Cold adaptation drives variability in needle structure and anatomy in <i><scp>P</scp>inus sylvestris</i> L. along a 1,900 km temperate–boreal transect

Jankowski, Aleksander; Wyka, Tomasz P.; Żytkowiak, Roma; Nihlgård, Bengt; Oleksyn, Jacek

doi:10.1111/1365-2435.12946

Cited by 40 publications

(31 citation statements)

References 73 publications

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“…Resin duct number decreased and relative duct area increased in the wood of trees growing at increasing elevation ( Figure 4) consistent with Wimmer and Grabner's [56] report of fewer resin ducts of Norway spruce from cooler habitats (Picea abies L.). Likewise, the increase in relative duct area with increasing elevation (and therefore lower air temperature; [57]), is similar to the linear relationship between relative duct area in needles and minimum air temperature in Scots pine (P. sylvestris L.) [58] yet different from the curvilinear response of needle duct traits to elevation of P. taiwanensis Hayata [59]. Limber pine invests more in resin duct defenses per unit radial wood growth with increasing elevation, however, resin flow is better predicted by resin duct number and area [24] which decreased in our study with increasing elevation.…”

Section: Discussionsupporting

confidence: 52%

Is Resistance to Mountain Pine Beetle Associated with Genetic Resistance to White Pine Blister Rust in Limber Pine?

Holtz

Schoettle

2018

Forests

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Limber pine (Pinus flexilis James) co-evolved with the mountain pine beetle (Dendroctonus ponderosae Hopkins; MPB) and is now also challenged by the non-native pathogen Cronartium ribicola (J.C. Fisch.) that causes the lethal disease white pine blister rust (WPBR). Previous research suggests that trees infected with WPBR can be preferred hosts for MPB. Using resin duct traits associated with MPB resistance, we tested for a relationship between resistance to MPB and WPBR in limber pine, in the absence of either biological agent. These analyses will help evaluate if MPB historically may have contributed to natural selection for WPBR resistance in advance of WPBR invasion, and could help explain the unusually high frequency of the dominant Cr4 allele for complete resistance to WPBR in limber pine populations of the Southern Rocky Mountains. Resin duct production, density and relative duct area did not differ between healthy trees previously inferred to carry the dominant Cr4 allele and trees that lack it at 22 sites, though some duct traits varied with elevation. MPB resistance does not appear to have played an evolutionary role in contributing to the high frequency of Cr4 in naïve populations, however, MPB may affect the future evolution of resistance to WPBR in the pines where the two pests coincide and WPBR will affect forest recovery after MPB epidemics. MPB-WPBR interactions in a changing climate will affect the future trajectory of limber pine.

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Section: Discussionsupporting

confidence: 52%

Is Resistance to Mountain Pine Beetle Associated with Genetic Resistance to White Pine Blister Rust in Limber Pine?

Holtz

Schoettle

2018

Forests

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“…There could be mechanical and chemical reasons for the preference of pine needles: Pine needles may have a mechanical advantage in size and structure over individual spruce needles, as pine needles are usually found as a bundle of 2-3 extremely narrow needles per sheath covering the base of the needle bundle. In addition, a greater thickness of outer epidermal walls of pine needles can support mechanical strength and protect the pine needles from desiccation, especially in winter (Jankowski et al 2017). This can support the durability of the nest building material.…”

Section: Nest Building Materialsmentioning

confidence: 99%

“…This could additionally contribute to longevity of the nest cover. From a chemical point of view, the thick-walled epidermis contributes to the defense against herbivores by forming specialized resin channels (Jankowski et al 2017). Resin is an important component of RWA nests because of its stabilizing and antibacterial effect (Christe et al 2003).…”

Section: Nest Building Materialsmentioning

confidence: 99%

Red Wood Ants prefer mature Pine Forests in Variscan Granite Environments (Formica rufa-group)

Mb²,

Gibhardt

2020

Preprint

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0AbstractWe used presence/absence data of 5,160 red wood ant nests (RWA; Formica polyctena) acquired in a systematic large-scale area-wide survey in two study areas (≈350 ha) in the Oberpfalz, NE Bavaria, Germany to explore for the first time the influence of variable (e.g., forest type, tree age) and quasi-invariant factors (e.g., tectonics, geochemical composition of the bedrock) on nest size, spatial distribution and nest density for Variscan granites. A combination of the forest type (mature pine-dominated forests (≥80–140 years) as main variable factor and the geochemical property of the Variscan granites with their high natural Radon potential and moderate heat production as main quasi-invariant factor could explain the high nest numbers in both study areas. In addition, the spatially clustered distribution patterns of the observed nests suggest a strong interaction between nests and their quasi-invariant environment, especially the directionality of the present-day stress field and the direction of the tectonically formed “Erbendorfer Line”. In general, such a combination of variable and quasi-invariant factors can be addressed as particularly favorable RWA habitats.

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“…Generally, needlelike leaves appear to be more drought-resistant than flattened leaves [ 5 , 6 ]. Previous studies on conifer “needles” have evaluated their morphology and physiology [ 7 – 9 ] but rarely focused on their developmental mechanisms and evolution. Pinaceae (the pine family), comprising 11 genera and approximately 230 species, is the most important component of the coniferous forests in the Northern Hemisphere, with both needlelike and flattened leaves [ 4 , 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

The flattened and needlelike leaves of the pine family (Pinaceae) share a conserved genetic network for adaxial-abaxial polarity but have diverged for photosynthetic adaptation

Ran

Feng

et al. 2020

BMC Evol Biol

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Background Leaves have highly diverse morphologies. However, with an evolutionary history of approximately 200 million years, leaves of the pine family are relatively monotonous and often collectively called “needles”, although they vary in length, width and cross-section shapes. It would be of great interest to determine whether Pinaceae leaves share similar morpho-physiological features and even consistent developmental and adaptive mechanisms. Results Based on a detailed morpho-anatomical study of leaves from all 11 Pinaceae genera, we particularly investigated the expression patterns of adaxial-abaxial polarity genes in two types of leaves (needlelike and flattened) and compared their photosynthetic capacities. We found that the two types of leaves share conserved spatial patterning of vasculatures and genetic networks for adaxial-abaxial polarity, although they display different anatomical structures in the mesophyll tissue differentiation and distribution direction. In addition, the species with needlelike leaves exhibited better photosynthetic capacity than the species with flattened leaves. Conclusions Our study provides the first evidence for the existence of a conserved genetic module controlling adaxial-abaxial polarity in the development of different Pinaceae leaves.

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Cold adaptation drives variability in needle structure and anatomy in Pinus sylvestris L. along a 1,900 km temperate–boreal transect

Cited by 40 publications

References 73 publications

Is Resistance to Mountain Pine Beetle Associated with Genetic Resistance to White Pine Blister Rust in Limber Pine?

Is Resistance to Mountain Pine Beetle Associated with Genetic Resistance to White Pine Blister Rust in Limber Pine?

Red Wood Ants prefer mature Pine Forests in Variscan Granite Environments (Formica rufa-group)

The flattened and needlelike leaves of the pine family (Pinaceae) share a conserved genetic network for adaxial-abaxial polarity but have diverged for photosynthetic adaptation

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