DNA aptamer affinity ligands for highly selective purification of human plasma-related proteins from multiple sources.

Nucleic acid aptamers are promising ligands for analytical and preparative-scale affinity chromatography applications. However, a full industrial exploitation requires that aptamer-grafted chromatography media provide a number of high technical standards that remained largely untested. Ideally, they should exhibit relatively high binding capacity associated to a very high degree of specificity. In addition, they must be highly resistant to harsh cleaning/sanitization conditions, as well as to prolonged and repeated exposure to biological environment. Here, we present practical examples of aptamer affinity chromatography for the purification of three human therapeutic proteins from various sources: Factor VII, Factor H and Factor IX. In a single chromatographic step, three DNA aptamer ligands enabled the efficient purification of their target protein, with an unprecedented degree of selectivity (from 0.5% to 98% of purity in one step). Furthermore, these aptamers demonstrated a high stability under harsh sanitization conditions (100h soaking in 1M NaOH). These results pave the way toward a wider adoption of aptamer-based affinity ligands in the industrial-scale purification of not only plasma-derived proteins but also of any other protein in general.

Transcriptional activation in the context of repression mediated by archaeal histones.

Many archaea (including all the methanogens, nearly all euryarchaeotes, and some crenarchaeotes) use histones as components of the chromatin that compacts their genomes. The archaeal histones are homo- and heterodimers that pair on DNA to form tetrasomes (as the eukaryotic histones H3 and H4 do). The resulting DNA packaging is known to interfere with assembly of the archaeal transcription apparatus at promoters; the ability of transcriptional activation to function in repressive archaeal chromatin has not yet been explored in vitro. Using four of the Methanocaldococcus jannaschii (Mja) histones, we have examined activation of the model Mja rb2 transcription unit by the Mja transcriptional activator Ptr2 in this simplified-chromatin context. Using hydroxyl radical footprinting, we find that the Ptr2-specific rb2 upstream activating site is a preferred histone-localizing site that nucleates histone: DNA-binding radiating from the rb2 promoter. Nevertheless, Ptr2 competes effectively with histones for access to the rb2 promoter and most potently activates transcription in vitro at histone concentrations that extensively coat DNA and essentially silence basal transcription.

Genome-wide identification of targets for the archaeal heat shock regulator phr by cell-free transcription of genomic DNA.

The hyperthermophilic archaeon Pyrococcus furiosus grows optimally near 100 degrees C and undergoes a heat shock response at 105 degrees C, mediated at least in part by the heat shock regulator Phr. Genes encoding a small heat shock protein (HSP20) and a member of the AAA(+) ATPase are the only known targets of the regulator, but a genetic mutant of Phr has yet to be characterized. We describe here an alternative approach for the identification of the regulon of Phr based on cell-free transcription of fragmented chromosomal DNA in the presence or absence of the regulator and hybridization of in vitro RNA to P. furiosus whole-genome microarrays. Our results confirmed the phr, the hsp20, and the aaa(+) ATPase genes as targets of Phr and also identified six additional open reading frames, PF0624, PF1042, PF1291, PF1292, PF1488, and PF1616, as Phr-responsive genes, which include that encoding di-myo-inositol phosphate synthase. Transcription of the identified novel genes was inhibited by Phr in standard transcription assays, and the novel consensus sequence 5'-TTTAnnnACnnnnnGTnAnnAAAA-3' (uppercase letters denote a high conservation of the bases) was inferred from our data as the Phr recognition motif. Mutational evidence for the significance of this sequence as Phr recognition was provided in DNA-binding experiments.

Hybrid Ptr2-like activators of archaeal transcription.

Methanocaldococcus jannaschii Ptr2, a member of the Lrp/AsnC family of bacterial DNA-binding proteins, is an activator of its eukaryal-type core transcription apparatus. In Lrp-family proteins, an N-terminal helix-turn-helix DNA-binding and dimerizing domain is joined to a C-terminal effector and multimerizing domain. A cysteine-scanning surface mutagenesis shows that the C-terminal domain of Ptr2 is responsible for transcriptional activation; two types of DNA binding-positive but activation-defective mutants are found: those unable to recruit the TBP and TFB initiation factors to the promoter, and those failing at a post-recruitment step. Transcriptional activation through the C-terminal Ptr2 effector domain is exploited in a screen of other Lrp effector domains for activation capability by constructing hybrid proteins with the N-terminal DNA-binding domain of Ptr2. Two hybrid proteins are effective activators: Ptr-H10, fusing the effector domain of Pyrococcus furiosus LrpA, and Ptr-H16, fusing the P. furiosus ORF1231 effector domain. Both new activators exhibit distinguishing characteristics: unlike octameric Ptr2, Ptr-H10 is a dimer; unlike Ptr2, the octameric Ptr-H16 poorly recruits TBP to the promoter, but more effectively co-recruits TFB with TBP. In contrast, the effector domain of Ptr1, the M. jannaschii Ptr2 paralogue, yields only very weak activation.

TBP domain symmetry in basal and activated archaeal transcription.

The TATA box binding protein (TBP) is the platform for assembly of archaeal and eukaryotic transcription preinitiation complexes. Ancestral gene duplication and fusion events have produced the saddle-shaped TBP molecule, with its two direct-repeat subdomains and pseudo-two-fold symmetry. Collectively, eukaryotic TBPs have diverged from their present-day archaeal counterparts, which remain highly symmetrical. The similarity of the N- and C-halves of archaeal TBPs is especially pronounced in the Methanococcales and Thermoplasmatales, including complete conservation of their N- and C-terminal stirrups; along with helix H'1, the C-terminal stirrup of TBP forms the main interface with TFB/TFIIB. Here, we show that, in stark contrast to its eukaryotic counterparts, multiple substitutions in the C-terminal stirrup of Methanocaldococcus jannaschii (Mja) TBP do not completely abrogate basal transcription. Using DNA affinity cleavage, we show that, by assembling TFB through its conserved N-terminal stirrup, Mja TBP is in effect ambidextrous with regard to basal transcription. In contrast, substitutions in either its N- or the C-terminal stirrup abrogate activated transcription in response to the Lrp-family transcriptional activator Ptr2.

An expanding family of archaeal transcriptional activators.

Transcriptional regulation in the archaea involves a mosaic of DNA-binding proteins frequently (although not exclusively) of bacterial type, modulating a eukaryal-type core transcription apparatus. Methanocaldococcus jannaschii (Mja) Ptr2, a homologue of the Lrp/AsnC family of bacterial transcription regulators that are among the most widely disseminated archaeal DNA-binding proteins, has been shown to activate transcription by its conjugate hyperthermophilic RNA polymerase. Here, two in vitro systems have been exploited to show that Ptr2 and a Lrp homologue from the thermophile Methanothermococcus thermolithotrophicus (Mth) activate transcription over a approximately 40 degrees C range, in conjunction with their cognate TATA-binding proteins (TBPs) and with heterologous TBPs. A closely related homologue from the mesophile Methanococcus maripaludis (Mma) is nearly inert as a transcriptional activator, but a cluster of mutations that converts a surface patch of Mma Lrp to identity with Ptr2 confers transcriptional activity. Mja, Mth, and Mma TBPs are interchangeable for basal transcription, but their ability to support Lrp-mediated transcriptional activation varies widely, with Mja TBP the most active and Mth TBP the least active partner. The implications of this finding for understanding the roles of TBP paralogues in supporting the gene-regulatory repertoires of archaeal genomes are briefly noted.

Archaeal transcription and its regulators.

The relatively complex archaeal RNA polymerases are constructed along eukaryotic lines, and require two initiation factors for promoter recognition and specific transcription that are homologues of the RNA polymerase II TATA-binding protein and TFIIB. Many archaea also produce histones. In contrast, the transcriptional regulators encoded by archaeal genomes are primarily of bacterial rather than eukaryotic type. It is this combination of elements commonly regarded as separate and mutually exclusive that promises unifying insights into basic transcription mechanisms across all three domains of life.

Promoter architecture and response to a positive regulator of archaeal transcription.

The archaeal transcription apparatus is chimeric: its core components (RNA polymerase and basal factors) closely resemble those of eukaryotic RNA polymerase II, but the putative archaeal transcriptional regulators are overwhelmingly of bacterial type. Particular interest attaches to how these bacterial-type effectors, especially activators, regulate a eukaryote-like transcription system. The hyperthermophilic archaeon Methanocaldococcus jannaschii encodes a potent transcriptional activator, Ptr2, related to the Lrp/AsnC family of bacterial regulators. Ptr2 activates rubredoxin 2 (rb2) transcription through a bipartite upstream activating site (UAS), and conveys its stimulatory effects on its cognate transcription machinery through direct recruitment of the TATA binding protein (TBP). A functional dissection of the highly constrained architecture of the rb2 promoter shows that a 'one-site' minimal UAS suffices for activation by Ptr2, and specifies the required placement of this site. The presence of such a simplified UAS upstream of the natural rubrerythrin (rbr) promoter also suffices for positive regulation by Ptr2 in vitro, and TBP recruitment remains the primary means of transcriptional activation at this promoter.

A fully recombinant system for activator-dependent archaeal transcription.

The core components of the archaeal transcription apparatus closely resemble those of eukaryotic RNA polymerase II, while the DNA-binding transcriptional regulators are predominantly of bacterial type. Here we report the construction of an entirely recombinant system for positively regulated archaeal transcription. By omitting individual subunits, or sets of subunits, from the in vitro assembly of the 12-subunit RNA polymerase from the hyperthermophile Methanocaldococcus jannaschii, we describe a functional dissection of this RNA polymerase II-like enzyme, and its interactions with the general transcription factor TFE, as well as with the transcriptional activator Ptr2.

Transcriptional regulation in Archaea.

During the past few decades, it has become clear that microorganisms can thrive under the most diverse conditions, including extremes of temperature, pressure, salinity and pH. Most of these extremophilic organisms belong to the third domain of life, that of the Archaea. The organisms of this domain are of particular interest because most informational systems that are associated with archaeal genomes and their expression are reminiscent of those seen in Eucarya, whereas, most of their metabolic aspects are similar to those of Bacteria. A better understanding of the regulatory mechanisms of gene expression in Archaea will, therefore, help to integrate the body of knowledge regarding the regulatory mechanisms that underlie gene expression in all three domains of life.

Activation of archaeal transcription by recruitment of the TATA-binding protein.

The hyperthermophilic archaeon Methanococcus jannaschii encodes two putative transcription regulators, Ptr1 and Ptr2, that are members of the Lrp/AsnC family of bacterial transcription regulators. In contrast, this archaeon's RNA polymerase and core transcription factors are of eukaryotic type. Using the M. jannaschii high-temperature in vitro transcription system, we show that Ptr2 is a potent transcriptional activator, and that it conveys its stimulatory effects on its cognate eukaryal-type transcription machinery from an upstream activating region composed of two Ptr2-binding sites. Transcriptional activation is generated, at least in part, by Ptr2-mediated recruitment of the TATA-binding protein to the promoter.

The mechanism of transcriptional activation by the topologically DNA-linked sliding clamp of bacteriophage T4.

Three viral proteins participate directly in transcription of bacteriophage T4 late genes: the sigma-family protein gp55 provides promoter recognition, gp33 is the co-activator, and gp45 is the activator of transcription; gp33 also represses transcription in the absence of gp45. Transcriptional activation by gp45, the toroidal sliding clamp of the T4 DNA polymerase holoenzyme, requires assembly at primer-template junctions by its clamp loader. The mechanism of transcriptional activation has been analyzed by examining rates of formation of open promoter complexes. The basal gp55-RNA polymerase holoenzyme is only weakly held in its initially formed closed promoter complex, which subsequently opens very slowly. Activation ( approximately 320-fold in this work) increases affinity in the closed complex and accelerates promoter opening. Promoter opening by gp55 is also thermo-irreversible: the T4 late promoter does not open at 0 degrees C, but once opened at 30 degrees C remains open upon shift to the lower temperature. At a hybrid promoter for sigma(70) and gp55-holoenzymes, only gp55 confers thermo-irreversibility of promoter opening. Interaction of gp45 with a C-terminal epitope of gp33 is essential for the co-activator function of gp33.