Swiss Federal Institute for Forest, Snow and Landscape Research WSL

For trees, growing should not be confused with putting on weight

In coniferous forests across the Northern Hemisphere, woody biomass production does not occur at the same time or rate as changes in tree stem size. This phenomenon presented in this month’s issue of Nature Plants was demonstrated and quantified by a large consortium of researchers including three members of the Swiss Federal Research Institute WSL.

Abb. 1. Forschende der WSL untersuchen im Lötschental, Kanton Wallis, seit 2007 das Holzwachstum von Fichten und Lärchen an 9 Standorten. Diese liegen entlang eines Höhengradienten zwischen 800 und 2200 m Meereshöhe. Klicken Sie auf das Bild, um es zu vergrössern. Foto: WSL
Fig. 1. WSL scientists have been monitoring wood formation in Norway spruce and European Larch since 2007 at 9 sites along an altitudinal gradient from 800 to 2200 m ASL in the Loetschental valley (Valais, Switzerland). Click on photo to enlarge. Photo: WSL
Abb. 2. Automatisch messende Dendrometer, im Bild an einer Lärche im Lötschental (Kanton Wallis, Schweiz), messen und speichern den Stammumfang alle 30 Minuten. Die Forschenden können auf diese Weise die Dynamik der Umfangschwankungen verfolgen. Klicken Sie auf das Bild, um es zu vergrössern. Foto: Henri Cuny, WSL
Fig. 2. Automatic dendrometers such as this one installed on a European larch in the Lötschental automatically measure and record stem circumference every 30 minutes, thus allowing scientists to monitor the dynamics of stem-girth variations. Click on photo to enlarge. Photo: Henri Cuny, WSL
Abb. 3. - Mit einem dünnen Spezialbohrer werden den untersuchten Bäumen 2 mm dicke und 1.5 cm lange Holzbohrkerne entnommen. Die Probeentnahme kann während einer Vegetationszeit am gleichen Baum wiederholt werden, um das Holzwachstum mit hoher zeitlicher Auflösung zu verfolgen. Klicken Sie auf das Bild, um es zu vergrössern. Foto: Henri Cuny, WSL
Fig. 3. Microcores of 2 mm in diameter and 1.5 cm in length (as the one visible here in the extracting chamber of the tool used) are collected using a very small borer. The sampling can thus be repeated on the same tree during the growing season to monitor wood formation with a high temporal resolution. Click on photo to enlarge. Photo: Henri Cuny, WSL
Abb. 4. - Anatomischer Querschnitt durch einen dünnen Holzbohrkern, wie er unter einem optischen Mikroskop mit 100-facher Vergrösserung sichtbar ist. Der Querschnitt zeigt die für Koniferen typischen Holzzellen, die Tracheiden. Wenn diese vom Kambium (C) gebildet werden, wachsen sie und verfestigen ihre Zellwände. Dieser Prozess ist die Grundlage für den signifikanten Zeitunterschied zwischen dem Zuwachs an Stammgrösse und seiner Biomasse. Klicken Sie auf die Grafik, um sie zu vergrössern. Grafik: Henri Cuny, WSL
Fig. 4. Anatomical section of wood realised from a microcore and observed with an optical microscope (× 100). The section contains the typical conifer wood cells, the tracheids. Once these tracheids have been produced by the cambium (C), they enlarge and then reinforce their walls. This developmental sequence is the basis for the significant time lag between the increase in size and the increase in biomass of tree stems. Click on graph to enlarge. Graph: Henri Cuny, WSL
Abb. 5. Jahreszeitliche Dynamik des Wachstums von Stammumfang, Holzzellengrösse (Xylem) und Produktion der Holzbiomasse. A. Variation des von ausserhalb des Stammes mit Dendrometern gemessenem Radialzuwachses. B. Wachstumsrate der Holzzellen, ermittelt aus den Zellmessungen während der Holzbildung. C. Biomasseproduktion, ermittelt aus den Zellmessungen während der Holzbildung. Klicken Sie auf die Grafik, um sie zu vergrössern. Grafik: Henri Cuny, WSL
Fig. 5. Seasonal dynamics of stem-girth increase, xylem size increase, and woody biomass production. A. Stem radial variations calculated from the external measurements with dendrometers. B. Rate of xylem size increase calculated from the cellular observation of wood formation. C. Rate of woody biomass production calculated from the cellular observation of wood formation. Click on graph to enlarge. Graph: Henri Cuny, WSL

The time lag observed between changes in tree size and tree mass suggests that these two growth processes exhibit different sensitivities to local environmental conditions such as light, temperature or water availability. These findings have crucial implications for our understanding of carbon cycle.

After years of monitoring of tree growth at the cellular scale, the researchers found that during the growing season, the woody biomass production lags behind stem-girth increase by about one month. This key result was presented in an international study led by Henri Cuny, formerly employed by the French National Institute for Agricultural Research INRA and currently working at the Swiss Federal Institute for Forest, Snow and Landscape Research WSL.

These findings are based upon thousands of cellular observations of wood formation and meteorological data collected at three sites in the Vosges mountains (northeastern France), and complemented by data from over 50 research sites spread across the Northern Hemisphere.

One important site in this network lies in the Lötschental valley, in Valais, Switzerland, along an altitudinal gradient from 800 to 2200 meters ASL. Since 2007, WSL researchers have been conducting high-resolution monitoring of wood formation in Norway spruce and European Larch, two emblematic Swiss species.

Tracking down wood formation with help of microcores

The co-authors of this study collected small wood samples called microcores during several years to precisely quantify the seasonal dynamics of the formation of tracheids, i.e., the cells that make up most of the wood in conifers.

“These samples gave us the ability to watch how individual tree rings are formed and carbon is locked in wood tissue,” stated Henri Cuny, the lead author of the paper. He continues, “however, measurements from high-precision instruments called dendrometers that record changes in tree size, showed a different picture: an impressive lag between the carbon allocation to wood and changes in tree size”.

Microscopic examination of microcore thin sections revealed that tracheids enlarge in a few days and then build their thick and lignified secondary walls, which can take over 2 months to complete. This developmental sequence is the basis for the significant time lag between the increase in size and the increase in biomass of tree stems.

Crucial implications for our understanding of carbon cycle

The study demonstrates the prevalence of this time lag in coniferous forests in Switzerland and across the Northern Hemisphere in general. The discovered time lag has crucial implications for carbon cycle assessment. For example, it means that the seasonal carbon sequestration into wood cannot be assessed directly from external measurements of stem size changes.

This detailed mechanistic representation of when and how carbon is sequestered into the wood in relation with environmental conditions provides crucial information to assess the impact of climate changes on tree growth and carbon fluxes in forest ecosystems.

Original article

Cuny H. et al. (2015) Woody biomass production lags stem-girth increase by over one month in coniferous forests. Nature Plants. doi:10.1038/nplants.2015.160

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