Arabidopsis mRNA polyadenylation machinery: comprehensive analysis of protein-protein interactions and gene expression profiling

Authors

Arthur G. Hunt, University of Kentucky
Ruqiang Xu, Virginia Commonwealth UniversityFollow
Balasubrahmanyam Addepalli, University of Kentucky
Suryadevara Rao, University of Kentucky
Kevin P. Forbes, University of Kentucky
Lisa R. Meeks, University of Kentucky
Denghui Xing, Miami University - Oxford
Min Mo, Miami University - Oxford
Hongwei Zhao, Miami University - Oxford
Amrita Bandyopadhyay, University of Kentucky
Lavanya Dampanaboina, University of Kentucky
Amanda Marion, University of Kentucky
Carol Von Lanken, University of Kentucky
Qingshun Quinn Li, Miami University - Oxford

Document Type

Article

Original Publication Date

2008

Journal/Book/Conference Title

BMC Genomics

Volume

9

DOI of Original Publication

10.1186/1471-2164-9-220

Comments

Originally published at http://dx.doi.org/10.1186/1471-2164-9-220

Date of Submission

September 2014

Abstract

Background

The polyadenylation of mRNA is one of the critical processing steps during expression of almost all eukaryotic genes. It is tightly integrated with transcription, particularly its termination, as well as other RNA processing events, i.e. capping and splicing. The poly(A) tail protects the mRNA from unregulated degradation, and it is required for nuclear export and translation initiation. In recent years, it has been demonstrated that the polyadenylation process is also involved in the regulation of gene expression. The polyadenylation process requires two components, the cis-elements on the mRNA and a group of protein factors that recognize the cis-elements and produce the poly(A) tail. Here we report a comprehensive pairwise protein-protein interaction mapping and gene expression profiling of the mRNA polyadenylation protein machinery in Arabidopsis.

Results

By protein sequence homology search using human and yeast polyadenylation factors, we identified 28 proteins that may be components of Arabidopsis polyadenylation machinery. To elucidate the protein network and their functions, we first tested their protein-protein interaction profiles. Out of 320 pair-wise protein-protein interaction assays done using the yeast two-hybrid system, 56 (~17%) showed positive interactions. 15 of these interactions were further tested, and all were confirmed by co-immunoprecipitation and/or in vitro co-purification. These interactions organize into three distinct hubs involving the Arabidopsis polyadenylation factors. These hubs are centered around AtCPSF100, AtCLPS, and AtFIPS. The first two are similar to complexes seen in mammals, while the third one stands out as unique to plants. When comparing the gene expression profiles extracted from publicly available microarray datasets, some of the polyadenylation related genes showed tissue-specific expression, suggestive of potential different polyadenylation complex configurations.

Conclusion

An extensive protein network was revealed for plant polyadenylation machinery, in which all predicted proteins were found to be connecting to the complex. The gene expression profiles are indicative that specialized sub-complexes may be formed to carry out targeted processing of mRNA in different developmental stages and tissue types. These results offer a roadmap for further functional characterizations of the protein factors, and for building models when testing the genetic contributions of these genes in plant growth and development.

Rights

© 2008 Hunt et al; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Is Part Of

VCU Anatomy and Neurobiology Publications