Quantitative analysis of trabecular bone tissue cryosections via a fully automated neural network-based approach.

Cryosectioning is known as a common and well-established histological method, due to its easy accessibility, speed, and cost efficiency. However, the creation of bone cryosections is especially difficult. In this study, a cryosectioning protocol for trabecular bone that offers a relatively cheap and undemanding alternative to paraffin or resin embedded sectioning was developed. Sections are stainable with common histological dying methods while maintaining sufficient quality to answer a variety of scientific questions. Furthermore, this study introduces an automated protocol for analysing such sections, enabling users to rapidly access a wide range of different stainings. Therefore, an automated 'QuPath' neural network-based image analysis protocol for histochemical analysis of trabecular bone samples was established, and compared to other automated approaches as well as manual analysis regarding scattering, quality, and reliability. This highly automated protocol can handle enormous amounts of image data with no significant differences in its results when compared with a manual method. Even though this method was applied specifically for bone tissue, it works for a wide variety of different tissues and scientific questions.

Cryosectioning and Immunohistochemistry Using Frozen Adult Murine Brain Neural Tissue.

Cryopreservation and immunohistochemistry offer a comprehensive, robust, and simple methodology to investigate neural patterning and cellular function. Rapid freezing of the whole brain allows excellent preservation of neural ultrastructure and tissue architecture without destroying sensitive protein epitopes that are often compromised following standard paraffin embedding histological techniques. Here, we present a rapid and simple protocol for employing cryosectioning and subsequent immunohistochemistry in the study of adult murine brain neural tissue.

Genome-Wide RNA Tomography in the Mouse Whole Olfactory Mucosa.

Spatial transcriptomics allows for the genome-wide profiling of topographic gene expression patterns within a tissue of interest. Here, we describe our methodology to generate high-quality RNA-seq libraries from cryosections from fresh frozen mouse whole olfactory mucosae. This methodology can be extended to virtually any vertebrate organ or tissue sample.

Fluorescent In Situ Hybridization for miRNA Combined with Staining of Proteins.

The last decades have illustrated the importance of microRNAs (miRNAs) in various biological and pathological processes. The combined visualization of miRNAs using fluorescent in situ hybridization (FISH) and proteins using immunofluorescence (IF) can reveal their spatiotemporal distribution in relation to the cell and tissue morphology and can provide interesting insights into miRNA-protein interactions. However, standardized protocols for co-localization of miRNAs and proteins are currently lacking, and substantial technical obstacles still need to be addressed. In particular, the incompatibility of protein IF protocols with steps required for miRNA FISH, such as proteolytic pretreatments and ethylcarbodiimide post-fixation, as well as hurdles related to low signal intensity of low-copy miRNAs, remains challenging. Our technique may considerably enhance miRNA-based research, as current detection techniques lack the ability to elucidate cellular and subcellular localization. Here, we describe an optimized 2-day protocol for combined detection of low-abundant miRNAs and proteins in cryosections of cardiac tissue, without the need for protease-dependent pretreatment or post-fixation treatment. We successfully demonstrate endothelial-specific localization of low-abundant miR-181c-5p in cardiac tissue. © 2023 Wiley Periodicals LLC. Basic Protocol: Fluorescent in situ hybridization for miRNA combined with staining of proteins.

Spatial Transcriptomics in Kidney Tissue.

Unlike bulk and single-cell/single-nuclei RNA sequencing methods, spatial transcriptome sequencing (ST-seq) resolves transcriptome expression within the spatial context of intact tissue. This is achieved by integrating histology with RNA sequencing. These methodologies are completed sequentially on the same tissue section placed on a glass slide with printed oligo-dT spots, termed ST-spots. Transcriptomes within the tissue section are captured by the underlying ST-spots and receive a spatial barcode in the process. The sequenced ST-spot transcriptomes are subsequently aligned with the hematoxylin and eosin (H&E) image, giving morphological context to the gene expression signatures within intact tissue. We have successfully employed ST-seq to characterize mouse and human kidney tissue. Here, we describe in detail the application of Visium Spatial Tissue Optimization (TO) and Visium Spatial Gene Expression (GEx) protocols for ST-seq in fresh frozen kidney tissue.

A quick and laidback way to detect the internal structure of the Drosophila eye: An alternative to cryosectioning.

Immunofluorescence techniques have been a great tool to chase the structure, localization, and function of many proteins within a cell. Drosophila eye is widely used as a model to answer various questions. However, the complex sample preparation and visualization methods restrict its use only with an expert's hand. Thus, an easy and hassle-free method is in need to broaden the use of this model even with an amateur's hand. The current protocol describes an easy sample preparation method using DMSO to image the adult fly eye. The brief description of sample collection, preparation, dissection, staining, imaging, storage, and handling has been described over here. For readers, the possible problems that might arise during the execution of the experiment have been described with their possible reason and solutions. The overall protocol reduces the use of chemicals and shortens the sample preparation time to only 3 h, which is significantly less in comparison to other protocols.

Cryosectioning and Immunohistochemistry of Peripheral Tissues of Mosquitoes.

Immunohistochemistry analysis of mosquitoes is complicated by the outer cuticle that prevents reagents from penetrating peripheral tissues. This protocol incorporates a cryosectioning method that provides a higher resolution of the internal architecture of mosquito peripheral sensory tissues and enables the visualization of protein expression. This eliminates the need for enzymatic steps to digest the outer cuticle that encases these tissues. This protocol can also be adapted for other tissues, such as the brain and the legs, as chitin exoskeleton thickness does not affect antibody penetration once the sample is sectioned.

Stage-dependent localization of F-actin and Na+ /K+ -ATPase in zebrafish embryos detected using optimized cryosectioning immunostaining protocol.

The increasing use of the zebrafish model in biomedical and (eco)toxicological studies aimed at understanding the function of various proteins highlight the importance of optimizing existing methods to study gene and protein expression and localization in this model. In this context, zebrafish cryosections are still underutilized compared with whole-mount preparations. In this study, we used zebrafish embryos (24-120 hpf) to determine key factors for the preparation of high-quality zebrafish cryosections and to determine the optimal protocol for (immuno)fluorescence analyses of Na+ /K+ -ATPase and F-actin, across developmental stages from 1 to 5 dpf. The results showed that the highest quality zebrafish cryosections were obtained after the samples were fixed in 4% paraformaldehyde (PFA) for 1 h, incubated in 2.5% bovine gelatin/25% sucrose mixture, embedded in OCT, and then sectioned to 8 µm thickness at -20°C. Fluorescence microscopy analysis of phalloidin-labeled zebrafish skeletal muscle revealed that 1-h-4% PFA-fixed samples allowed optimal binding of phalloidin to F-actin. Further immunofluorescence analyses revealed detailed localization of F-actin and Na+ /K+ -ATPase in various tissues of the zebrafish and a stage-dependent increase in their respective expression in the somitic muscles and pronephros. Finally, staining of zebrafish cryosections and whole-mount samples revealed organ-specific and zone-dependent localizations of the Na+ /K+ -ATPase α1-subunit. RESEARCH HIGHLIGHTS: This study brings optimization of existing protocols for preparation and use of zebrafish embryos cryosections in (immuno)histological analyses. It reveals stage-dependent localization/expression of F-actin and Na+ /K+ -ATPase in zebrafish embryos.

Isolation, culture, and cryosectioning of primary porcine retinal pigment epithelium on transwell cell culture inserts.

Primary culture and long-term maintenance of primary retinal pigment epithelium (RPE) is a useful model system for the study of ocular pathologies such as age-related macular degeneration. Here, we detail the steps for the isolation and long-term culture of primary porcine RPE. We also describe steps for cryoprotecting, cryosectioning, and interrogating with immunofluorescence and histochemistry RPE cells grown on transwell membranes. These techniques can be used in histological studies to detect sub-RPE deposits. For complete details on the use and execution of this protocol, please refer to Pilgrim et al., (2017).

Bimodal endocytic probe for three-dimensional correlative light and electron microscopy.

We present a bimodal endocytic tracer, fluorescent BSA-gold (fBSA-Au), as a fiducial marker for 2D and 3D correlative light and electron microscopy (CLEM) applications. fBSA-Au consists of colloidal gold (Au) particles stabilized with fluorescent BSA. The conjugate is efficiently endocytosed and distributed throughout the 3D endolysosomal network of cells and has an excellent visibility in both fluorescence microscopy (FM) and electron microscopy (EM). We demonstrate that fBSA-Au facilitates rapid registration in several 2D and 3D CLEM applications using Tokuyasu cryosections, resin-embedded material, and cryoelectron microscopy (cryo-EM). Endocytosed fBSA-Au benefits from a homogeneous 3D distribution throughout the endosomal system within the cell, does not obscure any cellular ultrastructure, and enables accurate (50-150 nm) correlation of fluorescence to EM data. The broad applicability and visibility in both modalities makes fBSA-Au an excellent endocytic fiducial marker for 2D and 3D (cryo)CLEM applications.

Hybridization Chain Reaction for mRNA Localization in Single Cells from Mouse and Human Cryosections.

In situ hybridization has been a robust method for detection of mRNA expression in whole-mount samples or tissue sections for more than 50 years. Recent technical advances for in situ hybridization have incorporated oligo-based probes that attain greater tissue penetration and signal amplification steps with restricted localization for visualization of specific mRNAs within single cells. One such method is third-generation in situ hybridization chain reaction (V3HCR). Here, we report an optimized protocol for V3HCR detection of gene expression using sectioned frozen tissues from mouse and human on microscope slides. Our methods and modifications for cryosectioning, tissue fixation, and processing over a three-day V3HCR protocol are detailed along with recommendations for aliquoting and storing V3HCR single-stranded DNA probes and hairpin amplifiers. In addition, we describe a method for blocking background signal from lipofuscin, a highly autofluorescent material that is widespread in human neurons and often complicates imaging efforts. After testing multiple strategies for reduction of lipofuscin, we determined that application of a lipofuscin quencher dye is compatible with V3HCR, in contrast to other methods like cupric sulfate quenching or Sudan Black B blocking that cause V3HCR signal loss. This adaptation enables application of V3HCR for in situ detection of gene expression in human neuronal populations that are otherwise problematic due to lipofuscin autofluorescence. © 2022 Wiley Periodicals LLC. Basic Protocol: Mouse and human fresh-frozen tissue in situ hybridization chain reaction on microscope slides Support Protocol: Aliquoting of HCR probes and hairpins.

In Situ Hybridization Combined with Immunohistochemistry in Cryosectioned Zebrafish Embryos.

As a vertebrate, the zebrafish has been widely used in biological studies. Zebrafish and humans share high genetic homology, which allows its use as a model for human diseases. Gene function study is based on the detection of gene expression patterns. Although immunohistochemistry offers a powerful way to assay protein expression, the limited number of commercially available antibodies in zebrafish restricts the application of costaining. In situ hybridization is widely used in zebrafish embryos to detect mRNA expression. This protocol describes how to obtain images by combining in situ hybridization and immunohistochemistry for zebrafish embryo sections. In situ hybridization was performed prior to cryosectioning, followed by antibody staining. Immunohistochemistry and the imaging of a single cryosection were performed after in situ hybridization. The protocol is helpful to unravel the expression pattern of two genes, first by in situ transcript detection and then by immunohistochemistry against a protein in the same section.

Cryo-ultramicrotomy and Mass Spectrometry Imaging Analysis of Nudibranch Microstructures.

In this paper, we investigate the presence of latrunculin A in the outer rim of a nudibranch Chromodoris kuiteri and show that by combining ultrathin cryosection methods with MALDI MSI we can achieve improved lateral (x and y) resolution and very high resolution in the z dimension by virtue of the ultrathin 200 nm thin cryosections. We also demonstrate that a post ionization laser increases sensitivity. Recent advances in MALDI source design have improved the lateral resolution (x and y) and sensitivity during MSI. Taken together, very high z resolution, from ultrathin sections, and improved lateral (x and y) resolution will allow for subcellular molecular imaging with the potential for subcellular 3D volume reconstruction.

Cryosectioning.

The protocols presented here describe steps for cryosectioning tissue samples to be used in light microscopy methodologies including histochemistry, enzyme immunohistochemistry, and immunofluorescence. © 2022 Wiley Periodicals LLC. Basic Protocol 1: Cryosectioning.

Intercellular nuclear migration in cryofixed tobacco male meiocytes.

In this study, intercellular nuclear migration (INM), also known as cytomixis, was documented in cryofixed plant meiocytes for the first time. Intact tobacco inflorescences and flower buds as well as dissected individual anthers were cryofixed in liquid nitrogen by plunge freezing. Cryosubstituted and cryosectioned male meiocytes were analyzed by light microscopy. For cryosubstitution, the frozen material was kept in acetic alcohol at - 70 °C for 1 week. For cryosectioning, the frozen material was sectioned at - 20 °C, and fixed with precooled acetic alcohol. Fixation of the intact tobacco inflorescences in Carnoy's solution was used as a control. Microscopy revealed good preservation of cell structure in the cryofixed anthers, flower buds, and inflorescences. INM was detectable in all the studied cryofixed and chemically fixed samples. The cytological picture of INM observed in the cryofixed meiocytes did not noticeably differ from the picture obtained with the chemically fixed cells. These results indicate that INM is observable irrespective of whether a physical or chemical fixation method is employed, with minimal damage from handling. Our results contradict the notion that INM is a phenomenon caused by mechanical, osmotic, or chemical artifacts during sample preparation.

SpineRacks and SpinalJ for efficient analysis of neurons in a 3D reference atlas of the mouse spinal cord.

Spatial analysis of spinal neurons is currently limited by a lack of tools for efficient preparation and imaging of the whole spinal cord (SC) and the absence of a 3D reference atlas. Here, we describe protocols for efficient sectioning of whole SC using SpineRacks and subsequent image registration, atlas mapping, and 3D analysis of cells and projections, using SpinalJ. Together, these tools enable high-throughput analyses of adult mouse SC and direct comparison of spatial information of neurons between animals and studies. For complete details on the use and execution of this protocol, please refer to Fiederling et al. (2021).

Evaluation of autofluorescence quenching techniques on formalin- fixed chicken tissues.

Autofluorescence (AF) in formalin-fixed and paraffin-embedded tissues limit their use in immunofluorescence staining techniques. Various methods have been used to reduce AF in human and animal tissues but no protocol has been optimized for avian tissues. The present study was undertaken to evaluate different treatment methods including ammonium chloride, glycine, Trypan blue, sodium borohydride, Sudan Black B, potassium permanganate, LED light, cupric sulphate combined with glycine, ammonium chloride and cupric sulphate in reducing AF in FFPE chicken tissues for the detection of FITC labelled antibodies against immune cell markers. Chicken tissues including conjunctiva, trachea and Harderian gland presented intense non-homogenous AF in cells resembling erythrocytes, connective cells and melanocytes. Only Sudan Black B effectively reduced AF in FFPE tissues; however, no specific fluorescent signal was observed for six FITC labelled antibodies against immune cell markers. Specific fluorescent signal from the FITC-labelled antibodies was observed in frozen chicken tissue sections with minimal AF, suggesting that the AF in FFPE tissues is related to the use of formaldehyde fixatives. In conclusion, this study demonstrates for the first time that AF quenching methods commonly used for other animal species are not appropriate for use in avian tissues and that frozen tissue sections are recommended for immunofluorescence staining techniques in poultry.

Cryosectioning and Immunostaining of Xenopus Embryonic Tissues.

The Xenopus embryo is a classical vertebrate model for molecular, cellular, and developmental biology. Despite many advantages of this organism, such as large egg size and external development, imaging of early embryonic stages is challenging because of nontransparent cytoplasm. Staining and imaging of thin tissue sections is one way to overcome this limitation. Here we describe a step-by-step protocol that combines cryosectioning of gelatin-embedded embryos with immunostaining and imaging. The purpose of this protocol is to examine various cellular and tissue markers after the manipulation of protein function. This protocol can be performed within a 2-d period and allows detection of many antigens by immunofluorescence.

Laser Capture Microdissection of Vascular Endothelial Cells from Frozen Heart Tissues.

Laser capture microdissection (LCM) enables researchers to selectively evaluate gene expression profiling of a specific cell type within a tissue. Vascular endothelial cells (EC) line the inside of vessel lumen and play an essential role in new blood vessel formation. It remains a challenge to determine vascular ECs-specific genes expression in vivo. Here, we described a method to dissect vascular ECs from the frozen heart tissue by LCM. The total RNA or proteins are then extracted from the ECs for further analysis.

Adhesive film applications help to prepare strawberry fruit sections for desorption electrospray ionization-mass spectrometry imaging.

Desorption electrospray ionization-mass spectrometry imaging (DESI-MSI) is a powerful tool to analyze the distribution of metabolites in biological tissues. Cryosectioning of biological tissues is usually required prior to DESI-MSI, but it can be difficult for tissues that are fragile, hard, and have a high-water content. The Kawamoto method uses transparent adhesive films to prepare cryosections; however, its application for plant tissues, such as strawberry tissues, in DESI-MSI has not been verified. In this study, strawberry cryosections maintained original structures were prepared using adhesive film. Subsequently, numerous peaks were detected for the sections using the positive and negative ion modes of DESI-MSI. Several primary and specialized metabolites, such as amino acids, sugars, organic acids, and flavonoids, were identified and visualized. These results suggest the use of adhesive films when cryosectioning could improve DESI-MSI analysis of the metabolites in strawberry fruits and various tissues of other plant species.