Picea glauca

Common Names: Black Hills spruce, Canadian spruce, cat spruce, skunk spruce, western white spruce, white spruce

Ethnobotanical Studies

Boreal Forest, Canada

Uses: Blood system disorders, Cough, cold and sore throat, Dermatological infections, Diabetes, Fainting and fits, Fever, Gastro-intestinal disorders, General health, Headache, Injuries, Musculoskeletal disorders, Odontological problems, Ophthalmological disorders, Poisoning, Pregnancy, child birth, puerperium, Respiratory system disorders, Urinary system disorders

DOI:: 10.1186/1746-4269-8-7
PubMed:: 22289509

Studies

Plant Defensin PgD1 a Biotechnological Alternative Against Plant Pathogens.

de Bem Matos AC et al (2024).; Probiotics Antimicrob Proteins.
DOI:: 10.1007/s12602-024-10333-0
PubMed:: 39243352

ToTE: A global database on trees of the treeline ecotone.

Dar FA et al (2024).; Ecology.
DOI:: 10.1002/ecy.4309
PubMed:: 38724027

Complementary roles of two classes of defense chemicals in white spruce against spruce budworm.

Ullah A, Klutsch JG and Erbilgin N (2024).; Planta.
DOI:: 10.1007/s00425-024-04383-5
PubMed:: 38551685

Limited Differences in Insect Herbivory on Young White Spruce Growing in Small Open Plantations and under Natural Canopies in Boreal Mixed Forests.

Yataco AP et al (2024).; Insects.
DOI:: 10.3390/insects15030196
PubMed:: 38535391

Young temperate tree species show different fine root acclimation capacity to growing season water availability.

Jaeger FC et al (2024).; Plant Soil.
DOI:: 10.1007/s11104-023-06377-w
PubMed:: 38510944

Contrasting physiological strategies explain heterogeneous responses to severe drought conditions within local populations of a widespread conifer.

Depardieu C et al (2024).; Sci Total Environ.
DOI:: 10.1016/j.scitotenv.2024.171174
PubMed:: 38402972

High-density genetic linkage mapping in Sitka spruce advances the integration of genomic resources in conifers.

Tumas H et al (2024).; G3 (Bethesda).
DOI:: 10.1093/g3journal/jkae020
PubMed:: 38366548

Long-insert sequence capture detects high copy numbers in a defence-related beta-glucosidase gene βglu-1 with large variations in white spruce but not Norway spruce.

Summary

This study examines CNV of defense genes in conifers against insects, using a probe set to measure gene copy numbers. Results shed light on the constitutive defense mechanisms in white spruce. Further research on CNV emergence and phenotype effects is suggested.

Genetics

Hung TH et al (2024).; BMC Genomics.
DOI:: 10.1186/s12864-024-09978-6
PubMed:: 38281030

The phenotypic and genetic effects of drought-induced stress on wood specific conductivity and anatomical properties in white spruce seedlings, and relationships with growth and wood density.

Soro A et al (2023).; Front Plant Sci.
DOI:: 10.3389/fpls.2023.1297314
PubMed:: 38186604

10.

Differences in photoprotective strategy during winter in Eastern white pine and white spruce.

Verhoeven A and Kornkven J (2023).; Tree Physiol.
DOI:: 10.1093/treephys/tpad131
PubMed:: 37861656

11.

Linkage between growth phenology and climate-growth responses along landscape gradients in boreal forests.

Tumajer J, Altman J and Lehejček J (2023).; Sci Total Environ.
DOI:: 10.1016/j.scitotenv.2023.167153
PubMed:: 37730045

12.

Increasing genomic prediction accuracy for unphenotyped full-sib families by modeling additive and dominance effects with large datasets in white spruce.

Nadeau S et al (2023).; Front Plant Sci.
DOI:: 10.3389/fpls.2023.1137834
PubMed:: 37035077

13.

Density-dependent plasticity in territoriality revealed using social network analysis.

Webber QMR et al (2023).; J Anim Ecol.
DOI:: 10.1111/1365-2656.13846
PubMed:: 36385608

14.

Hydraulic integrity of plant organs during drought stress and recovery in herbaceous and woody plant species.

Huber AE, Melcher PJ and Bauerle TL (2023).; J Exp Bot.
DOI:: 10.1093/jxb/erac451
PubMed:: 36371803

15.

On the significance of long-term trends in tree-ring N isotopes - The interplay of soil conditions and regional NOx emissions.

Savard MM et al (2023).; Sci Total Environ.
DOI:: 10.1016/j.scitotenv.2022.159580
PubMed:: 36280071

16.

Vertical gradients in photosynthetic physiology diverge at the latitudinal range extremes of white spruce.

Schmiege SC et al (2023).; Plant Cell Environ.
DOI:: 10.1111/pce.14448
PubMed:: 36151613

17.

Genetic basis of growth reaction to drought stress differs in contrasting high-latitude treeline ecotones of a widespread conifer.

Zacharias M et al (2022).; Mol Ecol.
DOI:: 10.1111/mec.16648
PubMed:: 35951000

18.

Even modest climate change may lead to major transitions in boreal forests.

Reich PB et al (2022).; Nature.
DOI:: 10.1038/s41586-022-05076-3
PubMed:: 35948640

19.

Sufficient conditions for rapid range expansion of a boreal conifer.

Dial RJ et al (2022).; Nature.
DOI:: 10.1038/s41586-022-05093-2
PubMed:: 35948635

20.

Tree Maladaptation Under Mid-Latitude Early Spring Warming and Late Cold Spell: Implications for Assisted Migration.

Benomar L et al (2022).; Front Plant Sci.
DOI:: 10.3389/fpls.2022.920852
PubMed:: 35874013

21.

Spruce giga-genomes: structurally similar yet distinctive with differentially expanding gene families and rapidly evolving genes.

Genetics

Gagalova KK et al (2022).; Plant J.
DOI:: 10.1111/tpj.15889
PubMed:: 35789009

22.

Applying space-for-time substitution to infer the growth response to climate may lead to overestimation of tree maladaptation: Evidence from the North American White Spruce Network.

Wu F et al (2022).; Glob Chang Biol.
DOI:: 10.1111/gcb.16304
PubMed:: 35714046

23.

Effect of Drought and Methyl Jasmonate Treatment on Primary and Secondary Isoprenoid Metabolites Derived from the MEP Pathway in the White Spruce Picea glauca.

Perreca E et al (2022).; Int J Mol Sci.
DOI:: 10.3390/ijms23073838
PubMed:: 35409197

24.

Efficient Multi-Sites Genome Editing and Plant Regeneration via Somatic Embryogenesis in Picea glauca.

Genetics

Cui Y et al (2021).; Front Plant Sci.
DOI:: 10.3389/fpls.2021.751891
PubMed:: 34721480

25.

Defensive Traits during White Spruce (Picea glauca) Leaf Ontogeny.

Lirette AO and Despland E (2021).; Insects.
DOI:: 10.3390/insects12070644
PubMed:: 34357304

26.

Tryblidiopsis magnesii sp. nov. from Picea glauca in Eastern Canada.

Tanney JB and Seifert KA (2019).; Fungal Syst Evol.
DOI:: 10.3114/fuse.2019.04.02
PubMed:: 32467903

27.

Organellar Genomes of White Spruce (Picea glauca): Assembly and Annotation.

Genetics

Jackman SD et al (2015).; Genome Biol Evol.
DOI:: 10.1093/gbe/evv244
PubMed:: 26645680

28.

Insights into conifer giga-genomes.

Review Genetics

De La Torre AR et al (2014).; Plant Physiol.
DOI:: 10.1104/pp.114.248708
PubMed:: 25349325

29.

Evolution of gene structure in the conifer Picea glauca: a comparative analysis of the impact of intron size.

Stival Sena J et al (2014).; BMC Plant Biol.
DOI:: 10.1186/1471-2229-14-95
PubMed:: 24734980

30.

Exploring Picea glauca aquaporins in the context of needle water uptake and xylem refilling.

Laur J and Hacke UG (2014).; New Phytol.
DOI:: 10.1111/nph.12806
PubMed:: 24702644

31.

Adaptation and exogenous selection in a Picea glauca × Picea engelmannii hybrid zone: implications for forest management under climate change.

De La Torre AR et al (2014).; New Phytol.
DOI:: 10.1111/nph.12540
PubMed:: 24200028

32.

Purine and pyrimidine nucleotide synthesis and degradation during in vitro morphogenesis of white spruce (Picea glauca).

Review Genetics

Stasolla C and Thorpe TA (2004).; Front Biosci.
PubMed:: 14977562