Name: Imaging Unrolled Whole Mounts of Maize Leaf Primordia
Uploaded: 2023-09-22T13:00:00
Duration: 2 min 48 s
Description: Watch this Scientific Journal Video about Imaging Unrolled Whole Mounts of Maize Leaf Primordia at JoVE.com

imaging unrolled whole mounts of maize leaf primordia

改进的玉米叶片原基成像方法

Grass crops are a major source of food and biofuel for the global population1, and improving leaf anatomy has the potential to increase their productivity2,3. However, our current understanding of how leaf anatomy is regulated in grasses is limited4 and requires the analysis of leaf primordia, as many anatomical and physiological traits of the leaf are predetermined early in development5,6,7. Cellular imaging techniques, such as fluorescence and confocal imaging, are indispensable for studying grass leaf anatomy and cellular traits, but these techniques are difficult to apply to grass leaf primordia because they are deeply ensheathed and rolled within the leaf whorl. We addressed this issue by developing methods for preparing transverse sections and unrolled whole-leaf mounts for fluorescence and confocal analysis of maize leaf primordia, a model system for studying grass leaf anatomy and development2,8.
The maize leaf, like all grass leaves, consists of a strap-like blade with a sheath that wraps around the stem and developing shoot9,10,11,12,13. The leaves develop from the shoot apical meristem (SAM) in a distichous pattern, where each new leaf initiates in the opposite position of the previous leaf, resulting in two ranks of leaves along the vertical axis&#160;(Figure 1A)14 . The developmental stage of each leaf primordium is identified by its position relative to the SAM, with the closest primordium designated as plastochron1 (P1) and the following primordia designated as P2, P3, and so on (Figure 1B,C)2. During development (Figure 1D), the leaf primordium first appears as a crescent-shaped buttress around the base of the SAM (P1), and then grows into a hood-shaped primordium that extends over the meristem (P2)9,10,11. The basal margins of the hood then expand laterally and overlap each other as the tip grows upward, forming a cone-shaped primordium (P3-P5)10. The primordium then rapidly grows in length, and the sheath-blade boundary at the base becomes more prominent with the formation of the ligule, the fringe-like projection on the adaxial side of the leaf (P6/P7). Finally, the leaf unrolls as it emerges from the whorl during steady-state growth, in which the dividing cells are restricted within the small basal region of the blade, forming a gradient with expanding and differentiating cells along the proximal-distal axis (P7/P8)15. The shoot apex of a maize seedling contains multiple primordia at different stages of development, making it an excellent model for studying leaf development8.
Accurate analysis of early leaf development requires staging or the use of standardized criteria to define distinct stages of primordium development in relation to other growth or morphological parameters. Because the leaf primordia are hidden within the grass shoot, investigators typically use parameters such as the age of the plant or the size of the emerging leaves as predictors for the stages and sizes of the leaf primordia9,16. In maize, the chronological age of the plant is determined either by the number of days after planting or germination (DAP/DAG)17,18. The vegetative stage (V stage) is determined by the uppermost leaf with a visible collar, a pale line on the abaxial side between the blade and the sheath that corresponds to the position of the ligule and auricles, a pair of wedge-shaped regions at the base of the blade&#160;(Figure 1A,B)17,19 . Between 20 and 25 DAG, the SAM transitions into an inflorescence meristem and ceases to produce new leaves20. The growth rates of maize leaf primordia can vary depending on the environment and the genotype of the plant. For this reason, plant age and the size of the emerging leaves cannot accurately predict the sizes of leaf primordia; however, using these parameters can help predict the range of primordia stages and sizes for experimental purposes.
Transverse section analysis is a popular method for examining leaf anatomy and development in maize and other grasses because it allows for the sampling of multiple plastochrons in a single section across the shoot21,22,23. This method is also convenient for cellular imaging of fresh samples, as the surrounding leaves serve as a scaffold&#160;that keeps the leaf primordia in place during sectioning and mounting24. However, a disadvantage of this method is that it can be challenging to precisely locate the target plastochron and region within the primordium when sectioning from an intact shoot. Furthermore, because leaf growth varies across plastochrons and along the proximal-distal axis2,5, imprecise sampling could result in an incorrect interpretation of the developmental stage and region of the primordium in a given section. Therefore, developing a method for precise transverse section sampling is critical for ensuring the accuracy and reproducibility of anatomical and developmental analyses of grass leaf primordia.
Whole-leaf mount analysis enables the comprehensive and integrative investigation of tissue and cellular processes that occur at the whole-organ scale, such as proliferative growth25 and vein patterning26,27,28. The method provides a paradermal overview of the leaf, allowing the discovery of distinct processes and patterns that would otherwise be difficult to detect using transverse section analysis24,27. Unlike in Arabidopsis, where there are already established methods for imaging whole-leaf mounts29,30, there is currently no standard method for imaging unrolled whole-leaf mounts in grasses. A previous protocol for unrolling isolated maize leaf primordia involved uncommon materials and was not suitable for cellular imaging31. Advanced imaging techniques, such as computed tomography (CT) and magnetic resonance imaging (MRI), can acquire 3D anatomical information without isolating and unrolling the primordia11,32,33, but they are expensive and require specialized equipment. Developing a technique to overcome the constraints imposed by the rolled and conical morphology of leaf primordia in maize and other grasses would advance investigations into their anatomical and developmental traits.
Here, we present methods for preparing transverse sections and unrolled whole mounts of maize leaf primordia for fluorescence and confocal imaging. We used these methods to quantify vein number and map the spatial-temporal hormone distribution in maize leaf primordia with fluorescent proteins (FPs)24. The first method involves removing the upper portion of older leaves from maize seedlings with a wire stripper (Figure 1E). By exposing the tip of the primordium (P5-P7), it becomes possible to determine its length without having to completely remove the older surrounding leaves, thus enabling easy and accurate sectioning. The second method involves unrolling and mounting whole-leaf primordia (P3-P7) with clear, double-sided nano tape (Figure 1F). These methods are suitable for visualizing various FPs24&#160;but need optimization for using fluorescent dyes and clearing reagents. In addition, we outline some procedures for flattening z-stacks, stitching images, and merging channels in ImageJ/FIJI34, which apply to the images produced by the two methods. These methods are useful for routine fluorescence or confocal imaging of maize leaves, but they can also be adapted for other model grass species, such as rice, Setaria, and Brachypodium.
<img alt="Figure 1" class="xfigimg" src="/files/ftp_upload/65239/65239fig01.jpg" /> 
Figure 1: Organization and morphology of maize leaf primordia and overview of the methods. (A) Schematic representation of a maize seedling. Maize has a distichous phyllotaxy, with the new leaf initiating at the opposite position of the previous leaf. The leaf number indicates the chronological order in which the leaves emerged from germination (i.e., first leaf, L1; second leaf, L2; third leaf, L3; etc.). Each leaf has a distal blade and a basal sheath delineated by a collar that corresponds to the ligule and auricle. The uppermost leaf with the collar visible denotes the vegetative stage. The seedling in this example is at the V2 stage, with the L2 collar (arrowhead) visible. The scissors icon indicates the location at the mesocotyl (me) where the seedling must be cut in order to be collected. (B) Schematic representation of the dissected shoot showing isolated L1 to L4, with the leaf primordia L5 to L9 shown as an enlarged image in (C). The plastochron number indicates the position of the primordium relative to the SAM, with the youngest leaf primordium (P1) closest to the SAM and the older leaf primordia (P2, P3, P4, and so on) successively farther away2. (D) Schematic representation of the morphology of maize leaf primordia from P1 to P5. (E) Schematic overview of the method for transverse section analysis of the maize leaf primordia. (1) Trim the older leaves with a wire stripper. (2) Measure the primordium and section the shoot. (3) Mount the section on a slide for imaging and processing (4, 5). (F) Schematic overview of the method for whole-mount analysis of the maize leaf primordia. (1) Remove the surrounding leaves to extract the primordium. (2) Cut and unroll the primordium flat on the nano tape. (3) Mount the sample for imaging and processing (4, 5). Abbreviations: L = leaf; bl = blade; sh = sheath; co = collar; me = mesocotyl; V = vegetative; P = plastochron; SAM = shoot apical meristem. <a href="https://www.jove.com/files/ftp_upload/65239/65239fig01large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>

作者聚焦：用于荧光和共聚焦成像的玉米叶片原基横向切片和展开整片的改进方法  

用于荧光和共聚焦成像的玉米叶原基横向切片和展开整片的制备方法的改进方法

Grasses like maize have leaf primordia grow within the shoot, making them difficult to study. We address this problem with improved protocols for preparing maize leaf transverse sections and whole mounts for fluorescence and confocal imaging. The first protocol uses a wire stripper to cut the older leaves, allowing the measurement of the primordium prior to sectioning.The second protocol uses clear, double-sided nano tape to unroll whole leaf primordium. These protocols improve the accuracy of transverse sectioning and enable unrolling of the leaf primordia, which have been very difficult to achieve due to their rolled, conical morphology. These methods will be useful for visualizing and quantifying leaf anatomical and developmental traits in maize and other grasses.Based on these methods, we plan to develop live cell imaging strategies to address questions in grass leaf development.

Watch this Scientific Journal Video about Imaging Unrolled Whole Mounts of Maize Leaf Primordia at JoVE.com

Imaging Unrolled Whole Mounts of Maize Leaf Primordia  

玉米叶原基展开的整个坐骑成像

通过切割一块矩形的透明双面纳米胶带并将其粘在干净的载玻片的中心而不去除胶带顶部的保护性塑料膜来开始制备载玻片。接下来，用剥线钳去除老叶子的上部来解剖滑槽。然后握住中尾部的滑槽，用牙探针小心地去除周围的叶子，以提取感兴趣的原基。要安装原基，请从胶带上取下保护膜。将暴露的原基放在胶带上。用剃须刀片在基部切割原基，丢弃基茎和下尾。为了更顺利地展开，通过将针尖浸入 100% 甘油中来润滑内侧或近轴叶表面。使用带有弯曲针的牙科探针展开原基。将针尖平行于表面放置，并通过轻轻按压胶带来展开外基缘。将外边缘粘附在胶带上，将针尖平行于叶片的长轴对齐。轻轻地将针向侧面滑动以展开并将叶子压平到胶带上。在展开的原木上滴一滴水。立即在水滴和原木上放置盖玻片。轻轻按下盖玻片的边缘，使其粘附在胶带上。完成后，将载玻片放在落射荧光显微镜载物台上以可视化荧光团。采用该方法对玉米叶原木中的荧光蛋白表达进行可视化和分析。与横截面分析相辅相成。全叶坐分析揭示了静脉形成过程中形式反应的组织和阶段特异性模式。全镶分析方法能够对玉米叶原基中的荧光蛋白表达进行定性和定量分析，表明该方法在检查玉米叶原基方面的有效性，由于其滚动形态而难以成像。

imaging-unrolled-whole-mounts-of-maize-leaf-primordia

Research

JoVE Journal

Biology

Imaging Unrolled Whole Mounts of Maize Leaf Primordia

Improved Methods for Preparing Transverse Sections and Unrolled Whole Mounts of Maize Leaf Primordia for Fluorescence and Confocal Imaging

In maize (Zea mays) and other grasses (Poaceae), the leaf primordia are deeply ensheathed and rolled within the leaf whorl, making it difficult to study early leaf development. Here, we describe methods for preparing transverse sections and unrolled whole mounts of maize leaf primordia for fluorescence and confocal imaging. The first method uses a wire stripper to remove the upper portions of older leaves, exposing the tip of the leaf primordium and allowing its measurement for more accurate transverse section sampling. The second method uses clear, double-sided nano tape to unroll and mount whole-leaf primordia for imaging. We show the utility of the two methods in visualizing and analyzing fluorescent protein reporters in maize. These methods provide a solution to the challenges presented by the distinctive morphology of maize leaf primordia and will be useful for visualizing and quantifying leaf anatomical and developmental traits in maize and other grass species.

Maize leaf primordia are deeply ensheathed and rolled, making them difficult to study. Here, we present methods for preparing transverse sections and unrolled whole mounts of maize leaf primordia for fluorescence and confocal imaging.

In maize (Zea mays) and other grasses (Poaceae), the leaf primordia are deeply ensheathed and rolled within the leaf whorl, making it difficult to study ...

科研

生物学

﻿Imaging Transverse Sections of Maize Leaf Primordia

Imaging Transverse Sections of Maize Leaf Primordia  

Begin by cutting the desired aged maize seedling at the mesocotyl tissue using a small knife or pair of scissors. Clean the seedling with a paintbrush. Then hold the wire stripper with its jaws facing the chute.Position the chute to the selected hole and squeeze the stripper handles together. Slide the stripper away from the chute to trim the upper portion of the leaves. Use a ruler to measure the length from the primordium's tip to the chute's base.To begin the leaf primordium imaging, hold the chute steady on a smooth surface under a stereo microscope at around 0.8x magnification. Using a razor blade or scalpel, make an initial cut slightly above the target region to discard the distal portion of the chute. Then obtain around 0.25 to 0.8 millimeter thin sections at the desired points along the length of the primordium.Once done, mount the leaf section on a clean glass slide. Apply a few drops of water directly to the section using a pipette. And place a cover slip on top.Apply a few more drops through the edges of the cover slip if needed. Place the slide on the epifluorescence microscope's stage and adjust the settings to visualize the fluorophore. Using this method, chance resection sampling was standardized by measuring the primordia prior to sectioning.A trend was discovered showing that the vanishing tassel two had a wider primordia and more veins than normal, indicating that the defect in the mutant began early in the leaf development. This method also enabled the systematic examination of the expression patterns of hormone response fluorescent protein reporters in the leaf primordia.

玉米叶原基横截面成像

Begin the preparation of the glass slide by cutting a rectangular piece of clear, double-sided nano tape and sticking it to the center of a clean glass slide without removing the protective plastic film on the top side of the tape. Next, dissect the chute by removing the upper portion of the older leaves with a wire stripper. Then hold the chute by the mesocaudal and carefully remove the surrounding leaves with a dental probe to extract the primordia of interest.For mounting the primordium, remove the protective film from the tape. Lay the exposed primordium on the tape. Cut the primordium at the base using a razor blade, discarding the basal stem and the hypocaudal.For smoother unrolling, lubricate the inner, or, adaxial leaf surface by dipping the needle tip into 100%glycerol. Unroll the primordium using a dental probe with a bent needle. Position the needle tip parallel to the surface and unfurl the outer basal margin by gently pressing it against the tape.With the outer margin adhering to the tape, align the needle tip parallel to the long axis of the leaf. Gently slide the needle sideways to unroll and flatten the leaf onto the tape. Apply a drop of water to the unrolled primordium.Immediately place a cover slip on the water drop and the primordium. Gently press down the edges of the cover slip so that they adhere to the tape. Once done, place the slide on the epifluorescence microscope stage to visualize the fluorophore.This method was followed to visualize and analyze the fluorescent protein expression in maize leaf primordia. Complementary to the transverse section analysis. The whole leaf mount analysis revealed tissue and stage-specific patterns of formal response during vein formation.Whole mount analysis method enabled qualitative and quantitative analyses of fluorescent protein expression in the maize leaf primordia, indicating the effectiveness of this method in examining the maize leaf primordia which are difficult to image due to their rolled morphology.