conditions. We then measured the kinetics of RANBP2 depletion and CG formation over time after RANBP2-siRNA transfection. Automated recognition of SC35 labeling on digital images enabled us to discriminate CGs from normal nuclear speckles. We found that RANBP2-negative cells and cells with CGs increased over time but with a different time course. The increase in CGs was later than the RANBP2 depletion. In a substantial proportion of cells, RANBP2 was reduced to a nondetectable level within 24 h of introduction of the siRNA, whereas it took 4872 h for CGs to appear. This suggests that nuclear speckles do not transform into CGs immediately after RANBP2 depletion, but Volume 23 March 15, 2012 | 1119 Molecular Biology of the Cell FIGURE 4: Sequential nuclear entry of speckle components at late mitosis was disrupted in RANBP2-depleted cells. CG constituents correlated with those present in MIGs at very late mitosis. Immunofluorescence analyses of RANBP2- or RAN-depleted HeLa cells using various antibodies against speckle-associated components are shown. The subcellular localization of each factor revealed in this study is EMA401 web summarized at the bottom, along with the previously reported sequence of their nuclear import at mitosis. Simultaneous staining of snRNPs and SC35 antigens in RANBP2-depleted cells showed that snRNPs are distributed in a speckled pattern in the nucleus without SC35. HeLa cells were knocked down for a series of nuclear transport receptor family members and stained with SC35 and DAPI. CGs were produced only when KPNB1 is depleted. IPO, importin; KPNA and KPNB, karyopherins; SNUPN, snurportin1; TNPO, transportin; XPO, exportin. TNPO3 was concentrated in the cytoplasm and was absent from the nuclear rim in cells depleted of RANBP2. Cells treated with siRANBP2 were transfected with the plasmid SR2/pcDNA3-FLAG-HA, and the localization of PubMed ID:http://www.ncbi.nlm.nih.gov/pubmed/19796370 TNPO3 was monitored by immunofluorescence using anti-FLAG antibodies. Bars, 10 m. Volume 23 March 15, 2012 RANBP2 for nuclear speckle and splicing | 1121 as well as bulk poly+ RNAs, showed a speckled pattern in the nucleus of RAN- or RANBP2knockdown cells. Simultaneous visualization confirmed that the CGcontaining cells formed partial speckles of snRNPs, early-entering factors in the absence of SC35 antigens. This suggests that a subset of speckle components is transported to the nucleus by RAN-unassisted mechanisms, as described for snRNPs and several other proteins. It is also possible that the effects of RANBP2 knockdown are specific to proteins that enter the nucleus at later time points because they use different transport receptors. To test this, we depleted cells for a series of importin and and exportin family members and asked whether these cells still produced CGs. We found that knockdown of most transport receptors, including SNUPN, which mediates nuclear import of snRNPs, did not cause CG formation. CGs emerged only when cells were depleted of KPNB1, a transport receptor for a wide variety of proteins, or TNPO3, an importin family protein for SR proteins. Consistent with this observation, the subcellular localization of TNPO3 was dysregulated in RANBP2-knockdown cells, suggesting that RANBP2 is a docking site for TNPO3 and is critical for its regulation. CG formation requires phosphorylation Our second finding from surveying the CG constituents was that CG localization of proteins correlated with their phosphorylation status. CGs were stained with SC35, which recognizes phosphorylate
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