Analysis of genotype-by-environment interaction in a multisite progeny test with Scots pine for supporting selection decisions

European Journal of Forest Research - In multisite forest genetic experiments, the presence of genotype?×?environment interaction (GEI) is common. GEI may negatively affect the...     

Analysis of microtubule and microfilament distribution in Pinus sylvestris roots following infection by Heterobasidion species

Cytoskeletal dynamics play a crucial role in pathogen recognition and cell defence during the initial interactions between an invader and plant host. The aim of the work reported here was to characterize how Heterobasidion annosum s.s., Heterobasidion parviporum, and Heterobasidion abietinum affect the microtubules and microfilaments of Pinus sylvestris root cells 12‐, 24‐, 48‐, and 96‐h post‐inoculation. Inoculation of P. sylvestris with H. parviporum or H. abietinum, which have a lower specificity for P. sylvestris than H. annosum s.s, resulted in greater reorganization of host microtubules during the early stages of interaction than inoculation with the more specific H. annosum s.s. In some infected cells, spots of actin aggregates were observed. Disruption of cytoskeletal components by the application of specific cytoskeletal inhibitors facilitated the entry of the H. parviporum and H. abietinum into roots. These results suggest that the P. sylvestris cytoskeleton plays a role in the host response in the initial stages of the host–pathogen interaction.     

Allometry varies among related families of Norway spruce

Key message

Slopes and intercepts of allometric equations for organs’ biomass varied among half-sib families of Norway spruce and between age categories in a family-dependent manner. Genetic variation should be accounted for when applying allometric analysis to mixtures of genetic groups.

Context

Genetic variation in relationships among plant biomass components was rarely addressed in trees, though depending on deployment strategies in tree improvement programs, variation among genetic groups in plant organs’ growth rates, and thus biomass allocation, would affect forest growth and carbon balance.

Aims

We investigated growth and biomass distribution in Norway spruce (Picea abies [L.] H. Karst) half-sib families. We assumed invariance among families in allometric relationships, and stability in growth rates of different organs between ages 2 and 8 years in the subset of those families. We also tested for ontogenetic trend in allometry using the independent dataset of biomass at age 21 years.

Methods

We analyzed allometric relationships among plant components using standardized major axis regression.

Results

Slopes and intercepts of allometric relationships varied among families, indicating variation in both organs’ growth rates and biomass partitioning at a given plant size. Variation in scaling exponents between age categories was also dependent on the family and plant organ considered.

Conclusion

Variation in slopes of allometric relationships indicates that a single scaling coefficient should not be applied when different genetic groups are compared. For the interpretation of age effect on biomass partitioning, both slopes and intercepts of allometric relationships should be examined.