甜樱桃果实雨裂机理研究

Q3 Agricultural and Biological Sciences Italus Hortus Pub Date : 2019-01-01 DOI:10.26353/j.itahort/2019.1.5965
M. Knoche
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引用次数: 1

摘要

甜樱桃(Prunus avium L.)的开裂严重限制了世界范围内的生产。它被认为是由过量的水摄取和随后的肿胀增加引起的。当超过临界阈值(“临界膨胀”)时,人们认为水果会破裂。缺乏支持这一广泛传播的概念的实验证据。相反,发表的数据质疑关键膨胀假说,必须考虑另一种解释。这篇迷你综述总结了过去二十年发表的实验研究,这些研究得出了甜樱桃开裂的另一种解释,即所谓的拉链假说。根据这一假设,开裂是一系列事件的结果,这些事件最终会在果皮和果肉上产生裂缝,并“解开”水果的拉链。它是基于以下事件的顺序:在第三阶段生长的皮肤中,特别是角质层中,由于参与角质层和蜡合成的基因下调而产生紧张(压力)。皮肤上的压力会导致角质层的应变和微裂缝。此外,角质层表面的潮湿和高湿度加剧了微开裂。微裂损害了角质层的屏障功能,并将水分吸收集中在果实表面的特定区域。水分绕过角质层,渗入果实,流向水势最负的地方。这些是外中果皮的大薄壁薄壁细胞,它们比小的厚壁表皮细胞和皮下细胞具有更大的负渗透电位。水分摄取导致单个细胞破裂。结果,细胞内容物渗漏到外质体中。甜樱桃的主要成分,如葡萄糖、果糖和苹果酸,现在以相当的浓度出现在外质体和共质体中。其结果有几个方面:首先,当表皮细胞在果肉汁液中酶解时,细胞肿胀减少并完全消失。其次,苹果酸提取细胞壁结合钙,削弱细胞壁,增加质膜的通透性,引起相邻细胞渗漏的连锁反应。细胞的渗漏和(低)膨胀的丧失导致细胞壁肿胀,特别是果胶中间薄片。肿胀的细胞壁降低了刚度、断裂张力和细胞粘附性,导致邻近细胞沿细胞壁分离。由皮肤张力产生的张力现在足以导致细胞沿着肿胀的壁分离并使皮肤破裂。这一过程在应力集中的裂纹尖端继续,导致裂纹伸长。这种皮肤以同样的方式“拉开”,就像在一块针织织物中传播的“拉链”或“梯子”。
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The mechanism of rain cracking of sweet cherry fruit
Sweet cherry (Prunus avium L.) cracking is a severe limitation in production worldwide. It is thought to be caused by excessive water uptake and a subsequent increase in turgor. When a critical threshold is exceeded (‘critical turgor’) the fruit is believed to crack. Experimental evidence supporting this wide spread concept is lacking. Instead, published data question the critical turgor hypothesis and an alternative explanation must be thought of. This mini review summarizes experimental research published in the last two decades that resulted in an alternative explanation of sweet cherry fruit cracking, the so called Zipper hypothesis. According to this hypothesis, cracking is the result of a series of events that ultimately propagate a crack through skin and flesh and ‘unzip’ the fruit. It is based on the following sequence of events: Tension (stress) develops in the skin during stage III growth and particularly in the cuticle due to a downregulation of genes involved in cutin and wax synthesis. Stress in the skin results in strain and microcracks in the cuticle. Furthermore, surface wetness on and high humidity above the strained cuticle aggravates microcracking. Microcracking impairs the cuticle’s barrier function and focuses water uptake in a particular region of the fruit surface. Water bypasses the cuticle, penetrates into the fruit and moves to sites where water potential is most negative. These are the large thin-walled parenchyma cells of the outer mesocarp that have a more negative osmotic potential than the small thick walled epidermal and hypodermal cells. Water uptake causes individual cells to burst. As a consequence, cell content leaks into the apoplast. Major constituents of sweet cherry such as glucose, fructose and malic acid now occur in the apoplast at comparable concentrations as in the symplast. The consequences are several fold: First, cell turgor decreases and is entirely lost when epidermal cells plasmolyse in the juice from the flesh. Second, malic acid extracts cell wall bound Ca, weakens cell walls and increases the permeability of plasma membranes causing a chain reaction of leakage of adjacent cells. The leakage of cells and the loss of the (low) turgor results in swelling of cell walls, in particular of the pectin middle lamella. Swollen cell walls have decreased stiffness, fracture tension and cell adhesion resulting in the separation of neighbouring cells along their cell walls. The tension generated by the strain of the skin is now sufficient to cause the cells to separate along their swollen walls and to rupture the skin. This process continues at the crack tip where the stress concentrates and causes the crack to elongate. The skin ‘unzips’ in the same way like a ‘zipper’ or a ‘ladder’ that propagates in a piece of knitted fabric.
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来源期刊
Italus Hortus
Italus Hortus Agricultural and Biological Sciences-Food Science
CiteScore
1.70
自引率
0.00%
发文量
18
期刊最新文献
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