Rheological and Microstructural Features of Plant Culture Media Doped with Biopolymers: Influence on the Growth and Physiological Responses of In Vitro-Grown Shoots of Thymus lotocephalus

N. Coelho, Alexandra Filipe, B. Medronho, Solange Magalhães, C. Vitorino, L. F. Alves, S. Gonçalves, A. Romano
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引用次数: 6

Abstract

In vitro culture is an important biotechnological tool in plant research and an appropriate culture media is a key for a successful plant development under in vitro conditions. The use of natural compounds to improve culture media has been growing and biopolymers are interesting alternatives to synthetic compounds due to their low toxicity, biodegradability, renewability, and availability. In the present study, different culture media containing one biopolymer (chitosan, gum arabic) or a biopolymer derivative [hydroxyethyl cellulose (HEC), carboxymethyl cellulose (CMC)], at 100 or 1000 mg L−1, were tested regarding their influence on the growth and physiological responses of Thymus lotocephalus in vitro culture. Cellulose-based biopolymers (HEC and CMC) and gum arabic were used for the first time in plant culture media. The results showed that CMC at 100 mg L−1 significantly improved shoot elongation while chitosan, at the highest concentration, was detrimental to T. lotocephalus. Concerning only the evaluated physiological parameters, all tested biopolymers and biopolymer derivatives are safe to plants as there was no evidence of stress-induced changes on T. lotocephalus. The rheological and microstructural features of the culture media were assessed to understand how the biopolymers and biopolymer derivatives added to the culture medium could influence shoot growth. As expected, all media presented a gel-like behaviour with minor differences in the complex viscosity at the beginning of the culture period. Most media showed increased viscosity overtime. The surface area increased with the addition of biopolymers and biopolymer derivatives to the culture media and the average pore size was considerably lower for CMC at 100 mg L−1. The smaller pores of this medium might be related to a more efficient nutrients and water uptake by T. lotocephalus shoots, leading to a significant improvement in shoot elongation. In short, this study demonstrated that the different types of biopolymers and biopolymer derivatives added to culture medium can modify their microstructure and at the right concentrations, are harmless to T. lotocephalus shoots growing in vitro, and that CMC improves shoot length.
掺有生物聚合物的植物培养基流变学和微观结构特性:对胸腺离体芽生长和生理反应的影响
离体培养是植物研究中重要的生物技术手段,合适的培养基是植物在离体条件下发育成功的关键。使用天然化合物来改善培养基已经越来越多,生物聚合物由于其低毒、可生物降解、可再生和可用性而成为合成化合物的有趣替代品。在本研究中,研究了含有一种生物聚合物(壳聚糖、阿拉伯胶)或一种生物聚合物衍生物[羟乙基纤维素(HEC)、羧甲基纤维素(CMC)]的不同培养基,在100或1000 mg L−1浓度下,对离体培养胸腺生长和生理反应的影响。纤维素基生物聚合物(HEC和CMC)和阿拉伯胶首次用于植物培养基。结果表明,CMC在100 mg L−1浓度下显著提高了芽伸长,而壳聚糖在最高浓度下对小头天竺葵的芽伸长不利。仅就评估的生理参数而言,所有测试的生物聚合物和生物聚合物衍生物对植物都是安全的,因为没有证据表明生物聚合物和生物聚合物衍生物对小头莲有应激引起的变化。对培养基的流变学和微观结构特征进行了评估,以了解添加到培养基中的生物聚合物和生物聚合物衍生物如何影响芽的生长。正如预期的那样,在培养开始时,所有培养基都表现出凝胶样行为,在复合粘度方面存在微小差异。大多数介质随着时间的推移粘度增加。随着生物聚合物和生物聚合物衍生物的加入,培养液的表面积增加,CMC在100 mg L−1时的平均孔径明显减小。该培养基的气孔越小,可能与小头莲芽对养分和水分的吸收效率越高有关,从而显著提高了小头莲芽的伸长率。总之,本研究表明,在培养基中添加不同类型的生物聚合物及其衍生物可以改变其微观结构,并且在适当的浓度下,对离体生长的小头莲芽无害,CMC可以提高小头莲芽的长度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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