Salts Induced Salinity and in Vitro Multiplication of Paronychia argentea

Osman, Nahid Abd Elhamid; Shatnawi, Mohamad; Shibli, Rida; Majdalawi, Majdi; Al Tawaha, Abdel Rahman M.; Qudah, Tamara

doi:10.12912/27197050/139408

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Tytuł artykułu

Salts Induced Salinity and in Vitro Multiplication of Paronychia argentea

Autorzy

Osman Nahid Abd Elhamid , Shatnawi Mohamad , Shibli Rida , Majdalawi Majdi , Al Tawaha Abdel Rahman M. , Qudah Tamara

Treść / Zawartość

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Identyfikatory

DOI

10.12912/27197050/139408

Warianty tytułu

Języki publikacji

Abstrakty

Paronychia argentea is a wild herb plant with a high medicinal value. P. argentea plant is a neglected herb that grows without any attention in terms of research for cultivation and propagation. The conventional propagation methods of P. argentea by seeds and cutting are not preferred due to low germination percentage and cutting rooting problems. As a substitute for seed propagation, effective micropropagation protocols were developed. Using 0.6 mg/L 6-Benzylaminopurine (BAP), maximum of 3.90 (shoot/explant) was produced on Murashige and Skoog (MS) medium. In vitro growth was significantly decreased with increasing NaCl concentration. Potassium (K) and nitrogen (N) concentrations in P. argentea plantlets decreased significantly under NaCl treatment. Level of protein in leaf tissue generally decreased with increased NaCl concentrations in the medium. Proline content in P. argentea plantlets increased significantly with increasing NaCl concentrations. An increased in NaCl concentration in the medium resulted in an increase in total soluble solids (TSS) in plant tissue. Moreover, as salinity level concentration increased relative water content was decreased. High NaCl was significantly affected in vitro plants growth. P. argentea showed that in vitro P. argentea plantlets could be tolerated to in vitro salinity.

Słowa kluczowe

micropropagation salinity Paronychia argentea protein proline

Wydawca

Lubelski Oddział Polskiego Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology
WNGB Wydawnictwo Naukowe

Czasopismo

Ecological Engineering & Environmental Technology

Rocznik

2021

Tom

Vol. 22, iss. 5

Strony

55--64

Opis fizyczny

Bibliogr. 44 poz., rys., tab.

Twórcy

autor

Osman Nahid Abd Elhamid

Faculty of Agricultural technology, Al Balqa Applied University, Salt, Jordan

autor

Shatnawi Mohamad

mshatnawi1@yahoo.com.au

Faculty of Agricultural technology, Al Balqa Applied University, Salt, Jordan

https://orcid.org/0000-0003-1030-9485

autor

Shibli Rida

Department of Agricultural Biotechnology and Genetic Engineering, Faculty of Agriculture Technology, Al-Ahliyya Amman University, Amman 19328, Jordan

autor

Majdalawi Majdi

Faculty of Zarqa, Al-Balqa Applied University, Zarqa, Jordan

autor

Al Tawaha Abdel Rahman M.

abdel-al-tawaha@ahu.edu.jo

Department of Biological Sciences, Al-Hussein Bin Talal University, Maan 71111, Jordan

https://orcid.org/0000-0001-5726-4363

autor

Qudah Tamara

Hamdi Mango Centre for Scientific Research, University of Jordan, Amman, Jordan

Bibliografia

1. Abdallah, S.H., Aung, B., Amyot, L., Lalin, I., Lachaal, M & Bouraui K.N. 2016. Salt stress (NaCl) affects plant growth and branch pathways of carotenoid and flavonoid biosyntheses in Solanum nigrum. Acta Physiol. Plan 38(3), 1-13.
2. Akcin, A., & Yalcin, E. 2016. Effect of salinity stress on chlorophyll, carotenoid content, and proline in Salicornia prostrata Pall. and Suaeda prostrata Pall. subsp. prostrata (Amaranthaceae). Braz. J. Bot 39 (1), 101–106.
3. Al-Ajlouni, Z., Abbas, S., & Shatnawi M. 2015. In vitro propagation, callus induction, and evaluation of active compounds Ruta graveolens. J. Food, Agric. Environ 13 (2), 101-106.
4. Al-Khayri, J.M. 2002. Growth, proline accumulation and ion content in sodium chloride-stressed callus of date palm. In vitro Cell. Dev. Biol. Plant 38, 79-82.
5. AL-Issa, R.M.S., Odat, N., Qrunfleh, I., Hasan, M., & Al-Tawaha, A.R. 2020. The impact of NaCl on different genotypes of tomato (Solanum Lycopersicon Mil) on germination, some physiology characteristics and gene expression. Eurasian Journal of Biosciences, 14(2), 4467-4470.
6. Al-Mahmood, H., Shatnawi, M., Shibli, R., Makhadmeh, I., Abubaker, S., & Shadiadeh A. 2012. Clonal propagation and medium-term conservation Capparis spinosa: A medicinal plant. J. Med. Plant. Res 6 (22, 3826-3836.
7. Alrayes, L.M., Al Khateeb, W.M., & Shatnawi M.A. 2016. Clonal propagation and antibacterial activity of Moringa peregrina (Forssk) Fiori plant. J. Adv. Biotechno 6 (1), 787-797.
8. Al-Tawaha, A .M. and Al-Ghzawi, A. 2013.Effect of Chitosan coating on seed germination and salt-tolerance of lentil (Lensculinaris L.) Res. on Crops14 (2), 489-491.
9. Al-Tawaha, A.R., Turk, M.A., Al-Tawaha, A.R.M., Alu’datt, M.H ., Wedyan, M., Al-Ramamneh, E. Al-D.M & Hoang, A.T. 2018. Using chitosan to improve growth of maize cultivars under salinity conditions. Bulg. J. Agric. Sci., 24 (3), 437–442
10. Amiro, M.S, & Qados, A. 2010. Effect of salt stress on plant growth and metabolism of bean plant Vicia faba (L.). J. Saudi Soc. Agric. Sci 10, 7-15.
11. Anderson, J.M & Boardman, N.K. 1964. Studies on the greening of dark grown bean plants II. Development of photochemical activity. Australian J Biol Sci 17, 93-101.
12. Atta, E., Nassar, A., Hasan, N., & Hasan N.A. 2013. New Flavonoid Glycoside and Pharmacological Activities of Pteranthus dichotomus Forssk. Rec. Nat. Prod 7, 69-79.
13. Braca, A., Bader, A., Siciliano, T., & De Tommasi, N. 2008. Secondary metabolites from Paronychia argentea. Magn. Reson. Chem 46, 88–93.
14. Chapman, H.D., & Pratt, P.F. 1961. Method of analysis for soil plants and water. University of California. pp, 169-170.
15. Conceição., Gomes, MA., Pestana, I.A., Santa- Catarina, C., Hauser-Davis R.A., & Suzuki, M.S 2017. Salinity effects on photosynthetic pigments, proline, biomass and nitric oxide in Salvinia auriculata Aubl. Acta Limnol. Bras 29, 9-13.
16. Craker, L.E., Gardner, Z., & Etter, S.C. 2003. Herbs in American fields: A horticultural perspective of herb and medicinal plant production in the United Sates. 1903–2003. HortScience 38, 977–983.
17. De Filippis, L.F., Hampp, R., Ziegler, H. 1981. The effect of sub-lethal concentrations of zinc, cadmium and mercury on Euglena growth and pigments. Z. Pflanzenphysiol 101, 37-47.
18. Duxbury, A.C., & Yentsch, C.S. 1956. Plankton pigment monographs. J. Mar. Res 15, 92-101.
19. Hung, T,N., & Chi, V.L. 2014. Country status report on medicinal and aromatic plants in Vietnam. In expert consultation on promotion of medicinal and aromatic plants in the Asia-Pacific Region. pp. 218–226.
20. Jiang, Y., Ding, X., Zhang, D., Deng, Q., Yu, C.L., Zhou, S., & Hui, D. 2017. Soil salinity increases the tolerance of excessive sulfur fumigation stress in tomato plants. Enviromen. Exp. Bot. J 133, 70–77.
21. Kaur, G., & Kumar, A. 2017. Effect of salinity stress on plant growth, chlorophyll content and carotenoids of Coriander (Coriandrum sativum L.) cultivars. Int. J. Curr. Res 9, 57536-57544.
22. Mosavi, N., Ebadi, M., Khorshidi, M., Masoudian, N., & Hokmabadi, H. 2018. Study of some physiological characteristics of potato tissue under salinity stress. Int. J. Farm. Alli. Sci 7(1), 1-5.
23. Murashige, T., & Skoog, F. 1962. A revised medium for rapid growth and bioassays with tobacco tissue cultures. Physiol. Plant 15, 473-479.
24. Naeem, M., Bhatti, I., Hafeez, R, & Ashraf, Y. 2004. Effect of some growth hormones (GA3, IAA and kinetin) on the morphology and early or delayed initiation of Bud of Lentil (Lens culinaris). Pak. J. Botnol 36 (4), 801-809.
25. Noubani, R., Abu Irmaileh, B., & Afifi, F. 2006. Folk utilization of traditional medicinal plants among rural population in Wadi Mujib–Jordan. Jordan Med. J 40 (4), 232-240.
26. Lee, K.D., Tawaha A.R.M. & Supanjani, 2005. Antioxidant status, stomatal resistance and mineral composition of hot pepper under salinity and boron stress. Bioscience Research, 2(3), 148-154
27. Petropoulo, S.A., Levizou, E., Ntatsi, G., Fernandes, A., Petrotos, K., Akoumianakis, K., Barros L, & Ferreira, I.C. 2017. Salinity effect on nutritional value, chemical composition and bioactive compounds content of Cichorium spinosum L. Food Chem 214, 129–136.
28. Poudel, K., Praski, K., & Shestha, D. 2018. Micropropagation and acclimatization of large Cardamom (Amomum subulatum Roxb.). Turkish J. of Agri. Nat. Sci 5(3), 231–235.
29. Qaryouti, M.M., Qawasmi, W., Hamdan, H., & Edwan, M. 2001. Influence of NaCl salinity stress on yield, plant water uptake and drainage water of tomato grown in soilless culture. Acta Hortic 747, 539-544.
30. Othman, Y., Al-Karaki, G., Al-Tawaha, A.R. & Al- Horani, A. 2006. Variation in germination and ion uptake in barley genotypes under salinity condition. World Journal of Agricultural Sciences, 2(1), 11-15.
31. Shatnawi, M.A., Shibli, R.A., Qrunfleh, I., Bataeineh, K., & Obeidat M. 2007. In vitro propagation and cryopreservation of Prunus avium using vitrification and encapsulation dehydration methods. J. Food, Agri. Environ 5 (2),204-208.
32. Shatnawi, M., Al-Fauri, A., Megdadi, H., Al-Shatnawi, M.K., Shibli, R.A., Abu-Romman, S., & Al- Ghzawi, A. 2010. In vitro multiplication of Chrysanthemum morifolium Ramat and its responses to NaCl induced salinity. Jordan J. of Biol. Sci 3 (3), 101-110.
33. Shatnawi, M.A. 2011. Multiplication and cryogenic storage of Artemisia herba-alba: A medicinal plant. J. Food, Agri. Environ 9, 340-344.
34. Shatnawi, M.A. 2013. Multiplication and cryopreservation of Yarrow (Achillea millefolium L., Astraceae). J. Agric. Sci. Technol 15, 163-173.
35. Shatnawi, M.A., Shibli, R.A., Shahrour, W.G., Al- Qudah, T.S., & Abu-Zahra, T. 2019. Micropropagation and conservation of Fig (Ficus carica L.). J. Adv. Agric 10,1669-1679.
36. Shibli, R.A., Kushad, M., Yousef, G.G., & Lila, M.A. 2007. Physiological and biochemical responses of tomato microshoots to induce salinity stress with associated ethylene accumulation. Plant Growth Regul 51, 159-169.
37. Siddiqi, E.H., Ashraf, M., Al-Qurainy, F., & Akram, N.A. 2011. Salt induced modulation in inorganic nutrients, antioxidant enzymes, proline content and seed oil composition in safflower (Carthamus tinctorius L.). J. Sci. Food Agric 91,2785–2793.
38. Sibole, J .V., Cabot, C., Poschenreder, C, & Barcelo, J. 2003. Efficient leaf ion partitioning, an overriding condition for abscisic acid controlled stomatal and leaf growth responses to NaCl salinization in two legumes. J. Exp. Bot 54 (390), 2111–2119.
39. Silveira, J.A.G, Melo, A.R.B, Viégas, R.A, & Oliveira, J.T.A. 2001. Salinity-induced effects on nitrogen assimilation related to growth in cowpea plants. Exp. Exp. Bot 46(2),171-179.
40. SPSS. 2017. Complex samples, SPSS INC., Chicago ILL: USA.
41. Tien., Vinh, D., Hoa, M.T., Khai, P.C., & Minh T.V. 2017. Micropropagation of lavender (Lavandula angustifolia). J. Innov. Pharm Biol. Sci 4 (2), 7-11.
42. Yaish, M.W. & Kumar P.P. 2015. Salt tolerance research in date palm tree (Phoenix dactylifera L.), past, present, and future perspectives. Front. Plant Sci. 6, 348-352.
43. Zama, D., Tebibel, Z., Benayssa, W., Benayache, F., Benayache, S., & Vlietinc A.J. 2007. Chlorpyrifos-induced oxidative stress and tissue damage in the liver, kidney, brain and fetus in pregnant rats: The protective role of the butanolic extract of Paronychia argentea L. Indian J. of Pharmacol 39, 145-150.
44. Zhao, G.Q., Ma, B.L, & Ren, C.Z. 2007. Growth, gas exchange, chlorophyll fluorescence and ion content of naked oat in response to salinity. Crop Sci 47, 123-131.

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Bibliografia

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