10.3791/1627-v

10.3791/54437-v

Deferred Growth Inhibition Assay to Quantify the Effect of Bacteria-derived Antimicrobials on Competition

10.3791/51265-v 14:44 min

Isolation of mRNAs Associated with Yeast Mitochondria to Study Mechanisms of Localized Translation

10.3791/50044-v

Live Imaging of GFP-labeled Proteins in Drosophila Oocytes

10.3791/3951-v 07:12 min

Rapid Fibroblast Removal from High Density Human Embryonic Stem Cell Cultures

10.3791/1316-v

Cell Block Preparation from Cytology Specimen with Predominance of Individually Scattered Cells

10.3791/816-v 12:06 min

The Structure of Skilled Forelimb Reaching in the Rat: A Movement Rating Scale

10.3791/51973-v 08:45 min

Utilizing Custom-designed Galvanotaxis Chambers to Study Directional Migration of Prostate Cells

10.3791/50722-v 06:10 min

A Fluorescence-based Exonuclease Assay to Characterize DmWRNexo, Orthologue of Human Progeroid WRN Exonuclease, and Its Application to Other Nucleases

10.3791/4458-v 14:08 min

Blastomere Explants to Test for Cell Fate Commitment During Embryonic Development

10.3791/4449-v 10:55 min

Study of the DNA Damage Checkpoint using Xenopus Egg Extracts

10.3791/4442-v 13:54 min

Preparation of Cell-lines for Conditional Knockdown of Gene Expression and Measurement of the Knockdown Effects on E4orf4-Induced Cell Death

Interactome-Seq: A Protocol for Domainome Library Construction, Validation and Selection by Phage Display and Next Generation Sequencing

作者： Maria Felicia Soluri1, Simone Puccio2, Giada Caredda2, Giorgio Grillo3, Vito Flavio Licciulli3, Arianna Consiglio3, Paolo Edomi4, Claudio Santoro1, Daniele Sblattero4, Clelia Peano5,6 1Department of Health Sciences,Università del Piemonte Orientale & IRCAD, Novara, Italy, 2Institute of Biomedical Technologies,National Research Council, Segrate, Milan, Italy, 3Institute of Biomedical Technologies,National Research Council, Bari, Italy, 4Department of Life Sciences,University of Trieste, Italy, 5Institute of Genetic and Biomedical Research,National Research Council, Rozzano, Milan, Italy, 6Humanitas Clinical and Research Center, Rozzano, Milan, Italy

简介：

Overview

This article presents a method for constructing a 'domainome' library from any DNA source, utilizing a combination of phage display, a folding reporter, and next-generation sequencing. This approach enables the characterization and selection of proteins against specific targets, facilitating various protein-based research applications.

Key Study Components

Area of Science

Protein research
Phage display technology
Next-generation sequencing

Background

Understanding protein domains and their functions is crucial in biology.
Current methods for protein characterization can be biased or limited in scope.
High-throughput techniques are needed for comprehensive analysis.
Domainome libraries can enhance functional studies of proteins.

Purpose of Study

To develop an unbiased method for constructing domainome libraries.
To enable the selection of proteins against various targets.
To provide a robust analysis framework for protein interactions.

Methods Used

Phage display for protein selection.
Next-generation sequencing for detailed analysis.
Web tools for data characterization and analysis.
Integration of multiple technologies for comprehensive research.

Main Results

The method allows for high-throughput and unbiased protein characterization.
Successful construction of domainome libraries from diverse DNA sources.
Enhanced sensitivity in analyzing protein interactions.
Web tools provide precise characterization of domainomes and interactomes.

Conclusions

This approach significantly advances protein-based research methodologies.
It opens new avenues for studying protein interactions and functions.
The integration of technologies offers a powerful tool for researchers.

Frequently Asked Questions

What is a domainome library?

A domainome library is a collection of protein domains constructed from DNA sources, allowing for the study of various protein interactions and functions.

How does phage display work?

Phage display is a technique that allows for the selection of proteins by displaying them on the surface of bacteriophages, enabling interaction studies with various targets.

What are the advantages of using next-generation sequencing?

Next-generation sequencing provides high-throughput capabilities and detailed insights into the genetic makeup of proteins, enhancing the analysis of protein interactions.

Can this method be applied to any DNA source?

Yes, the method is designed to be versatile and can be applied to various DNA sources for constructing domainome libraries.

What types of studies can benefit from this approach?

This approach can benefit functional studies, protein interaction network analysis, and characterization of structural properties of proteins.

The protocols described allow the construction, characterization and selection (against the target of choice) of a "domainome" library made from any DNA source. This is achieved by a research pipeline that combines different technologies: phage display, a folding reporter and next generation sequencing with a web tool for data analysis.

标签: Interactome, Domainome Library, Phage Display, Next-generation Sequencing, Protein Research, Functional Studies, ORF Library, Sonication, Agarose Gel Electrophoresis, DNA Fragmentation, Vector Preparation, DNA Purification, Enzyme Treatment,