A rapid method of fruit cell isolation for cell size and shape measurements
© McAtee et al; licensee BioMed Central Ltd. 2009
- Received: 29 January 2009
- Accepted: 29 April 2009
- Published: 29 April 2009
Cell size is a structural component of fleshy fruit, contributing to important traits such as fruit size and texture. There are currently a number of methods for measuring cell size; most rely either on tissue sectioning or digestion of the tissue with cell wall degrading enzymes or chemicals to release single cells. Neither of these approaches is ideal for assaying large fruit numbers as both require a considerable time to prepare the tissue, with current methods of cell wall digestions taking 24 to 48 hours. Additionally, sectioning can lead to a measurement of a plane that does not represent the widest point of the cell.
To develop a more rapid way of measuring fruit cell size we have developed a protocol that solubilises pectin in the middle lamella of the plant cell wall releasing single cells into a buffered solution. Gently boiling small fruit samples in a 0.05 M Na2CO3 solution, osmotically balanced with 0.3 M mannitol, produced good cell separation with little cellular damage in less than 30 minutes. The advantage of combining a chemical treatment with boiling is that the cells are rapidly killed. This stopped cell shape changes that could potentially occur during separation. With this method both the rounded and angular cells of the apple cultivars SciRos 'Pacific Rose' and SciFresh 'Jazz'™ were observed in the separated cells. Using this technique, an in-depth analysis was performed measuring cell size from 5 different apple cultivars. Cell size was measured using the public domain ImageJ software. For each cultivar a minimum of 1000 cells were measured and it was found that each cultivar displayed a different distribution of cell size. Cell size within cultivars was similar and there was no correlation between flesh firmness and cell size. This protocol was tested on tissue from other fleshy fruit including tomato, rock melon and kiwifruit. It was found that good cell separation was achieved with flesh tissue from all these fruit types, showing a broad utility to this protocol.
We have developed a method for isolating single cells from fleshy fruit that reduces the time needed for fruit cell separation. This method was used to demonstrate differences in cell size and shape for 5 different apple cultivars. While firmness between the different cultivars is independent of cell size, apples with more angular cells appear to be firmer.
- Cell Size
- Apple Fruit
- Apple Cultivar
- Fleshy Fruit
Cell shape and size are important determinants of fruit size and texture. Recent reports investigating these links include Solanum lycopersicum (tomato) Malus × domestica (apples) , Prunus avium (Sweet cherry) [3, 4]Diospyros species (Persimmon) , Prunus persica (peach)  and Musa species (banana) . In these cases, cell number or cell size was either estimated from fixed tissue that had then undergone sectioning, or cell maceration using chemical or enzymic digestions over 12 to 48 hours. However, the labour, chemical and time intensive nature of these techniques limits the number of samples and treatments that can analysed. There is increasing demand from fruit physiologists and breeders for more rapid techniques that allow analysis of larger numbers of fruits so that more robust conclusions can be derived about the importance of cell size and packing in fruit quality.
In apple fruit, texture is a primary consumer preference, making this a principle target for apple fruit breeders and pomologists. Texture is a complex trait, determined by the interaction of many factors such as cell wall chemistry, cell size and shape, cell packing and cell turgor . Cell size has been shown to be one of the critical components for textural differences in apple, with juiciness being associated with larger cells [9, 10]. Microscopy studies of bite action have shown that high levels of juiciness are achieved when cells are broken open, whereas when the fracture occurs between cells low levels of juiciness are found . Apples have an extensive breeding history which has lead to the availability of many of cultivars displaying a wide range of fruit characters for size and texture.
Apple fruit flesh or cortex comprises of homogeneous parenchyma-type cells. There is a variation of cell sizes across the apple fruit with cells under the skin being smaller (70 uM), increasing in size (to approx 250 uM) towards the centre of the flesh [12, 13]. Towards the inner cortex, the apple cells become more elongated, spreading out in a radial pattern, lying alongside air gaps . Growth within the apple fruit varies according to position, with more rapid growth occurring at the calyx than at the stalk . Growth in apple fruit is achieved through a combination of cell division and cell expansion and, unlike other fruit, enlargement of air gaps between cells [16, 17]. Apple fruit continue to increase in size right up to harvest, albeit at a reduced rate once maturity has been reached [12, 18]. Fruit size can be altered by crop load or environmental effects, and results from changes in both number and size of cells . While there can be a considerable range of cell size within a cultivar, cell size is also genetically determined with apples like 'Bramley's Seedling' having particularly large cells [13, 18, 20].
One of the main issues with measuring cell size using fixing and sectioning is that often the cells are not spherical, and so the plane of sectioning will determine the size measurement. Additionally, there is no guarantee that you are viewing from the widest point of the cell. One solution to address this is to separate the individual cells of the tissue. The intercellular adhesion of plant cells is dependent on pectin, which is the major constituent of the middle lamella and, to a lesser extent, also found in plant cell walls, . Pectinate polysaccharides are complex carbohydrates that consist of a backbone of 1,4 linked alpha-galacturonic acid subunits otherwise known as homogalacturonan, with occasionally 1,2 linked rhamnose subunits. The rhamnogalacturonan I facilitate the linkage of neutral sugar side chains, consisting of arabinans, galactans and arabinogalactans, which give pectin its adhesive properties by allowing pectin to bond with various other cell wall components. The strength of binding between the side chains of the pectic acid backbone is dependent on the presence of calcium and magnesium, which are involved in the cross-linking of pectic polymers. These cofactors fortify the adhesive properties of the pectic substances. Initially cell separation was achieved by treating the tissue with solutions containing chromic acid , or combinations of chromic acid and nitric acid . This was later modified to use cell wall digesting enzymes [1, 23, 24]. The use of enzymes to separate cells has traditionally been associated with long incubation periods (12 to 48 hours) increasing the possibility of cell shape changes as the pectins are digested and/or changes in turgor.
In apples, cell size is not only determined genetically, but also by environment, crop load and maturity. Due to this complexity there is a need to assay a large number of apples to tease out the genetic component of size. We aimed to develop a more rapid, method to measure cell size using isolated cells. To separate the cells, we used Na2CO3 which is known to solubilise pectins . We utilised this method to measure cell size and shape in different apple cultivars with known differences in texture to establish whether cultivar related differences could be observed using this technique. Finally we tested this method against other fleshy fruit to assess its utility as a more general cell isolation method.
Isolation of single cells
Prior to microscopic imaging, harvested cell preparations were re-suspended by gentle flicking of the tube, 30 ul aliquots of suspended tissue were spotted onto clean glass microscopy slides and viewed at 4× under bright field with contrast maximised. Images were collected in a grid like manner to reduce biased selection of cells, using a CoolSnap digital camera and captured using RSImage software, version 1.9.2 (Roper Scientific Ltd, Tucson, Arizona). Images were saved as 24 bit Tiff files.
Analysis of cell size of different apple cultivars
The size of cells was analysed using the public domain ImageJ software package http://rsb.info.nih.gov/ij/. For each image an unadjusted image was kept open to check that measurement of cells were consistent with the raw image. The threshold was set so the outline of each cell was clearly differentiated from the background, and then each image was converted to binary (black and white). Each cell was then filled using "Fill holes". Where cells had not been completely separated then the "Watershed" separation was used to separate out the single cells from the clumps. Occasionally intact cells were not filled completely due to small gaps in the outline. If this occurred then the gaps were manually filled and before proceeding with the "Fill holes" again. Areas were calculated using "analyse particles" with a particle size cut-off threshold of 1100 pixels. A skeletonised image was obtained and visually checked that the cells analysed were whole and single (Figure 1B–D).
Size of apple cells from different cultivars
Average weight (g)
Average size (um2)
168 ± 16
180 ± 7
198 ± 2
184 ± 8
191 ± 4
Isolated Cells are representative of cells from untreated tissue
Cell separation is achieved in other fleshy fruit
Here we have shown a robust simple method of isolating single cells from fleshy fruit. Once single cells have been isolated we used a freeware software to measure cell size. In this study we found no correlation between cell size and firmness either within a cultivar, or across cultivars. Interestingly cultivars with more angular cells ('SciFresh' and 'Cripps Pink') have a firmer flesh. From the confocal microscopy images the 'Scifresh' flesh appears to have a higher cell density and therefore greater cell-to-cell contact compared to the 'SciRos' apples. This is consistent with previous findings with firm fleshed 'Granny Smith' apples having more densely packed cells compared to the rounder cells of softer fleshed 'Rubinette' apples . Whether other textural traits, such as juiciness, that has previously been associated with large cells  can be linked to cell size in these cultivars is yet to be established. The method presented here would greatly facilitate such comparisons, and allow greater numbers of fruit to be analysed to understand the impacts of orchard and storage factors on fruit morphology.
The authors would like to thank Marcus Davy for statistical advice, Roswitha Schröder for cell wall-related advice, Jacqui Ross for help with the confocal microscope, Erika Varkonyi-Gasic, Sol Green for critically reading the manuscript and FRST (NZ) contract C06X0705 for funding the programme.
- Bertin N, Gautier H, Roche C: Number of cells in tomato fruit depending on fruit position and source-sink balance during plant development. Plant Growth Regulation. 2002, 36 (2): 105-112. 10.1023/A:1015075821976.View ArticleGoogle Scholar
- Harada T, Kurahashi W, Yanai M, Wakasa Y, Satoh T: Involvement of cell proliferation and cell enlargement in increasing the fruit size of Malus species. Scientia Horticulturae. 2005, 105 (4): 447-456. 10.1016/j.scienta.2005.02.006.View ArticleGoogle Scholar
- Olmstead JW, Lezzoni AF, Whiting MD: Genotypic differences in sweet cherry fruit size are primarily a function of cell number. Journal of the American Society for Horticultural Science. 2007, 132 (5): 697-703.Google Scholar
- Yamaguchi M, Sato I, Takase K, Watanabe A, Ishiguro M: Differences and yearly variation in number and size of mesocarp cells in sweet cherry (Prunus avium L.) cultivars and related species. Journal of the Japanese Society for Horticultural Science. 2004, 73 (1): 12-18.View ArticleGoogle Scholar
- Hamada K, Hasegawa K, Kitajima A, Ogata T: The relationship between fruit size and cell division and enlargement in cultivated and wild persimmons. Journal of Horticultural Science & Biotechnology. 2008, 83 (2): 218-222.Google Scholar
- Quilot B, Genard M: Is competition between mesocarp cells of peach fruits affected by the percentage of wild species genome?. Journal of Plant Research. 2008, 121 (1): 55-63. 10.1007/s10265-007-0125-9.View ArticlePubMedGoogle Scholar
- Jullien A, Munier-Jolain NG, Malezieux E, Chillet M, Ney B: Effect of pulp cell number and assimilate availability on dry matter accumulation rate in a banana fruit [Musa sp AAA group 'Grande Naine' (Cavendish subgroup)]. Annals of Botany. 2001, 88 (2): 321-330. 10.1006/anbo.2001.1464.View ArticleGoogle Scholar
- Harker FR, Stec MGH, Hallett IC, Bennett CL: Texture of parenchymatous plant tissue: A comparison between tensile and other instrumental and sensory measurements of tissue strength and juiciness. Postharvest Biology and Technology. 1997, 11 (2): 63-72. 10.1016/S0925-5214(97)00018-5.View ArticleGoogle Scholar
- Allan-Wojtas P, Sanford KA, McRae KB, Carbyn S: An integrated microstructural and sensory approach to describe apple texture. Journal of the American Society for Horticultural Science. 2003, 128 (3): 381-390.Google Scholar
- Mann H, Bedford D, Luby J, Vickers Z, Tong C: Relationship of instrumental and sensory texture measurements of fresh and stored apples to cell number and size. Hortscience. 2005, 40 (6): 1815-1820.Google Scholar
- Harker FR, Hallett IC: Physiological-Changes Associated with Development of Mealiness of Apple Fruit During Cool Storage. Hortscience. 1992, 27 (12): 1291-1294.Google Scholar
- Bain JM, Robertson RN: The physiology of growth in apple fruits. 1 Cell size, cell number and fruit development. Australian Journal of Scientific Research. 1951, B4: 75-91.Google Scholar
- Reeve RM: Histological investigations of texture in apples. II Structure and intercellular spaces. Food Research. 1953, 18: 604-617.View ArticleGoogle Scholar
- Khan AA, Vincent JFV: Anisotropy af apple parenchyma. Journal of the Science of Food and Agriculture. 1990, 52: 455-466. 10.1002/jsfa.2740520404.View ArticleGoogle Scholar
- Skene DS: The distribution of growth and cell division in the fruit of Cox's Orange Pippin. Annals of Botany. 1966, 30: 493-512.Google Scholar
- Drazeta L, Lang A, Hall AJ, Volz RK, Jameson PE: Air volume measurement of 'Braeburn' apple fruit. Journal of Experimental Botany. 2004, 55 (399): 1061-1069. 10.1093/jxb/erh118.View ArticlePubMedGoogle Scholar
- Verboven P, Kerckhofs G, Mebatsion HK, Ho QT, Temst K, Wevers M, Cloetens P, Nicolai BM: Three-dimensional gas exchange pathways in pome fruit characterized by synchrotron x-ray computed tomography. Plant Physiology. 2008, 147 (2): 518-527. 10.1104/pp.108.118935.PubMed CentralView ArticlePubMedGoogle Scholar
- Tukey HB, Young JO: Gross morphology and histology of developing fruit of the apple. Botanical Gazette. 1942, 104: 3-25. 10.1086/335103.View ArticleGoogle Scholar
- Smith WH: Cell-multiplication and cell-enlargement in the development of the flesh of the apple fruit. Annals of Botany. 1950, 16 (53): 23-38.Google Scholar
- Smith WH: The histological structure of the flesh of the apple in relation to growth and senescence. The Journal of Pomology and Horticultural Science. 1940, 18: 249-260.Google Scholar
- Somerville C, Bauer S, Brininstool G, Facette M, Hamann T, Milne J, Osborne E, Paredez A, Persson S, Raab T, Vorwerk S, Youngs H: Toward a systems approach to understanding plant-cell walls. Science. 2004, 306 (5705): 2206-2211. 10.1126/science.1102765.View ArticlePubMedGoogle Scholar
- Brown R, Rickless P: A new method for the study of cell division and cell extension with some preliminary observations on the effect of temperature and nutrients. Proceedings of the Royal Society of London B. 1949, 136: 110-125. 10.1098/rspb.1949.0008.View ArticleGoogle Scholar
- Bohner J, Bangerth F: Effects of Fruit-Set Sequence and Defoliation on Cell Number, Cell-Size and Hormone Levels of Tomato Fruits (Lycopersicon-Esculentum Mill) within a Truss. Plant Growth Regulation. 1988, 7 (3): 141-155.Google Scholar
- Bunger-Kibler S, Bangerth F: Relationship between cell number, cell size and fruit size of seeded fruits of tomato (Lycopersicon seculentum Mill.), and those induced parthernocarpically by the application of plant growth regulators. Plant Growth Regulation. 1982, 1: 143-154.Google Scholar
- Jarvis MC, Hall MA, Threlfall DR, Friend J: The polysaccharide structure of potato cell walls: Chemical fractionation. Planta. 1981, 152 (2): 93-100. 10.1007/BF00391179.View ArticlePubMedGoogle Scholar
- Blanpied GD, Bramlage WJ, Dewey DH, LaBell RL, Massey LM, Mattus GE, Stiles WC, Watada AE: A standardized method for collecting apple pressure test data. New York Food Life Science Bulletin. 1978, 74: 1-8.Google Scholar
- Hallett IC, Macrae EA, Wegrzyn TF: Changes in Kiwifruit Cell-Wall Ultrastructure and Cell Packing During Postharvest Ripening. International Journal of Plant Sciences. 1992, 153 (1): 49-60. 10.1086/297006.View ArticleGoogle Scholar
- Lapsley KG, Escher FE, Hoehn E: The Cellular Structure of Selected Apple Varieties. Food Structure. 1992, 11 (4): 339-349.Google Scholar
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