Multiple regions of NSR1 are sufficient for accumulation of a fusion protein within the nucleolus

Nuclear localization signal binding proteins in higher plant nuclei

The import of proteins into the nucleus is a vital process that is mediated by proteins which specifically recognize nuclear localization signals (NLSs). These factors have not been identified in plants. Previously, we demonstrated that higher plants possess a low-affinity binding site at the nuclear pore that specifically binds to several classes of functional NLSs. By the use of crosslinking reagents and a radiolabeled peptide to the bipartite NLS from the endogenous plant transcription factor Opaque2, two NLS binding proteins (NBPs) of 50-60 kDa and at least two NBPs of 30-40 kDa were identified. Competition studies indicated that labeling was specific for the functional NLS but not a mutant NLS impaired in vivo or a peptide unrelated to NLSs. Also, the apparent dissociation constant (100-300 microM) for labeling was similar to that of the binding site. Proteins of similar mass were labeled with two different crosslinking reagents, and concentration and time studies indicated that these NBPs were distinct proteins and not aggregates. Treatment with salt, detergent, or urea before or during NLS binding demonstrated that the properties of the binding site and the NBPs were identical. This tight correlation strongly indicates that some or all of the NBPs constitute the nuclear pore binding site. Overall, our results indicate that some components of NLS recognition are located at the nuclear pores in higher plants.

The nucleolus

The transcriptionally active rRNA genes have the remarkable ability to organize and integrate the biochemical pathway of ribosome production into a structural framework, the nucleolus. The past year has seen numerous advances in our understanding of the relationships between nucleolar substructures, the site of ribosomal RNA (rRNA) gene transcription and the pathway of ribosome maturation. Progress has also been made both in the molecular identification of nucleolar constituents and in our understanding of the interactions between these components and their assembly into higher order structures.