Next Article in Journal
Improvement and Assessment of Convolutional Neural Network for Tree Species Identification Based on Bark Characteristics
Previous Article in Journal
A Study to Assess the Conservation Effectiveness of Nature Reserves in Hainan, China, from 2000 to 2021
Previous Article in Special Issue
Spatial–Temporal Distribution Pattern of Ormosia hosiei in Sichuan under Different Climate Scenarios
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Forests
Volume 14
Issue 7
10.3390/f14071294
forests-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Effect of Waterlogging Stress on Leaf Anatomical Structure and Ultrastructure of Phoebe sheareri Seedlings

by
Fenghou Shi
1,*,
Zhujing Pan
1,
Pengfei Dai
1,
Yongbao Shen
1,
Yizeng Lu
2 and
Biao Han
2
1
Collaborative Innovation Centre of Sustainable Forestry in Southern China, College of Forestry, Nanjing Forestry University, Nanjing 210037, China
2
Shandong Provincial Center of Forest and Grass Germplasm Resources Resources, Jinan 250102, China
*
Author to whom correspondence should be addressed.
Forests 2023, 14(7), 1294; https://doi.org/10.3390/f14071294
Submission received: 20 May 2023 / Revised: 17 June 2023 / Accepted: 20 June 2023 / Published: 23 June 2023
(This article belongs to the Special Issue Advances in Plant Science Research: Celebrating Nanjing Forestry University’s 120th Anniversary)
Browse Figures
Review Reports Versions Notes

Abstract

:
Phoebe sheareri is an excellent roadside tree with a wide distribution range and high ornamental value. Excessive moisture can affect the external morphology, the microstructure, and the ultrastructure of the leaf. Little is known at present regarding the leaf structure of P. sheareri under waterlogging stress. In this paper, the external morphology of leaves, the microstructure of leaf epidermis, and the ultrastructure of mesophyll cells of P. sheareri seedlings under waterlogging stress and drainage were dynamically observed. Waterlogging stress contributed to the yellowing and wilting of P. sheareri seedling leaves, the gradual closing of leaf epidermal stomata, increasing density of leaf stomata, gradual loosening of the arrangement of leaf cell structure, and merging of leaf palisade tissue cells. Waterlogging stress forced the structure of the chloroplast membranes to blur, gradually causing swelling, and deformation, with plasmolysis occurring in severe cases. During waterlogging, the basal lamellae were disorganized, and the mitochondrial membrane structure was damaged. The damaged state of the leaves was not relieved after drainage. Waterlogging stress not only inhibited the growth of leaves, but also accelerated the closure of stomata, disordered the arrangement of palisade tissue and spongy tissue gradually, and damaged the internal organelles of mesophyll cells.

1. Introduction

Climate change affects atmospheric precipitation, leading to extreme weather events and an increase in the frequency and duration of floods [1,2]. During the plum rain season in the middle and lower reaches of the Yangtze River, China, there are extended periods of continuous heavy rainfall, which severely hinder seedling growth [3]. Moisture is one of the essential elements in the growth of seedlings, but waterlogging stress can arise from saturation or even excessive water in the soil [4]. Excessive water directly affects the diffusion of oxygen in plant tissue, forming an oxygen-deficient environment, and heavily impairing gas exchange between plants and the atmosphere [5]. Prolonged waterlogging and hypoxic environments ultimately lead to the accumulation of toxic metabolites and the increase of reactive oxygen species, affecting the physiological and biochemical processes of seedlings, and hindering the growth of seedlings, and, thus, eventually leading to cell death and plant senescence [6,7,8]. Although most plants perform poorly when waterlogged, they can resist waterlogging stress by changing their morphological structures, physiological characteristics, cell structures, etc. [5,9].
Under waterlogging conditions, the appearance of leaves may show signs of wilting, curling, or even abscission [10]. When 15~25-cm-tall Celosia argentea and Melampodium paludosum were waterlogged for ten days, the leaf of M. paludosuma appeared to droop after three days, and those of C. argentea appeared to droop after 7 days, and both had no ornamental value after the waterlogging treatment ended [11].
The effects of waterlogging stress on seedlings are not only reflected in the changes in external morphology, but also in changes in the internal cell structure of seedling leaves, such as the destruction of cell membrane structure, swelling and deformation of chloroplasts, loose arrangement of grana lamellae, and extravasation of mitochondrial contents [12,13,14]. Seedlings can cope with waterlogging stress by controlling stomatal closure level and leaf gas exchange rate, which can be reflected in the dynamic changes of leaf anatomical structure [15]. In the previous study, after seedlings of Sorghum bicolor were waterlogged for two weeks, leaf thickness significantly decreased, mainly due to changes in the thickness of the upper epidermal and mesophyll cells [16]. When Avicennia marina was waterlogged by means of experimentally simulated semidiurnal tides, it was observed that, with increasing duration of waterlogging, leaf thickness, mesophyll thickness, palisade parenchyma thickness, palisade–spongy ratio, and hypodermis thickness decreased, but the mesophyll to leaf thickness ratio increased [17]. After deep waterlogging treatment (with a waterlogging depth exceeding 20 cm of the soil layer), the leaf structure of Quercus shumardii blurred, some palisade tissue cells became irregular, becoming almost round or oval, the gap of sponge tissue cells became larger, and some lower epidermal cells disintegrated [18].
In addition, the morphology and structure of organelles. such as chloroplasts and mitochondria, in mesophyll cells change under waterlogging stress, which plays an important role in leaf photosynthesis [4]. In the study, a waterlogged pool of Zea mays was maintained at 2–3 cm above the soil surface. During the different waterlogging stages, the cytoderm structure of Z. mays became incomplete and exhibited indistinct gradation, irregular chloroplast configuration, reduction in chloroplast numbers in mesophyll cells, and dimming of the mitochondrial outer membrane. Fine-grained substance exosmosis occurred and structures became diluted after exposure to waterlogging [12]. Under waterlogging treatment, there were almost no substances in the cells of Chionanthus virginicus leaves, due to the chloroplasts degrading, starch particles accumulating in large quantities, and severe damage to the structure of the cells [19]. The chloroplasts of Carya illnoinensis showed similar changes after waterlogging for 30 days, in that the chloroplasts were swollen and rounded, the number of osmophilic particles increased, and the lamella structure began to loosen [20]. Thus, it is important to investigate the effects of waterlogging on leaves in terms of external morphology, anatomical structure and ultrastructure.
As an evergreen Phoebe tree in the Lauraceae family, Phoebe sheareri is suitable for places with warm, humid climates and fertile soil. P. sheareri has a long growth cycle, a tall and beautiful tree shape, and dense branches and leaves, and is an excellent shade tree and roadside tree with high ornamental value [21,22]. In addition, P. sheareri wood is hard, straight textured, corrosion-resistant, and durable, and has a special fragrance. It is is an excellent material for high-end furniture, architecture, and wooden utensils, and is the royal building material of choice for palaces, and tombs and for their gardens [23]. The phenomenon of waterlogging often occurs in the Yangtze River Delta region, which is an area where P. sheareri is widely distributed, so it is important to study the response of P. sheareri seedling leaves to waterlogging [24]. Currently, studies on the stress resistance of P. sheareri have mainly focused on low-temperature stress [25] and drought stress [26], and less research has been connducted on waterlogging stress.
Few studies have reported on the effects of different durations of waterlogging and drainage on the leaf morphology and structure of P. sheareri. In this study, we used the “double pot method” to artificially simulate the waterlogging experimental environment. The aims were the following: (1) to measure changes in the leaf morphology, leaf epidermal stomata, leaf anatomical structure and ultrastructure of P. sheareri under waterlogging and drainage; (2) to understand the changes and coping mechanisms of the leaf structure of P. sheareri seedlings in a waterlogging environment; (3) to provide basic waterlogging informational support for the promotion and application of the P. sheareri species.
Based on the results of the above-related studies, before the experiment began, we speculated that, during waterlogging treatment, the leaf morphology of Phoebe sheareri seedlings would exhibit gradual yellowing, falling off, and even dying. The leaf anatomical structure would gradually change, with the width and opening and closing degrees of the leaf epidermal layer becoming smaller, the palisade tissue cells becoming irregular and nearly round or oval, the cell spaces becoming larger, and the leaf thickness decreasing. In leaf ultrastructure, the chloroplast and mitochondrial organelles would be damaged, the chloroplast shape would change, gradually swelling and becoming round, the lamellar structure would gradually loosen, the mitochondrial membrane would be damaged, and the contents would exude. We further speculated that the damaged states of leaf morphology, anatomical structure and ultrastructure might not improve after drainage treatment of Phoebe sheareri seedlings after the waterlogging.

2. Materials and Methods

2.1. Plant Materials

The experimental materials were 2-year-old container seedlings of P. sheareri. The seeds were collected from the wild population of Qionglong Mountain, Suzhou, Jiangsu Province. In the middle of June 2020, container seedlings, with basically the same growth, were selected for pot change transplanting. The transplanting container was a plastic flowerpot with a height of 20 cm, an upper diameter of 23 cm, and a lower diameter of 19 cm, The seedling substrate was produced by Jiangsu Xingnong Substrate Technology Co., Ltd., (Zhenjiang, China) with a dry bulk density of 0.4 g/cm3, total porosity of 64%, large to small porosity ratio of 1:5, pH 7.6, EC 3.2, organic matter content of 41%, and total nitrogen, phosphorus, and potassium content of 3.8%. When transplanting, the seedling substrate from the original containers was gently washed away to preserve the entire root system of the seedlings as much as possible; An equal amount of seedling substrate was put into each plastic flowerpot, and one seedling transplanted to each container. Sufficient root fixing water was poured in. After transplanting, the seedlings were placed in the greenhouse of Baima Teaching and Scientific Research Base of Nanjing Forestry University (Baima Town, Lishui District, Nanjing, China) for slow seedling growth, during which normal water and fertilizer management was carried out.

2.2. Waterlogging Treatment

To explore the leaf morphology, anatomical structure and ultrastructure changes in P. sheareri under waterlogged and waterlogged–drainage conditions, we used the “double pot method” to artificially simulate the waterlogging environment.
This experiment adopted a single factor completely randomized block design and consisted of two parts: a waterlogging experiment and a waterlogging–drainage experiment. A total of 180 plants, with roughly the same growth potential, were used in the two-part experiment, from which 30 seedlings were randomly selected for each treatment, and three biological replicates were applied. A total of 120 seedlings were divided into four waterlogging experiments. A total of 60 seedlings participated in the drainage process, being waterlogged for 12 days and drained for 6 days and 12 days, respectively. The seedlings under normal management and without waterlogging treatment were used as the control group (Table 1).
The waterlogging treatment began on 11 September 2020, named the 0-day for waterlogging stress. In adopting the “double pot method”, the seedlings of P. sheareri were placed in a lotus basin together with a plastic pot, and tap water was poured in to obtain a water level approximately 2–5 cm above the substrate (Figure 1). Throughout the test, the water level change was observed, and timely replenishment maintained the submergence level. The waterlogging-drainage treatment involved removing seedlings treated with waterlogging for 12 days from their lotus pots and draining the substrate naturally without water.

2.3. Indicator Determination

Plant sampling: we observed and photographed the overall shape and morphological changes of seedlings during the treatment of waterlogging stress and drainage. At 9:00 a.m. on the sampling day, 3–5 standard plants were selected, and the 3rd to 5th intact functional leaves from the bottom to the top of the seedlings were collected, and washed with tap water several times to remove any dirt and dust accumulated on their surfaces. Small circular pieces, about 0.5 cm wide, from the central part of the leaves (avoiding the main veins), were taken as samples, put into glutaraldehyde fixative solution, and stored at 4 °C, so as to observe the changes in the stomata, anatomical structure and microstructure of the seedling leaves.
Seedling leaf morphological observation: we observed the morphological changes of P. sheareri seedlings and their leaves, and took pictures to record the growth status of seedlings and leaves under different waterlogging and drainage periods.
Stomata and anatomical structure of seedling leaf epidermis: referring to the method of Jain et al. [27], the leaf stomata and anatomical structure of P. sheareri seedlings were observed, recorded and photographed using Scanning Electron Microscopy (SEM).
The samples were taken out of the glutaraldehyde, and rinsed to remove traces of glutaraldehyde. The fixed samples were dehydrated through a series of dehydrating solutions (gradually dehydrated at 30%, 70%, 80%, and 90% ethanol gradients), and subjected to critical point drying. The dehydrated samples were fixed on an adhesive platform and sputtered with a film of gold using an ion-beam sputter coater. The samples were examined under an FEI Quanta 200 Scanning Electron Microscope (USA) at Nanjing forestry university, Nanjing, China. The stomatal length, stomatal width, stomatal opening rate, and stomatal number per unit area were observed and photographed under a 600× microscope, and were measured by Image J (a free, Java-based image-processing package, version 1.8.0.112). This process was repeated 3 times, and 5 visual fields were randomly observed to calculate the average value.
Microstructure of seedling mesophyll cells: referring to the method of Salah et al. [28], the internal ultrastructure of mesophyll cells of P. sheareri was observed, recorded and photographed with a transmission electron microscope.
The samples were taken out and washed 3 times with 100 mmol/L phosphoric acid buffer at pH 7.4. They were fixed in 1% buffered osmium tetroxide for 1 h (this process was carried out in a fume hood) and then cleaned 3 times for 10 min each time. Then, the samples were placed in ethanol of different concentration gradients (30%, 45%, 60%, 75%) for dehydration treatment. Finally, the samples were treated with anhydrous ethanol and pure acetone for 30 min. After the above dehydration treatment, the samples were soaked in Spurr’s epoxy resin (Sigma-Aldrich, St. Louis, MO, USA) for 12 h, and kept in a dark environment. Using an ultra-thin slicer, the samples were sliced into 50 nm sections. After staining, the samples were observed and photographed under transmission electron microscopy (JEM 2100 High-Resolution Transmission Electron Microscopy, Tokyo, Japan). This was repeated 3 times, and 3 visual fields randomly observed.

2.4. Statistical Analysis

A Shapiro–Wilk test, one-way analysis of variance (ANOVA) data analyses and Duncan multiple comparisons were performed with SPSS version 22.0, which were used to assess data normality and to analyze the differences in the waterlogging and waterlogging–drainage treatments, respectively. Comparisons with p values less than 0.05 were considered significantly different (expressed in lowercase letters), and those with less than 0.01 were considered extremely significantly different (expressed in uppercase letters). The correlation analyses were performed with the Pearson model two-tail test.

3. Results

3.1. Changes in Leaf Morphology of Phoebe sheareri Seedlings during Waterlogging Stress and Drainage

With the extension of waterlogging stress time, the leaf morphology of P. sheareri seedlings changed (Table 2). New leaves sprouted on the seedlings of P. sheareri after 6 days of waterlogging stress. Under waterlogging stress for 12 days, some leaves drooped for a short time at noon or dusk, but the droop disappeared at night and early morning. However, after 18 days of waterlogging, the leaves wilted continuously and did not recover, which indicated that the leaves were severely damaged. The seedlings that had been waterlogged for 12 days were drained. When they were drained for 6 days, the leaves drooped, wilted, and became chlorotic. Nearly 50% of the seedlings died. When the seedlings were drained for 12 days, 50% of the leaf lost green coloring and turned yellow, 50% of the leaf withered and fell off, 83% of the P. sheareri seedlings died, the leaves did not recover to their states before waterlogging and showed more serious damage.

3.2. Changes in Leaf Epidermal Stomata of Phoebe sheareri Seedlings during Waterlogging Stress and Drainage

3.2.1. Effects of Waterlogging Stress on Leaf Epidermis Stomata of Phoebe sheareri Seedlings

The stomata of P. sheareri seedling leaves are concentrated in the lower epidermis of the leaves, are mostly oval or nearly round, and the stomata apparatus is composed of two kidney-shaped guard cells (Figure 2a). The observation of stomata in the leaf epidermis of P. sheareri under waterlogging stress showed that, with the extension of stress time, stomata in the leaf epidermis gradually closed, and its opening degree gradually decreased (Figure 2).
With the extension of waterlogging stress time, the stomatal length in the leaves of P. sheareri seedlings did not change significantly, and the stomatal width showed a gradually decreasing trend (Table 3 and Table A1). The stomatal width of seedlings under waterlogging stress for 6 days had extremely significant differences from those of other treatments (p < 0.01). Compared to waterlogging stress for 12 days and 18 days, the stomatal width increased by 2.56 μm and 2.85 μm, respectively, during waterlogging stress for 6 days. The effect of waterlogging stress on leaf stomatal opening rate reached an extremely significant level (p < 0.01) and gradually decreased with the extension of waterlogging time. Compared with the control group, the stomatal opening rate decreased by 14.52% after 18 days of waterlogging treatment. At 18 days of waterlogging stress, the stomatal width and stomatal opening rate of P. sheareri seedlings were the lowest, at 2.67 μm and 13.03%, respectively. Under the condition of waterlogging stress, the stomatal density of P. sheareri seedlings increased gradually, and there were extremely significant differences among different treatments (p < 0.01). The order, from large to small, was the following: waterlogging stress for 18 days > waterlogging stress for 12 days > waterlogging stress for 6 days > Control group).

3.2.2. Effect of the Waterlogging-Drainage Process on Leaf Epidermal Stomata of Phoebe sheareri Seedlings

With the extension of drainage time, the stomatal opening degree and the number of stomata per unit area witnessed gradual decrease (Figure 3c,d). The leaf stomatal length of P. sheareri seedlings showed gradual increase after drainage (Table 4 and Table A2), among which, the leaf stomatal length of the seedlings drained for 12 days had extremely significant differences from that of the control seedlings (p < 0.01), and had significant differences from that of the seedlings waterlogged for 12 days and drained for 6 days (p < 0.05). After waterlogging stress for 12 days and drainage for 12 days, leaf stomatal length reached a maximum (16.16 μm), with an increase of 2.81 μm compared with the control group.
Compared with 12 days of waterlogging treatment, there was no significant change in leaf stomatal width after 6 days and 12 days of drainage. After drainage, the stomatal opening rate of seedlings decreased with the extension of drainage time. The stomatal opening rate of the P. sheareri seedlings drained for 12 days was extremely significantly lower than that of the control seedlings and of the seedlings under waterlogging stress for 12 days (p < 0.01). In terms of leaf stomatal density, there was an extremely significant difference between that of seedlings waterlogged for 12 days and that of seedlings drained for 12 days (p < 0.01), with a difference of 654 n/mm2, but no significant differences between that of seedlings waterlogged for 12 days and that of seedlings drained for 6 days.

3.3. Changes in Leaf Anatomical Structure of Phoebe sheareri Seedlings during Waterlogging Stress and Drainage Process

3.3.1. Effects of Waterlogging Stress on Leaf Anatomical Structure of Phoebe sheareri Seedlings

With the extension of waterlogging stress time, the internal structure of P. sheareri leaves changed (Figure 4). The upper and lower epidermis cells of the control seedlings were arranged neatly and closely, the palisade tissue cells were plump and arranged neatly in a long column, and the spongy tissue cells were nearly round and arranged loosely (Figure 4a). There were no obvious changes in the anatomical structure of P. sheareri seedling leaves when they were waterlogged for 6 days (Figure 4b). After 12 days of waterlogging stress, palisade tissue cells of seedling leaves fused with unclear boundaries and loose arrangements, and the spongy tissue cells became smaller (Figure 4c). After 18 days of waterlogging stress, due to the narrowing of lower epidermis cells and the widening of upper epidermis cells, the palisade tissue cells shortened with increased intercellular spaces, and disorderly arranged spongy tissue cells (Figure 4d).
With the extension of waterlogging stress time, the total leaf thickness of P. sheareri seedlings witnessed an initial increase and then a decrease (Table 5 and Table A3). The total leaf thickness of P. sheareri seedlings reached the maximum (88.58 μm) under waterlogging stress for 6 days, presenting a significant difference compared with those of seedlings at other waterlogging stress time nodes (p < 0.01).
In the process of waterlogging stress, the upper epidermis thickness of P. sheareri seedling leaves did not change significantly. At 6 days of waterlogging stress, the thickness of the upper epidermis reached the maximum value (6.82 μm), with a difference of 0.88 μm compared with the control group. Compared to that of the control seedlings, the thickness of the lower epidermis of the seedlings’ leaves under waterlogging stress showed a decreasing trend, during which the difference between the lower epidermal thickness of the seedlings waterlogged for 6 days and those of the seedlings enduring waterlogged stress for 12 days and 18 days reached a very extremely significant level (p < 0.01).
The leaf palisade tissue thickness of P. sheareri seedlings at the different waterlogging times was in the following order: waterlogging stress for 6 days > Control group > waterlogging stress for 12 days > waterlogging stress for 18 days. The palisade tissue thickness reached the maximum at 6 days after waterlogging treatment, and there was an extremely significant difference between other treatments (p < 0.01). The thicknesses of leaf spongy tissue among different treatments experienced significant differences (p < 0.05), and showed a trend of initial increase and subsequent decrease with the extension of stress time. Compared with the control group, the palisade tissue thickness increased by 4.74 μm after 6 days of waterlogging treatment, with extremely significant differences (p < 0.01).
The thickness ratio of palisade tissue to the spongy tissue of P. sheareri seedling leaves treated with waterlogging was larger than that of the control, and decreased gradually with the extension of waterlogging stress time. The ratio of palisade tissue to spongy tissue reached the maximum value at waterlogging stress for 6 days, and was extremely significantly higher than those at 18 days of waterlogging treatment and the control group (p < 0.01).

3.3.2. Effect of Waterlogging-Drainage Process on the Anatomical Structure of Phoebe sheareri Seedling Leaves

After 6 days of drainage, the cross-sections of upper epidermal cells on the leaf surface became wider and were nearly rectangular (Figure 5c). The cross-sections of lower epidermal cells become narrower with palisade tissues arranged loosely and the spongy tissue cells thickened (Figure 5c). After 12 days of drainage, the degree of damage of cells in each part of the seedling leaves was aggravated, the upper epidermis cells became narrower, and the palisade tissue cells became shorter, and, thus, the cell gap increased, the palisade tissue and spongy tissue cells fused with blurred boundaries, increased layer number and enlarged thickness of spongy tissue cells (Figure 5d).
The total leaf thickness of the seedlings decreased gradually after drainage, and there was no significant difference between the seedlings after 12 days of waterlogging (Table 6 and Table A4). The upper epidermal thickness of the leaves of P. sheareri seedlings showed a trend of increasing and then decreasing after drainage; in contrast, the lower epidermal thickness of the leaves showed a trend of decreasing and then increasing. The thickness of the upper epidermis reached its minimum value at 12 days of drainage, which was significantly different from other treatments (p < 0.01). The thickness of the lower epidermis reached the minimum value at 6 days of drainage, which decreased by 1.08 μm compared to 12 days of waterlogging stress and by 5.43 μm compared to the control. There was an extremely significant difference between the thicknesses of the lower epidermal layers of the leaves of P. sheareri seedlings drained for 6 days and those drained for 12 days (p < 0.01).
With the extension of drainage time, the thickness of leaf palisade tissue of P. sheareri seedlings decreased initially and then increased, and the thickness of palisade tissue of seedling leaves treated with drainage was extremely significantly smaller than those of the control seedlings and the 12-day-waterlogged seedlings (p < 0.01). The thickness of spongy tissue in the leaves of P. sheareri seedlings increased first and then decreased after drainage, which was extremely significantly different from that of the control seedlings (p < 0.01). Compared with waterlogging stress for 12 days, the spongy tissue thickness increased after 12 days and 18 days of drainage, by 3.12 μm and 2.47 μm, respectively.
The thickness ratio of palisade tissue to spongy tissue in seedling leaves drained for 6 days was significantly different from that of control seedlings (p < 0.05), but the thickness ratio of palisade tissue to spongy tissue in leaves was not significantly different between the seedlings drained for 12 days and the control seedlings. The ratio of palisade tissue to spongy tissue decreased by 41.56% and 36.25%, respectively, after drainage for 12 days and 18 days, compared with waterlogging stress for 12 days.

3.4. Ultrastructural Changes in Mesophyll cells of Phoebe sheareri Seedlings during Waterlogging Stress and Drainage

3.4.1. Effect of the Ultrastructure of Leaf Mesophyll Cells of Phoebe sheareri Seedlings under Waterlogging Stress

With the extension of waterlogging stress time, the organelle structures, such as the structures of chloroplasts and mitochondria, in the leaves of P. sheareri seedlings changed to different degrees (Figure 6).
The cell walls of seedling leaves without waterlogged treatment were smooth, clear, and complete, and the cytoplasmic membrane was intact without folds (Figure 6a). The structure of the inner and outer membranes of the chloroplast was visible. It was fusiform and distributed in the inner membrane of the plasma membrane along its long axis with the thylakoids packed tightly, the grana lamellae arranged neatly, and a few plastid pellets and starch grains randomly distributed in the chloroplast. The mitochondrial structure was normal and complete, and its capsule visible, which was circular and distributed near the chloroplast with many inclusions.
After 6 days of waterlogging stress, the structure of the chloroplast membrane in seedling leaves was still clear and intact, but the chloroplasts were swollen in oval shapes, some chloroplasts had separated from the cell wall and moved toward the center of the cell, and the thylakoids were still stacked but not obviously so, the arrangement of the lamellae of some basal grains had changed, which might have been caused by the extrusion of starch grains (Figure 6b). The starch grains gradually became larger, some of them appeared with bright and dark stripes, and the mitochondrial structure was normal, distributed near chloroplasts, without obvious changes.
After 12 days of waterlogging stress, the chloroplast outer membrane of seedling leaf cells was no longer clear and there were impurities attached (Figure 6c). The chloroplast had clearly swelled, from spindle shapes to irregular ellipses. Plasmolysis appeared with blurred thylakoid structure and disorderly arranged grana lamellae. The plastid pellets had clearly swelled and increased. The outer membranes of the mitochondria were damaged, broken and incomplete, the contents of the mitochondria had spilled out, the matrix had become thinner, and the inner crest structure had vanished.
After 18 days of waterlogging stress, the chloroplast membrane of seedling leaf cells was wavy with rough edges, loose basal lamellae and partial dissolution (Figure 6d). Holes had appeared, and the starch grains in the chloroplast cells were irregular in shape, and distributed with many bright and dark stripes. Meanwhile, the plastid pellets were irregular and round. The mitochondrial outer membrane rupture was incomplete with impurities attached, some of the mitochondria merged, and some mitochondria had formed small vacuoles due to the break of the outer membrane and the outflow of the contents.

3.4.2. Effect of the Waterlogging-Drainage Process on the Ultrastructure of Leaf Mesophyll Cells of Phoebe sheareri Seedlings

The chloroplast outer membranes of leaf cells became rough with attached impurities when the seedlings were waterlogged for 12 days and drained for 6 days (Figure 7c). The chloroplasts swelled and distorted to an irregular oval shape. Meanwhile, their quantity decreased, and plasmolysis occurred. The thylakoid and grana inside the cells were blurred due to the disappearance of compact structure and the disorder of grana lamellae. The color of plastid pellets became lighter and dark patches appeared. The outer membranes of mitochondria were damaged, broken, and incomplete, and, thus, phenomena like the outflow of mitochondria inclusions, thinned matrix, and the disappearance of the inner crest structure occurred.
After 12 days of drainage, the leaf mesophyll cells were severely atrophied, and the outer membranes of the chloroplasts were wavy with impurities attached (Figure 7d). With intensified plasmolysis, the volume of plastid pellets became larger, the number and volume of starch grains increased, and some starch grains showed irregular shapes, due to the extrusion of plastid pellets. Impurities were attached to the outer membranes of mitochondria, and the structure of the inner crest disappeared.

3.5. Correlation Analysis of Leaf Structure Indexes of Phoebe sheareri Seedlings during Waterlogging Stress and Drainage

When the seedlings were drained after 12 days of waterlogging, the leaf anatomical structure of the seedlings witnessed significant change, which affected photosynthesis, respiration, and transpiration of leaves, as well as the growth and physiological metabolism of the seedlings. To investigate the relationship of leaf anatomical structure, correlation analysis was performed on related indicators of P. sheareri seedling leaves during waterlogging stress and the drainage process, respectively (Table 7 and Table 8).
When P. sheareri seedlings were treated with drainage after waterlogging, there was a certain correlation between the stomatal structure and anatomical structure of leaves (Table 8). There was a significant negative correlation between leaf stomatal density and thinner epidermis thickness (0.01 < p < 0.05). The leaf stomatal opening rate was significantly positively correlated with the stomatal width (0.01 < p < 0.05). The total leaf thickness had an extremely significant positive correlation with the stomatal width and the stomatal opening (p < 0.01).
Under conditions of waterlogging stress, a certain correlation existed between leaf stomatal structure and leaf anatomical structure indices of P. sheareri seedlings (Table 7). There was an extremely significant negative correlation between stomatal density and the thickness of the lower epidermis (p < 0.01), the reason being that the stomatal density of P. sheareri concentrates in the lower epidermis, and change of stomatal density is closely related to change in lower epidermis thickness. The stomatal opening rate of the leaf epidermis was significantly positively correlated with stomatal width (p < 0.05), and significantly negatively correlated with stomatal density (0.01 < p < 0.05), indicating that the stomatal opening degree of P. sheareri seedlings was mainly affected by stomatal width and stomatal density during the waterlogging process. The thickness of spongy tissue was significantly positively correlated with the thickness of palisade tissue (p < 0.05).

4. Discussion

In the waterlogged environment, on the one hand, seedlings maintain their metabolic activity by consuming carbon reserves to facilitate the development of aerenchyma, adventitious roots, and hypertrophied lenticels, and, on the other hand, they decrease their metabolisms to preserve compounds for use in post-hypoxic conditions [29]. Waterlogging stress leads to hypoxia in the root system of seedlings, which, in turn, causes damage to the above-ground parts of seedlings, including leaves and other tissues and organs, through the accumulation of oxidation products [30,31].

4.1. Leaf Morphology

Under adverse circumstances, the change of leaf morphology is the most intuitive manifestation of the physiological state of seedlings. Changes in leaf shape can be environmentally induced, demonstrating that leaves are capable of responding to the surrounding climate conditions in a flexible manner [30]. Under conditions of waterlogging stress, the morphology of seedlings changes adaptively, the formation and growth of new leaves is blocked, the seedlings gradually age and fall off, and the growth of seedlings slows down [11]. Due to waterlogging stress, the leaves of Pterocarya stenoptera [32] and Morus alba [33] seedlings turned yellow, wilted, withered, and fell off. However, some studies have found that different plant species exhibit varying degrees of waterlogging symptoms due to their waterlogging tolerance. For example, after 18 days of waterlogging stress treatment, the lower leaves of Populus seedlings sensitive to waterlogging stress showed obvious chlorosis, while those tolerant to waterlogging stress had no significant change [34]. This paper demonstrates that, with the extension of waterlogging stress time, the leaves of P. sheareri seedlings gradually wilted, withered, and even fell off, which was similar to the research results of Kumutha et al. [35], Geng et al. [36], etc. In the early stage of waterlogging, the seedlings of P. sheareri grew new leaves and showed a short-term and recoverable wilting phenomenon. With the extension of waterlogging time, the wilting phenomenon of seedlings continued and could not be recovered. This was because the short-term waterlogging environment made P. sheareri seedlings mobilize their stress resistance mechanism to produce a large amount of energy and maintain the normal physiological metabolism of the seedlings, which was more conducive to the growth of P. sheareri seedlings. Waterlogging also had no significant effect on the growth and morphology of Malus hupehensis (Pamp.) Rehd. at the beginning of waterlogged treatment [37]. However, a long-term continuous waterlogging environment led to hypoxia in the roots of the seedlings, which made it impossible to synthesize and transform more energy to support growth, which was similar to the results of Cerasus campanulata after being waterlogged [38]. Consequently, the damaged metabolic mechanism in the seedlings blocked the synthesis of organic matter, inhibited the normal physiological metabolic process, affected the leaf morphology, and even led to leaf abscission [39].
This paper found that after waterlogging stress was relieved, the seedlings did not return to the state when waterlogged or before waterlogging. After 12 days of drainage, the seedlings appeared with the phenomenon of leaf abscission, and the survival rate declined steadily, which was different from Taxodium ‘Zhongshansha 407’, which survived without obvious symptoms of damage after relief of waterlogging [40]. The discrepancy results from Taxodium ‘Zhongshansha 407’ being a strong water-tolerant plant, maintaining a static watering-resistant strategy during the watering-out process [41,42]. However, it has also been shown that during the follow-up observation, grass plants, such as Cynodon dactylon, began to sprout new buds after the waterlogging environment was relieved, indicating that long-term waterlogging did not seriously affect their normal physiological functions, and the seedlings could recover growth through self-repair after the waterlogging stress was relieved [43]. The reason is that, although the leaf structures and functions of the seedlings were damaged under the condition of long-time continuous hypoxia, the overall growth of the seedlings was not affected, and survival could be guaranteed by adjusting the material and energy distribution of organs [40]. This suggests that the recovery process mainly depends on the type of species and nutrient reserves [44,45]. Plants with low levels of nutrient reserves cannot survive and grow with reserve substances under waterlogging for a long time [41].

4.2. Stomata and Anatomical Structure of Leaf Epidermis

The response of leaf epidermal structure to waterlogging stress is mainly reflected in the shape and arrangement of leaf epidermal cells, stomatal conductance, and stomatal density. The seedlings exchange gas, water, and signals with the external environment through the adjustment of stomatal size and density, which play an important role in the regulation of stress resistance [46,47]. Leaves respond to stress by changing stomatal size, degrees of opening and closing, and density [48]. Leaf stomata are sensitive to the leaf water status. Stomata close actively to reduce water evaporation and increase waterlogging tolerance [12,49]. In this paper, it was found that waterlogging stress reduced the activity of guard cells in leaves of P. sheareri seedlings, and contributed to change of stomatal morphology and movement, increase in the ratio of length to width for stomata in the lower epidermis and stomatal density, as well as decreased stomatal opening degree, similar to the results of Gu et al. [50]. It is an adaptive strategy for plants, and under waterlogging conditions, plants growing in permanently damp environments have more stomata than those growing in dry habitats [49]. To maintain normal gas exchange and energy balance, the leaves quickly close part of the stomata, which may reduce leaf transpiration and the damage of waterlogging stress [51]. At the same time, the smaller the stomata, the higher the water use efficiency under conditions of favorable water supply [52]. The leaf stomatal status of P. sheareri seedlings gradually recovered after the waterlogging stress was relieved, but could not be restored to the state before waterlogging. The reason for this is that the waterlogging stress seriously damaged the stomatal state of the leaves and the internal cell structure, and even with drainage the stomatal status could not be recovered.
The leaf is the main organ for photosynthesis, respiration and transpiration of seedlings, and the unification of morphological structural change and function is the biological basis for seedlings to adapt to the growth environment [53,54]. It was found that under the condition of waterlogging, the upper epidermal cells, lower epidermal cells and palisade tissue cells of P. sheareri leaves transformed from a tight and neat arrangement to a loose arrangement. At the later stage of stress, the palisade tissue cells fused, the gaps became larger, and spongy tissue cells became smaller and were disorderly in arrangement, similar to the research results of Ren et al. [12]. Yin et al. [51] observed that intercellular spaces increased significantly in Chrysanthemum zawadskii leaves under waterlogged conditions, which facilitated rapid gas exchange. Intercellular spaces appeared in the leaf structure, which represented another positive adaptation to waterlogging, which could improve the capacity for oxygen capture, and help to store and exchange gases within the waterlogged tissues [55,56]. With the extension of stress time, the thickness of the upper epidermis and palisade tissue, and the ratio of the palisade tissue to spongy tissue of P. sheareri leaves experienced an initial increase and a subsequent decrease. This finding was different from that reported by Zhang et al. [16], who observed that the leaf thickness of Sorghum bicolor decreased under waterlogging stress, mainly due to changes in the thickness of the upper epidermal and mesophyll cells. The leaf thickness and its components increased differently after 6 days of waterlogging, which indicated that the stress-resistant mechanism of seedlings could respond quickly in a short time to maintain the normal growth of seedlings through leaf thickening, promoting the development of seedling leaves to a certain extent, similar to the results for Chrysanthemum zawadskii [49]. At the later stage of waterlogging stress, the leaf thickness was thinner due to decreased turgor pressure, which caused the enlargement of the cell gap and the loose arrangement of cells affecting the thickness of leaves [16].
After being relieved of waterlogging stress, the anatomical structure of P. sheareri seedling leaves confirmed that the degree of damage to all parts of the cells was aggravated, in that the upper epidermis cells became narrow, palisade tissue and spongy tissue cells were fused with blurred boundaries, the thickness of leaves and their components were not much different from those of the waterlogged seedlings, and even showed signs of gradual thinning. The reason is that although they grew in a normal water environment after drainage, the leaf structure of P. sheareri seedlings had been seriously and irreversibly damaged during the waterlogging process.

4.3. Mesophyll Cell Ultrastructure

Photosynthesis is directly influenced by the morphology and ultrastructure of chloroplasts, and in adverse circumstances, the obvious organelles in plant mesophyll cells are chloroplasts and mitochondria [28]. Their morphologies and internal structures change with the external environment [12]. This paper found that under the conditions of waterlogging stress, the chloroplast membrane structure of seedling leaf cells ruptured gradually, the chloroplasts swelled continuously, deforming from spindles to irregular ellipses and separating from the cell wall with a tendency to move towards the center of the cell. The grana and thylakoids lost their compact and orderly arrangements and the grana lamellae gradually twisted. Thylakoid membrane degradation and lipid accumulation increased the number and volume of plastid pellets. Such changes also occurred in the waterlogging stress experiments of Zea mays and Sorghum bicolor [12,14]. The chloroplasts of Kosteletzkya virginica became spherical and their volume decreased under waterlogging. Moreover, the lamellae of thylakoids swelled, and chloroplast inclusions decreased [13]. Waterlogging damages the ultrastructure of mesophyll cells and reduces the photosynthetic capacity of the leaf [57]. The breakdown of membrane systems caused by waterlogging on mesophyll cells results in apoptosis and the loss of photosynthetic potential [58].
Compared with the seedlings waterlogged for 12 days, the ultrastructure of mesophyll cells in the seedlings drained for 6 days did not change significantly and did not show obvious signs of recovery. After 12 days of drainage, the chloroplast structure of leaf cells was further damaged, the outer membranes of chloroplasts blurred, the swelling of chloroplasts was aggravated, the separation of plasma wall was obvious, and a large amount of starch accumulated to form large starch granules, indicating that 12 days after the stress was relieved, the damage to chloroplasts was more serious than that caused by waterlogging. The reason is that the waterlogging environment caused irreversible damage to the chloroplast structure of P. sheareri seedlings. The chloroplast membrane gradually disintegrated, and grana and starch grains piled up together, resulting in the decline of the photosynthetic areas and hindering normal photosynthesis. The chloroplast structure could not be restored to the normal state after the stress was relieved [59]. In addition, this paper confirmed that there was a certain correlation between the abnormality of chloroplast structure and leaf color of P. sheareri seedlings during waterlogging progression. When waterlogged for 12 days, the young leaves of P. sheareri seedlings wilted, curled, and turned yellow. Among the chloroplast ultrastructures over the same period, it was observed that the thylakoid had a fuzzy structure, and the number and volume of plastid pellets increased, which was similar to the research results of Sun et al. [60] and Liu et al. [61].
As important organelles in respiration, mitochondria can not only provide energy for various life activities, but also participate in processes such as cell differentiation, cell information transmission, and cell apoptosis, with the ability to regulate cell growth and cell cycle [62]. Furthermore, certain mitochondria grow longer and become dysfunctional with time, and their membranes disintegrate [57]. After 12 days of waterlogging stress, the mitochondrial structure of P. sheareri seedling leaf cells began to change significantly, as the outer membranes broke and degraded, and contents flowed out. With the extension of stress time, the mitochondrial damage intensified, the membrane structure was damaged and degraded gradually, and the mitochondria fused. The phenomenon of mitochondria gradually swelling and finally disintegrating under waterlogging also occurred in Kosteletzkya virginica [11]. After the stress was relieved, the ultrastructure of mitochondria in leaf cells was not significantly improved, and the structure was still loose and fuzzy, indicating that the respiratory function of P. sheareri seedlings was damaged after drainage. Observation of Cabernet sauvignon cells found that vitamin C in mitochondria may flow out together with the contents, thereby causing programmed cell death (PCD), resulting in partial mitochondrial apoptosis and the formation of small vacuoles [63]. Some studies have also found that cell necrosis caused by programmed cell death of chloroplasts and mitochondria may be one of the mechanisms by which Ammodendron argenteum and Triticum aestivum seedlings adapt to water stress [64,65].
Under stress conditions, two organelles, the chloroplasts and the mitochondria, interact with each other. After the mitochondrial structure is destroyed, the metabolism of the seedling is disordered, unable to provide energy for the transport of photosynthetic products and, thus, affecting the transport of photosynthetic products in the chloroplasts for seedling survival [66]. As a result, a large amount of starch accumulates in the chloroplasts, which cannot be transported in time. When the number of starch grains reaches a certain amount, it causes mechanical damage to the thylakoid structure, thereby affecting chloroplast photosynthetic rate and photosynthetic activity [57,67]. This paper confirmed that chloroplasts and mitochondria have different response times and degrees of response to stress. Chloroplasts began to respond in the early stage of stress in P. sheareri by changing their shape, size and membrane structure, and their systems became disordered and scattered, whereas mitochondria began to rupture the outer membrane, release contents and form small vacuoles in the late stage of stress. This asynchronous stress response alleviates the damage and ensures that P. sheareri seedlings can carry out physiological adjustments in a short time to maintain normal physiological metabolic functions. This pattern was also observed in Populus simonii under waterlogging stress, where chloroplasts were sensitive to stress, while mitochondrial structures were relatively stable [66]. This mechanism can only cope with stress for a short time and cannot play a role in a long-term continuous waterlogging environment. However, some studies have found that in the process of stress, mitochondria are less sensitive, and their stress response occurs later than that of chloroplasts since mitochondria need to provide senescent leaves with the energy required for various life activities, such as the transfer and transportation of nutrients [28].
Leaves are sensitive to environmental changes with strong plasticity, and the changes in their external morphology and anatomical structural characteristics can better reflect the adaptability of plants to waterlogging [17]. With the extension of waterlogging time, the balance between the organelles of P. sheareri seedlings was gradually broken, the chloroplasts were deformed, the plasma walls separated, the mitochondrial membranes were damaged, the inclusions were exuded, and the grainy lamellae were gradually distorted, resulting in leaf thickness changes [55,68]. The thickness of leaf components of P. sheareri gradually decreased under waterlogging conditions, especially the lower epidermis thickness. In addition, due to the influence of waterlogging environment on gas exchange, the stomatal opening of leaves also decreased gradually [48]. Under the influence of these factors, the leaf external morphology showed gradual wilting. When waterlogging stress causes irreversible damage to leaf cells, leaf stomata and leaf thickness gradually decrease, and organelles, such as chloroplasts and mitochondria, gradually disintegrate and cavitate, eventually causing leaf morphology to wither and seedling death [69,70].
Taken together, these results showed that leaf morphology, anatomical structure and ultrastructure associated with increasing waterlogging treatment respond differently. Nevertheless, leaf physiology or molecular mechanisms can further reveal the correlation between seedling leaves and changes in the external moisture environment. Additional measurements of leaf physiology, internal structure and moisture should be made in future studies to obtain further information.

5. Conclusions

This paper confirmed that waterlogging stress affects the external morphology of the leaves of P. sheareri seedlings, mainly reflected in aspects such as the inhibition of the growth of new leaves, gradual yellowing and wilting of leaves, and leaf abscission in severe cases. Further observation of the microstructure of the leaf epidermis illustrated that waterlogging stress leads to stomatal closure and increased stomatal density of the leaf epidermis, anda long-term waterlogging environment reduces the thickness of leaves and their components. Waterlogging stress mainly affects organelles such as chloroplasts and mitochondria, causing damage to chloroplast outer membranes, changes in shape, plasmolysis, disarray of grana lamellae arrangements, decrease of mitochondrial matrix concentrations, and disappearance of inner crest structures. After P. sheareri seedlings were treated with drainage, their leaf morphology, stomata, epidermal structure and mesophyll cells did not improve significantly, which was attributed to the fact that the seedlings suffered irreversible damage during the waterlogging process, and their internal metabolic mechanism was seriously injured and could not be recovered. Based on the leaf morphology and various indices, the seedlings of P. sheareri performed best in several aspects such as leaf morphology, leaf epidermis microstructure and mesophyll cell ultrastructure when they were waterlogged for 6 days, which indicated that a short-term waterlogging treatment can promote better development of the leaves and their internal mechanisms in P. sheareri seedlings. However, under conditions of long-term waterlogging, the damage became increasingly serious.
This paper focused on preliminary observations of the changes in the external morphology of leaves, the microstructure of leaf epidermis, and the ultrastructure of mesophyll cells of P. sheareri seedlings under waterlogging stress and during the waterlogging–drainage process, but lacked deep exploration on the differences in the waterlogging resistance mechanisms among the internal organelles of P. sheareri seedlings and the dynamic changes in the internal metabonomics and molecular mechanisms of P. sheareri seedlings under waterlogging stress. In the future, it is still necessary to conduct in-depth research on the linkage mechanism of cell structure and function of seedling leaves in adverse environments, as well as on metabolomics and the molecular mechanisms.

Author Contributions

F.S. contributed to conceptualization, investigation, supervision, writing—review and editing. Z.P. contributed to conceptualization, data curation and visualization, writing—original draft, writing—review and editing. P.D. contributed to conceptualization, investigation, data curation and visualization, writing—review and editing. Y.S. contributed to supervision, conceptualization, review and editing. Y.L. and B.H. contributed to supervision, review and editing. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the subject of Key R&D Plan of Shandong Province (Major Scientific and Technological Innovation Project): Mining and Accurate Identification of Forest Tree Germplasm Resources (2021LZGC023); Jiangsu Agriculture Science and Technology Innovation Fund (CX (19) 2123).

Data Availability Statement

All data relevant to the study are included in the article.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Table
Table A1. ANOVA of leaf epidermal stomata of seedlings under waterlogging stress.
Table A1. ANOVA of leaf epidermal stomata of seedlings under waterlogging stress.
IndexSquare SumDegree of FreedomMean SquareF Valuep Value
Stomatal length5.64731.8821.6170.225
Stomatal width74.140324.71380.5350.000
Stomatal opening rate0.06030.020210.7540.000
Stomatal density6,649,454.50232,216,484.834106.0440.000
Table
Table A2. ANOVA of leaf epidermal stomata of seedlings during the waterlogging-drainage process.
Table A2. ANOVA of leaf epidermal stomata of seedlings during the waterlogging-drainage process.
IndexSquare SumDegree of FreedomMean SquareF Valuep Value
Stomatal length20.99836.996.4910.004
Stomatal width67.621322.54072.1430.000
Stomatal opening rate0.05230.017312.2980.000
Stomatal density3,949,174.5213131,631.507122.4220.000
Table
Table A3. ANOVA of leaf anatomical structure of seedlings under waterlogging stress.
Table A3. ANOVA of leaf anatomical structure of seedlings under waterlogging stress.
IndexSquare SumDegree of FreedomMean SquareF Valuep Value
Total blade thickness2271.9403757.313193.1400.000
The thickness of the upper epidermis6.61632.2051.6180.225
The thickness of the lower epidermis103.091334.36423.1200.000
Palisade tissue thickness 674.1943224.731163.0640.000
Spongy tissue thickness289.756396.58525.9080.000
The ratio of palisade tissue to the spongy tissue0.21930.07314.2750.000
Table
Table A4. ANOVA of leaf anatomical structure of seedlings during the waterlogging-drainage process.
Table A4. ANOVA of leaf anatomical structure of seedlings during the waterlogging-drainage process.
IndexSquare SumDegree of FreedomMean SquareF Valuep Value
Total blade thickness802.0693267.35693.8490.000
The thickness of the upper epidermis30.688310.22920.7530.000
The thickness of the lower epidermis83.573327.85815.8610.000
Palisade tissue thickness 146.466348.82229.2860.000
Spongy tissue thickness78.828326.2766.8950.003
The ratio of palisade tissue to the spongy tissue0.30130.10015.9700.000

References

  1. Chen, H.; Wu, Q.; Ni, M.; Chen, C.; Han, C.; Yu, F. Transcriptome analysis of endogenous hormone response mechanism in roots of Styrax tonkinensis under waterlogging. Front. Plant Sci. 2022, 13, 896850. [Google Scholar] [CrossRef]
  2. Arnell, N.W.; Gosling, S.N. The impacts of climate change on river flood risk at the global scale. Clim. Change 2016, 134, 387–401. [Google Scholar] [CrossRef] [Green Version]
  3. Pan, L.; Xue, L. Plant physiological mechanisms in adapting to waterlogging stress: A review. Chin. J. Ecol. 2012, 31, 2662–2672. (In Chinese) [Google Scholar] [CrossRef]
  4. Pan, J.; Sharif, R.; Xu, X.; Chen, X. Mechanisms of waterlogging tolerance in plants: Research progress and prospects. Front. Plant Sci. 2021, 11, 627331. [Google Scholar] [CrossRef] [PubMed]
  5. Zhou, W.G.; Chen, F.; Meng, Y.J.; Chandrasekaran, U.; Luo, X.F.; Yang, W.Y.; Shu, K. Plant waterlogging/flooding stress responses: From seed germination to maturation. Plant Physiol. Biochem. 2020, 148, 228–236. [Google Scholar] [CrossRef] [PubMed]
  6. Wei, W.L.; Li, D.H.; Wang, L.H.; Ding, X.; Zhang, Y.X.; Gao, Y.; Zhang, X.R. Morpho-anatomical and physiological responses to waterlogging of sesame (Sesamum indicum L.). Plant Sci. 2013, 208, 102–111. [Google Scholar] [CrossRef] [PubMed]
  7. Kaur, G.; Vikal, Y.; Kaur, L.; Kalia, A.; Mittal, A.; Kaur, D.; Yadav, I. Elucidating the morpho-physiological adaptations and molecular responses under long-term waterlogging stress in maize through gene expression analysis. Plant Sci. 2021, 304, 110823. [Google Scholar] [CrossRef] [PubMed]
  8. Zhang, P.; Lyu, D.; Jia, L.; He, J.; Qin, S. Physiological and de novo transcriptome analysis of the fermentation mechanism of Cerasus sachalinensis roots in response to short-term waterlogging. BMC Genom. 2017, 18, 649. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  9. Doupis, G.; Kavroulakis, N.; Psarras, G.; Papadakis, I. Growth, photosynthetic performance and antioxidative response of ‘Hass’ and ‘Fuerte’ avocado (Persea americana Mill.) plants grown under high soil moisture. Photosynthetica 2017, 55, 655–663. [Google Scholar] [CrossRef]
  10. Wu, J.; Wang, J.; Hui, W.; Zhao, F.; Wang, P.; Su, C.; Gong, W. Physiology of plant responses to water stress and related genes: A review. Forests 2022, 13, 324. [Google Scholar] [CrossRef]
  11. Yang, W.C.; Lin, K.H.; Wu, C.W.; Chang, Y.J.; Chang, Y.S. Effects of waterlogging with different water resources on plant growth and tolerance capacity of four herbaceous flowers in a bioretention basin. Water 2020, 12, 1619. [Google Scholar] [CrossRef]
  12. Ren, B.Z.; Zhang, J.W.; Dong, S.T.; Liu, P.; Zhou, B. Effects of waterlogging on leaf mesophyll cell ultrastructure and photosynthetic characteristics of Summer Maize. PLoS ONE 2016, 11, e0161424. [Google Scholar] [CrossRef] [Green Version]
  13. Zhou, J.; Wan, S.W.; Li, G.; Qin, P. Ultrastructure changes of seedlings of Kosteletzkya virginica under waterlogging conditions. Biol. Plant. 2011, 55, 493–498. [Google Scholar] [CrossRef]
  14. Zhang, R.D.; Zhou, Y.F.; Yue, Z.X.; Chen, X.F.; Cao, X.; Xu, X.X.; Xing, Y.F.; Jiang, B.; Ai, X.Y.; Huang, R.D. Changes in photosynthesis, chloroplast ultrastructure, and antioxidant metabolism in leaves of sorghum under waterlogging stress. Photosynthetica 2019, 57, 1076–1083. [Google Scholar] [CrossRef] [Green Version]
  15. Li, C.; Wan, Y.; Shang, X.; Fang, S. Responses of microstructure, ultrastructure and antioxidant enzyme activity to PEG-Induced drought stress in Cyclocarya paliurus Seedlings. Forests 2022, 13, 836. [Google Scholar] [CrossRef]
  16. Zhang, R.D.; Zhou, Y.F.; Yue, Z.X.; Chen, X.F.; Cao, X.; Ai, X.Y.; Jiang, B.; Xing, Y.F. The leaf-air temperature difference reflects the variation in water status and photosynthesis of sorghum under waterlogged conditions. PLoS ONE 2019, 14, e0219209. [Google Scholar] [CrossRef] [Green Version]
  17. Xiao, Y.; Jie, Z.L.; Wang, M.; Lin, G.H.; Wang, W.Q. Leaf and stem anatomical responses to periodical waterlogging in simulated tidal floods in mangrove Avicennia marina seedlings. Aquat. Bot. 2009, 91, 231–237. [Google Scholar] [CrossRef]
  18. Yang, J.; He, K.Y.; Li, X.C.; Huang, L.B. Influences of waterlogging stress on the growth and leaf anatomical structures of two oak species. J. For. Eng. 2008, 110, 34–37. (In Chinese) [Google Scholar]
  19. Zhao, X.Y.; Han, L.X.; Zhang, G.X. Physiological characteristics and leaf structure of Chionanthus virginicus seedlings under flooding stress. Acta Bot. Boreali-Occident. Sin. 2023, 43, 410–420. (In Chinese) [Google Scholar]
  20. Liu, G.Q.; Zhu, H.J.; Zhou, B.B.; Sheng, J.Y.; Zang, X. Effects of drought and flooding stress on photosynthetic characteristics of pecan Carya illinoinensis Wangenh. and ultrastructure of its chloroplast. Jiangsu J. Agric. Sci. 2012, 28, 1429–1433. (In Chinese) [Google Scholar]
  21. Ye, Z.H.; Huang, S.L.; Zhu, J.; Zou, H.H.; Tan, G.W. Propagation, maintenance and landscape application of four ornamental plant species of Phoebe. Guangdong Landsc. Archit. 2016, 38, 48–51. (In Chinese) [Google Scholar]
  22. Wang, Y.; Ma, X.H.; Lu, Y.F.; Hu, X.E.; Lou, L.H.; Tong, Z.K.; Zhang, J.H. Assessing the current genetic structure of 21 remnant populations and predicting the impacts of climate change on the geographic distribution of Phoebe sheareri in southern China. Sci. Total Environ. 2022, 846, 157391. [Google Scholar] [CrossRef]
  23. Wang, Z.; Dong, Z. Research on the development and utilization of plant resources in the genus Phoebe. Heilongjiang Agric. Sci. 2008, 180, 119–121. (In Chinese) [Google Scholar]
  24. Shi, H.; Deng, Y.; Liu, S.; Li, M. Container seedling cultivation techniques of Phoebe sheareri in Wuhan area. Hubei For. Sci. Technol. 2020, 49, 83–84. (In Chinese) [Google Scholar]
  25. Wang, Z.M.; Zhou, T.T.; Xue, L.; Xu, J.X. Effect of low temperature stress on physiological characteristics of seedlings of four landscape species. J. Anhui Agric. Univ. 2016, 43, 209–214. (In Chinese) [Google Scholar]
  26. Li, G.F.; Li, Y.Z.; Zhu, Y.Z.; Zheng, W.J.; Li, M.X.; Hu, J.L.; Fei, Y.J.; Zhu, S.J. Exogenous application of melatonin to mitigate drought stress-induced oxidative damage in Phoebe sheareri seedlings. PeerJ 2023, 11, e15159. [Google Scholar] [CrossRef]
  27. Jain, R.; Singh, A.; Singh, S.P.; Chandra, A.; Pathak, A.D. Morphological and anatomical aberrations induced by waterlogging in sugarcane. J. Environ. Biolog. 2019, 40, 634–640. [Google Scholar] [CrossRef]
  28. Salah, A.; Zhan, M.; Cao, C.G.; Han, Y.L.; Ling, L.; Liu, Z.H.; Li, P.; Ye, M.; Jiang, Y. Gamma-Aminobutyric acid promotes chloroplast ultrastructure, antioxidant capacity, and growth of waterlogged maize seedlings. Sci. Rep. 2019, 9, 484. [Google Scholar] [CrossRef] [Green Version]
  29. Bhusa, N.; Kim, H.S.; Han, S.G.; Yoon, T.M. Photosynthetic traits and plant-water relations of two apple cultivars grown as bi-leader trees under long-term waterlogging conditions. Environ. Exp. Bot. 2020, 176, 104111. [Google Scholar] [CrossRef]
  30. Zhou, P.Y.; Qian, J.; Yuan, W.D.; Yang, X.; Di, B.; Meng, Y.; Shao, J.Z. Effects of interval flooding stress on physiological characteristics of Apple leaves. Horticulturae 2021, 7, 331. [Google Scholar] [CrossRef]
  31. Jimenez, J.D.; Cardoso, J.A.; Dominguez, M.; Fischer, G.; Rao, I. Morpho-anatomical traits of root and non-enzymatic antioxidant system of leaf tissue contribute to waterlogging tolerance in Brachiaria grasses. Grassl. Sci. 2015, 61, 243–251. [Google Scholar] [CrossRef]
  32. Xu, L.P.; Pan, Y.L.; Yu, F.Y. Effects of water-stress on growth and physiological changes in Pterocarya stenoptera seedlings. Sci. Hortic. 2015, 190, 11–23. [Google Scholar] [CrossRef]
  33. Rao, L.Y.; Li, S.Y.; Cui, X. Leaf morphology and chlorophyll fluorescence characteristics of mulberry seedlings under waterlogging stress. Sci. Rep. 2021, 11, 1337. [Google Scholar] [CrossRef] [PubMed]
  34. Peng, Y.J.; Zhou, Z.X.; Zhang, Z.; Yu, X.L.; Zhang, X.Y.; Du, K.B. Molecular and physiological responses in roots of two full-sib poplars uncover mechanisms that contribute to differences in partial submergence tolerance. Sci. Rep. 2018, 8, 12829. [Google Scholar] [CrossRef] [PubMed]
  35. Kumutha, D.; Ezhilmathi, K.; Sairam, R.K.; Srivastava, G.C.; Deshmukh, P.S.; Meena, R.C. Waterlogging induced oxidative stress and antioxidant activity in pigeonpea genotypes. Biol. Plant. 2009, 53, 75–84. [Google Scholar] [CrossRef]
  36. Geng, R.N.; Zhang, X.Y.; Fan, X.P.; Hu, Q.; Ni, T.H.; Du, K.B. Waterlogging tolerance evaluation of fifteen poplar clones cultivated in the Jianghan Plain of China. Not. Bot. Horti Agrobot. Cluj Napoca 2021, 49, 12421. [Google Scholar] [CrossRef]
  37. Liu, X.; Peng, Y.; Fan, J.J.; Zhang, W.X.; Li, X.; Zou, X. Effects of waterlogging stress on growth and physiological characteristics in Malus hupehensis. Nonwood For. Res. 2018, 36, 35–42. (In Chinese) [Google Scholar] [CrossRef]
  38. Lu, R.H.; Xu, L.X.; Zhou, X.X.; Sheng, S.H.; Feng, C.; Chen, C.; Tang, L. Effects of flooding stress on growth and photosynthesis of Cerasus campanulate seedlings. Acta Agric. Univ. Jiangxiensis 2022, 44, 871–881. (In Chinese) [Google Scholar] [CrossRef]
  39. Tong, M.Y.; Huang, J.Q.; Li, C.J. Effects of waterlogging on morphology and chlorophyll fluorescence characteristics of cherry tomato at seedling stage. J. Irrig. Drain. 2019, 38, 8–15. (In Chinese) [Google Scholar] [CrossRef]
  40. Hua, J.F.; Han, L.W.; Wang, Z.Q.; Shi, Q.; Yin, Y.L. The growth and photosynthesis characters of Taxodium hybrid’Zhongshanshan 407’ following the de-submergence. J. Nanjing For. Univ. Nat. Sci. Ed. 2017, 41, 191–196. (In Chinese) [Google Scholar]
  41. Tanaka, K.; Masumori, M.; Yamanoshita, T.; Tange, T. Morphological and anatomical changes of Melaleuca cajuputi under submergence. Trees 2011, 25, 695–704. [Google Scholar] [CrossRef]
  42. Yu, X.Q.; Luo, N.; Yan, J.P.; Tang, J.C.; Liu, S.W.; Jiang, Y.W. Differential growth response and carbohydrate metabolism of global collection of perennial ryegrass accessions to submergence and recovery following de-submergence. J. Plant Physiol. 2012, 169, 1040–1049. [Google Scholar] [CrossRef] [PubMed]
  43. Feng, Y.L.; Xian, X.D. Preliminary observation on the growth recovery of five grass plants after long-term flooding. South China Agric. 2012, 6, 18–21. (In Chinese) [Google Scholar] [CrossRef]
  44. Voesenek, L.A.C.J.; Colmer, T.D.; Pierik, R.; Millenaar, F.F.; Peeters, A.J.M.; Peeters, A. How plants cope with complete submergence. New Phytol. 2006, 170, 213–226. [Google Scholar] [CrossRef] [Green Version]
  45. Bailey-Serres, J.; Voesenek, L.A.C.J. Flooding stress: Acclimations and genetic diversity. Annu. Rev. Plant Biol. 2008, 59, 313–339. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  46. Florez-Velasco, N.; Balaguera-Lopez, H.E.; Restrepo-Diaz, H. Effects of foliar urea application on lulo (Solanum quitoense cv. septentrionale) plants grown under different waterlogging and nitrogen conditions. Sci. Hortic. 2015, 186, 154–162. [Google Scholar] [CrossRef]
  47. Luan, H.Y.; Guo, B.J.; Pan, Y.H.; Lv, C.; Shen, H.Q.; Xu, R.G. Morpho-anatomical and physiological responses to waterlogging stress in different barley (Hordeum vulgare L.) genotypes. Plant Growth Regul. 2018, 85, 399–409. [Google Scholar] [CrossRef]
  48. Yin, D.M.; Zhang, Z.G.; Luo, H.L. Anatomical responses to waterlogging in Chrysanthemum zawadskii. Sci. Hortic. 2012, 146, 86–91. [Google Scholar] [CrossRef]
  49. Malik, A.I.; Colmer, T.D.; Lambers, H.; Schortemeyer, M. Changes in physiological and morphological traits of roots and shoots of wheat in response to different depths of waterlogging. Aust. J. Plant Physiol. 2001, 28, 1121–1131. [Google Scholar] [CrossRef]
  50. Gu, X.B.; Xue, L.; Lu, L.H.; Song, G.H.; Xie, M.; Zhang, H.Q. Characteristics of the response of Actinidia polygama to long-term waterlogging stress. J. Fruit Sci. 2019, 36, 327–337. (In Chinese) [Google Scholar] [CrossRef]
  51. Rood, S.B.; Nielsen, J.L.; Shenton, L.; Gill, K.M.; Letts, M.G. Effects of flooding on leaf development, transpiration, and photosynthesis in narrowleaf cottonwood, a willow-like poplar. Photosynth. Res. 2010, 104, 31–39. [Google Scholar] [CrossRef] [PubMed]
  52. Blanke, M.M.; Cooke, D.T. Effects of flooding and drought on stomatal activity, transpiration, photosynthesis, water potential and water channel activity in strawberry stolons and leaves. Plant Growth Regul. 2004, 42, 153–160. [Google Scholar] [CrossRef]
  53. Li, G.; Hu, S.; Zhao, X.Y.; Kumar, S.; Li, Y.X.; Yang, J.J.; Hou, H.W. Mechanisms of the morphological plasticity induced by phytohormones and the environment in plants. Int. J. Mol. Sci. 2021, 22, 765. [Google Scholar] [CrossRef] [PubMed]
  54. Chitwood, D.H.; Sinha, N.R. Evolutionary and environmental forces sculpting leaf development. Curr. Biol. 2016, 26, R297–R306. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  55. Wang, W.Q.; Xiao, Y.; Chen, L.Z.; Lin, P. Leaf anatomical response to periodical waterlogging in simulated semidiurnal tides in mangrove Bruguiera gymnorrhiza seedlings. Aquat. Bot. 2007, 86, 223–228. [Google Scholar] [CrossRef]
  56. Yin, D.M.; Chen, S.M.; Chen, F.D.; Guan, Z.Y.; Fang, W.M. Morpho-anatomical and physiological responses of two Dendranthema species to waterlogging. Environ. Exp. Bot. 2010, 68, 112–130. [Google Scholar] [CrossRef]
  57. Sharma, S.; Bhatt, U.; Sharma, J.; Kalaji, H.M.; Mojski, J.; Soni, V. Ultrastructure, adaptability, and alleviation mechanisms of photosynthetic apparatus in plants under waterlogging: A review. Photosynthetica 2022, 60, 430–444. [Google Scholar] [CrossRef]
  58. Bertamini, M.; Muthuchelian, K.; Nedunchezhian, N. Shade effect alters leaf pigments and photosynthetic responses in Norway spruce (Picea abies L.) grown under field conditions. Photosynthetica 2006, 44, 227–234. [Google Scholar] [CrossRef]
  59. Qi, H.Y.; Liu, Y.; Liu, H.T. Effect of water deficit on stomatal characteristics and ultrastructure of chloroplast in tomato leaves. Acta Bot. Boreali-Occident. Sin. 2009, 29, 9–15. (In Chinese) [Google Scholar]
  60. Sun, W.W.; Meng, X.M.; Xu, X.Y.; Wu, M.H.; Qin, M.Y.; Lin, M.M.; Zhang, X.Y.; Yue, G.Z. Contents of pigments and anatomical structure in the leaves of Forsythia koreana ‘Sun Gold’. Bull. Bot. Res. 2020, 40, 321–329. (In Chinese) [Google Scholar]
  61. Shao, G.C.; Lan, J.J.; Yu, S.E.; Liu, N.; Guo, R.Q.; She, D.L. Photosynthesis and growth of winter wheat in response to waterlogging at different growth stages. Photosynthetica 2013, 51, 429–437. [Google Scholar] [CrossRef]
  62. Navarro, A.; Boveris, A. The mitochondrial energy transduction system and the aging process. Am. J. Physiol. Physiol. 2007, 292, C670–C686. [Google Scholar] [CrossRef]
  63. Shen, J.; Zhang, Z.W. Cytomorphological studies of programmed cell death in Cabernet sauvignon induced by artificial drought stress. J. Northwest A F Univ. (Nat. Sci. Ed.) 2009, 37, 125–132. (In Chinese) [Google Scholar] [CrossRef]
  64. Jiang, Z.; Song, X.F.; Zhou, Z.Q.; Wang, L.K.; Li, J.W.; Deng, X.Y.; Fan, H.Y. Aerenchyma formation: Programmed cell death in adventitious roots of winter wheat (Triticum aestivum) under waterlogging. Funct. Plant Biol. 2010, 37, 748–755. [Google Scholar] [CrossRef]
  65. Xu, P.; Li, J.; Lv, H.Y.; Li, Y.J.; Li, J.; Ma, C.L. Effects of drought stress on ultrastructure of chloroplasts and mitochondria and membrane lipid peroxidation of Ammodendron argenteum seedlings. Arid Zone Res. 2016, 33, 120–130. (In Chinese) [Google Scholar] [CrossRef]
  66. Du, K.B.; Xu, L.; Tu, B.K.; Shen, B.X. Influences of soil flooding on ultrastructure and photosynthetic capacity of leaves of one-year old seedlings of two poplar clones. Sci. Silvae Sin. 2010, 46, 58–64, 183. (In Chinese) [Google Scholar]
  67. Vassileva, V.; Simova-Stoilova, L.; Demirevska, K.; Feller, U. Variety-specific response of wheat (Triticum aestivum L.) leaf mitochondria to drought stress. J. Plant Res. 2009, 122, 445–454. [Google Scholar] [CrossRef]
  68. Hu, J.; Ren, B.Z.; Dong, S.T.; Liu, P.; Zhao, B.; Zhang, J.W. Phosphoproteomic and physiological analysis revealed 6-benzyladenine improved the operation of photosynthetic apparatus in waterlogged summer maize. Environ. Exp. Bot. 2021, 193, 104679. [Google Scholar] [CrossRef]
  69. Peng, Y.J.; Zhou, Z.X.; Tong, R.G.; Hu, X.Y.; Du, K.B. Anatomy and ultrastructure adaptations to soil flooding of two full-sib poplar clones differing in flood-tolerance. Flora 2017, 233, 90–98. [Google Scholar] [CrossRef]
  70. Du, K.B.; Xu, L.; Wu, H.; Tu, B.K.; Zheng, B. Ecophysiological and morphological adaption to soil flooding of two poplar clones differing in flood-tolerance. Flora 2012, 207, 96–106. [Google Scholar] [CrossRef]
Forests 14 01294 g001 550
Figure 1. Schematic diagram of “double pot method”.
Figure 1. Schematic diagram of “double pot method”.
Forests 14 01294 g001
Forests 14 01294 g002 550
Figure 2. Changes in leaf epidermal stomata of seedlings under waterlogging stress. (a): Control group; (b): Waterlogging stress for 6 days; (c): Waterlogging stress for 12 days; (d): Waterlogging stress for 18 days.
Figure 2. Changes in leaf epidermal stomata of seedlings under waterlogging stress. (a): Control group; (b): Waterlogging stress for 6 days; (c): Waterlogging stress for 12 days; (d): Waterlogging stress for 18 days.
Forests 14 01294 g002
Forests 14 01294 g003a 550Forests 14 01294 g003b 550
Figure 3. Changes in leaf epidermal stomata of seedlings during the waterlogging-drainage process. (a): Control group; (b): Waterlogging stress for 12 days; (c): Waterlogging stress for 12 days and drainage for 6 days; (d): Waterlogging stress for 12 days and drainage for 12 days.
Figure 3. Changes in leaf epidermal stomata of seedlings during the waterlogging-drainage process. (a): Control group; (b): Waterlogging stress for 12 days; (c): Waterlogging stress for 12 days and drainage for 6 days; (d): Waterlogging stress for 12 days and drainage for 12 days.
Forests 14 01294 g003aForests 14 01294 g003b
Forests 14 01294 g004 550
Figure 4. Changes in leaf anatomical structure of seedlings under waterlogging stress. (a): Control group; (b): Waterlogging stress for 6 days; (c): Waterlogging stress for 12 days; (d): Waterlogging stress for 18 days; LE: Lower epidermis; ST: Spongy tissue; PT: Palisade tissue; UE: Upper epidermis.
Figure 4. Changes in leaf anatomical structure of seedlings under waterlogging stress. (a): Control group; (b): Waterlogging stress for 6 days; (c): Waterlogging stress for 12 days; (d): Waterlogging stress for 18 days; LE: Lower epidermis; ST: Spongy tissue; PT: Palisade tissue; UE: Upper epidermis.
Forests 14 01294 g004
Forests 14 01294 g005a 550Forests 14 01294 g005b 550
Figure 5. Changes in leaf anatomical structure of seedlings during the waterlogging-drainage process. (a): Control group; (b): Waterlogging stress for 12 days; (c): Waterlogging stress for 12 days and drainage for 6 days; (d): Waterlogging stress for 12 days and drainage for 12 days; LE: Lower epidermis; ST: Spongy tissue; PT: Palisade tissue; UE: Upper epidermis.
Figure 5. Changes in leaf anatomical structure of seedlings during the waterlogging-drainage process. (a): Control group; (b): Waterlogging stress for 12 days; (c): Waterlogging stress for 12 days and drainage for 6 days; (d): Waterlogging stress for 12 days and drainage for 12 days; LE: Lower epidermis; ST: Spongy tissue; PT: Palisade tissue; UE: Upper epidermis.
Forests 14 01294 g005aForests 14 01294 g005b
Forests 14 01294 g006 550
Figure 6. Ultrastructural changes of mesophyll cells of Phoebe sheareri seedlings under waterlogging stress. (a): Control group; (b): Waterlogging stress for 6 days; (c): Waterlogging stress for 12 days; (d): Waterlogging stress for 18 days; CW: Cell wall; Chl: Chloroplast; M: Mitochondrion; P: Plastoglobule; SG: Starch granule; GL: Granum lamella.
Figure 6. Ultrastructural changes of mesophyll cells of Phoebe sheareri seedlings under waterlogging stress. (a): Control group; (b): Waterlogging stress for 6 days; (c): Waterlogging stress for 12 days; (d): Waterlogging stress for 18 days; CW: Cell wall; Chl: Chloroplast; M: Mitochondrion; P: Plastoglobule; SG: Starch granule; GL: Granum lamella.
Forests 14 01294 g006
Forests 14 01294 g007a 550Forests 14 01294 g007b 550
Figure 7. Ultrastructural changes of mesophyll cells of Phoebe sheareri seedlings during the waterlogging-drainage process. (a): Control group; (b): Waterlogging stress for 12 days; (c): Waterlogging stress for 12 days and drainage for 6 days; (d): Waterlogging stress for 12 days and drainage for 12 days; CW: Cell wall; Chl: Chloroplast; M: Mitochondrion; P: Plastoglobule; SG: Starch granule; GL: Granum lamella.
Figure 7. Ultrastructural changes of mesophyll cells of Phoebe sheareri seedlings during the waterlogging-drainage process. (a): Control group; (b): Waterlogging stress for 12 days; (c): Waterlogging stress for 12 days and drainage for 6 days; (d): Waterlogging stress for 12 days and drainage for 12 days; CW: Cell wall; Chl: Chloroplast; M: Mitochondrion; P: Plastoglobule; SG: Starch granule; GL: Granum lamella.
Forests 14 01294 g007aForests 14 01294 g007b
Table
Table 1. Each treatment of P. sheareri seedlings for waterlogging and waterlogging-drainage experiments.
Table 1. Each treatment of P. sheareri seedlings for waterlogging and waterlogging-drainage experiments.
ExperimentTreatment
Part 1 Waterlogging treatmentControl group (without waterlogging treatment)
Waterlogging stress for 6 days
Waterlogging stress for 12 days
Waterlogging stress for 18 days
Part 2 Waterlogging-drainage treatmentControl group (without waterlogging treatment)
Waterlogging stress for 12 days
Waterlogging stress for 12 days and drainage for 6 days
Waterlogging stress for 12 days and drainage for 12 days
Three biological replicates were applied for each treatment.
Table
Table 2. Changes in leaf morphology of Phoebe sheareri seedlings under waterlogging stress.
Table 2. Changes in leaf morphology of Phoebe sheareri seedlings under waterlogging stress.
Experimental TreatmentLeaf Morphology
Control groupThe seedlings grew normally with green leaves and no wilting and drooping phenomenon;
Waterlogging stress for 6 daysThe seedlings and their leaves grew well with 2–3 new leaves on the top;
Waterlogging stress for 12 daysAbout 30% of the leaves appeared with yellow spots, and 50% of the leaves appeared with a temporary wilting phenomenon;
Waterlogging stress for 18 daysAll leaves of the seedling wilted and drooped, and all of the terminal bud and basal leaves of the seedlings turned yellow and fell off;
Waterlogging stress for 12 days and drainage for 6 daysNearly 50% of the leaves drooped, and 50% of the leaves lost green coloring and turned yellow
Waterlogging stress for 12 days and drainage for 12 daysAll leaves withered and drooped, 50% of the leaves lost green coloring and turned yellow, and 50% of the leaves withered and fell off.
Table
Table 3. Determination results of leaf epidermal stomata of seedlings under waterlogging stress.
Table 3. Determination results of leaf epidermal stomata of seedlings under waterlogging stress.
TreatmentStomatal Length (μm)Stomatal Width (μm)Stomatal Opening Rate (%)Stomatal Density (n/mm2)
Control group13.35 ± 0.49 Aa7.35 ± 0.34 Aa27.55 ± 0.34 Aa2082 ± 22.47 Dd
Waterlogging stress for 6 days14.18 ± 0.38 Aa5.52 ± 0.28 Bb22.91 ± 0.06 Bb2336 ± 12.96 Cc
Waterlogging stress for 12 days14.58 ± 0.33 Aa2.96 ± 0.20 Cc17.41 ± 0.76 Cc3298 ± 75.58 Bb
Waterlogging stress for 18 days14.71 ± 0.66 Aa2.67 ± 0.11 Cc13.03 ± 0.25 Dd3467 ± 5.59 Aa
Note: Different capital letters indicated extremely significant differences between treatments (p < 0.01), and different lowercase letters indicated significant differences between treatments (p < 0.05). The same applies to the below.
Table
Table 4. Determination results of leaf epidermal stomata of Phoebe sheareri seedlings during the waterlogging-drainage process.
Table 4. Determination results of leaf epidermal stomata of Phoebe sheareri seedlings during the waterlogging-drainage process.
TreatmentStomatal Length (μm)Stomatal Width (μm)Stomatal Opening Rate (%)Stomatal Density (n/mm2)
Control group13.35 ± 0.49 Bb7.35 ± 0.34 Aa27.55 ± 0.34 Aa2082 ± 22.47 Cc
Waterlogging stress for 12 days14.58 ± 0.33 ABb2.96 ± 0.20 Bb17.41 ± 0.76 Bb3298 ± 75.58 Aa
Waterlogging stress for 12 days and drainage for 6 days14.68 ± 0.53 ABb2.96 ± 0.14 Bb15.91 ± 0.36 BCbc3272 ± 53.80 Aa
Waterlogging stress for 12 days and drainage for 12 days16.16 ± 0.44 Aa3.04 ± 0.19 Bb15.22 ± 0.44 Cc2644 ± 70.95 Bb
Table
Table 5. Determination results of leaf anatomical structure of seedlings under waterlogging stress.
Table 5. Determination results of leaf anatomical structure of seedlings under waterlogging stress.
TreatmentTotal Blade Thickness (μm)The Thickness of the Upper Epidermis (μm)The Thickness of the Lower Epidermis (μm)Palisade Tissue Thickness (μm)Spongy Tissue Thickness (μm)The Ratio of Palisade Tissue to the Spongy Tissue
Control group77.15 ± 0.66 Bb5.94 ± 0.50 Aa9.10 ± 0.47 Aa28.49 ± 0.27 Bbc32.31 ± 1.01 BCb0.88 ± 0.02 Bb
Waterlogging stress for 6 days88.58 ± 1.40 Aa6.82 ± 0.76 Aa9.00 ± 0.17 Aa41.56 ± 0.52 Aa37.05 ± 0.99 Aa1.12 ± 0.03 Aa
Waterlogging stress for 12 days63.67 ± 0.43 Cc5.36 ± 0.18 Aa4.75 ± 0.70 Bb29.07 ± 0.41 Bb26.73 ± 0.87 Cd1.09 ± 0.05 Aa
Waterlogging stress for 18 days62.62 ± 0.75 Cc6.62 ± 0.48 Aa4.29 ± 0.67 Bb27.18 ± 0.78 Bc29.53 ± 0.47 Cc0.92 ± 0.02 Bb
Table
Table 6. Determination results of leaf anatomical structure of seedlings during the waterlogging-drainage process.
Table 6. Determination results of leaf anatomical structure of seedlings during the waterlogging-drainage process.
TreatmentTotal Blade Thickness (μm)The Thickness of the Upper Epidermis (μm)The Thickness of the Lower Epidermis (μm)Palisade Tissue Thickness (μm)Spongy Tissue Thickness (μm)The Ratio of Palisade Tissue to the Spongy Tissue
Control group77.15 ± 0.66 Aa5.94 ± 0.50 Aa9.10 ± 0.47 Aa28.49 ± 0.27 Aa32.31 ± 1.01 Aa0.88 ± 0.02 Bb
Waterlogging stress for 12 days63.67 ± 0.43 Bb5.36 ± 0.18 Aa4.75 ± 0.70 BCbc29.07 ± 0.41 Aa26.73 ± 0.87 Bc1.09 ± 0.05 Aa
Waterlogging stress for 12 days and drainage for 6 days63.16 ± 0.64 Bb6.08 ± 0.31 Aa3.67 ± 0.40 Cc22.92 ± 0.38 Bb29.85 ± 0.80 BCb0.77 ± 0.03 Bc
Waterlogging stress for 12 days and drainage for 12 days61.73 ± 0.74 Bb3.00 ± 0.14 Bb6.37 ± 0.73 Bb23.26 ± 0.69 Bb29.20 ± 0.80 BCbc0.80 ± 0.03 Bbc
Table
Table 7. Correlation analysis of leaf anatomical structure indexes of Phoebe sheareri seedlings under waterlogging stress.
Table 7. Correlation analysis of leaf anatomical structure indexes of Phoebe sheareri seedlings under waterlogging stress.
X1X2X3X4X5X6X7X8X9X10
X11
X2−0.970 *1
X3−0.9450.973 *1
X40.907−0.981 *−0.970 *1
X5−0.5600.7440.740−0.8561
X60.0850.095−0.071−0.1740.4901
X7−0.8410.9470.934−0.990 **0.9190.2731
X8−0.0630.2980.337−0.4770.8550.5400.5891
X9−0.3440.5570.584−0.7070.966 *0.4940.7940.959 *1
X100.421−0.266−0.1030.0890.307−0.0140.0050.7020.5341
X1: Stomatal length (μm), X2: Stomatal width (μm), X3: Stomatal opening rate (%), X4: Stomatal density (n/mm2), X5: Total Blade thickness (μm), X6: The thickness of the upper epidermis (μm), X7: The thickness of the lower epidermis (μm), X8: palisade tissue thickness (μm), X9: Spongy tissue thickness (μm), X10: The ratio of palisade tissue to the spongy tissue; ** indicates correlation at 0.01 level, * indicates correlation at 0.05 level, the same below.
Table
Table 8. Correlation analysis of leaf anatomical structure indexes of Phoebe sheareri seedlings during the waterlogging–drainage process.
Table 8. Correlation analysis of leaf anatomical structure indexes of Phoebe sheareri seedlings during the waterlogging–drainage process.
X1X2X3X4X5X6X7X8X9X10
X11
X2−0.7671
X3−0.8460.985 *1
X40.336−0.862−0.7791
X5−0.8430.991 **0.997 **−0.7901
X6−0.8610.3780.4720.1270.4841
X7−0.4230.8900.841−0.974 *0.835−0.0771
X8−0.6740.5100.637−0.2230.5790.3970.4301
X9−0.4940.8130.719−0.7990.7680.2650.692−0.0771
X10−0.226−0.0990.0550.315−0.0190.158−0.0950.804−0.6541
** indicates correlation at 0.01 level, * indicates correlation at 0.05 level.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Shi, F.; Pan, Z.; Dai, P.; Shen, Y.; Lu, Y.; Han, B. Effect of Waterlogging Stress on Leaf Anatomical Structure and Ultrastructure of Phoebe sheareri Seedlings. Forests 2023, 14, 1294. https://doi.org/10.3390/f14071294

AMA Style

Shi F, Pan Z, Dai P, Shen Y, Lu Y, Han B. Effect of Waterlogging Stress on Leaf Anatomical Structure and Ultrastructure of Phoebe sheareri Seedlings. Forests. 2023; 14(7):1294. https://doi.org/10.3390/f14071294

Chicago/Turabian Style

Shi, Fenghou, Zhujing Pan, Pengfei Dai, Yongbao Shen, Yizeng Lu, and Biao Han. 2023. "Effect of Waterlogging Stress on Leaf Anatomical Structure and Ultrastructure of Phoebe sheareri Seedlings" Forests 14, no. 7: 1294. https://doi.org/10.3390/f14071294

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop