Fluorochrome-labeled RNA as a sensitive, strand-specific probe for direct fluorescence in situ hybridization.

Detection of target RNA by in situ hybridization (ISH) in the classic and confocal fluorescence microscope was performed using strand-specific single-stranded RNA probes labeled directly with the fluorochromes fluorescein isothiocyanate or Texas red. The probes, produced by in vitro transcription from PCR-generated templates with T7 RNA polymerase and fluorochromized UTP, gave ISH signals directly visible by fluorescence microscopy without the use of any immunological detection step. In avoiding antibodies, it was possible to strongly increase the sensitivity of the ISH since antibodies may contain RNase which can reduce hybridization signals considerably, even beyond the detection limit. Fluorescent RNA probes thus allowed for the detection of low numbers of target molecules per cell, such as minus strand intermediates in picornavirus RNA replication. Using appropriate denaturing conditions, the targets could be visualized in a double-stranded configuration as well as in the presence of a 100-fold excess of complementary RNA. Furthermore, double ISH for the simultaneous detection of two different RNA species, such as plus and minus strand RNA of poliovirus, or of different regions of the viral genomic RNA was possible with appropriate fluorescent strand-specific probes labeled with different fluorochromes. Combination of ISH and immunofluorescence was found feasible if RNA was present in relatively large amounts. In addition to the investigation of virus replication, possible applications of fluorochromized RNA probes might include antisense RNA detection as well as plant virus resistance and gene silencing.

Intracellular localization of poliovirus plus- and minus-strand RNA visualized by strand-specific fluorescent In situ hybridization.

The time courses of poliovirus plus- and minus-strand RNA synthesis in infected HEp-2 cells were monitored separately, using a quantitative RNase assay. In parallel, viral RNA and proteins were located in situ by confocal microscopy within cells fixed by a protocol determined to retain their native size and shape. Plus- and minus-strand RNAs were visualized by fluorescent in situ hybridization (FISH) with strand-specific riboprobes. The probes were labelled with different fluorochromes to allow for the simultaneous detection of plus- and minus-strand RNA. The FISH experiments showed minus-strand RNA to be present in distinct, regularly sized, round structures throughout the viral replication cycle. Plus-strand RNA was found in the same structures and also in smaller clusters of vesicles. Association of viral RNA with membranes was demonstrated by combining FISH with immunofluorescence (IF) detection of the viral 2B- and 2C-containing P2 proteins, which are known to be markers for virus-induced membranes. At early times postinfection, the virus-induced membranous structures were distributed through most of the cytoplasm, whereas around peak RNA synthesis, both RNA-associated membranous structures migrated to the center of the cell. During this process, the plus- and minus-strand-containing larger structures stayed as recognizable entities, whereas the plus-strand-containing granules coalesced into a juxtanuclear area of membranous vesicles. An involvement of Golgi-derived membranes in the formation of virus-induced vesicles and RNA synthesis early in infection was investigated by IF with 2C- and Golgi-specific antibodies.

Reversible dissociation of the poliovirus replication complex: functions and interactions of its components in viral RNA synthesis.

Membrane-bound replication complexes containing transcriptionally active replicative intermediates (RI) can be isolated from poliovirus-infected HEp-2 cells and consist of rosette-like structures of virus-induced vesicles surrounding the replicating viral RNA. At low ionic strength and low temperature, the rosettes reversibly dissociate into individual tubulated vesicles. As determined by immunoelectron microscopy and immunoprecipitation, the vesicles carry a set of viral structural and nonstructural proteins as well as RI RNA. At 30 degrees C, the vesicles reassociate into rosettes synthesizing plus-strand RNA in the RI. The in vitro transcriptional activities of rosettes and vesicles kept separated by high dilution were assessed by an RNase protection assay. The synthesis of the first 178 nucleotides at the 5' end of the plus strand was considered to reflect initiation, and the detection of a 530-nucleotide fragment in the P2 genomic region was considered to reflect elongation. It could be shown that the initiation and elongation of plus strands on individual vesicles are comparable to those in rosettes, with initiation proceeding in de novo-assembled initiation complexes. By use of detergent treatment it was found that initiation, but not elongation, is dependent on vesicular membranes.