Gpn1 and Gpn3 associate tightly and their protein levels are mutually dependent in mammalian cells.

Gpn1 and Gpn3 are GTPases individually required for nuclear targeting of RNA polymerase II. Here we show that whereas Gpn3-EYFP distributed between the cytoplasm and cell nucleus, it was mainly cytoplasmic when coexpressed with Gpn1-Flag. Gpn3-Flag retained Gpn1-EYFP in the cytoplasm. However, Gpn3-EYFP/Gpn1-Flag nucleocytoplasmic shuttling was revealed after inhibiting nuclear export with leptomycin B. All Gpn3-EYFP coimmunoprecipitated with Gpn1-Flag, and all Gpn1-EYFP with Gpn3-Flag. Importantly, most endogenous Gpn1 and Gpn3 also associate. Gpn1-Gpn3 interaction was essential to maintain steady-state protein levels of both GTPases. We propose that most Gpn1 and Gpn3 associate, are mobilized, and function as a protein complex.

A nuclear export sequence in GPN-loop GTPase 1, an essential protein for nuclear targeting of RNA polymerase II, is necessary and sufficient for nuclear export.

XAB1/Gpn1 is a GTPase that associates with RNA polymerase II (RNAPII) in a GTP-dependent manner. Although XAB1/Gpn1 is essential for nuclear accumulation of RNAPII, the underlying mechanism is not known. A XAB1/Gpn1-EYFP fluorescent protein, like endogenous XAB1/Gpn1, localized to the cytoplasm but it rapidly accumulated in the cell nucleus in the presence of leptomycin B, a chemical inhibitor of the nuclear transport receptor Crm1. Crm1 recognizes short peptides in substrate proteins called nuclear export sequences (NES). Here, we employed site-directed mutagenesis and fluorescence microscopy to assess the functionality of all six putative NESs in XAB1/Gpn1. Mutating five of the six putative NESs did not alter the cytoplasmic localization of XAB1/Gpn1-EYFP. However, a V302A/L304A double mutant XAB1/Gpn1-EYFP protein was clearly accumulated in the cell nucleus, indicating the disruption of a functional NES. This functional XAB1/Gpn1 NES displays all features present in most common and potent NESs, including, in addition to Φ1-Φ4, a critical fifth hydrophobic amino acid Φ0. Therefore, in human Gpn1 this NES spans amino acids 292-LERLRKDMGSVAL-304. XAB1/Gpn1 NES is remarkably conserved during evolution. XAB1/Gpn1 NES was sufficient for nuclear export activity, as it caused a complete exclusion of EYFP from the cell nucleus. Molecular modeling of XAB1/Gpn1 provided a mechanistic reason for NES selection, as functionality correlated with accessibility, and it also suggested a mechanism for NES inhibition by intramolecular masking. In conclusion, we have identified a highly active, evolutionarily conserved NES in XAB1/Gpn1 that is critical for nucleo-cytoplasmic shuttling and steady-state cytoplasmic localization of XAB1/Gpn1.