Abstract
The root rot pathogens in Norway spruce (Picea abies) Heterobasidion ssp. cause substantial loss in carbon sequestered in forest and economic revenue for forest owners. To facilitate strategic breeding planning for increased resistance against this pathogen in particular, the blue stain fungus Endoconidiophora polonica, growth and wood quality traits (wood density and spiral grain), we estimated additive genetic parameters, correlations and the potential response from selection. Parameters were estimated from a progeny trial series established at two sites (25 years from planting) and their parents in a seed orchard (43 years from grafting). A standard half-sib analysis based on progenies and a parent–offspring regression was used for estimation of heritabilities. Resistance against the pathogens was measured as lesion length under bark after inoculations in phloem. Heritability values varied with site and estimation procedure from 0.06 to 0.33, whereas the phenotypic variance (as CV P ) is high and fairly stable around 40–50 %. Heritability values for wood density and spiral grain in the same material varied from 0.32 to 0.63. The highest heritability values were generally obtained from parent–offspring regression. There is no evidence of resistance traits being genetically correlated with growth or wood quality traits. Wood density is negatively correlated with stem diameter. Implications for breeding are discussed.
Highlights
Tree breeding programs for Norway spruce (Picea abies (L.) Karst.) that aim to increase the productivity and added value from forest have in order to increase the volume production per unit area traditionally emphasized on selection for climatic adaptation, growth and to some extent external stem quality
Wood density is negatively correlated with stem diameter
The coefficients of additive genetic (CVA) and phenotypic (CVP) variance for EP and HP were higher than those found for growth traits and DENS
Summary
Tree breeding programs for Norway spruce (Picea abies (L.) Karst.) that aim to increase the productivity and added value from forest have in order to increase the volume production per unit area traditionally emphasized on selection for climatic adaptation, growth and to some extent external stem quality. There is evidence of genetic variation in both resistance and several wood quality traits (summarized in: Eriksson 2010; Swedjemark et al 2012), but the practical implementation of these traits in breeding programs has not yet been fully accomplished due to uncertainties about efficient screening methods and the genetic gain that can be obtained. Production of seed in seed orchards containing selected genotypes is the most cost-effective way of delivering genetic gain from a Norway spruce breeding program. It is the additive proportion of the genetic variance that can be utilized in open pollinated seed orchards. A successful breeding strategy depends on reliable estimates of genetic parameters such as additive genetic and phenotypic variances, the narrow-sense
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