Pinus contorta

Common Names: scrub pine, shore pine, tamarack pine, lodgepole pine

Ethnobotanical Studies

1.

Boreal Forest, Canada

Uses: Cough, cold and sore throat, Injuries

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

Studies

1.

The potential of non-native tree species to provide major ecosystem services in Austrian forests.

Konic J et al (2024).; Front Plant Sci.
DOI:: 10.3389/fpls.2024.1402601
PubMed:: 39011308

2.

Factors limiting the potential range expansion of lodgepole pine in Interior Alaska.

Walker XJ et al (2024).; Ecol Appl.
DOI:: 10.1002/eap.2983
PubMed:: 38840517

3.

Temperature dependence of pollen germination and tube growth in conifers relates to their distribution along an elevational gradient in Washington State, USA.

Hsu HW and Kim SH (2024).; Ann Bot.
DOI:: 10.1093/aob/mcae079
PubMed:: 38808688

4.

Water quality effects of peat rewetting and leftover conifer brash, following peatland restoration and tree harvesting.

Gaffney PPJ et al (2024).; J Environ Manage.
DOI:: 10.1016/j.jenvman.2024.121141
PubMed:: 38781874

5.

Pine needle abortions in cattle due to consumption of Pinus ponderosa in Argentina: Case reports.

Martinez A et al (2024).; Toxicon.
DOI:: 10.1016/j.toxicon.2024.107712
PubMed:: 38614243

6.

Unraveling the multifaceted effects of climatic factors on mountain pine beetle and its interaction with fungal symbionts.

Zaman R et al (2024).; Glob Chang Biol.
DOI:: 10.1111/gcb.17207
PubMed:: 38413744

7.

Distribution of Cronartium x flexili, an interspecific hybrid of two fungal tree rust pathogens, in subalpine forest ecosystems of western USA.

Kozhar O et al (2024).; Fungal Biol.
DOI:: 10.1016/j.funbio.2023.11.005
PubMed:: 38341263

8.

Evidence that Ophiostomatoid fungal symbionts of mountain pine beetle do not play a role in overcoming lodgepole pine defenses during mass attack.

Fortier CE et al (2024).; Mol Plant Microbe Interact.
DOI:: 10.1094/MPMI-06-23-0077-R
PubMed:: 38240660

9.

Can the Seed Trade Provide a Potential Pathway for the Global Distribution of Foliar Pathogens? An Investigation into the Use of Heat Treatments to Reduce Risk of Dothistroma septosporum Transmission via Seed Stock.

Tubby K et al (2023).; J Fungi (Basel).
DOI:: 10.3390/jof9121190
PubMed:: 38132790

10.

A Pine in Distress: How Infection by Different Pathogenic Fungi Affect Lodgepole Pine Chemical Defenses.

Zaman R et al (2023).; Microb Ecol.
DOI:: 10.1007/s00248-023-02272-0
PubMed:: 37486583

11.

Oviposition substrate location by the invasive woodwasp Sirex noctilio: The combined effect of chemical cues emitted by its obligate symbiont Amylostereum areolatum and different host-tree species.

Masagué S et al (2023).; Pest Manag Sci.
DOI:: 10.1002/ps.7596
PubMed:: 37273195

12.

Peeking under the canopy: anomalously short fire-return intervals alter subalpine forest understory plant communities.

Kiel NG, Braziunas KH and Turner MG (2023).; New Phytol.
DOI:: 10.1111/nph.19009
PubMed:: 37259635

13.

Stomatal, mesophyll and biochemical limitations to photosynthesis and their relationship with leaf structure over an elevation gradient in two conifers.

Guo J et al (2023).; Photosynth Res.
DOI:: 10.1007/s11120-023-01022-0
PubMed:: 37212937

14.

Beauveria bassiana exhibits strong virulence against Dendroctonus ponderosae in greenhouse and field experiments.

Fernandez KX et al (2023).; Appl Microbiol Biotechnol.
DOI:: 10.1007/s00253-023-12499-z
PubMed:: 37017732

15.

Gymnosperms of Idaho: Chemical Compositions and Enantiomeric Distributions of Essential Oils of Abies lasiocarpa, Picea engelmannii, Pinus contorta, Pseudotsuga menziesii, and Thuja plicata.

Swor K et al (2023).; Molecules.
DOI:: 10.3390/molecules28062477
PubMed:: 36985451

16.

Less fuel for the next fire? Short-interval fire delays forest recovery and interacting drivers amplify effects.

Braziunas KH, Kiel NG and Turner MG (2023).; Ecology.
DOI:: 10.1002/ecy.4042
PubMed:: 36976178

17.

Regeneration strategies and forest resilience to changing fire regimes: Insights from a Goldilocks model.

Ramiadantsoa T, Ratajczak Z and Turner MG (2023).; Ecology.
DOI:: 10.1002/ecy.4041
PubMed:: 36964987

18.

Naïve Pine Terpene Response to the Mountain Pine Beetle (Dendroctonus ponderosae) through the Seasons.

Musso AE et al (2023).; J Chem Ecol.
DOI:: 10.1007/s10886-023-01418-1
PubMed:: 36929332

19.

Bark Beetles Utilize Ophiostomatoid Fungi to Circumvent Host Tree Defenses.

Zaman R et al (2023).; Metabolites.
DOI:: 10.3390/metabo13020239
PubMed:: 36837858

20.

Decoupling of height growth and drought or pest resistance tradeoffs is revealed through multiple common-garden experiments of lodgepole pine.

Liu Y et al (2023).; Evolution.
DOI:: 10.1093/evolut/qpad004
PubMed:: 36637132

21.

Predicting the impact of invasive trees from different measures of abundance.

Moyano J et al (2023).; J Environ Manage.
DOI:: 10.1016/j.jenvman.2022.116480
PubMed:: 36306626

22.

Predictive accuracy of post-fire conifer death declines over time in models based on crown and bole injury.

Shearman TM et al (2023).; Ecol Appl.
DOI:: 10.1002/eap.2760
PubMed:: 36218008

23.

Essential Oil Compositions of Pinus Species (P. contorta Subsp. contorta, P. ponderosa var. ponderosa, and P. flexilis); Enantiomeric Distribution of Terpenoids in Pinus Species.

Ankney E et al (2022).; Molecules.
DOI:: 10.3390/molecules27175658
PubMed:: 36080426

24.

Pest defences under weak selection exert a limited influence on the evolution of height growth and drought avoidance in marginal pine populations.

Liu Y et al (2022).; Proc Biol Sci.
DOI:: 10.1098/rspb.2022.1034
PubMed:: 36069017

25.

Development of PCR-based markers for the identification and detection of Lophodermella needle cast pathogens on Pinus contorta var. latifolia and P. flexilis.

Ata JP et al (2022).; J Microbiol Methods.
DOI:: 10.1016/j.mimet.2022.106546
PubMed:: 35931227

26.

Using landscape genomics to delineate seed and breeding zones for lodgepole pine.

Genetics

Yu Y et al (2022).; New Phytol.
DOI:: 10.1111/nph.18223
PubMed:: 35569109

27.

Evaluating the accuracy of variant calling methods using the frequency of parent-offspring genotype mismatch.

Genetics

Jasper RJ et al (2022).; Mol Ecol Resour.
DOI:: 10.1111/1755-0998.13628
PubMed:: 35510784

28.

Evidence of Coevolution Between Cronartium harknessii Lineages and Their Corresponding Hosts, Lodgepole Pine and Jack Pine.

McAllister CH et al (2022).; Phytopathology.
DOI:: 10.1094/PHYTO-09-21-0370-R
PubMed:: 35166574

29.

Host Defense Metabolites Alter the Interactions between a Bark Beetle and its Symbiotic Fungi.

Agbulu V et al (2022).; Microb Ecol.
DOI:: 10.1007/s00248-021-01894-6
PubMed:: 34674014

30.

Soil biotic and abiotic effects on seedling growth exhibit context-dependent interactions: evidence from a multi-country experiment on Pinus contorta invasion.

Nuske SJ et al (2021).; New Phytol.
DOI:: 10.1111/nph.17449
PubMed:: 33966267

31.

Comparative Gene Expression Analysis Reveals Mechanism of Pinus contorta Response to the Fungal Pathogen Dothistroma septosporum.

Lu M et al (2021).; Mol Plant Microbe Interact.
DOI:: 10.1094/MPMI-10-20-0282-R
PubMed:: 33258711

32.

Variation in Aquaporin and Physiological Responses Among Pinus contorta Families Under Different Moisture Conditions.

Khan S et al (2019).; Plants (Basel).
DOI:: 10.3390/plants8010013
PubMed:: 30621354

33.

Cambial injury in lodgepole pine (Pinus contorta): mountain pine beetle vs fire.

Arbellay E et al (2017).; Tree Physiol.
DOI:: 10.1093/treephys/tpx102
PubMed:: 29121262

34.

Pinus contorta invasions increase wildfire fuel loads and may create a positive feedback with fire.

Taylor KT et al (2017).; Ecology.
DOI:: 10.1002/ecy.1673
PubMed:: 27935641

35.

Belowground legacies of Pinus contorta invasion and removal result in multiple mechanisms of invasional meltdown.

Dickie IA et al (2014).; AoB Plants.
DOI:: 10.1093/aobpla/plu056
PubMed:: 25228312

36.

Identification and expression of the chloroplast clpP gene in the conifer Pinus contorta.

Clarke AK, Gustafsson P and Lidholm JA (1994).; Plant Mol Biol.
PubMed:: 7999999