Autoimmunity to deltaNp63alpha in chronic ulcerative stomatitis.

Chronic ulcerative stomatitis (CUS) is a recently described mucocutaneous condition in which patients experience chronic, painful, ulcerative lesions of the oral mucosa. CUS is diagnosed by immunofluorescence studies that demonstrate antinuclear antibodies. These autoantibodies are specific for a protein, deltaNp63alpha, which is normally expressed in basal cell nuclei of stratified squamous epithelia. The purpose of this study was to characterize the autoimmune response in CUS. Protein antigens were produced by in vitro transcription/translation of polymerase chain-reaction (PCR)-amplified cDNAs. We used immunoblotting and immunoprecipitation experiments with serum from CUS patients to examine the (1) antibody isotype, (2) immunogenic functional domains of the deltaNp63alpha antigen, and (3) cross-reactivity with homologous p53, p73, and p63 proteins. Results demonstrate CUS patient antibodies to deltaNp63alpha, and 52% of cases have circulating IgA isotype antibodies. The N-terminal and DNA-binding domains are the immunodominant regions, and antibody cross-reactivity with p53, p63, and p73 isoforms is limited.

Coordinate regulation of ribosomal component synthesis in Acanthamoeba castellanii: 5S RNA transcription is down regulated during encystment by alteration of TFIIIA activity.

Transcription of large rRNA precursor and 5S RNA were examined during encystment of Acanthamoeba castellanii. Both transcription units are down regulated almost coordinately during this process, though 5S RNA transcription is not as completely shut down as rRNA transcription. The protein components necessary for transcription of 5S RNA and tRNA were determined, and fractions containing transcription factors comparable to TFIIIA, TFIIIB, and TFIIIC, as well as RNA polymerase III and a 3'-end processing activity, were identified. Regulation of 5S RNA transcription could be recapitulated in vitro, and the activities of the required components were compared. In contrast to regulation of precursor rRNA, there is no apparent change during encystment in the activity of the polymerase dedicated to 5S RNA expression. Similarly, the transcriptional and promoter-binding activities of TFIIIC are not altered in parallel with 5S RNA regulation. TFIIIB transcriptional activity is unaltered in encysting cells. In contrast, both the transcriptional and DNA-binding activities of TFIIIA are strongly reduced in nuclear extracts from transcriptionally inactive cells. These results were analyzed in terms of mechanisms for coordinate regulation of rRNA and 5S RNA expression.

Characterization and partial purification of two pre-tRNA 5'-processing activities from Daucus carrota (carrot) suspension cells.

Two distinct RNase P-like activities which cleave leader sequences from pre-tRNA molecules to give mature 5' ends have been identified in carrot suspension-culture cells. An Escherichia coli pre-tRNA(Phe) and a tobacco pre-tRNA(Tyr) were transcribed in vitro then used as substrates for processing reactions in a cell-free extract. The pre-tRNA(Tyr) transcript was used to establish optimal salt and divalent cation requirements for processing. Kinetic experiments were then carried out on both substrates to determine if 5' and 3' processing were ordered. Primer extension analysis of processing intermediates and stable products verified that an ammonium sulfate fraction of the extract was indeed capable of accurately processing the 5' ends of both pre-tRNAs. Subsequent fractionation of the 5' end-processing activity by chromatography on phosphocellulose revealed two distinct activities, eluting at 0.1 and 0.5 M KCI, when assayed with the tobacco pre-tRNA(Tyr) substrate. When the same fractions were assayed with the E. coli pre-tRNA(Phe), only the 0.1 M KCI fraction exhibited activity. Both of the active fraction display sensitivity to micrococcal nuclease (MN) and proteinase K indicating each is a ribonucleoprotein, a result not seen with other plant RNase Ps. Subsequent FPLC fractionation of the two activities using Mono Q and Mono S columns demonstrated that the two activities could be further distinguished on the basis of their chromatographic behavior.

Sequence organization of the Acanthamoeba rRNA intergenic spacer: identification of transcriptional enhancers.

The primary sequence of the entire 2330 bp intergenic spacer of the A.castellanii ribosomal RNA gene was determined. Repeated sequence elements averaging 140 bp were identified and found to bind a protein required for optimum initiation at the core promoter. These repeated elements were shown to stimulate rRNA transcription by RNA polymerase I in vitro. The repeats inhibited transcription when placed in trans, and stimulated transcription when in cis, in either orientation, but only when upstream of the core promoter. Thus, these repeated elements have characteristics similar to polymerase I enhancers found in higher eukaryotes. The number of rRNA repeats in Acanthamoeba cells was determined to be 24 per haploid genome, the lowest number so far identified in any eukaryote. However, because Acanthamoeba is polyploid, each cell contains approximately 600 rRNA genes.

Sequence and organization of 5S RNA genes from the eukaryotic protist Acanthamoeba castellanii.

A 5S RNA genomic clone has been isolated from Acanthamoeba castellanii and the sequence of the coding region plus flanking DNA was determined. This clone encodes an RNA whose sequence matches that of 5S RNA from this organism. There is sequence similarity in the 5'-flanking region to other eukaryotic 5S RNA genes which require or are greatly affected by upstream regions for transcriptional activity. The immediate 3'-flanking region has a termination sequence similar to that found in all genes that are transcribed by RNA polymerase III. The 5S RNA genes of A. castellanii are dispersed, which is highly unusual, since the majority of eukaryotic organisms contain 5S genes clustered in tandem repeats. There may be up to 480 genes encoding 5S RNA in each A. castellanii cell.

Specific transcription of an Acanthamoeba castellanii 5S RNA gene in homologous nuclear extracts.

An RNA polymerase III in vitro transcription system has been developed from the protist Acanthamoeba castellanii. The system is dependent on a cloned 5S RNA gene and utilizes a nuclear extract which contains all the necessary protein components. The system is assembled from completely homologous components. Primer extension and RNA sequencing analysis confirm that the in vitro 5S RNA transcript is identical to the 5S RNA isolated from cells. The transcription complex forms unusually rapidly on the 5S RNA gene and is stable to challenge by excess competitor templates. Several 5' deletion mutants were constructed and indicate that the region upstream of -33 is dispensable. Deletion to +16 show the region between -33 and +16 to be required for transcription, a region outside the canonical internal control region.