Fossil taxa in the family Pinaceae, and their phylogenetic implications

Klymiuk, Ashley Annette

Unknown Date

No description available.

Pinus

Picea

Pinaceae

Fossil taxa in the family Pinaceae, and their phylogenetic implications

Klymiuk, Ashley Annette

11 1900

Although the peak diversity of Pinaceae is reflected by many Cretaceous seed cones representing extinct genera, the oldest definitive record of the family is attributable to an extant genus. A seed cone discovered at the Valanginian Apple Bay locality extends the record of Picea by ~75 Ma, resolving a ghost lineage predicted by molecular dating analyses. However, a pine from the Eocene Princeton Chert indicates that extant genera are themselves relicts of greater historical diversity. Pinus arnoldii Miller is reconstructed here as the first organismal concept for an extinct member of Pinaceae, on the basis of anatomical attachments between the seed cones attributable to Subgenus Pinus, and vegetation like that of Subgenus Strobus. The phylogenetic implications of these fossils are assessed through cladistic analyses, and comparisons with maximum likelihood ancestral states reconstructed on topologies derived from Bayesian cpDNA analysis of extant Pinus and Picea. / in Systematics & Evolution

Pinus

Picea

Pinaceae

Studium vlivu iontů vybraných kovů na kulturu raných somatických embryí smrku

Petřek, Jiří

January 2006

Angl. resumé

somatická embrya; ionty; smrk (Picea)

Transport růstových regulátorů při indukci somatické embryogeneze u smrku

Vlašínová, Helena

January 2005

Angl. resumé

Stanovení obsahu monoterpenů v silicích smrku ztepilého (Picea abies) pomocí GC/MS

Chvílíčková, Iva

January 2006

No description available.

monoterpeny; smrk ztepilý (Picea abies)

Improving the wood strength of Sitka spruce (Picea sitchensis) through selective breeding

Kennedy, Stuart G.

January 2009

Tree breeders worldwide have highlighted the importance of wood quality within the juvenile core in determining final timber strength. The potential for improving timber strength by estimating genetic parameters of certain wood properties of Sitka spruce (Picea sitchensis) within the outer zone of the juvenile core was investigated. Fifteen trees were sampled from each of 33 families selected from a 20 year old open pollinated progeny trial. A number of wood properties critical to wood strength were measured; namely, density, grain angle, microfibril angle and branching characteristics. Clearwood stiffness and strength along with indirect measures of stiffness using acoustics and density using Pilodyn measurements were assessed. All wood properties were moderately heritable, wood density and acoustic velocity were the most heritable traits (h2 i 0.71 and 0.67 respectively). Genetic correlations showed that wood strength and stiffness were strongly correlated with wood density (0.86 and 1.04 respectively) and microfibril angle (-0.79 and -0.62 respectively). Acoustic velocity was strongly correlated with wood stiffness (0.81) and microfibril angle (- 0.83). The ability to select trees for wood stiffness with the use of acoustics along with the moderate inheritance of this trait should enable improvements in the wood quality of Sitka spruce. Despite the unfavourable correlation between growth rate and some key wood quality traits associated with timber strength, selection of certain families would enable modest gains to be made in both growth rate and wood quality.

634.9

Sitka spruce : Picea sitchensis : Wood

Post-fire recovery and successional dynamics of an old growth red spruce forest in the southern Appalachian Mountains

Krustchinsky, Adam R.

15 May 2009

Red spruce is a shade-tolerant conifer whose distribution and abundance reflect Quaternary climate history as well as natural and anthropogenic disturbances. This species once extended further south than its present localities, because of natural and anthropogenic disturbances such as logging, windthrow, and fire. Little is known about the disturbance regime of this species, because long term stand dynamics are difficult to obtain. This-long lived species is hypothesized to be suffering a decline in radial growth, density and abundance at the present time. Recent research suggests pollution, biotic stresses, climate change and natural stand dynamics are the driving forces behind these decreases. The purpose of this study is to investigate the influence of fire in a mesic ecosystem, specifically a high-elevation red spruce (Picea rubens Sarg.) forest on Whitetop Mountain in the southern Appalachian Mountains. Six plots were established in a high elevation red spruce stand to characterize the stand composition. Tree ring data were collected to investigate radial growth relations to inter-annual climatic variability and cross-sections were used to investigate fire history. Red spruce continued to establish throughout the 19th century until a severe fire occurred in 1919 and caused a new cohort of yellow birch (Betula alleghaniensis Britt.) to establish within the stand. Logging and fire caused high mortality in the stand, yet many spruce remain that outdate the past disturbances. Red spruce saplings continue to persist in the stand, showing regeneration despite the abundant hardwoods. Moisture was the main contributing factor to red spruce growth in the dendroclimatic analysis. Red spruce radial growth was significantly correlated to high precipitation and low temperatures of the previous growing season, which is similar to recent research results. This study collaborates the current literature on red spruce growth along with the results found here in creating a model to represent the growth characteristics of red spruce when inter-mixed with hardwoods after a severe disturbance.

Picea

red spruce

disturbance

succession

climate

The action of sodium sulfite on sprucewood.

Trucano, Peter J. (Peter Joseph)

06 1900

No description available.

Lignins

Spruce

Neutral sulfite pulping

Picea

Post-fire recovery and successional dynamics of an old growth red spruce forest in the southern Appalachian Mountains

Krustchinsky, Adam R.

15 May 2009

Red spruce is a shade-tolerant conifer whose distribution and abundance reflect Quaternary climate history as well as natural and anthropogenic disturbances. This species once extended further south than its present localities, because of natural and anthropogenic disturbances such as logging, windthrow, and fire. Little is known about the disturbance regime of this species, because long term stand dynamics are difficult to obtain. This-long lived species is hypothesized to be suffering a decline in radial growth, density and abundance at the present time. Recent research suggests pollution, biotic stresses, climate change and natural stand dynamics are the driving forces behind these decreases. The purpose of this study is to investigate the influence of fire in a mesic ecosystem, specifically a high-elevation red spruce (Picea rubens Sarg.) forest on Whitetop Mountain in the southern Appalachian Mountains. Six plots were established in a high elevation red spruce stand to characterize the stand composition. Tree ring data were collected to investigate radial growth relations to inter-annual climatic variability and cross-sections were used to investigate fire history. Red spruce continued to establish throughout the 19th century until a severe fire occurred in 1919 and caused a new cohort of yellow birch (Betula alleghaniensis Britt.) to establish within the stand. Logging and fire caused high mortality in the stand, yet many spruce remain that outdate the past disturbances. Red spruce saplings continue to persist in the stand, showing regeneration despite the abundant hardwoods. Moisture was the main contributing factor to red spruce growth in the dendroclimatic analysis. Red spruce radial growth was significantly correlated to high precipitation and low temperatures of the previous growing season, which is similar to recent research results. This study collaborates the current literature on red spruce growth along with the results found here in creating a model to represent the growth characteristics of red spruce when inter-mixed with hardwoods after a severe disturbance.

Picea

red spruce

disturbance

succession

climate

Population Genetics and Genome Organization of Norway Spruce

Larsson, Hanna

January 2012

Understanding the underlying genetic causes of adaptation to local conditions is one of the main goals of population genetics. A strong latitudinal cline in the phenotypic trait of bud set is observed in present day populations of Norway spruce (Picea abies (L.) Karst). The first step towards determining how this strong selection on adaptive traits translates at the loci underlying the trait was to use multilocus sequence data to gain information on the fundamental population genetic properties of Norway spruce. We determined that the level of LD was low and genetic diversity was in the low range. Coalescent simulations revealed a demographic scenario of a fairly old and severe bottleneck as consistent with the observed data. To examine the role of selection at genes putatively involved in the control of bud set we, again, used a multilocus data set to test for deviations from neutrality and demographic scenarios inferred from background loci. Different candidate genes were identified by using different approaches, highlighting the difficulty in predicting how local adaptation will manifest itself on different time scales and in rangewide samples. When examining properties important in the design of association studies, the inevitable next step in identifying genes involved in local adaptation, we found that previous estimates of a low level of LD were highly influenced by the joint analysis of several loci over a large distribution range and that estimates of LD was in fact heterogeneous across loci and increased within populations. In addition, we found that within species tests for deviations from neutral expectations were highly sensitive to sample size. Additional genomic sequence characterization in Norway spruce is necessary to provide more comprehensive sets of markers for association studies, also including gene promoters and non-genic regions of the genome. In the final paper we show that the HMPR method is effective in constructing libraries enriched for the single copy fraction of the genome when applied to the large and dominantly repetitive genome of Norway spruce. In summary, the studies presented in this thesis together constitute a foundation for future studies on adaptive evolution in Norway spruce.

Picea abies

demographic history

linkage disequilibrium

HMPR