Study on the n-alkane patterns in some grasses and factors affecting the n-alkane patterns

Y. ZHANG; Y. TOGAMURA; K. OTSUKI

doi:10.1017/S0021859604004526

Abstract

The proportions of alkanes in plant cuticular waxes are influenced by sampling date, site and grazing pressure. Alkanes in organs of major wild forage grasses in Japan were evaluated to estimate the intake and diet composition of grazing animals. Samples of four grasses from a fixed site in native grassland and three grass species from different sites were collected from June to November, to test the temporal and spatial effects on alkane concentrations. Most alkane concentrations in Miscanthus sinensis Anderss, Pleioblastus chino (Franch. Et Savat.) Makino, Sasa nipponica and Zoysia japonica increased from June to July, and then decreased to mid November. Alkane concentrations in the Z. japonica sward used to test the effects of grazing pressure decreased from May to September. Although the sampling dates affected the alkane concentrations, the species effects accounted for 70–93% of the observed variation. Grazing pressure affected only the C29 (n-Nonacosane) alkane concentrations in dead aboveground materials of Z. japonica, but altered the ratios of C29[ratio ]C31 (n-Hentriacontane) in both dead and live Z. japonica. There were positive correlations between C27 (n-Heptacosane), C29 and C35 (n-Pentatriacontane) alkane concentrations in live leaves of M. sinensis and of C31 in live leaves of P. chino with growing season temperature and radiation. The concentrations of C25, C27 and C29 in dead leaves of M. sinensis and of C33 (n-Tritriacontane) and C35 in live Z. japonica were significantly correlated only with radiation. Alkane concentrations differed between the sampling sites, and considerable differences were observed between samples from Iwate and Kumamoto. Both live leaf and dead leaf samples from M. sinensis contained substantial amounts of C27, C29, C31, C33 and C35, and showed that alkane concentrations in stems were much lower during the whole growing season. Although concentrations of C29 were highest in Sasa nipponica (Makino) makino et Shibata, concentrations of C31 or C33 were highest in the other three grass species. Grazing pressures had little effect on alkane patterns, in which alkanes with odd-numbered carbon chains were predominant and most alkanes were of chain length C25 (n-Pentacosane) to C35 (n-Pentatriacontane).

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Rommerskirchen, Florian Plader, Anna Eglinton, Geoffrey Chikaraishi, Yoshito and Rullkötter, Jürgen 2006. Chemotaxonomic significance of distribution and stable carbon isotopic composition of long-chain alkanes and alkan-1-ols in C4 grass waxes. Organic Geochemistry, Vol. 37, Issue. 10, p. 1303.

Smith, Lori L. and Strickland, James R. 2007. Improved GC/MS Method for Quantitation of n-Alkanes in Plant and Fecal Material. Journal of Agricultural and Food Chemistry, Vol. 55, Issue. 18, p. 7301.

Schwark, L. 2010. Handbook of Hydrocarbon and Lipid Microbiology. p. 279.

Lin, L.J. Zhu, X.Y. Jiang, C. Luo, H.L. Wang, H. Zhang, Y.J. and Hong, F.Z. 2012. The potential use of n-alkanes, long-chain alcohols and long-chain fatty acids as diet composition markers: indoor validation with sheep and herbage species from the rangeland of Inner Mongolia of China. Animal, Vol. 6, Issue. 3, p. 449.

Kirkels, Frederique MSA Jansen, Boris and Kalbitz, Karsten 2013. Consistency of plant-specificn-alkane patterns in plaggen ecosystems: A review. The Holocene, Vol. 23, Issue. 9, p. 1355.

Gamarra, Bruno and Kahmen, Ansgar 2015. Concentrations and δ2H values of cuticular n-alkanes vary significantly among plant organs, species and habitats in grasses from an alpine and a temperate European grassland. Oecologia, Vol. 178, Issue. 4, p. 981.

Guo, Yanjun Guo, Na He, Yuji and Gao, Jianhua 2015. Cuticular waxes in alpine meadow plants: climate effect inferred from latitude gradient in Qinghai‐Tibetan Plateau. Ecology and Evolution, Vol. 5, Issue. 18, p. 3954.

Gamarra, B. Sachse, D. and Kahmen, A. 2016. Effects of leaf water evaporative 2H‐enrichment and biosynthetic fractionation on leaf wax n‐alkane δ2H values in C3 and C4 grasses. Plant, Cell & Environment, Vol. 39, Issue. 11, p. 2390.

Hegebarth, Daniela and Jetter, Reinhard 2017. Cuticular Waxes of Arabidopsis thaliana Shoots: Cell-Type-Specific Composition and Biosynthesis. Plants, Vol. 6, Issue. 4, p. 27.

Gamarra, Bruno and Kahmen, Ansgar 2017. Low secondary leaf waxn-alkane synthesis on fully mature leaves of C3 grasses grown at controlled environmental conditions and variable humidity. Rapid Communications in Mass Spectrometry, Vol. 31, Issue. 2, p. 218.

Jansen, Boris and Wiesenberg, Guido L. B. 2017. Opportunities and limitations related to the application of plant-derived lipid molecular proxies in soil science. SOIL, Vol. 3, Issue. 4, p. 211.

van den Bos, V. Engels, S. Bohncke, S. J. P. Cerli, C. Jansen, B. Kalbitz, K. Peterse, F. Renssen, H. and Sachse, D. 2018. Late Holocene changes in vegetation and atmospheric circulation at Lake Uddelermeer (The Netherlands) reconstructed using lipid biomarkers and compound‐specific δD analysis. Journal of Quaternary Science, Vol. 33, Issue. 1, p. 100.

Aichner, Bernhard Ott, Florian Słowiński, Michał Noryśkiewicz, Agnieszka M. Brauer, Achim and Sachse, Dirk 2018. Leaf wax <i>n</i>-alkane distributions record ecological changes during the Younger Dryas at Trzechowskie paleolake (northern Poland) without temporal delay. Climate of the Past, Vol. 14, Issue. 11, p. 1607.

Ratnayake, Amila Sandaruwan Sampei, Yoshikazu and Ratnayake, Nalin Prasanna 2019. Characteristics of sedimentary organic matter and vascular plants in tropical brackish Bolgoda Lake, Sri Lanka: Implications for paleoecology and chemotaxonomy. Regional Studies in Marine Science, Vol. 30, Issue. , p. 100726.

Jaroensuk, Juthamas Intasian, Pattarawan Wattanasuepsin, Watsapon Akeratchatapan, Nattanon Kesornpun, Chatchai Kittipanukul, Narongyot and Chaiyen, Pimchai 2020. Enzymatic reactions and pathway engineering for the production of renewable hydrocarbons. Journal of Biotechnology, Vol. 309, Issue. , p. 1.

Shaheenuzzamn, Md Shi, Shandang Sohail, Kamran Wu, Hongqi Liu, Tianxiang An, Peipei Wang, Zhonghua and Hasanuzzaman, Mirza 2021. Regulation of cuticular wax biosynthesis in plants under abiotic stress. Plant Biotechnology Reports, Vol. 15, Issue. 1, p. 1.

Fang, Yue Yang, Jing Zhao, Shijing Wu, Jie Huang, Yuying and Yang, Huan 2021. Shorter average chain length of n-alkanes from flowers than leaves of modern plants: Implications for the use of n-alkane-derived proxies in soils. GEOCHEMICAL JOURNAL, Vol. 55, Issue. 5, p. e19.

Zhu, Junyan Huang, Kelin Cheng, Daojie Zhang, Cao Li, Rui Liu, Fangbin Wen, Huilin Tao, Lingling Zhang, Youze Li, Cuihong Liu, Shengrui and Wei, Chaoling 2022. Characterization of Cuticular Wax in Tea Plant and Its Modification in Response to Low Temperature. Journal of Agricultural and Food Chemistry, Vol. 70, Issue. 43, p. 13849.

Liu, Jinzhao Zhao, Jiaju He, Ding Huang, Xianyu Jiang, Chong Yan, Hong Lin, Guanghui and An, Zhisheng 2022. Effects of plant types on terrestrial leaf wax long-chain n-alkane biomarkers: Implications and paleoapplications. Earth-Science Reviews, Vol. 235, Issue. , p. 104248.

Article contents

Study on the n-alkane patterns in some grasses and factors affecting the n-alkane patterns

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Study on the n-alkane patterns in some grasses and factors affecting the n-alkane patterns

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests