Fragment viability, regenerative capacity and protoplast isolation of invasive Australian swamp stonecrop (Crassula helmsii)

IF 1.9 4区生物学 Q2 MARINE & FRESHWATER BIOLOGY

Aquatic Botany Pub Date : 2024-11-15 DOI:10.1016/j.aquabot.2024.103835

Menno W.J. Bok , Janneke M.M. van der Loop , Hein H. van Kleef , Rob S.E.W. Leuven

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引用次数: 0

Abstract

Australian swamp stonecrop (Crassula helmsii) is an amphibious plant native to Australasia and highly invasive in Europe. Managing the spread and impacts of this invader is challenging due to its ability to regenerate from small vegetative plant fragments. In several infested water systems in the Netherlands, the dispersal of this species is currently being prevented using water filters with a mesh size as small as 1 mm² in their outflows. However, it remains unclear whether these filters are truly capable of preventing the spread of small regenerative fragments. To identify potential shortcomings in the management of C. helmsii dispersal, we investigated the regeneration of detached vegetative fragments. A laboratory experiment was conducted to study the regenerative capacity of C. helmsii fragments of varying sizes (0.5–2 mm). We examined the growth performance (stem count, cumulative stem length) of fragments originating from nodes, leaves, shoots, roots, and meristem tissue cuts. All fragments originating from nodal tissue were able to successfully regenerate. Isolated meristem tissue of 0.5 mm was able to regenerate but exhibited malformed growth. Shoot tips demonstrated the best growth performance. While we successfully isolated protoplasts from C. helmsii node tissue, our cultures were compromised, and regeneration could not be assessed. Our research indicates regenerative potential from node fragments as small as a cluster of apical meristem cells. These findings suggest shortcomings in current measures for dispersal prevention of C. helmsii, as they do not prevent the dispersal of plant fragments with a length <2 mm. We recommend re-evaluating the effectiveness of various types of dispersal barriers currently applied in vulnerable natural areas to prevent the spread and subsequent regeneration of small vegetative fragments of C. helmsii.

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入侵的澳大利亚沼泽石竹（Crassula helmsii）的碎片活力、再生能力和原生质体分离

澳大利亚沼泽石竹（Crassula helmsii）是一种原产于澳大拉西亚的两栖植物，在欧洲具有很强的入侵性。由于这种入侵植物能从小植株碎片再生，因此管理其扩散和影响具有挑战性。目前，在荷兰几个受侵扰的水系中，使用网眼小至 1 平方毫米的滤水器防止该物种扩散。然而，目前还不清楚这些过滤器是否真的能够防止小型再生碎片的扩散。为了找出螺旋藻传播管理中的潜在缺陷，我们对脱离的无性碎片的再生进行了调查。我们进行了一项实验室实验，研究不同大小（0.5-2 毫米）的头鹤草（C. helmsii）碎片的再生能力。我们考察了来自节、叶、芽、根和分生组织切口的碎片的生长表现（茎数、累积茎长）。所有来自节组织的片段都能成功再生。0.5 毫米的分离分生组织能够再生，但表现出畸形生长。芽尖的生长表现最好。虽然我们成功地从 C. helmsii 节组织中分离出了原生质体，但我们的培养物受损，无法评估再生能力。我们的研究表明，小到一簇顶端分生组织细胞的节点碎片都具有再生潜力。这些研究结果表明，目前防止螺旋藻扩散的措施存在缺陷，因为这些措施无法防止长度为 2 毫米的植物碎片扩散。我们建议重新评估目前在脆弱的自然区域使用的各种类型的扩散屏障的有效性，以防止螺旋藻小植株片段的扩散和随后的再生。

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来源期刊

Aquatic Botany 生物-海洋与淡水生物学

CiteScore

3.80

自引率

5.60%

发文量

审稿时长

6 months

期刊介绍： Aquatic Botany offers a platform for papers relevant to a broad international readership on fundamental and applied aspects of marine and freshwater macroscopic plants in a context of ecology or environmental biology. This includes molecular, biochemical and physiological aspects of macroscopic aquatic plants as well as the classification, structure, function, dynamics and ecological interactions in plant-dominated aquatic communities and ecosystems. It is an outlet for papers dealing with research on the consequences of disturbance and stressors (e.g. environmental fluctuations and climate change, pollution, grazing and pathogens), use and management of aquatic plants (plant production and decomposition, commercial harvest, plant control) and the conservation of aquatic plant communities (breeding, transplantation and restoration). Specialized publications on certain rare taxa or papers on aquatic macroscopic plants from under-represented regions in the world can also find their place, subject to editor evaluation. Studies on fungi or microalgae will remain outside the scope of Aquatic Botany.