A big step toward mirror-image ribosomes.

Synthetic protein factories could one day make durable drugs the body can't break down.

Total Synthesis of Ripostatin B and Structure-Activity Relationship Studies on Ripostatin Analogs.

Described is the total synthesis of the myxobacterial natural product ripostatin B and of a small number of analogs. Ripostatin B is a polyketide-derived 14-membered macrolide that acts as an inhibitor of bacterial RNA-polymerase, but is mechanistically distinct from rifamycin-derived RNA-polymerase inhibitors that are in use for tuberculosis treatment. The macrolactone ring of ripostatin B features two stereocenters and a synthetically challenging doubly skipped triene motif, with one of the double bonds being in conjugation with the ester carbonyl. Appended to the macrolactone core are an extended hydroxy-bearing phenylalkyl side chain at C13 and a carboxymethyl group at C3. The triene motif was established with high efficiency by ring-closing olefin metathesis, which proceeded in almost 80% yield. The side chain-bearing stereocenter α to the ester oxygen was formed in a Paterson aldol reaction between a methyl ketone and a ß-chiral ß-hydroxy aldehyde with excellent syn selectivity (dr >10:1). The total synthesis provided a blueprint for the synthesis of analogs with modifications in the C3 and C13 side chains. The C3-modified analogs showed good antibacterial activity against efflux-deficient Escherichia coli but, as ripostatin B, were inactive against Mycobacterium tuberculosis, in spite of significant in vitro inhibition of M. tuberculosis RNA-polymerase.

Bacteriophage T7 RNA polymerase transcription elongation is inhibited by site-specific, stereospecific benzo[c]phenanthrene diol epoxide DNA lesions.

Benzo[c]phenanthrene diol epoxide (B[c]PhDE), the ultimate carcinogenic metabolite of the environmental pollutant benzo[c]phenanthrene, reacts with DNA primarily at the exocyclic amino groups of purines, forming B[c]PhDE-DNA adducts that differ in their stereochemical configurations and their effect on biological processes such as transcription. To determine the effect of these stereoisomers on RNA synthesis, in vitro T7 RNA polymerase transcription assays were performed using DNA templates modified on the transcribed strand by either a site-specific (+)-trans- or (-)-trans-anti-B[c]PhDE-N(6)-dA lesion located within the sequence 5'-CTCTCACTTCC-3'. The results show that both (-)-trans-anti-B[c]PhDE-N(6)-dA and (+)-trans-anti-B[c]PhDE-N(6)-dA block RNA synthesis. Furthermore, both B[c]PhDE-dA stereoisomeric adducts lead to lower levels of initiation of transcription relative to that observed using an unmodified DNA template. In contrast to these results, placement of the adduct on the nontranscribed strand within the template does not impede transcription elongation. In addition to the assessment of the effect of the lesions on transcription elongation, the resulting transcripts were characterized in terms of their base composition. A high level of base misincorporation is detected at the 3'-ends of truncated transcripts, with guanosine being most frequently incorporated opposite the modified nucleotide rather than the expected uridine. This result supports the notion that translocation past a modified base in a DNA template relies in part on correct base incorporation, and suggests that stalling of RNA polymerases at damaged sites in DNA may well be dependent on both the presence of the lesion and the base which is incorporated opposite the modified nucleotide.

Structural requirements for the interdomain linker of alpha subunit of Escherichia coli RNA polymerase.

The carboxy-terminal domain of the alpha subunit of Escherichia coli RNA polymerase, which is connected with the core part of RNA polymerase through a long flexible linker, plays decisive roles in transcription activation by directly interacting with a large number of transcription factors and upstream (UP) element DNA. Here we constructed a set of mutant RNA polymerases, each containing a mutant alpha subunit with an altered interdomain linker. Deletion of three amino acids from the linker exhibited 50% inhibition of cAMP receptor protein- (CRP-) dependent lac P1 transcription. Deletion of six amino acids completely knocked out the activity. Insertion of three amino acids did not affect the activity, whereas 40-60% inhibition was observed after insertion of one, two, or four amino acids. Substitution of 10 consecutive glycine residues resulted in nearly 90% reduction of the CRP-dependent activity, whereas 50% activity was retained after substitution of 10 proline residues or a sequence expected to form a strong alpha-helix. Essentially the same results were obtained with UP element-dependent rrnB P1 transcription. These observations altogether suggest that (i) sufficient length of the interdomain linker is required for transcription activation mediated by the alpha carboxy-terminal domain, (ii) the linker is not totally unstructured but has structural and torsional preferences to facilitate positioning of the carboxy-terminal domain to a proper location for the interaction with CRP and UP element, and (iii) CRP-dependent activation and UP element-dependent activation share a common intermediary state in which the positioning of the alpha carboxy-terminal domain is of primary importance.

Dimeric association of Escherichia coli RNA polymerase alpha subunits, studied by cleavage of single-cysteine alpha subunits conjugated to iron-(S)-1-[p-(bromoacetamido)benzyl]ethylenediaminetetraacetate.

Proximity relationships between the two associated monomers of the Escherichia coli RNA polymerase alpha subunit were studied using a set of four mutant alpha subunits, each with a single Cys residue at one of the naturally occurring positions (54, 131, 176, and 269). These mutant alpha subunits were conjugated with the cutting reagent iron-(S)-1-[p-(bromoacetamido)benzyl]ethylenediaminetetraacetate (Fe-BABE), and the peptide backbone was cleaved at locations near the modified Cys. Analysis of the cleavage sites identified segments within approximately 12 A of the conjugation site. These results show that, for intermolecular cutting, segments of the subunit assembly domain (N-terminal domain) of one subunit and the linker region between N- and C-terminal domains of the other subunit are near each other, and the N-terminal domains of both subunits are in close proximity to one another. Intramolecular cutting however, was observed only within an individual N- or C-terminal domain.

Quaternary structure of DNA-dependent RNA polymerase from Escherichia coli. Measurement of distances by fluorescence energy transfer.

Distances between the subunits in Escherichia coli RNA polymerase (core and holo enzyme) and the rifamycin binding site have been determined using the nonradiative energy transfer technique. The appropriate donor and acceptor labels have been chosen in order to optimize the spectral overlap and maximize the energy transfer. Spacer linked derivatives of rifamycin SV possessing nitrobenzo-oxadiazole groups (energy acceptor) were synthesized for this purpose. The donor label, acetylaminoethylaminonaphthalene sulfonate, was introduced into the intact enzyme, and the subunits were separated. Enzyme molecules selectively labelled on one kind of subunit were produced by mixed reconstitution techniques employing labelled and non labelled subunits. The labelled beta'-subunit could not be prepared in sufficient amounts. Energy transfer distances between the enzyme-bound rifamycin derivative and the subunits were determined to be approximately 5.9 nm for sigma, 7.2 nm for alpha 2 and 6.1 nm for beta.

In vitro synthesis of enzymes of the tryptophan operon of Escherichia coli. Evidence for positive control of transcription.

A protein fraction, called At (= anti termination) factor, has been isolated from extracts of E. coli and partially purified. The At factor stimulates the synthesis in vitro of anthranilate synthetase, an enzyme encoded by two genes of the tryptophan (trp) operon, but has no effect on the synthesis of T7 RNA polymerase and other T7- and T4 coded proteins. The At factor stimulates the synthesis of trp mRNA; it has no effect on the translation of trp mRNA. We conclude that in vitro transcription of the trp operon is positively controlled.