Linking dendroecology and association genetics in natural populations: Stress responses archived in tree rings associate with SNP genotypes in silver fir (Abies alba Mill.).

Genetic association studies in forest trees would greatly benefit from information on the response of trees to environmental stressors over time, which can be provided by dendroecological analysis. Here, we jointly analysed dendroecological and genetic data of surviving silver fir trees to explore the genetic basis of their response to the iconic stress episode of the 1970s and 1980s that led to large-scale forest dieback in Central Europe and has been attributed to air pollution. Specifically, we derived dendrophenotypic measures from 190 trees in the Bavarian Forest that characterize the resistance, resilience and recovery during this growth depression, and in the drought year in 1976. By focusing on relative growth changes of trees and by standardizing the dendrophenotypes within stands, we accounted for variation introduced by micro- and macroscale environmental differences. We associated the dendrophenotypes with single nucleotide polymorphisms (SNPs) in candidate genes using general linear models (GLMs) and the machine learning algorithm random forest with subsequent feature selection. Most trees at our study sites experienced a severe growth decline from 1974 until the mid-1980s with minimum values during the drought year. Fifteen genes were associated with the dendrophenotypes, including genes linked to photosynthesis and drought stress. With our study, we show that dendrophenotypes can be a powerful resource for genetic association studies that permit to account for micro- and macroenvironmental variation when data are derived from natural populations. We call for a wider collaboration of dendroecologists and forest geneticists to integrate individual tree-level dendrophenotypes in genetic association studies.

Contrasting effects of long distance seed dispersal on genetic diversity during range expansion.

Currently many attempts are made to reconstruct the colonization history of plant species after the last ice age. A surprising finding is that during the colonization phase genetic diversity did not decrease as much as expected. In this paper we examine whether long distance seed dispersal events could play a role in the unexpected maintenance of genetic diversity during range expansion. This study is based on simulations carried out with a maternally inherited haploid locus using a cellular automaton. The simulations reveal a close relationship between the frequency of long distance seed dispersal events and the amount of genetic diversity preserved during colonization. In particular, when the colonized region is narrow, a complete loss of genetic diversity results from the occurrence of very rare long distance dispersal (LDD) events. We call this phenomenon the 'embolism effect'. However, slightly higher rates of LDD events reverse this effect, up to the point that diversity is better preserved than in a pure diffusion model. This phenomenon is linked to the reorganization of the genetic structure during colonization and is called the 'reshuffling effect'.

New insights into allelic diversity of a phosphoeno/pyruvate carboxylase in the conifer Picea abies (l.) Karst.

Two genomic full-length alleles of a phosphoenolpyruvate carboxylase (PEPC; EC 4.1.1.31) were isolated and analysed in the gymnosperm Norway spruce [Picea abies (L.) Karst.]. Mendelian segregation analysis confirmed that the two alleles belong to the same DNA gene locus. Southern analysis was performed using exon and intron probes, separately. A small gene family was discovered when exon probes were used. The isolated gene locus was termed PEPC-1 and found to exhibit the largest PEPC genomic sequence characterised so far in the plant kingdom. This is due to comparatively long intron sequences, and to an additional intron in the 3'-untranslated region. Sequence homology of the two full-length PEPC-1 alleles is 99.8%. From exon variation, one single exchange of an amino acid was deduced. The introns harboured polymorphic regions that were analysed for variability among three different spruce individuals. Within-PEPC-1 genotyping revealed that all three individuals could be unambiguously distinguished from each other. The results are discussed with respect not only to exon/intron site evolution among alleles but also to particular genomic features of a gymnosperm PEPC in comparison to PEPC in angiosperms.

Comparative study of genetic variation and differentiation of two pedunculate oak (Quercus robur) stands using microsatellite and allozyme loci

In a comparative study four codominant microsatellite loci and seven allozyme gene loci have been used to investigate the genetic variation and differentiation of two pedunculate oak stands in North Germany. Both number and effective number of alleles were five to six times higher and the observed heterozygosity was three times higher for the microsatellite than for the allozyme loci. One stand showed an overall excess of homozygotes. In general the microsatellites were closer to Hardy-Weinberg expectation. The genetic distances between the two stands were distinctly higher for microsatellites. For most parameters microsatellites exhibited smaller interlocus variation than the allozymes. The different impact of population genetic processes on the genetic structure as assessed by microsatellites or allozymes is discussed.

Characterisation and inheritance of polymorphic plastid microsatellites in Abies.

Two polymorphic microsatellite loci were identified and sequenced in the genus Abies, using primer pairs derived from chloroplast simple sequence repeats (SSRs) of Pinus thunbergii. PCR products exhibited considerable length variation among six different Abies species and within Abies alba. F1 progeny of both an interspecific and an intraspecific reciprocal cross confirmed that the two SSRs were predominantly paternally inherited. The maternal size variant predominantly occurred in the megagametophytes analysed. First analysis of the two chloroplast microsatellites in seven natural populations of A. alba revealed 36 different haplotypes. The use of these highly polymorphic SSRs as potential markers in population genetics is discussed.