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Capítulo 16: Analyzing Gene Expression and Function Back To Chapter

16.14: In-situ Hybridization

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In-situ Hybridization

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16.13: Reporter Genes

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16.15: Chromatin Immunoprecipitation- ChIP

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In situ hybridization is a technique used to locate DNA or RNA in cultured cells or in chemically preserved tissue sections.

RNA in situ hybridization is used to monitor where a gene is being expressed by detecting and quantifying the specific mRNA transcripts.

The target mRNAs are detected by single-stranded, complementary RNA probes that are created by in vitro transcription of a DNA template or synthesized by a chemical reaction.

The probes are labeled with radioactive isotopes, fluorophores, or other reporter molecules, such as biotin or digoxigenin, that can be bound and detected by a labeled antibody.

RNA in situ hybridization has four main steps: tissue fixation, permeabilization, hybridization, and detection.

To begin, fresh tissue is harvested and chemically treated to stop any biochemical reactions within the tissue and preserve its structural integrity. This preservation technique is called tissue fixation.

Next, proteins and lipids in the tissue need to be removed for the probe to access and bind the target RNA.

To degrade the proteins and permeabilize the cell membrane, the sample is treated with 0.2 molar hydrochloric acid and enzymes such as proteinases, while detergents are used to break down the lipids.

The target RNA is then hybridized with the probes at a temperature just below the melting point of the RNA-probe hybrid. This helps the probes to anneal with the complementary mRNAs. Unbound and loosely bound probes are removed by performing several washes.

The method for detecting the hybridized probes depends on the type of label. Radioactive probes are exposed to photographic films, while fluorescent probes are visible under fluorescent microscopes.

For other labels, antibodies against the reporter molecule are tagged with a fluorescent or colorimetric dye.

Detection of hybridized probes reveals the distribution of specific mRNAs indicating where the genes of interest are expressed.

16.14: In-situ Hybridization

In situ hybridization (ISH) is a technique used to detect and localize specific DNA or RNA molecules in cells, tissue, or tissue sections using a labeled probe. The technique was first used in 1969 for the investigation of nucleic acids. It is currently an essential tool in scientific research and clinical settings, especially for diagnostic purposes.

Types of probes and labels

A probe is a complementary strand of DNA or RNA that binds to corresponding nucleotide sequences in a cell. Many different probes, such as single-stranded DNA probes, double-stranded DNA probes, antisense RNA probes or riboprobes, and synthetic oligodeoxynucleotide probes, are used in in situ hybridization. The choice of probe depends on several factors, including their sensitivity, specificity, stability, and ease of penetration into the tissue sample.

These probes can be labeled with radioisotopes, fluorescent dyes, or other antigen molecules for detection purposes. The ³H, ³⁵S, and ³²P are widely used radiolabeled probes, while non-radioactive labels include biotin, digoxigenin, and fluorescein. These labels can be attached to the probe DNA molecule via end-labeling, nick-translation, or random primer synthesis methods. Detection methods, such as autoradiography, fluorescence microscopy, or immunohistochemistry, are used for target visualization based on the label attached to the hybridized probe.

**Advantages and disadvantages of in situ hybridization**

One of the major advantages of in situ hybridization is that it can even be applied to frozen tissues to enable maximum use of tissues that are difficult to obtain. In addition, it can be combined with other techniques, such as immunohistochemistry, to detect protein and active mRNA in the sample. However, while working with samples that have low DNA and RNA copies, it may be difficult to identify targets using in situ hybridization.

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In Situ Hybridization DNA Probe RNA Probe Labeled Probe Nucleic Acid Investigation Scientific Research Diagnostic Purposes Probes And Labels Single-stranded DNA Probe Double-stranded DNA Probe Antisense RNA Probe Riboprobe Synthetic Oligodeoxynucleotide Probe Sensitivity Specificity Stability Penetration Into Tissue Sample Radioisotopes Fluorescent Dyes Antigen Molecules 3H Label 35S Label 32P Label Non-radioactive Labels Biotin Label Digoxigenin Label Fluorescein Label End-labeling Method Nick-translation Method Random Primer Synthesis Method Autoradiography Detection Method Fluorescence Microscopy Detection Method Immunohistochemistry Detection Method

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