Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants

Institut for Geovidenskab og Naturforvaltning

Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Standard

Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants. / Huang, Weiwei; Reddy, Gadi V.P.; Li, Yueyi; Larsen, Jørgen Bo; Shi, Peijian.

I: Symmetry, Bind 12, Nr. 8, 1345, 08.2020, s. 1-10.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Huang, W, Reddy, GVP, Li, Y, Larsen, JB & Shi, P 2020, 'Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants', Symmetry, bind 12, nr. 8, 1345, s. 1-10. https://doi.org/10.3390/sym12081345

APA

Huang, W., Reddy, G. V. P., Li, Y., Larsen, J. B., & Shi, P. (2020). Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants. Symmetry, 12(8), 1-10. [1345]. https://doi.org/10.3390/sym12081345

Vancouver

Huang W, Reddy GVP, Li Y, Larsen JB, Shi P. Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants. Symmetry. 2020 aug.;12(8):1-10. 1345. https://doi.org/10.3390/sym12081345

Author

Huang, Weiwei ; Reddy, Gadi V.P. ; Li, Yueyi ; Larsen, Jørgen Bo ; Shi, Peijian. / Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants. I: Symmetry. 2020 ; Bind 12, Nr. 8. s. 1-10.

Bibtex

@article{c6d017e2903a431ca9579159b3a4dfe1,

title = "Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants",

abstract = "Leaves, as the most important photosynthetic organ of plants, are intimately associated with plant function and adaptation to environmental changes. The scaling relationship of the leaf dry mass (or the fresh mass) vs. leaf surface area has been referred to as “diminishing returns”, suggesting that the leaf area fails to increase in proportion to leaf dry mass (or fresh mass). However, previous studies used materials across different families, and there is lack of studies testing whether leaf fresh mass is proportional to the leaf dry mass for the species in the same family, and examining the influence of the scaling of leaf dry mass vs. fresh mass on two kinds of diminishing returns based on leaf dry mass and fresh mass. Bamboo plants (Poaceae: Bambusoideae) are good materials for doing such a study, which have astonishingly similar leaf shapes across species. Bamboo leaves have a typical parallel venation pattern. In general, a parallel venation pattern tends to produce a more stable symmetrical leaf shape than the pinnate and palmate venation patterns. The symmetrical parallel veins enable leaves to more regularly hold water, which is more likely to result in a proportional relationship between the leaf dry mass and absolute water content, which consequently determines whether the scaling exponent of the leaf dry mass vs. area is significantly different from (or the same as) that of the leaf fresh mass vs. area. In the present study, we used the data of 101 bamboo species, cultivars, forms and varieties (referred to as 101 (bamboo) taxa below for convenience) to analyze the scaling relationships between the leaf dry mass and area, and between leaf fresh mass and area. We found that the confidence intervals of the scaling exponents of the leaf fresh mass vs. dry mass of 68 out of the 101 taxa included unity, which indicates that for most bamboo species (67.3%), the increase in leaf water mass keeps pace with that of leaf dry mass. There was a significant scaling relationship between either leaf dry mass or fresh mass, and the leaf surface area for each studied species. We found that there was no significant difference between the scaling exponent of the leaf dry mass vs. leaf area and that of the leaf fresh mass vs. leaf area when the leaf dry mass was proportional to the leaf fresh mass. The goodness of fit to the linearized scaling relationship of the leaf fresh mass vs. area was better than that of the leaf dry mass vs. area for each of the 101 bamboo taxa. In addition, there were significant differences in the normalized constants of the leaf dry mass vs. fresh mass among the taxa (i.e., the differences in leaf water content), which implies the difference in the adaptabilities to different environments across the taxa.",

keywords = "Bambusoideae, Diminishing returns, Reduced major axis, The proportional relationship, The scaling relationship",

author = "Weiwei Huang and Reddy, {Gadi V.P.} and Yueyi Li and Larsen, {J{\o}rgen Bo} and Peijian Shi",

year = "2020",

month = aug,

doi = "10.3390/sym12081345",

language = "English",

volume = "12",

pages = "1--10",

journal = "Symmetry: Culture and Science",

issn = "0865-4824",

publisher = "MDPI",

number = "8",

}

RIS

TY - JOUR

T1 - Increase in absolute leaf water content tends to keep pace with that of leaf dry mass—evidence from bamboo plants

AU - Huang, Weiwei

AU - Reddy, Gadi V.P.

AU - Li, Yueyi

AU - Larsen, Jørgen Bo

AU - Shi, Peijian

PY - 2020/8

Y1 - 2020/8

N2 - Leaves, as the most important photosynthetic organ of plants, are intimately associated with plant function and adaptation to environmental changes. The scaling relationship of the leaf dry mass (or the fresh mass) vs. leaf surface area has been referred to as “diminishing returns”, suggesting that the leaf area fails to increase in proportion to leaf dry mass (or fresh mass). However, previous studies used materials across different families, and there is lack of studies testing whether leaf fresh mass is proportional to the leaf dry mass for the species in the same family, and examining the influence of the scaling of leaf dry mass vs. fresh mass on two kinds of diminishing returns based on leaf dry mass and fresh mass. Bamboo plants (Poaceae: Bambusoideae) are good materials for doing such a study, which have astonishingly similar leaf shapes across species. Bamboo leaves have a typical parallel venation pattern. In general, a parallel venation pattern tends to produce a more stable symmetrical leaf shape than the pinnate and palmate venation patterns. The symmetrical parallel veins enable leaves to more regularly hold water, which is more likely to result in a proportional relationship between the leaf dry mass and absolute water content, which consequently determines whether the scaling exponent of the leaf dry mass vs. area is significantly different from (or the same as) that of the leaf fresh mass vs. area. In the present study, we used the data of 101 bamboo species, cultivars, forms and varieties (referred to as 101 (bamboo) taxa below for convenience) to analyze the scaling relationships between the leaf dry mass and area, and between leaf fresh mass and area. We found that the confidence intervals of the scaling exponents of the leaf fresh mass vs. dry mass of 68 out of the 101 taxa included unity, which indicates that for most bamboo species (67.3%), the increase in leaf water mass keeps pace with that of leaf dry mass. There was a significant scaling relationship between either leaf dry mass or fresh mass, and the leaf surface area for each studied species. We found that there was no significant difference between the scaling exponent of the leaf dry mass vs. leaf area and that of the leaf fresh mass vs. leaf area when the leaf dry mass was proportional to the leaf fresh mass. The goodness of fit to the linearized scaling relationship of the leaf fresh mass vs. area was better than that of the leaf dry mass vs. area for each of the 101 bamboo taxa. In addition, there were significant differences in the normalized constants of the leaf dry mass vs. fresh mass among the taxa (i.e., the differences in leaf water content), which implies the difference in the adaptabilities to different environments across the taxa.

AB - Leaves, as the most important photosynthetic organ of plants, are intimately associated with plant function and adaptation to environmental changes. The scaling relationship of the leaf dry mass (or the fresh mass) vs. leaf surface area has been referred to as “diminishing returns”, suggesting that the leaf area fails to increase in proportion to leaf dry mass (or fresh mass). However, previous studies used materials across different families, and there is lack of studies testing whether leaf fresh mass is proportional to the leaf dry mass for the species in the same family, and examining the influence of the scaling of leaf dry mass vs. fresh mass on two kinds of diminishing returns based on leaf dry mass and fresh mass. Bamboo plants (Poaceae: Bambusoideae) are good materials for doing such a study, which have astonishingly similar leaf shapes across species. Bamboo leaves have a typical parallel venation pattern. In general, a parallel venation pattern tends to produce a more stable symmetrical leaf shape than the pinnate and palmate venation patterns. The symmetrical parallel veins enable leaves to more regularly hold water, which is more likely to result in a proportional relationship between the leaf dry mass and absolute water content, which consequently determines whether the scaling exponent of the leaf dry mass vs. area is significantly different from (or the same as) that of the leaf fresh mass vs. area. In the present study, we used the data of 101 bamboo species, cultivars, forms and varieties (referred to as 101 (bamboo) taxa below for convenience) to analyze the scaling relationships between the leaf dry mass and area, and between leaf fresh mass and area. We found that the confidence intervals of the scaling exponents of the leaf fresh mass vs. dry mass of 68 out of the 101 taxa included unity, which indicates that for most bamboo species (67.3%), the increase in leaf water mass keeps pace with that of leaf dry mass. There was a significant scaling relationship between either leaf dry mass or fresh mass, and the leaf surface area for each studied species. We found that there was no significant difference between the scaling exponent of the leaf dry mass vs. leaf area and that of the leaf fresh mass vs. leaf area when the leaf dry mass was proportional to the leaf fresh mass. The goodness of fit to the linearized scaling relationship of the leaf fresh mass vs. area was better than that of the leaf dry mass vs. area for each of the 101 bamboo taxa. In addition, there were significant differences in the normalized constants of the leaf dry mass vs. fresh mass among the taxa (i.e., the differences in leaf water content), which implies the difference in the adaptabilities to different environments across the taxa.

KW - Bambusoideae

KW - Diminishing returns

KW - Reduced major axis

KW - The proportional relationship

KW - The scaling relationship

U2 - 10.3390/sym12081345

DO - 10.3390/sym12081345

M3 - Journal article

AN - SCOPUS:85096228272

VL - 12

SP - 1

EP - 10

JO - Symmetry: Culture and Science

JF - Symmetry: Culture and Science

SN - 0865-4824

IS - 8

M1 - 1345

ER -

ID: 253232486