Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-13T03:28:28.246Z Has data issue: false hasContentIssue false
  • English
  • Français

3D modelling of thallus topography of Lobaria pulmonaria facilitates understanding of water storage pools

Published online by Cambridge University Press:  20 February 2019

Nathan H. PHINNEY Open the ORCID record for Nathan H. PHINNEY [Opens in a new window]
Nathan H. PHINNEY*
Affiliation:
Environmental Sciences and Natural Resource Management, Norwegian University of Life Sciences, 1432 Ås, Norway. Email: naph@nmbu.no
Get access Rights & Permissions [Opens in a new window]

Abstract

Lobaria pulmonaria is a widespread epiphytic foliose lichen that exhibits a prominent reticulum, a structure that has a presumed role in mechanical support and water capture. Using photogrammetry, thallus topography was digitally modelled in three dimensions to calculate 3D surface area (A3D), which was consistently greater than areas extracted from projected images (A2D). The A3D:A2D ratio, a proxy for topographic three-dimensionality, was strongly correlated with both specific thallus mass (STM) and external water-holding capacity (WHCexternal), suggesting that the reticulum in L. pulmonaria extends hydration, photosynthetic activity and growth, following rainfall. Three-dimensionality was more pronounced in larger thalli, which is likely beneficial to liquid water-dependent internal cephalodia that occur more in older thalli and most often within the fovea.

Keywords

ecohydrologyfunctional traitshydrationmacrolichen morphologyphotogrammetrypoikilohydry
Type
Articles
Information
The Lichenologist , Volume 51 , Issue 1 , January 2019 , pp. 89 - 95
Copyright
© British Lichen Society, 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Barták, M., Solhaug, K. A., Vrábliková, H. & Gauslaa, Y. (2006) Curling during desiccation protects the foliose lichen Lobaria pulmonaria against photoinhibition. Oecologia 149: 553560.Google Scholar
Bidussi, M., Gauslaa, Y. & Solhaug, K. A. (2013) Prolonging the hydration and active metabolism from light periods into nights substantially enhances lichen growth. Planta 237: 13591366.Google Scholar
Boudon, F., Pradal, C., Cokelaer, T., Prusinkiewicz, P. & Godin, C. (2012) L-Py: an L-system simulation framework for modeling plant architecture development based on a dynamic language. Frontiers in Plant Science 3: 76.Google Scholar
Broom, F. D., Parkinson, B. N., Green, T. G. A. & Seppelt, R. D. (1999) Small-scale field mapping of lichen distribution in three dimensions with a computer-based position-tracking system. Oecologia 119: 552556.Google Scholar
Cornejo, C. & Scheidegger, C. (2013) Morphological aspects associated with repair and regeneration in Lobaria pulmonaria and L. amplissima (Peltigerales, Ascomycota). Lichenologist 45: 285289.Google Scholar
Esseen, P.-A., Olsson, T., Coxson, D. & Gauslaa, Y. (2015) Morphology influences water storage in hair lichens from boreal forest canopies. Fungal Ecology 18: 2635.Google Scholar
Esseen, P.-A., Rönnqvist, M., Gauslaa, Y. & Coxson, D. (2017) Externally held water – a key factor for hair lichens in boreal forest canopies. Fungal Ecology 30: 2938.Google Scholar
Gauslaa, Y. (2014) Rain, dew, and humid air as drivers of lichen morphology, function and spatial distribution in epiphytic lichens. Lichenologist 46: 116.Google Scholar
Gauslaa, Y. & Solhaug, K. A. (1998) The significance of thallus size for the water economy of the cyanobacterial old forest lichen Degelia plumbea . Oecologia 116: 7684.Google Scholar
Gauslaa, Y., Palmqvist, K., Solhaug, K. A., Hilmo, O., Holien, H., Nybakken, L. & Ohlson, M. (2009) Size-dependent growth in two old-growth associated macrolichens species. New Phytologist 181: 683692.Google Scholar
Gauslaa, Y., Solhaug, K. A. & Longinotti, S. (2017) Functional traits prolonging photosynthetically active periods in epiphytic cephalolichens during desiccation. Environmental and Experimental Botany 141: 8391.Google Scholar
Hinchcliffe, G., Bollard-Breen, B., Cowan, D. A., Doshi, A., Gillman, L. N., Maggs-Kolling, G., de los Ríos-Murillo, A. & Pointing, S. B. (2017) Advanced photogrammetry to assess lichen colonisation in the hyper-arid Namib Desert. Frontiers in Microbiology 8: 2083.Google Scholar
Honegger, R. (1993) Tansley Review No. 60. Developmental biology of lichens. New Phytologist 125: 659677.Google Scholar
Jenness, J. S. (2004) Calculating landscape surface area from digital elevation models. Wildlife Society Bulletin 32: 829839.Google Scholar
Korpela, I. S. (2008) Mapping of understory lichens with airborne discrete-return LiDAR data. Remote Sensing of Environment 112: 38913897.Google Scholar
Lange, O. L., Kilian, E. & Ziegler, H. (1986) Water vapor uptake and photosynthesis in lichens: performance differences in species with green and blue-green algae as phycobionts. Oecologia 71: 104110.Google Scholar
Larsson, P. & Gauslaa, Y. (2011) Rapid juvenile development in old forest lichens. Botany 89: 6572.Google Scholar
Merinero, S., Hilmo, O. & Gauslaa, Y. (2014) Size is a main driver for hydration traits in cyano- and cephalolichens of boreal rainforest canopies. Fungal Ecology 7: 5966.Google Scholar
Nguyen, C. V., Lovell, D. R., Adcock, M. & La Salle, J. (2014) Capturing natural-colour 3D models of insects for species discovery and diagnostics. PLoS ONE 9: e94346.Google Scholar
Novak, P., Li, C., Shevchuk, A. I., Stepanyan, R., Caldwell, M., Hughes, S., Smart, T. G., Gorelik, J., Ostanin, V. P. & Moss, G. W. (2009) Nanoscale live-cell imaging using hopping probe ion conductance microscopy. Nature Methods 6: 279281.Google Scholar
Phinney, N. H., Solhaug, K. A. & Gauslaa, Y. (2018) Rapid resurrection of chlorolichens in humid air: specific thallus mass drives rehydration and reactivation kinetics. Environmental and Experimental Botany 148: 184191.Google Scholar
Reeb, C., Kaandorp, J., Jansson, F., Puillandre, N., Dubuisson, J. Y., Cornette, R., Jabbour, F., Coudert, Y., Patiño, J. & Flot, J. F. (2018) Quantification of complex modular architecture in plants. New Phytologist 218: 859872.Google Scholar
Shorrocks, B., Marsters, J., Ward, I. & Evennett, P. (1991) The fractal dimension of lichens and the distribution of arthropod body lengths. Functional Ecology 5: 457460.Google Scholar
Stanton, D. E. & Horn, H. S. (2013) Epiphytes as “filter-drinkers”: life-form changes across a fog gradient. Bryologist 116: 3442.Google Scholar
Valladares, F., Sancho, L. G. & Ascaso, C. (1998) Water storage in the lichen family Umbilicariaceae . Botanica Acta 111: 99107.Google Scholar
Young, G., Dey, S., Rogers, A. & Exton, D. (2017) Cost and time-effective method for multi-scale measures of rugosity, fractal dimension, and vector dispersion from coral reef 3D models. PLoS ONE 12: e0175341.Google Scholar