ELIMÄKI locus is required for mechanosensing and proprioception in birch trees

AbstractThe remarkable vertical and radial growth observed in tree species, encompasses a major physical challenge for wood forming tissues. To compensate with increasing size and weight, cambium-derived radial growth increases the stem width, thereby supporting the aerial body of trees. This feedback appears to be part of a so-called “proprioception” (1, 2) mechanism that controls plant size and biomass allocation. Yet, how trees experience or respond to mechanical stress derived from their own vertical loading, remains unknown. Here, we combined two strategies to dissect the proprioceptive response in birch. First, we show that in response to physical loading, trees promote radial growth with different magnitudes along the stem. Next, we identified a mutant cultivar (B. pubescens cv. Elimäki) in which the main stem shows normal vertical development, but collapses after three months. By inducing precocious flowering, we generated a backcrossed population (BC1) by producing two generations in 4 years. In his scheme, we uncovered a recessive trait (eki) that segregates and genetically maps with a Mendelian monogenic pattern. Unlike WT, eki is resistant to vertical mechanical stimulation. However, eki responds normally to the gravitropic stimulus by making tension wood. Before the collapse, cell size in eki is compromised resulting in radial growth defects, depending on stem height. Cell walls of developing xylem and phloem tissues have delayed differentiation in eki, and its tissues are softer compared to WT as indicated by atomic force microscopy (AFM). The transcriptomic profile of eki highlighted the overlap with that of the Arabidopsis response to touch. Taken together, our results suggest that the mechanical environment and cell wall properties of developing woody tissues, can significantly affect the growth responses to vertical loading thereby compromising their proprioceptive capacity. Additionally, we introduce a fast forward genetics strategy to dissect complex phenotypes in trees.

Download Full-text

Growth of Bauhinia thonningii trees and saplings over a decade in a savanna in Zambia: interactions of climate, fire and source of regeneration

Journal of Tropical Ecology ◽

10.1017/s0266467408005099 ◽

2008 ◽

Vol 24 (4) ◽

pp. 407-415 ◽

Cited By ~ 5

Author(s):

Emmanuel Ngulube Chidumayo

Keyword(s):

Radial Growth ◽

Plant Size ◽

Height Growth ◽

Dry Season ◽

Tree Size ◽

Maximum Temperature ◽

Climate Factors ◽

Growth Responses ◽

Hot Dry Season ◽

Cool Dry Season

AbstractThe present study investigated how climate and plant size affect the growth of Bauhinia thonningii and how fire and source of regeneration (grown from coppice versus seedlings) might modify the results. The study was conducted over a period of 10 y, from 1997 to 2007, at a savanna site in central Zambia. Trees were marked and monitored throughout the entire period; they showed a phase of declining growth (1998–2003) and a phase of low growth (2004–2007). During the phase of declining growth autocorrelation was high but either weakened or disappeared during the phase of low growth. After adjusting data for autocorrelation, climate factors and tree size accounted for between 14% and 35% of the variation in annual tree radial growth. However, the growth responses of trees to climate factors and tree size varied with the source of regeneration (i.e. coppice or seedling) and fire treatment. Trees of seedling origin were only affected by climate factors and tree size when exposed to annual burning whereas all trees of coppice origin were significantly affected by climate factors and tree size, regardless of the fire treatment. However, basal radial growth of saplings that were monitored for 4 y (2003–2007) was significantly influenced by maximum temperature and rainfall that accounted for 33–47% of the variance in annual radial growth under fire protection. Saplings recovered from shoot die-back during the cool dry season by resprouting in the hot dry season and this annual die-back slowed the height growth of B. thonningii saplings.

Download Full-text

Radial Growth Responses to Temperature by 58ChaetomiumSpecies, and Some Taxonomic Relationships

Mycologia ◽

10.1080/00275514.1977.12020087 ◽

1977 ◽

Vol 69 (3) ◽

pp. 492-502 ◽

Cited By ~ 10

Author(s):

P. D. Millner

Keyword(s):

Radial Growth ◽

Growth Responses ◽

Taxonomic Relationships

Download Full-text

Radial Growth Response of European Larch Provenances to Interannual Climate Variation in Poland

Forests ◽

10.3390/f12030334 ◽

2021 ◽

Vol 12 (3) ◽

pp. 334

Author(s):

Norbert Szymański ◽

Sławomir Wilczyński

Keyword(s):

Radial Growth ◽

Climatic Factors ◽

Principal Component ◽

Climatic Conditions ◽

Growth Responses ◽

European Larch ◽

Temperature And Precipitation ◽

Provenance Trials ◽

High Precipitation ◽

Climatic Elements

The present study identified the similarities and differences in the radial growth responses of 20 provenances of 51-year-old European larch (Larix decidua Mill.) trees from Poland to the climatic conditions at three provenance trials situated in the Polish lowlands (Siemianice), uplands (Bliżyn) and mountains (Krynica). A chronology of radial growth indices was developed for each of 60 European larch populations, which highlighted the interannual variations in the climate-mediated radial growth of their trees. With the aid of principal component, correlation and multiple regression analysis, supra-regional climatic elements were identified to which all the larch provenances reacted similarly at all three provenance trials. They increased the radial growth in years with a short, warm and precipitation-rich winter; a cool and humid summer and when high precipitation in late autumn of the previous year was noted. Moreover, other climatic elements were identified to which two groups of the larch provenances reacted differently at each provenance trial. In the lowland climate, the provenances reacted differently to temperature in November to December of the previous year and July and to precipitation in September. In the upland climate, the provenances differed in growth sensitivity to precipitation in October of the previous year and June–September. In the mountain climate, the provenances responded differently to temperature and precipitation in September of the previous year and to precipitation in February, June and September of the year of tree ring formation. The results imply that both climatic factors and origin (genotype), i.e., the genetic factor, mediate the climate–growth relationships of larch provenances.

Download Full-text

Radial growth responses of two dominant conifers to climate in the Altai Mountains, Central Asia

Agricultural and Forest Meteorology ◽

10.1016/j.agrformet.2020.108297 ◽

2021 ◽

Vol 298-299 ◽

pp. 108297

Author(s):

Jian Kang ◽

Shaowei Jiang ◽

Jacques C. Tardif ◽

Hanxue Liang ◽

Shaokang Zhang ◽

...

Keyword(s):

Central Asia ◽

Radial Growth ◽

Altai Mountains ◽

Growth Responses

Download Full-text

Climate Differently Impacts the Growth of Coexisting Trees and Shrubs under Semi-Arid Mediterranean Conditions

Forests ◽

10.3390/f12030381 ◽

2021 ◽

Vol 12 (3) ◽

pp. 381

Author(s):

J. Julio Camarero ◽

Cristina Valeriano ◽

Antonio Gazol ◽

Michele Colangelo ◽

Raúl Sánchez-Salguero

Keyword(s):

Soil Moisture ◽

Radial Growth ◽

Pinus Halepensis ◽

Growth Dynamics ◽

Early Summer ◽

Growth Responses ◽

Shrub Species ◽

High Soil Moisture ◽

Semi Arid ◽

Mediterranean Conditions

Background and Objectives—Coexisting tree and shrub species will have to withstand more arid conditions as temperatures keep rising in the Mediterranean Basin. However, we still lack reliable assessments on how climate and drought affect the radial growth of tree and shrub species at intra- and interannual time scales under semi-arid Mediterranean conditions. Materials and Methods—We investigated the growth responses to climate of four co-occurring gymnosperms inhabiting semi-arid Mediterranean sites in northeastern Spain: two tree species (Aleppo pine, Pinus halepensis Mill.; Spanish juniper, Juniperus thurifera L.) and two shrubs (Phoenicean juniper, Juniperus phoenicea L.; Ephedra nebrodensis Tineo ex Guss.). First, we quantified the intra-annual radial-growth rates of the four species by periodically sampling wood samples during one growing season. Second, we quantified the climate–growth relationships at an interannual scale at two sites with different soil water availability by using dendrochronology. Third, we simulated growth responses to temperature and soil moisture using the forward, process-based Vaganov‒Shashkin (VS-Lite) growth model to disentangle the main climatic drivers of growth. Results—The growth of all species peaked in spring to early summer (May–June). The pine and junipers grew after the dry summer, i.e., they showed a bimodal growth pattern. Prior wet winter conditions leading to high soil moisture before cambium reactivation in spring enhanced the growth of P. halepensis at dry sites, whereas the growth of both junipers and Ephedra depended more on high spring–summer soil moisture. The VS-Lite model identified these different influences of soil moisture on growth in tree and shrub species. Conclusions—Our approach (i) revealed contrasting growth dynamics of co-existing tree and shrub species under semi-arid Mediterranean conditions and (ii) provided novel insights on different responses as a function of growth habits in similar drought-prone regions.

Download Full-text