An interactome analysis reveals that Arabidopsis thaliana GRDP2 interacts with proteins involved in post-transcriptional processes.

The Arabidopsis thaliana glycine-rich domain protein 2 (AtGRDP2) gene encodes a protein of unknown function that is involved in plant growth and salt stress tolerance. The AtGRDP2 protein (787 aa, At4g37900) is constituted by three domains: a DUF1399 located at the N-terminus, a potential RNA Recognition Motif (RRM) in the central region, and a short glycine-rich domain at the C-terminus. Herein, we analyzed the subcellular localization of AtGRDP2 protein as a GFP translational fusion and found it was localized in the cytosol and the nucleus of tobacco leaf cells. Truncated versions of AtGRDP2 showed that the DUF1399 or the RRM domains were sufficient for nuclear localization. In addition, we performed a yeast two-hybrid split-ubiquitin assay (Y2H) to identify potential interactors for AtGRDP2 protein. The Y2H assay identified proteins associated with RNA binding functions such as PABN3 (At5g65260), EF-1α (At1g07920), and CL15 (At3g25920). Heterodimeric associations in planta between AtGRDP2 and its interactors were carried out by Bimolecular Fluorescence Complementation (BiFC) assays. The data revealed heterodimeric interactions between AtGRDP2 and PABN3 in the nucleus and AtGRDP2 with EF-1α in the cytosol, while AtGRDP2-CL15 associations occurred only in the chloroplasts. Finally, functional characterization of the protein-protein interaction regions revealed that both DUF1399 and RRM domains were key for heterodimerization with its interactors. The AtGRDP2 interaction with these proteins in different compartments suggests that this glycine-rich domain protein is involved in post-transcriptional processes.

Spectroscopic analysis of moss (Ceratodon purpureus and Physcomitrella patens) recombinant non-symbiotic hemoglobins.

Non-symbiotic hemoglobins (nsHbs) are O(2)-binding proteins widely distributed in land plants, including primitive bryophytes. Little is known about the properties of bryophyte nsHbs. Here, we report the spectroscopic characterization of two moss recombinant nsHbs, CerpurnsHb of Ceratodon purpureus and PhypatnsHb of Physcomitrella patens. Spectra showed that the absorption maxima of the ferrous and ferric forms of recombinant CerpurnsHb are located at 418, 531 and 557 nm and 407, 537, 569 (shoulder) and 632 (shoulder) nm, respectively, and of PhypatnsHb are located at 422, 529 and 557 nm and 407, 531, 571 (shoulder) and 647 (shoulder) nm, respectively. These absorption maxima are similar to those of rice Hb1. Also, the absorption maxima of the oxygenated ferrous form of recombinant CerpurnsHb and PhypatnsHb are located at 412, 541 and 575 nm and 414, 541 and 574 nm, respectively, similar to those of oxygenated rice Hb1 and cowpea leghemoglobin II. This evidence indicates that CerpurnsHb and PhypatnsHb are mostly hexacoordinate and that they bind O(2).