Morphogeometric Approaches to Non-vascular Plants

Stanton, Daniel E.; Reeb, Catherine

doi:10.3389/fpls.2016.00916

Cited by 14 publications

(11 citation statements)

References 96 publications

(104 reference statements)

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“…production, population density or other abundance related dependent variables (Enquist, Brown, 238 & West 1998;Enquist et al 1999). Stanton and Reeb (2016) suggested that some characteristics 239 of bryophytes may be allometrically scaled like vascular plants, which was verified in this study. 240…”

Section: Plants Plant Allometry Focuses On Relationships Between Plasupporting

confidence: 78%

An allometric scaling approach to estimate epiphytic bryophyte biomass in tropical montane cloud forests

Lai

Liu

Kuo³

et al. 2020

Preprint

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10Epiphytic bryophytes (EB) are some of the most commonly found plant species in tropical 11 montane cloud forests, and they play a disproportionate role in influencing the terrestrial 12 hydrological and nutrient cycles. However, it is difficult to estimate the abundance of EB due to 13 the nature of their "epiphytic" habitat. This study proposes an allometric scaling approach to 14 measure EB biomass, implemented in 16,773 ha tropical montane cloud forests of northeastern 15Taiwan. A general allometry was developed to estimate EB biomass of 100 cm 2 circular-shaped 16 mats (n = 131) and their central depths. A point-intercept instrument was invented to measure 17 the depths of EB along tree trunks (n = 210) below 3-m from the ground level (sampled stem 18 surface area [SSA]) in twenty-one 30  30 m plots. Biomass of EB of each point measure was 19 derived using the general allometry and was aggregated across each SSA, and its performance 20 was evaluated. Total EB biomass of a tree was estimated by referring to an in-situ conversion 21 model and was interpolated for all trees in the plots (n = 1451). Finally, we assessed EB 22 biomass density at the plot scale and preliminarily estimated EB biomass of the study region. 23The general EB biomass-depth allometry showed that the depth of an EB mat was a salient 24 variable for biomass estimation (R 2 = 0.72, p < 0.001). The performance of upscaling from mats 25 to SSA was satisfactory, which allowed us to further estimate mean ( standard deviation) EB 26 biomass of the 21 plots (272  104 kg ha -1 ) and to provide preliminary estimation of the total 27 EB biomass of 4562 Mg for the study region. Since a significant relationship between tree size 28 and EB abundance is commonly found, regional EB biomass may be mapped by integrating our 29 method and three-dimensional airborne data. 30

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Section: Plants Plant Allometry Focuses On Relationships Between Plasupporting

confidence: 78%

An allometric scaling approach to estimate epiphytic bryophyte biomass in tropical montane cloud forests

Lai

Liu

Kuo³

et al. 2020

Preprint

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“…Different units within individuals are genetically identical and, thus, their shape differences reflect other sources of variation, such as position along the segmental series [ 5 ], enviromental heterogeneity [ 4 , 7 ], or developmental noise [ 8 ]. While the within-individual shape variation of modular segments in streptophyte plants and invertebrates has recently been investigated in a number of studies [ 2 , 5 – 7 , 9 ], there are much less data on patterns of quantitative shape plasticity in the bryopsidalean green macroalgae, such as Halimeda . These organisms are typical by so called translational symmetry , i.e.…”

Section: Introductionmentioning

confidence: 99%

Morphological allometry constrains symmetric shape variation, but not asymmetry, of Halimeda tuna (Bryopsidales, Ulvophyceae) segments

Neustupa

Němcová

2018

PLoS ONE

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Green algae of the genus Halimeda have modular siphonous thalli composed of multiple repeated segments. Morphological variation among the segments has been related to various environmental factors, which often jointly affect their size and shape. The segments are bilaterally symmetric, which means that their shape variation can be decomposed into the symmetric and asymmetric components. Asymmetric variation might reflect both environmental heterogeneity and developmental instability of morphogenetic processes during the development of segments. In the present study, we examined if segment shape in H. tuna is related to their size and if an allometric relationship can also be found with respect to their asymmetry. Relative contributions of directional and fluctuating asymmetry to the segment shape variation within individual plants were investigated at two close localities in the northern Adriatic Sea. A series of equidistant semilandmarks were set along the outline of the segments, and analyzed by geometric morphometrics using two parallel methods to optimize their final position. Symmetric variation was strongly constrained by allometry, which also explained differences between populations. Smaller segments were significantly more asymmetric, but the difference in asymmetry between populations could not be explained solely by this allometric relationship. These differences between populations might have been caused by variation in local environmental factors. We conclude that members of the genus Halimeda represent an intriguing model system for studies of morphometric symmetry and asymmetry of sessile marine organisms, including effects of allometric relationships and infraspecific variation in relation to environmental factors of the benthic coastal habitats.

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“…The inferred length of the branches subtending nodes in Japanese Weissia is relatively short (< 0.0031), suggesting rapid and parallel sporophyte modifications (cleistocarpy) in this clade, as also shown in European and North American Weissia by Werner et al (2005). Gametophytes often display a high degree of polymorphism while sporophytes remain less variable at intra-and inter-specific levels in bryophytes (Stanton & Reeb 2016). In the case of Weissia, however, our results suggest that sporophytes in Weissia species are more plastic than gametophytes between species, as also found in Funariaceae Schwägrichen (1830: 43) (Fife 1985).…”

Section: Discussionmentioning

confidence: 97%

A taxonomic revision of cleistocarpous species of Weissia (Pottiaceae, Bryophyta) in Japan

Inoue

Tsubota

2017

Phytotaxa

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Four species, including one newly described, of Japanese cleistocarpous species of Weissia (Pottiaceae): W. exserta, W. japonica, W. kiiensis and W. parajaponica sp. nov. are recognized based on molecular phylogenetic inference and morphological reassessment. For each species, typification, description, distribution, illustrations and photographs are presented, and a key to the species is included. Rapid sporophyte modifications in Weissia and monophyletic positions of these four species are supported by the analysis using concatenated chloroplast rbcL and rps4 gene sequences. A lectotype is designated for W. controversa which is the type species of the genus, and a new combination, W. loncophylla is proposed for Trachycarpidium lonchophyllum.

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Morphogeometric Approaches to Non-vascular Plants

Cited by 14 publications

References 96 publications

An allometric scaling approach to estimate epiphytic bryophyte biomass in tropical montane cloud forests

An allometric scaling approach to estimate epiphytic bryophyte biomass in tropical montane cloud forests

Morphological allometry constrains symmetric shape variation, but not asymmetry, of Halimeda tuna (Bryopsidales, Ulvophyceae) segments

A taxonomic revision of cleistocarpous species of Weissia (Pottiaceae, Bryophyta) in Japan

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