Intraspecific polymorphism of pollen grains in Artemisia herba Alba Asso in the Tiaret region (West of Algeria): Pollen polymorphism in Artemisia herba Alba Asso

Benchohra Maghni; Mohammed Ait  Hammou; Anfal Bochra Maghni; Wahiba Baghdache; Nebia Belkilali; Imane Khanfer

doi:10.11594/jaab.06.01.04

Penulis

Benchohra Maghni Laboratory of Agro-Biotechnology and Nutrition in Semi-Arid Areas, Faculty of Nature and Life Sciences, University Ibn Khaldoun, Tiaret, Algeria
Mohammed Ait Hammou Faculty of Nature and Life Sciences, University Ibn Khaldoun, Tiaret, Algeria https://orcid.org/0000-0002-5187-6294
Anfal Bochra Maghni Faculty of Natural and Life Sciences, , Annexe of Medicine, Ibn Khaldoun University, BP 14000, Tiaret , Algeria
Wahiba Baghdache Faculty of Natural and Life Sciences, Ibn Khaldoun University, BP 14000, Tiaret
Nebia Belkilali Faculty of Natural and Life Sciences, Ibn Khaldoun University, BP 14000, Tiaret
Imane Khanfer Faculty of Natural and Life Sciences, Ibn Khaldoun University, BP 14000, Tiaret , Algeria

DOI:

https://doi.org/10.11594/jaab.06.01.04

Kata Kunci:

Atrémisia herba alba Asso, Apertures, Morphology, Pollen, Polymorphism

Abstrak

This study allowed us to determine the appearance and pollen apertures of 200 individuals of Atrémesia herba alba from three areas in Algeria. The pollen morphology determined at the three stations studied is Tricolorpé, of which two grain shapes were encountered, spherical and elongated with three aper-tures and distinct diameters. Results obtained from pollen di-ameter measurements revealed a significant effect, which con-firms a very marked intra- and inter-population variability of this character. Indeed, the spherical pollen diameters vary be-tween 13.20 and 20 µm (Ain Dheb area) and between 16.56 and 29.90 µm in individuals from the two Chellala areas. The elon-gated pollen diameters from the Chellala region have diameters fluctuating between 34.31/25.46 to 29.90/16.56 µm and have diameters between 19/14.81 and 28.55 /18.54 µm for the Ain Dheb area.

Unduhan

Data unduhan tidak tersedia.

Referensi

Akinnubi, F. M., Akinloye, A. J., & Oladipo, O. T. (2014). Pollen Grain Morphology of Some Select-ed Species of Asteraceae in South Western Nigeria. Research in Plant Biology, 4(6), 17-23.

Bahadur, S., Ahmad, M., Mir, S., Zafar, M., Sultana, S., Ashfaq, S., & Arfan, M. (2018). Identification of monocot flora using pollen features through scanning electron microscopy. Microscopy Research and Technique, 81(6), 599–613.

Bottraud, I. (1994). Pollen aperture polymorphism in the Angiosperms: importance, possible causes and consequences. Acta Botanica Gallica, 141, 109–122. CrossRef

Cai, M., Ye, P., Yang, X., & Li, C. (2019). Vegetation and climate change in the Hetao Basin (North-ern China) during the last interglacial-glacial cycle. Journal of Asian Earth Sciences., 171, 1–8. CrossRef

Cao, X., Tian, F., Li, K., Ni, J., Yu, X., Liu, L., & Wang, N. (2021). Lake surface sediment pollen da-taset for the alpine meadow vegetation type from the eastern Tibetan Plateau and its poten-tial in past climate reconstructions. Earth System Science Data, 13, 3525–3537. CrossRef

Charlotte, P. (2015). Évolution et Développement des grains de pollen chez les angiospermes. Université Paris Saclay (COmUE), Français [Evolution and Development of Pollen Grains in Angiosperms. Paris Saclay University (COmUE), French. NNT]. NNT: 2015SACLS201. HAL Id: tel-01282138. Direct Link.

Cui, Q. Y., Zhao, Y., Qin, F., Liang, C., Li, Q., & Geng, R. W. (2019). Characteristics of the modern pollen assemblages from different vegetation zones in Northeast China: Implications for pollen based climate reconstruction. Science China Earth Sciences., 62, 1564–1577. Cross-Ref

De Abreu, V. H. R., da Conceiç˜ao Santos, J., Esteves, R. L., & Gonçalves-Esteves, V. (2015). Pollen morphology of Praxelis (Asteraceae, Eupatorieae, Praxelinae) in Brazil. Plant Systematics and Evolution, 301(2), 599–608. CrossRef

Diot, M. F. (2000). Le végétal en archéologie : Pollen et palynologie [Plants in Archaeology: Pollen and Palynology]. Ed. CNRS. Périgueux. p19

Ghahreman, A., Noorbakhsh, S. N., Mehdigholi, K. & Attar, F. (2007). Pollen Morphology of Ar-temisia L. (Asteraceae). Iranian Journal of Botany, 13 (1): 21-29. Tehran

Grímsson, F., Grimm, G. W., & Zetter, R. (2017a). Tiny pollen grains: first evidence of Saururaceae from the Late Cretaceous of western North America. Peer J, 5:e3434 CrossRef

Grímsson, F., Grimm, G. W., Zetter, R., & Denk, T. (2016). Cretaceous and Paleogene Fagaceae from North America and Greenland: evidence for a Late Cretaceous split between Fagus and the remaining Fagaceae. Acta Palaeobotanica, 56, 247–305

Grímsson, F., Kapli, P., Hofmann, C., Zetter, R., & Grimm, G. W. (2017b). Eocene Loranthaceae pollen pushes back divergence ages for major splits in the family. Peer J, 5:e3373 CrossRef

Grímsson, F., Zetter, R., Halbritter, H., & Grimm, G. W. (2014). Aponogeton pollen from the Creta-ceous and Paleogene of North America and West Greenland: Implications for the origin and palaeobiogeography of the genus. Review of Palaeobotany and Palynology, 200, 161–187. CrossRef

Halbritter, H., Ulrich, S., Grímsson, F., Weber, M., Zetter, R., Hesse M., Buchner, R., Svojtka, M., & Frosch-Radivo, M. (2018). Illustrated Pollen Terminology, (2End). Springer.p487 CrossRef

Hayat, K., Khan, W. M., Khan, M. N., & Shah, S. N. (2023). Pollen morphological investigation of selected species of family Asteraceae from Pakistan by using light and scanning electron microscopy. Microscopy Research and Technique, 1–16. CrossRef

Hesse, M., M., Weber, R.. Buchner, A.. Frosch-Radivo., and Ulrich, S. (2009). Pollen Terminology – An illustrated handbook. Springer-Verlag Wien. Direct Link.

Hussain, A., Potter, D., Hayat, M. Q., Sahreen, S., & Bokhari, S. A. I. (2019). Pollen morphology and its systematic implication on some species of Artemisia herba-alba Asso. from Gilgit-Baltistan Pakistan. Bangladesh Journal of Plant Taxonomy, 26(2), 157–168. CrossRef

Jiang, L., Wang, Q., Ye, L., Lin, Yr. (2005). Pollen Morphology of Artemisia L. and Its Systematic Significance. Wuhan University Journal of Natural Sciences, 10(2): 448-454. CrossRef

Khan, S. U., Zafar, M., Ullah, R., Shahat, A. A., Ahmad, M., Sultana, S., & Malik, K. (2021b). Pollen diversity and its implications to the systematics of mimosaceous species by LM and SEM. Microscopy Research and Technique, 84(1), 42–55. CrossRef

Khan, S., Jan, G., Ahmad, M., Gul, F., Zafar, M., Mangi, J. U. D., Majeed, S. (2021a). Morpho-palynological assessment of some species of family Asteraceae and Lamiaceae of District Bannu, Pakistan on the bases of light microscope & scanning electron microscopy. Micros-copy Research and Technique, 84(6), 1220–1232. CrossRef

Koutsodendris, A., Allstadt, F. J., Kern, O. A., Kousis, I.,Schwarz, F., Vannacci, M., Woutersen, A., Appel, E., Berke,M. A., Fang, X. M., Friedrich, O., Hoorn, C., Salzmann, U., & Pross, J. (2019) . Late Pliocene vegetation turnover on the NE Tibetan Plateau (Central Asia) triggered by early Northern Hemisphere glaciation, Global Planet. Change, 180, 117–125, CrossRef

Kursat, M., Civelek, S., Baser, B., Ozbey, F., & Emre, I. (2023). Pollen morphology of Artemisia L. (Asteraceae) in Turkey and its systematic value. Grana, 62(4), 257–276. CrossRef

Lu, K. Q., Qin, F., Li, Y., Xie, G., Li, J. F., Cui, Y. M., Ferguson, D. K., Yao, Y. F., Wang, G. H., & Wang, Y. F. (2020). A new approach to interpret vegetation and ecosystem changes through time by establishing a correlation between surface pollen and vegetation types in the eastern central Asian desert. Palaeogeography, Palaeoclimatology, Palaeoecology, 551, 12. Cross-Ref

Lu, L. L., Jiao, B. H., Qin, F., Xie, G., Lu, K.Q., Li, J.F., Sun, B., Li, M., Ferguson, D. K., Gao, T.G., Yao, Y.F., & Wang, Y. F. (2022) Artemisia pollen dataset for exploring the potential ecological in-dicators in deep time. Earth System Science Data, 14, 3961–3995. CrossRef

Maghni, B., Adda, A., Merah, O., (2017). Evaluating morphological variability of Artemisia herba- alba asso from western Algeria. Journal of Fundamental and Applied Sciences, 9(1), 509–527. CrossRef

Maghni, B., Ait Hammou, M., Khedim, R., Maatoug, M., Hellal, B. (2020) Palynological study of angiosperms of rostomid park of Tiaret in Algeria. Journal of Fundamental and Applied Sci-ences, 12(1), 1-11. Direct Link.

Maghni, B., Bougoutaia, Y., Abderrabi, k., Adda, A., and Othmane, M. (2016). Optimization of DNA Extraction and PCR Conditions for Genetic Diversity Study in Artemisia herba-alba from Al-geria. Scientific Journal of Genetics Genes Therapy, 2(1), 010–012. CrossRef

Maghni, B., Hellal, B., Maatoug, M. (2018). Dynamics of the anatomical variability of Artemisia herba-alba in Algeria. Biosystems Diversity, 26(3), 239–244. CrossRef

McClelland, H. L. O., Halevy, I., Wolf-Gladrow, D. A., Evans, D., & Bradley, A. S. (2021). Statistical uncertainty in paleoclimate proxy reconstructions, Geophysical Research Letters, 48, e2021GL092773, CrossRef

Mignot, A., Hoss, C., Dajoz, I., Leuret, C., Henry, J.P., Dreuillaux, J.M., Heberle-Bors, E., & Till-bottraud, I. (1994). Pollen aperture polymorphism in the Angiosperms: importance, possi-ble causes and consequences. Acta Botanica Gallica, 141: 109–122. CrossRef

Muhammad, Q.H., Muhammad A., Mir A.K., Ghazalah, Y., Nighat, S., and Shazia, J. (2009). Phylo-genetic analysis of Artemisia L. (Asteraceae) based on micromorphological traits of pollen grains. African Journal of Biotechnology, 8 (23), 6561-6568. Direct Link.

PIerce, N.B., and Simpson, M.G. (2009). Polyaperturate pollen types and ratios of hetero-morphism in the monocot genus Conostylis (Haemodoraceae). Australian Systematic Bota-ny , 22, 16–30. Direct Link.

Ragho, K. S. (2020). Role of pollen morphology in taxonomy and detection of adulterations in crud drugs. Journal of Plant Science and Phytopathology, 4, 24–27. CrossRef

Roland, F., & Claude, J. (1989). Organisation Des Plantes à Fleurs [Organization of Flowering Plants]. (3rd Ed). Paris: Masson. Pp. 82-90

Stephen, A. (2014). Pollen: A microscopic wonder of plant kingdom. International Journal of Ad-vanced Research in Biological Sciences, 1(9),45–62. Direct Link.

Tierney, J. E., Poulsen, C. J., Montanez, I. P., Bhattacharya, T., Feng, R., Ford, H. L., Honisch, B., Inglis, G. N., Pe-tersen, S. V., Sagoo, N., Tabor, C. R., Thirumalai, K., Zhu, J., Burls, N. J., Fos-ter, G. L., Godderis, Y., Huber, B. T.,Ivany, L. C., Turner, S. K., Lunt, D. J., McElwain, J. C., Mills, B. J. W., Otto-Bliesner, B. L., Ridgwell, A., & Zhang, Y.G. (2020). Past climates inform our future, Science, 370, eaay3701, CrossRef

Till-Bottraud, I., Gouyon, P. H., Venable, D. L., and Godelle, B. (2001). The number of competitors providing pollen on a stigma strongly influences intraspecific variation in number of pollen apertures. Evolutionary Ecology Research, 3, 231–253.

Till-Bottraud, I., Vincent, M., Dajoz, I., & Mignot, A. (1999). Pollen aperture hetero-morphism.Variation in pollen-type proportions along altitudinal transects in Viola calcarata. Comptes Rendus de l’Académie des Sciences de Paris, Sciences de la Vie, 322: 579–589. Di-rect Link.

Torrell, M., Garcia-Jacas, N., Susanna, A., Valles, J. (1999). Phylogeny in Artemisia (Asteraceae, Anthemideae) Inferred from Nuclear Ribosomal DNA (ITS) Sequences,Taxon, 48, 721-736 Direct Link.

Ullah, F., Zafar, M., Ahmad, M., Dilbar, S., Shah, S. N., Sohail, A., Zaman, W., Iqbal, M., Bahadur, S. & Tariq, A. (2018). Pollen morphology of subfamily Caryophylloideae (Caryophyllaceae) and its taxonomic significance. Microscopy Research and Technique, 81(7): 704–715. CrossRef

Umber, F., Zafar, M., Ullah, R., Bari, A., Khan, M. Y., Ahmad, M., & Sultana, S. (2022). Implication of light and scanning electron micros-copy for pollen morphology of selected taxa of family Asteraceae and Brassicaceae. Microscopy Research and Technique, 85(1), 373–384. Cross-Ref

Watson, L. E., Bates, P. L., Evans, T. M., Unwin, M.M., & Estes, J. R. (2002). Molecular Phylogeny of subtribe Artemisiinae (Asteraceae), including Artemisia and its allied and segregate genera. BMC Evolutionary Biology, 2, 17. CrossRef

Wodehouse, R. P. (1928). Pollen Grain Morphology in the Classification of the Anthemideae, Bul-letin of the Torrey Botanical Club, 53, 479–485, CrossRef

Wu, F. L., Fang, X. M., & Miao, Y. F. (2020). Aridification history of the West Kunlun Mountains since the mid-Pleistocene based on sporopollen and microcharcoal records, Palaeogeogra-phy, Palaeoclimatology, Palaeoecology, 547, 109680, CrossRef

Zhao, Y. T., Miao, Y. F., Fang, Y. M., Li, Y., Lei, Y., Chen, X. M., Dong, W. M., & An, C. B. (2021). In-vestigation of factors affecting surface pollen assemblages in the Balikun Basin, central Asia: Implications for palaeoenvironmental reconstructions, Ecological Indicators, 123, 107332, CrossRef

Intraspecific polymorphism of pollen grains in Artemisia herba Alba Asso in the Tiaret region (West of Algeria)

Pollen polymorphism in Artemisia herba Alba Asso

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