Differential transcription of multiple copies of a silk worm gene encoding tRNA(Gly1)

Transcriptional activation of a moderately expressed tRNA gene by a positioned nucleosome

All of the members of a tRNA1(Gly) multigene family from the mulberry silkworm, Bombyx mori, have identical coding regions and consequently identical internal promoter elements, but are transcribed at different levels. A moderately expressed copy, tRNA1(Gly)-4 from within this multigene family, which was transcribed to 30-50% of the highly transcribed gene copies harboured two typical TATAA box sequences in the 5' upstream region at positions -27 nt and -154 nt with respect to the +1 nt of mature tRNA. Deletion of the distal TATAA sequence at -154 nt brought down the transcription more than 70%, whereas mutation of the proximal element did not affect transcription. tRNA1(Gly)-4 could be readily assembled into chromatin, with a positioned nucleosome in the upstream region, and the assembled nucleosome formed stable complexes with the transcription factors TFIIIC and TFIIIB. Organization of the gene into nucleosomes also enhanced transcription significantly above that of the naked DNA, reaching transcription levels comparable with those of the highly transcribed copies. This nucleosome-mediated enhancement in transcription was absent when the distal TATAA sequences were deleted, whereas mutation of the proximal TATAA element showed no effect. In the absence of the distal TATAA sequences, assembly into the nucleosome inhibited transcription of tRNA1(Gly)-4. TFIIIB bound directly through the distal TATAA sequence at -154 nt and the positioned nucleosome facilitated its interaction with TFIIIC. The direct binding of TFIIIB to the DNA provided anchoring of the factor to the template DNA which conferred a higher stability on the TFIIIB-TFIIIC-DNA complex. We have proposed a novel mechanism for the nucleosome-mediated stimulation of pol III (RNA polymerase III) transcription of tRNA genes, a model not presented previously.

Modulation of differential transcription of tRNA genes through chromatin organization

In higher eukaryotes, tRNA multigene families comprise several copies encoding the same tRNA isoacceptor species. Of the 11 copies of a tRNA1Gly family from the mulberry silkworm Bombyx mori, individual members are differentially transcribed in vivo in the B. mori-derived BmN cell lines and in vitro in silk gland nuclear extracts. These genes have identical coding regions and hence harbour identical internal control sequences (the A and B boxes), but differ significantly in their 5' and 3' flanking regions. In the present study, we demonstrate the role of chromatin structure in the down-regulation of the poorly expressed copy, tRNA1Gly-6,7. Distinct footprints in the 5'-upstream region of the poorly transcribed gene in vitro as well as in vivo suggested the presence of nucleosomes. A theoretical analysis of the immediate upstream sequence of this gene copy also revealed a high propensity of nucleosome formation. The low transcription of tRNA1Gly-6,7 DNA was further impaired on assembly into chromatin and this inhibition was relieved by externally supplemented TFIIIC with an associated histone acetyltransferase activity. The inhibition due to nucleosome assembly was absent when the 5'-upstream region beyond -53 nt was deleted or entirely swapped with the 5'-upstream region of the highly transcribed gene copy, which does not position a nucleosome. Footprinting of the in vitro assembled tRNA1Gly-6,7 chromatin confirmed the presence of a nucleosome in the immediate upstream region potentially masking TFIIIB binding. Addition of TFIIIC unmasked the footprints present on account of the nucleosome. Our studies provide the first evidence for nucleosomal repression leading to differential expression of individual members from within a tRNA multigene family.

Transcription of individual tRNAGly1 genes from within a multigene family is regulated by transcription factor TFIIIB

Members of a multigene family from the silkworm Bombyx mori have been classified based on their transcriptions in homologous nuclear extracts, into three groups of highly, moderately and poorly transcribed genes. Because all these gene copies have identical coding sequences and consequently identical promoter elements (the A and B boxes), the flanking sequences modulate their expression levels. Here we demonstrate the interaction of transcription factor TFIIIB with these genes and its role in regulating differential transcriptions. The binding of TFIIIB to the poorly transcribed gene -6,7 was less stable compared with binding of TFIIIB to the highly expressed copy, -1. The presence of a 5' upstream TATA sequence closer to the coding region in -6,7 suggested that the initial binding of TFIIIC to the A and B boxes sterically hindered anchoring of TFIIIB via direct interactions, leading to lower stability of TFIIIC-B-DNA complexes. Also, the multiple TATATAA sequences present in the flanking regions of this poorly transcribed gene successfully competed for TFIIIB reducing transcription. The transcription level could be enhanced to some extent by supplementation of TFIIIB but not by TATA box binding protein. The poor transcription of -6,7 was thus attributed both to the formation of a less stable transcription complex and the sequestration of TFIIIB. Availability of the transcription factor TFIIIB in excess could serve as a general mechanism to initiate transcription from all the individual members of the gene family as per the developmental needs within the tissue.

A novel TATA-box-binding factor from the silk glands of the mulberry silkworm, Bombyx mori

The presence of one or more TATATAA motifs in the flanking sequences of individual members of a multi-gene tRNA(Gly)(1) family from the mulberry silkworm, Bombyx mori, negatively modulated the transcription of the gene copies. Characterization of proteins from posterior silk gland nuclear extracts, binding to the TATATAA motif, identified a novel 43 kD protein, designated here as P43 TATA-box-binding factor (TBF). The protein was purified to homogeneity. P43 TBF binding was highly sequence-specific and showed a 100-fold-higher affinity for binding than the TATA-box-binding protein (TBP). The protein also showed binding to the TATAAA sequence of the actin5C promoter. P43 TBF inhibited transcription of all the tRNA genes examined, as well as RNA polymerase II transcription from the actin5C promoter. The amino acid sequence of eleven peptides generated from P43 TBF did not share homology with proteins that bind the TATA box, such as TBP, TRF (TBP-related factor) or TLFs (TBP-like factors) reported from other sources. Inhibition of transcription of tRNA genes by P43 TBF could not be reversed by TBP. The inhibitory effect appeared to be exerted through sequestration of the associated transcription factors.

Characterization of RNA polymerase III transcription factor TFIIIC from the mulberry silkworm, Bombyx mori

Fractionation of nuclear extracts from posterior silk glands of mulberry silkworm Bombyx mori, resolved the transcription factor TFIIIC into two components (designated here as TFIIIC and TFIIIC1) as in HeLa cell nuclear extracts. The reconstituted transcription of tRNA genes required the presence of both components. The affinity purified TFIIIC is a heteromeric complex comprising of five subunits ranging from 44 to 240 kDa. Of these, the 51-kDa subunit could be specifically crosslinked to the B box of tRNA1Gly. Purified swTFIIIC binds to the B box sequences with an affinity in the same range as of yTFIIIC or hTFIIIC2. Although an histone acetyl transferase (HAT) activity was associated with the TFIIIC fractions during the initial stages of purification, the HAT activity, unlike the human TFIIIC preparations, was separated at the final DNA affinity step. The tRNA transcription from DNA template was independent of HAT activity but the repressed transcription from chromatin template could be partially restored by external supplementation of the dissociated HAT activity. This is the first report on the purification and characterization of TFIIIC from insect systems.

Differential expression of individual gene copies from within a tRNA multigene family in the mulberry silkworm Bombyx mori

In mulberry silkworm Bombyx mori, tRNA1(Gly) constitutes a multigene family from which the individual members are transcribed at different levels in vitro in homologous nuclear extracts. We report here the quantification of functional transcripts of these gene copies in vivo in B. mori-derived BmN cells based on a suppression assay. The gene copies were converted to encode suppressor tRNAs and co-transfected into cell lines with reporter gene(s) harbouring one or more nonsense mutations and the reporter gene activity was quantified. Individual members of the gene family were transcribed to very high-, medium- and very low-levels, following the same pattern as in vitro. All these gene copies were maximally expressed in Bm cells as compared to other insect cell lines.

A spider tRNA(Ala) requires a far upstream sequence element for expression

Within the series of timed differential accumulations of small RNAs we have shown to prelude the synthesis of fibroin in the large ampullate glands of Nephila clavipes (Nc), we are currently directing our attention to the alanine tRNAs. This work reports the subcloning of the members of a tRNAAla gene cluster and the optimization of their transcription in a heterologous cell-free system derived from Bombyx mori (Bm) silkglands. Our data show that the heterologous cell-free system supports the faithful and differential transcription of the individual spider alanine tRNA genes. We are thus making use of the extract to characterize the individual genes with respect to flank-contained regulatory elements through cell-free transcription of gene derivatives. The work has been initiated with pNTA3 because of its high transcriptional activity. Interestingly, the transcription of this gene requires a far upstream sequence, an uncommon modality in tRNA genes.

Differential expression of individual suppressor tRNA(Trp) gene gene family members in vitro and in vivo in the nematode Caenorhabditis elegans

Eight different amber suppressor tRNA (suptRNA) mutations in the nematode Caenorhabditis elegans have been isolated; all are derived from members of the tRNA(Trp) gene family (K. Kondo, B. Makovec, R. H. Waterston, and J. Hodgkin, J. Mol. Biol. 215:7-19, 1990). Genetic assays of suppressor activity suggested that individual tRNA genes were differentially expressed, probably in a tissue- or developmental stage-specific manner. We have now examined the expression of representative members of this gene family both in vitro, using transcription in embryonic cell extracts, and in vivo, by assaying suppression of an amber-mutated lacZ reporter gene in animals carrying different suptRNA mutations. Individual wild-type tRNA(Trp) genes and their amber-suppressing counterparts appear to be transcribed and processed identically in vitro, suggesting that the behavior of suptRNAs should reflect wild-type tRNA expression. The levels of transcription of different suptRNA genes closely parallel the extent of genetic suppression in vivo. The results suggest that differential expression of tRNA genes is most likely at the transcriptional rather than the posttranscriptional level and that 5' flanking sequences play a role in vitro, and probably in vivo as well. Using suppression of a lacZ(Am) reporter gene as a more direct assay of suptRNA activity in individual cell types, we have again observed differential expression which correlates with genetic and in vitro transcription results. This provides a model system to more extensively study the basis for differential expression of this tRNA gene family.

Expression of individual members of a tRNA(Gly)1 multigene family in vivo follows the same pattern as in vitro

Individual members of a tRNA(Gly)1 multigene family from Bombyx mori are transcribed to different levels in vitro in homologous nuclear extracts but their transcription status in vivo is not known. Two sets of tRNA(Gly)1 belonging to the extreme groups of highly transcribed and barely transcribed copies have been examined for their expression patterns in vivo in B. mori-derived cell lines following transfection. We have developed a sensitive and reliable method for directly quantifying the transcription levels of transfecting tRNA genes without relying on the biological activity of the transcript. The strategy involved the insertion of synthetic oligodeoxyribonucleotide sequences into the coding region of the transfecting gene and monitoring the transcripts in an RNase protection assay using an antisense probe that clearly distinguished them from the endogenous tRNAs. The oligonucleotide insertion did not significantly affect the transcriptional status of the genes, even though the distance between the A and B boxes was enhanced by 10-15 nt. In vivo also the transcription of tRNA(Gly)1 reached very high levels, whereas the transcripts arising from tRNA(Gly)1-6:7 accounted for only 2-5% of the former, closely resembling the transcription patterns in vitro. These individual gene copies having identical coding sequences and consequently the same internal conserved regions, differed only in their flanking sequences which modulate their transcription levels.

Transcriptional silencing of a tRNA1Gly copy from within a multigene family is modulated by distal cis elements

Individual copies of tRNA1Gly from within the multigene family in Bombyx mori could be classified based on in vitro transcription in homologous nuclear extracts into three categories of highly, moderately, or weakly transcribed genes. Segregation of the poorly transcribed gene copies 6 and 7, which are clustered in tandem within 425 base pairs, resulted in enhancement of their individual transcription levels, but the linkage itself had little influence on the transcriptional status. For these gene copies, when fused together generating a single coding region, transcription was barely detectable, which suggested the presence of negatively regulating elements located in the far flanking sequences. They exerted the silencing effect on transcription overriding the activity of positive regulatory elements. Systematic analysis of deletion, chimeric, and mutant constructs revealed the presence of a sequence element TATATAA located beyond 800 nucleotides upstream to the coding region acting as negative modulator, which when mutated resulted in high level transcription. Conversely, a TATATAA motif reintroduced at either far upstream or far downstream flanking regions exerted a negative effect on transcription. The location of cis-regulatory sequences at such farther distances from the coding region and the behavior of TATATAA element as negative regulator reported here are novel. These element(s) could play significant roles in activation or silencing of genes from within a multigene family, by recruitment or sequestration of transcription factors.

Silkworm TFIIIB binds both constitutive and silk gland-specific tRNA Ala promoters but protects only the constitutive promoter from DNase I cleavage

We have identified a complex between TFIIIB and the upstream promoter of silkworm tRNA Ala genes that is detectable by gel retardation and DNase I footprinting. Formation of this complex depends on the integrity of previously identified upstream promoter elements and on the presence of other silkworm transcription factors, either TFIIID or a fraction that contains both TFIIIC and TFIIID. We have used this complex to compare the interactions of TFIIIB with two kinds of tRNA Ala genes whose different in vitro transcription properties are conferred by the upstream segments of their promoters. These are the tRNA C Ala genes, which are transcribed constitutively, and the tRNA SG Ala genes, which are transcribed only in the silk gland. We find that TFIIIB binds tRNA SG Ala genes with lower affinity than it binds tRNA C Ala genes. In addition, the TFIIIB complex formed on tRNA SG Ala genes differ qualitatively from those formed on tRNA C Ala genes. Both the transcriptional activity of tRNA SG Ala complexes and the ability of the complexes to protect upstream DNA from DNase I digestion are reduced.

The BN51 protein is a polymerase (Pol)-specific subunit of RNA Pol III which reveals a link between Pol III transcription and pre-rRNA processing

The three eukaryotic nuclear RNA polymerase (Pol) contain common and unique subunits. Cloning of the unique Pol III subunit genes in yeast cells has revealed a potential homolog in the mammalian system, the BN51 gene. The human BN51 gene was originally isolated as a suppressor of a temperature-sensitive cell cycle mutant of BHK cells (tsBN51). Although tsBN51 cells have a marked decrease in RNA Pol III activity at the nonpermissive temperature, direct biochemical evidence for the BN51 protein being a human Pol III subunit was lacking. Using antibodies directed against the BN51 protein, we show the following: (i) the BN51 protein copurifies with Pol III activity, (ii) Pol III activity can be specifically immunoprecipitated from HeLa nuclear extracts, and (iii) the immunopurified BN51 complex is active in restoring both nonspecific and promoter-specific Pol III activity. Our findings provide direct biochemical evidence for BN51 being a Pol III-specific subunit. Despite the fact that BN51 is not a subunit of Pol I, the production of mature Pol I transcripts is inhibited in tsBN51 cells at the nonpermissive temperature. tsBN51 cells appear defective in processing the 32S precursor rRNA into mature 5.8S and 28S rRNA at the nonpermissive temperature. We surmise that ribosome assembly has halted because of the loss of Pol III transcripts. Thus, there is regulation of the synthesis of mature Pol I transcripts by a posttranscriptional mechanism based on the availability of Pol III transcripts.