Hermann Heumann

Mapping of Catalytic Residues in the RNA Polymerase Active Center

When the Mg2+ ion in the catalytic center of Escherichia coli RNA polymerase (RNAP) is replaced with Fe2+, hydroxyl radicals are generated. In the promoter complex, such radicals cleave template DNA near the transcription start site, whereas the β′ subunit is cleaved at a conserved motif NADFDGD (Asn-Ala-Asp-Phe-Asp-Gly-Asp). Substitution of the three aspartate residues with alanine creates a dominant lethal mutation. The mutant RNAP is catalytically inactive but can bind promoters and form an open complex. The mutant fails to support Fe2+-induced cleavage of DNA or protein. Thus, the NADFDGD motif is involved in chelation of the active center Mg2+.

Topography of intermediates in transcription initiation of E.coli

Three characteristic footprinting patterns resulted from probing the Escherichia coli RNA polymerase T7 A1 promoter complex by hydroxyl radicals in the temperature range between 4 degrees C and 37 degrees C. These were attributed to the closed complex, the intermediate complex and the open complex. In the closed complex, the RNA polymerase protects the DNA only at one side over five helical turns. In the intermediate complex, the range of the protected area is extended further downstream by two helical turns. This region of the DNA helix is fully protected, indicating that the RNA polymerase wraps around the DNA between base positions −13 and +20. In the open complex, a stretch between base positions −7 and +2, which was fully protected in the intermediate complex, becomes accessible towards hydroxyl radicals but only in the codogenic strand, indicating that the DNA strands are unwound. Our data suggest that only the DNA downstream of the promoter is involved in this unwinding process.

HIV-1 reverse transcriptase-associated RNase H cleaves RNA/RNA in arrested complexes: implications for the mechanism by which RNase H discriminates between RNA/RNA and RNA/DNA.

Reverse transcription of human immunodeficiency virus type 1 (HIV‐1) is primed by tRNA(Lys3), which forms an 18 base pair RNA homoduplex with its 3′ terminus and the primer binding site (PBS) of the viral genome. Using an in vitro system mimicking initiation of minus strand DNA synthesis, we analyzed the mechanism by which HIV‐1 reverse transcriptase (RT)‐associated ribonuclease H (RNase H) distinguishes between RNA/DNA and RNA/RNA (dsRNA). tRNA(Lys3) was hybridized to a PBS‐containing RNA template and extended by addition of deoxynucleoside triphosphates (dNTPs). In the presence of all four dNTPs, initial cleavage of the RNA template occurred immediately downstream of the tRNA‐DNA junction, reflecting RNase H specificity for RNA in a RNA/DNA hybrid. However, in the absence of DNA synthesis, or limiting this by chain termination, the PBS was cleaved at a constant distance of 18 nucleotides upstream of the nascent primer 3′ terminus. The position of cleavage remained in register with the position of DNA synthesis arrest, indicating that hydrolysis of homoduplex RNA is spatialy co‐ordinated with DNA synthesis. Kinetic studies comparing cleavage rates of an analogous DNA primer/PBS heteroduplex and the tRNA(Lys3)/PBS homoduplex showed that while the former is cleaved as rapidly as RT polymerizes, the latter proceeds 30‐fold slower. Although the RNase H domain hydrolyzes dsRNA when RT is artificially arrested, specificity for RNA/DNA hybrids is maintained when DNA is actively synthesized, since residency of the RNase H domain at a single base position is not long enough to allow significant cleavage on dsRNA.

A cinematographic view of Escherichia coli RNA polymerase translocation.

A series of RNA synthesizing transcription complexes, initiated at the T7 A1 promoter and halted at specific base positions ranging from +12 to +40, were analyzed by footprinting techniques; exonuclease III was used to determine the position of the bound RNA polymerase on the DNA and hydroxyl radicals were used to visualize the protein‐‐DNA contact sites within the protected areas. In the binding (open) complex without RNA there are two DNA‐domains, differing in their protection pattern. The first, extending from position +18 to ‐13, termed ‘melting domain’, is fully protected, whereas the second, extending from ‐14 to ‐55, termed ‘recognition domain’, shows only partial protection. At this domain, RNA polymerase is attached to one side of the DNA only, as indicated by the 10‐bp periodicity of the protection pattern. Our data show that the formation of a mature RNA transcribing complex is characterized by dissociation of the RNA polymerase from the recognition domain, whereby the size of the melting domain remains constant. This process is accomplished if the nascent RNA has reached a length of 11 bases. As the RNA reaches a length of 20 bases, the size of the melting domain decreases from approximately 30 to 23 bp. Further RNA synthesis leaves the protection pattern essentially unchanged. These data demonstrate that the formation of a mature RNA transcribing complex can be described by at least two transitions.

The sigma(70) subunit of RNA polymerase induces lacUV5 promoter-proximal pausing of transcription

The σ70 subunit of Escherichia coli RNA polymerase (RNAP) is a transcription initiation factor that can also be associated with RNAP during elongation. We provide biochemical evidence that σ70 induces a transcription pause at the lacUV5 promoter after RNAP has synthesized a 17-nucleotide transcript. The σ70-dependent pausing requires an interaction between σ70 and a part of the lac repressor operator sequence resembling a promoter −10 consensus. The polysaccharide heparin triggers the release of σ70 from the paused complexes, supporting the view that during the transition from initiation to elongation the interactions between σ70 and core RNAP are weakened. We propose that the binding and retention of σ70 in elongation complexes are stabilized by its ability to form contacts with DNA of the transcription bubble. In addition, we suggest that the σ70 subunit in the elongation complex may provide a target for regulation of gene expression.

Localization of the Active Site of HIV-1 Reverse Transcriptase-associated RNase H Domain on a DNA Template Using Site-specific Generated Hydroxyl Radicals

Reverse transcriptase (RT)-associated ribonuclease H (RNase H) can cleave both the RNA template of DNA/RNA hybrids as well as double-stranded (ds) RNA. This report shows that human immunodeficiency virus (HIV)-RT can also cleave the template strand of dsDNA when Mg2+ is replaced by Fe2+ in the RNase H active site of HIV-RT. The cleavage mechanisms as well as the positions of the cut vary depending on whether RNA or DNA is used. While DNA is cleaved 17 base positions upstream of the primer 3′-end, RNA is cleaved 18 base positions upstream. Competition experiments show that Fe2+ replaces the catalytically active Mg2+ of RT-associated RNase H. The bound Fe2+ is the source of locally generated OH-radicals that cleave the most proximate base in the DNA. Electrophoretic mobility studies of the cleaved fragments suggest that DNA is cleaved by an oxidative mechanism, while RNA is cleaved by an enzymatic mechanism which is indistinguishable from the Mg2+-dependent cleavage. The Fe2+-dependent cuts can be used to trace the active site of RT-associated RNase H on dsDNA as well as on dsRNA and DNA/RNA hybrids. The observed 1 base difference in the cleavage positions on DNA and RNA templates can be attributed to conformational differences of the bound nucleic acids. We suggest that the lower pitch of dsRNA and DNA/RNA hybrids compared with dsDNA permits accommodation of an additional base pair in the region between the primer 3′-end and the Fe2+-dependent cleavage position at the RNase H active site.

INFLUENCE OF MG2+ AND TEMPERATURE ON FORMATION OF THE TRANSCRIPTION BUBBLE

The transcription bubble formed in the binding complex of T7A1 promoter upon Escherichia coli RNA polymerase was analyzed by chemical probes, namely by single-strand specific reagents, to map the unpaired bases in the bubble, and by FeEDTA, to analyze the accessibility of the DNA backbone. The latter probe could also be used as a local hydroxyl radical probe placed close to the Mg2+-binding site in the active center. The data show that the transcription bubble consists of two parts, an Mg2+-dependent part and an Mg2+-independent part, both having individual transition temperatures. The data further suggest that formation of a transcription active open complex is preceded by a transition state complex having enhanced affinity for those Mg2+ ions presumably participating in the formation of the catalytic site. Our data also suggests that the three catalytically active Mg2+ ions in RNA polymerase are functionally not equivalent. One/two of the three Mg2+ ions are responsible for the polymerization, the other two/one for enlargement of the transcription bubble.

Conformational rearrangements of an archaeal chaperonin upon ATPase cycling

Chaperonins are double-ring protein assemblies with a central cavity that provides a sequestered environment for in vivo protein folding. Their reaction cycle is thought to consist of a nucleotide-regulated alternation between an open substrate-acceptor state and a closed folding-active state. The cavity of ATP-charged group I chaperonins, typified by Escherichia coli GroEL [1], is sealed off by a co-chaperonin, whereas group II chaperonins--the archaeal thermosome and eukaryotic TRiC/CCT [2]--possess a built-in lid [3-5]. The mechanism of the lids rearrangements requires clarification, as even in the absence of nucleotides, thermosomes of Thermoplama acidophilum appear open in vitrified ice [6] and closed in crystals [4]. Here we analyze the conformation of the thermosome at each step of the ATPase cycle by small-angle neutron scattering. The apo-chaperonin is open in solution, and ATP binding induces its further expansion. Closure seems to occur during ATP hydrolysis and before phosphate release, and represents the rate-limiting step of the cycle. The same closure can be triggered by the crystallization buffer. Thus, the allosteric regulation of group II chaperonins appears different from that of their group I counterparts.

Flexibility of the DNA enhances promoter affinity of Escherichia coli RNA polymerase.

Two types of mechanisms are discussed for the formation of active protein‐DNA complexes: contacts with specific bases and interaction via specific DNA structures within the cognate DNA. We have studied the effect of a single nucleoside deletion on the interaction of Escherichia coli RNA polymerase with a strong promoter. This study reveals three patterns of interaction which can be attributed to different sites of the promoter, (i) direct base contact with the template strand in the ‘‐35 region’ (the ‘recognition domain’), (ii) a DNA structure dependent interaction in the ‘‐10 region’ (the ‘melting domain’), and (iii) an interaction which is based on a defined spatial relationship between the two domains of a promoter, namely the ‘recognition domain’ and the ‘melting domain’.

DNA-dependent RNA polymerase of Escherichia coli induces bending or an increased flexibility of DNA by specific complex formation

Escherichia coli RNA polymerase is shown to induce bending or an increased flexibility of the promoter DNA. This is a specific effect of holoenzyme (core enzyme and sigma‐factor). The centre of the flexibility is 3 bp upstream of the initiation point of RNA synthesis. This flexibility or bending is maintained during RNA synthesis by core enzyme.