In Vivo Observation of a Nuclear Channel-like System: Evidence for a Distinct Interchromosomal Domain Compartment in Interphase Cells

Abstract

We have investigated the interchromosomal domain compartment in living cells by transfecting cDNA coding for Xenopus vimentin, engineered to contain a nuclear localization signal (NLS), coupled to the green fluorescent protein. In human vimentin-free SW13 cells, this chimeric protein was deposited in body-like “dots” both at 37°C, the nonpermissive temperature for assembly of the amphibian vimentin, and 28°C, the optimal temperature for Xenopus vimentin assembly, indicating that the chimeric protein was assembly incompetent. However, when transfected into a subclone stably expressing Xenopus NLS-vimentin (SW13-SC), the chimeric protein incorporated, as a fluorescent tracer, into the structures formed by NLS-vimentin and allowed us to visualize the outgrowth of the vimentin fibers after a temperature shift to 28°C in living cells. In particular, we followed the time-dependent outgrowth of fibers from nuclear dots, first connecting two dots each and with time three and more, eventually generating a spatially restricted fiber system consisting of few loop-like arrays traversing the nucleus. Virtually identical results were obtained when the temperature was lowered only to 30 and 32°C, respectively. An engineered human NLS-vimentin, without need for temperature shift, formed seemingly identical patterns of nuclear fibrils at 37°C in three additionally transfected human cell lines: MCF-7, PLC, and HeLa. When the epithelial cytokeratin pair 8 and 18 was expressed in the nucleus via an engineered NLS in the cytokeratin 18 gene, more network-like, extended filament arrays were generated. Notably, in cotransfection experiments with Xenopus NLS-vimentin, we observed that the formation of these cytokeratin networks at 37°C initiated from dots that nearly entirely colocalized with the aggregated amphibian NLS-vimentin. After a shift to 28°C, extending Xenopus NLS-vimentin and cytokeratin filaments frequently followed the same path through the nucleus. These data indicate that interphase cells contain a seemingly equivalent, accessible interchromosomal space.