William T. McAllister

Structure of a T7 RNA polymerase elongation complex at 2.9 A resolution.

The single-subunit bacteriophage T7 RNA polymerase carries out the transcription cycle in an identical manner to that of bacterial and eukaryotic multisubunit enzymes. Here we report the crystal structure of a T7 RNA polymerase elongation complex, which shows that incorporation of an 8-base-pair RNA–DNA hybrid into the active site of the enzyme induces a marked rearrangement of the amino-terminal domain. This rearrangement involves alternative folding of about 130 residues and a marked reorientation (about 130° rotation) of a stable core subdomain, resulting in a structure that provides elements required for stable transcription elongation. A wide opening on the enzyme surface that is probably an RNA exit pathway is formed, and the RNA–DNA hybrid is completely buried in a newly formed, deep protein cavity. Binding of 10 base pairs of downstream DNA is stabilized mostly by long-distance electrostatic interactions. The structure implies plausible mechanisms for the various phases of the transcription cycle, and reveals important structural similarities with the multisubunit RNA polymerases.

The phage RNA polymerases are related to DNA polymerases and reverse transcriptases.

The single subunit DNA‐dependent RNA polymerase (RNAP) that is encoded by bacteriophage T7 is the prototype of a class of relatively simple RNAPs that includes the RNAPs of the related phages T3 and SP6, as well as the mitochondrial RNAPs. The T7 enzyme has been crystallized, and recent genetic and biochemical analyses have facilitated an interpretation of this structure. A growing body of evidence suggests that the phage‐like RNAPs are related to other nucleotide polymerases such as DNA polymerases, RNA‐dependent RNA polymerases, and reverse transcriptases. In this work, we review information concerning the structure and function of T7 RNAP, and evidence in support of its assignment to a broader class of nucleotide polymerases.

Cloning and expression of the bacteriophage T3 RNA polymerase gene

The gene that encodes the RNA polymerase of bacteriophage T3 (gene 1) has been cloned into a pBR322 derivative under the control of an inducible lacUV5 promoter. Large quantities of the protein are synthesized after induction of cells that carry this plasmid. RNA polymerase purified from these overproducing cells selectively initiates transcription from T3 promoter sequences as demonstrated by transcription of a dual promoter plasmid that carries both T3 and T7 promoters. Cells that carry the T3 RNA polymerase gene can complement amber mutants of T3 that are defective in gene 1 but not gene 1 amber mutants of T7, and vice versa; this experiment demonstrates the specificity of these enzymes in vivo.

The Stability of Abortively Cycling T7 RNA Polymerase Complexes Depends upon Template Conformation

We have developed a promoter competition assay to determine whether T7 RNA polymerase dissociates from its template during abortive cycling. We find that the stability of the initiation complex (IC) depends upon the conformation of the promoter, and that the degree to which the template is unwound contributes importantly to the stability of the IC. On linear DNA or a relaxed plasmid template, the stability of the IC is very low (t1/2 < 1 min). However, on a supercoiled template, the IC has a stability that is comparable to that of a paused elongation complex (t1/2 = 14 min). At a synthetic promoter that is single stranded in the initiation region (from -5 and downstream), the polymerase forms a highly stable complex (t1/2 > 30 min) even in the absence of RNA synthesis. These findings are important to our understanding of the transition from the IC to an EC.

Transfection of a glycosylated phosphatidylinositol-anchored folate-binding protein complementary DNA provides cells with the ability to survive in low folate medium.

KB cells express a folate-binding protein that is anchored to the plasma membrane by a glycosylated phosphatidylinositol (GPI) tail and these cells can grow in medium containing a very low folate concentration (1 nM). In contrast, mouse 3T3 cells do not express a membrane-associated folate-binding protein and cannot grow under similar low folate conditions. In these studies, 3T3 cells were transfected with a vector containing the cDNA that codes for the KB cell folate-binding protein. In contrast to the wild-type 3T3 cells, the transfected 3T3 cells express a level of folate-binding protein similar to KB cells, 1 and 1.4 ng/micrograms protein, respectively. The capacity for binding [3H] folate to the surface of transfected 3T3 cells cultured in folate-deficient medium is 7.7 pmol/10(6) cells, and this is approximately 50% of the surface binding capacity of KG cells under similar culture conditions. Moreover, after treatment of the transfected 3T3 cells with phospholipase C specific for phosphatidylinositol, the binding of [3H] folate to the surface of these cells is reduced by 90%, indicating that, like the KB cells, the folate-binding protein is anchored to the plasma membrane by a GPI tail. Although the doubling time of wild-type 3T3 cells markedly increases after 13 d of culture in folate-deficient medium, the doubling time of both the transfected 3T3 cells and KB cells do not change. The results of these experiments indicate that the GPI-anchored folate-binding protein provides a mechanism to maintain a level of folate that permits the folate-dependent metabolic functions necessary for cell survival under low folate conditions.

Regulation of coliphage T3 and T7 RNA polymerases by the lac represser-operator system

The single-polypeptide RNA polymerases that are encoded by bacteriophage T7 and its relatives form the basis of highly specific and efficient transcription systems. Here, we describe the regulation of transcription from phage promoters by the lac repressor-operator system of Escherichia coli. A synthetic oligodeoxyribonucleotide that contains the core sequence of the lac operator (lacO) was cloned at various distances downstream from the transcription start point (tsp) of the T3 and T7 promoters. The ability of lac repressor to prevent transcription from the phage promoters in vitro was dependent on the position of the operator. Efficient repression was observed when the center of the operator was placed between +14 and +27 (+1 being the tsp), whereas the repressor had little effect when bound to operators centered at +64. For in vivo studies, the chloramphenicol acetyltransferase (CAT)-encoding reporter gene was placed under the control of various promoter-operator constructs, and introduced into bacterial cells containing the genes for the lac repressor and T3 or T7 RNA polymerase. As with in vitro studies, high levels of repression (greater than 4000-fold) of T3 and T7 RNA polymerase activity were achieved, and repression was reversed by the inducer isopropyl-beta-D-thiogalactopyranoside. When the T3 promoter-lacO constructs are used to regulate the expression of a target gene in combination with an inducible RNA polymerase gene under control of the lacUV5 promoter, the doubly regulated system provides extremely tight levels of repression, yet allows high levels of expression after induction. In such a system, we observed a greater than 10(5)-fold increase in CAT activity within 30 min after induction. This system should prove useful in cloning and expressing genes that are potentially toxic to the host cells.

Identification of proteins associated with the yeast mitochondrial RNA polymerase by tandem affinity purification

The abundance of mitochondrial (mt) transcripts varies under different conditions, and is thought to depend upon rates of transcription initiation, transcription termination/attenuation and RNA processing/degradation. The requirement to maintain the balance between RNA synthesis and processing may involve coordination between these processes; however, little is known about factors that regulate the activity of mtRNA polymerase (mtRNAP). Recent attempts to identify mtRNAP–protein interactions in yeast by means of a generalized tandem affinity purification (TAP) protocol were not successful, most likely because they involved a C‐terminal mtRNAP–TAP fusion (which is incompatible with mtRNAP function) and because of the use of whole‐cell solubilization protocols that did not preserve the integrity of mt protein complexes. Based upon the structure of T7 RNAP (to which mtRNAPs show high sequence similarity), we identified positions in yeast mtRNAP that allow insertion of a small affinity tag, confirmed the mature N‐terminus, constructed a functional N‐terminal TAP–mtRNAP fusion, pulled down associated proteins, and identified them by LC–MS–MS. Among the proteins found in the pull‐down were a DEAD‐box protein (Mss116p) and an RNA‐binding protein (Pet127p). Previous genetic experiments suggested a role for these proteins in linking transcription and RNA degradation, in that a defect in the mt degradadosome could be suppressed by overexpression of either of these proteins or, independently, by mutations in either mtRNAP or its initiation factor Mtf1p. Further, we found that Mss116p inhibits transcription by mtRNAP in vitro in a steady‐state reaction. Our results support the hypothesis that Mss116p and Pet127p are involved in modulation of mtRNAP activity. Copyright

Optimization of the hygromycin B resistance-conferring gene as a dominant selectable marker in mammalian cells

The HyR gene, conferring resistance to hygromycin B (Hy), has been modified for optimal expression in mammalian cells. Modifications to the HyR gene and its expression cassette include: (1) removal of all upstream start codons, (2) conversion of the region around the start codon to the consensus sequence associated with efficient translation initiation, and (3) removal of downstream splice donor and acceptor sequences. The resulting HyR gene is an efficient dominant selectable marker that is useful for studies requiring resistance from a low-copy-number gene driven by a promoter of moderate strength. The HyR gene was also tested for its compatibility with BPV vectors. Mouse C127 cells harboring pHyR-BPV plasmids exhibited properties of BPV-transformed cells and were resistant to toxic levels of Hy. The vectors were stable as episomes and present in high copy. The HyR gene thus joins the NmR (neo) gene as the only dominant selectable markers that are known to be compatible with BPV replication.

Multiple Functions of Yeast Mitochondrial Transcription Factor Mtf1p during Initiation

Transcription of the yeast mitochondrial genome is carried out by an RNA polymerase (Rpo41p) that is related to single subunit bacteriophage RNA polymerases but requires an additional factor (Mtf1p) for initiation. In this work we show that Mtf1p is involved in multiple roles during initiation including discrimination of upstream base pairs in the promoter, initial melting of three to four base pairs around the site of transcript initiation, and suppression of nonspecific initiation. It, thus, appears that Mtf1p is functionally analogous to initiation factors of multisubunit RNA polymerases, such as σ. Photocross-linking experiments reveal close proximity between Mtf1p and the promoter DNA and show that the C-terminal domain makes contacts with the template strand in the vicinity of the start site. Interestingly, Mtf1p is related to a class of RNA methyltransferases, suggesting an early evolutionary link between RNA synthesis and processing.

Effects of Substitutions in a Conserved DX2GR Sequence Motif, Found in Many DNA-dependent Nucleotide Polymerases, on Transcription by T7 RNA Polymerase

The region in bacteriophage T7 RNA polymerase (RNAP) comprising residues 421-425 contains a sequence motif (DX(2)GR) that is conserved among many DNA-dependent nucleotide polymerases. We have found that alterations in this motif result in enzymes that display weaker retention of the RNA product during transcript initiation, a decreased ability to make the transition to a stable elongation complex, and changes in substrate binding and catalytic activity. Many of these defects are coupled with an altered response to the presence or absence of the non-template strand. The observed constellation of defects supports a role for the motif in interacting with and stabilizing the RNA:DNA hybrid during the early stages of transcript initiation. This is consistent with the position of the motif in a T7 RNAP initiation complex. Although a conserved DX(2)GR sequence motif is also observed in multisubunit RNAPs, the structural organization of the motif and the manner in which it interacts with the RNA:DNA hybrid in the latter enzymes is different from that in T7 RNAP. However, another element in the multisubunit RNAPs that contains a highly conserved arginine residue may play the same role as R425 in T7 RNAP. (c) 2002 Elsevier Science Ltd.