作者：Ashly Brown1, Stephen Brown2, Debra Ellisor2, Nellwyn Hagan1, Elizabeth Normand1, Mark Zervas2 1Department of Neuroscience, Division of Biology and Medicine,Brown University, 2Department of Molecular Biology, Cell Biology and Biochemistry, Division of Biology and Medicine,Brown University

简介：Genetic Inducible Fate Mapping (GIFM) marks and tracks cells with fine spatial and temporal control in vivo and elucidates how cells from a specific genetic lineage contribute to developing and adult tissues. Demonstrated here are the techniques required to fate map E12.5 mouse embryos for epifluorescent and explant analysis.

全文：

Overview

This article discusses Genetic Inducible Fate Mapping (GIFM), a technique that allows for precise marking and tracking of cells in vivo. It elucidates the contributions of specific genetic lineages to both developing and adult tissues, with a focus on E12.5 mouse embryos.

Key Study Components

Area of Science

Neuroscience
Cell Biology
Developmental Biology

Background

Fate mapping is essential for understanding progenitor contributions to tissue.
GIFM links gene expression to cell behaviors in vivo.
This technique can be applied to various biological studies.
It is particularly useful in studying early brain development.

Purpose of Study

To demonstrate the GIFM technique for tracking cell lineage.
To explore its applications in gene inactivation studies.
To provide insights into animal models of human disease.

Methods Used

Marking and tracking cells in vivo.
Using epifluorescent analysis.
Employing explant analysis techniques.
Demonstrating procedures in a laboratory setting.

Main Results

Successful tracking of cells from specific genetic lineages.
Insights into the contributions of progenitor cells to tissue development.
Demonstrated applicability to various research contexts.
Enhanced understanding of early brain development processes.

Conclusions

GIFM is a powerful tool for studying cell lineage in vivo.
It provides valuable insights into developmental biology.
The technique has broad applications in neuroscience and disease modeling.

Frequently Asked Questions

What is Genetic Inducible Fate Mapping?

Genetic Inducible Fate Mapping (GIFM) is a technique used to mark and track cells in vivo based on their genetic lineage.

How can GIFM be applied in research?

GIFM can be applied to study early brain development, gene inactivation studies, and animal models of human disease.

What are the key components of the GIFM technique?

The key components include marking cells, tracking them in vivo, and analyzing their contributions to tissue development.

What types of analysis are used in GIFM?

Epifluorescent analysis and explant analysis are commonly used in GIFM studies.

Who conducted the study on GIFM?

The study was conducted by Deborah Ellisor and colleagues from Brown University.

What is the significance of fate mapping?

Fate mapping is significant for understanding how progenitor cells contribute to specific structures and cell types in tissues.

标签: Genetic Inducible Fate Mapping Fate Maps Marking And Tracking Cells In Vivo Progenitors Specific Structures Cell Types Genetic Inducible Fate Mapping (GIFM) Gene Expression Cell Fate Cell Behaviors X-CreER Lines Bacteriophage Protein Cre Recombinase CreERT Modified Estrogen Receptor Ligand Binding Domain Tamoxifen Recombination LoxP Sites Stop Cassette Reporter Gene GFP Mice Breeding Conditional Reporter Allele

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