0.21 reported in Table 1, a crude estimate of average r(W, H) is 0.03, which is equivalent to MLH explaining <0.1% of trait variance. These findings are consistent with a recent meta-analysis that reported a mean r(W, H) of 0.09 for life history traits and 0.01 for morphometric traits (Coltman and Slate, 2003). In summary, MLH is a poor replacement for f, such that very large sample sizes are required to detect variance in inbreeding in most populations.