Programmed vesicle fusion triggers gene expression.

The membrane properties of phospholipid vesicles can be manipulated to both regulate and initiate encapsulated biochemical reactions and networks. We present evidence for the inhibition and activation of reactions encapsulated in vesicles by the exogenous addition of charged amphiphiles. While the incorporation of cationic amphiphile exerts an inhibitory effect, complementation of additional anionic amphiphiles revitalize the reaction. We demonstrated both the simple hydrolysis reaction of ß-glucuronidase and the in vitro gene expression of this enzyme from a DNA template. Furthermore, we show that two vesicle populations decorated separately with positive and negative amphiphiles can fuse selectively to supply feeding components to initiate encapsulated reactions. This mechanism could be one of the rudimentary but effective means to regulate and maintain metabolism in dynamic artificial cell models.

Single-Molecule FRET Analysis of Replicative Helicases.

Over the recent years single-molecule fluorescence resonance energy transfer (smFRET) technique has proven to be one of the most powerful tools for revealing mechanistic insights into helicase activities. Here we describe details of single-molecule FRET assays for probing DNA unwinding activities as well as functional dynamics by replicative helicases in real time. The ability of smFRET to measure the behavior of biomolecules at a nanometer scale enabled us to address how the leading and lagging strand synthesis are coordinated during DNA replication, to resolve DNA unwinding steps of Bacteriophage T7 helicase, and to observe heterogeneous unwinding patterns modulated by the DNA binding domain of E1 helicase. These single-molecule FRET assays are generally applicable to other replicative and nonreplicative hexameric helicases.

A replication-deficient adenovirus enhances liposome-mediated nucleic acid transfer into a stable cell line expressing T7 RNA polymerase.

Liposome-mediated transfer of nucleic acids into a cell line expressing bacteriophage T7 RNA polymerase was enhanced by addition of a replication-deficient adenovirus (Ad5-259A) to transfection mixtures. Increasing quantities of Ad5-259A resulted in a dose-related (up to 30-fold) enhancement of reporter gene activity expressed in BT7-H cells transfected with plasmid DNA containing the reporter sequence fused to the internal ribosome entry site of encephalomyocarditis virus. Similarly, Ad5-259A enhanced reporter gene expression 7-fold following transfection of DNA containing the reporter sequence under transcriptional control of the Rous sarcoma virus long terminal repeat. Addition of Ad5-295A to transfection mixtures increased the proportion of cells staining positively for reporter gene activity, from 2 to 25% when the reporter was expressed via the T7 polymerase and from 20 to 50% when the reporter was under the control of a eucaryotic promoter. Thus, Ad5-259A enhanced reporter protein activities expressed by cytoplasmic T7-directed transcription and cap-independent initiation of translation, or nuclear transcription and cap-dependent translation. Transfection enhancement was blocked by neutralizing antibody to Ad5, and is most likely related to the endosome-disrupting activities of the virus. Adenovirus enhancement of liposome-mediated transfection provides a useful method for efficient nucleic acid transfer into eucaryotic cells.

Transient state kinetics of transcription elongation by T7 RNA polymerase.

The single subunit DNA-dependent RNA polymerase (RNAP) from bacteriophage T7 catalyzes both promoter-dependent transcription initiation and promoter-independent elongation. Using a promoter-free substrate, we have dissected the kinetic pathway of single nucleotide incorporation during elongation. We show that T7 RNAP undergoes a slow conformational change (0.01-0.03 s(-1)) to form an elongation competent complex with the promoter-free substrate (dissociation constant (Kd) of 96 nM). The complex binds to a correct NTP (Kd of 80 microM) and incorporates the nucleoside monophosphate (NMP) into RNA primer very efficiently (220 s(-1) at 25 degrees C). An overall free energy change (-5.5 kcal/mol) and internal free energy change (-3.7 kcal/mol) of single NMP incorporation was calculated from the measured equilibrium constants. In the presence of inorganic pyrophosphate (PPi), the elongation complex catalyzes the reverse pyrophosphorolysis reaction at a maximum rate of 0.8 s(-1) with PPi Kd of 1.2 mM. Several experiments were designed to investigate the rate-limiting step in the pathway of single nucleotide addition. Acid-quench and pulse-chase kinetics indicated that an isomerization step before chemistry is rate-limiting. The very similar rate constants of sequential incorporation of two nucleotides indicated that the steps after chemistry are fast. Based on available data, we propose that the preinsertion to insertion isomerization of NTP observed in the crystallographic studies of T7 RNAP is a likely candidate for the rate-limiting step. The studies here provide a kinetic framework to investigate structure-function and fidelity of RNA synthesis and to further explore the role of the conformational change in nucleotide selection during RNA synthesis.

Kinetics of nucleotide incorporation opposite DNA bulky guanine N2 adducts by processive bacteriophage T7 DNA polymerase (exonuclease-) and HIV-1 reverse transcriptase.

Six oligonucleotides with carcinogen derivatives bound at the N2 atom of deoxyguanosine were prepared, including adducts derived from butadiene, acrolein, crotonaldehyde, and styrene, and examined for effects on the replicative enzymes bacteriophage DNA polymerase T7- (T7-) and HIV-1 reverse transcriptase for comparison with previous work on smaller DNA adducts. All of these adducts strongly blocked dCTP incorporation opposite the adducts. dATP was preferentially incorporated opposite the acrolein and crotonaldehyde adducts, and dTTP incorporation was preferred at the butadiene- and styrene-derived adducts. Steady-state kinetic analysis indicated that the reduced catalytic efficiency with adducted DNA involved both an increased Km and attenuated kcat. Fluorescence estimates of Kd and pre-steady-state kinetic measurements of koff showed no significantly decreased affinity of T7- with the adducted oligonucleotides or the dNTP. Pre-steady-state kinetics showed no burst phase kinetics for dNTP incorporation with any of the modified oligonucleotides. These results indicate that phosphodiester bond formation or a conformational change of the enzyme.DNA complex is rate-limiting instead of the step involving release of the oligonucleotide. Thio elemental effects for dNTP incorporation were generally relatively small but variable, indicating that the presence of adducts may sometimes make phosphodiester bond formation rate-limiting but not always.

The linker region between the helicase and primase domains of the bacteriophage T7 gene 4 protein is critical for hexamer formation.

The gene 4 protein of bacteriophage T7, a functional hexamer, comprises DNA helicase and primase activities. Both activities depend on the unidirectional movement of the protein along single-stranded DNA in a reaction coupled to the hydrolysis of dTTP. We have characterized dTTPase activity and hexamer formation for the full-length gene 4 protein (gp4) as well as for three carboxyl-terminal fragments starting at residues 219 (gp4-C219), 241 (gp4-C241), and 272 (gp4-C272). The region between residues 242 and 271, residing between the primase and helicase domains, is critical for oligomerization of the gene 4 protein. A functional TPase active site is dependent on oligomerization. During native gel electrophoresis, gp4, gp4-C219, and gp4-C241 migrate as oligomers, whereas gp4-C272 is monomeric. The steady-state k(cat) for dTTPase activity of gp4-C272 increases sharply with protein concentration, indicating that it forms oligomers only at high concentrations. gp4-C219 and gp4-C241 both form a stable complex with gp4, whereas gp4-C272 interacts only weakly with gp4. Measurements of surface plasmon resonance indicate that a monomer of T7 DNA polymerase binds to a dimer of gp4, gp4-C219, or gp4-C241 but to a monomer of gp4-C272. Like the homologous RecA and F(1)-ATPase proteins, the oligomerization domain of the gene 4 protein is adjacent to the amino terminus of the NTP-binding domain.

Gene expression using the vaccinia virus/T7 RNA polymerase hybrid system.

This unit describes a transient cytoplasmic expression system that relies on the synthesis of the bacteriophage T7 RNA polymerase in the cytoplasm of mammalian cells. A gene of interest is inserted into a plasmid such that it comes under the control of the T7 RNA polymerase promoter (p(T7)). Using liposome-mediated transfection, this recombinant plasmid is introduced into the cytoplasm of cells infected with vTF7-3, a recombinant vaccinia virus encoding bacteriophage T7 RNA polymerase. During incubation, the gene of interest is transcribed with high efficiency by T7 RNA polymerase. For large-scale work, protocols are provided for insertion of the p(T7)-regulated gene into a second recombinant vaccinia virus by homologous recombination and subsequent coinfection with vTF7-3 into cells grown in suspension or for direct transfection into OST7-1 cells (a stable cell line that constitutively expresses the T7 RNA polymerase). Expressed protein is then analyzed by pulse-labeling and purified. One new development to this vaccinia virus/T7 RNA polymerase hybrid expression system described here is the VOTE inducible expression system, which eliminates the need to use two recombinant viruses or a special cell line.

Single d(GpG)/cis-diammineplatinum(II) adduct-induced inhibition of DNA polymerization.

A 44 nucleotide DNA template containing a single site-specifically placed cisplatin adduct (cis-[Pt(NH3)2[d(GpG)-N7(1),-N7(2)]]) was annealed with a primer, positioning its 3'-end four bases before the adduct in the template strand. DNA polymerization in the presence of all four nucleotides revealed that both HIV-1 reverse transcriptase (RT) and T7 DNA polymerase strongly paused at one nucleotide preceding the first platinated guanine and at the positions opposite the two platinated guanines. Analysis of single nucleotide incorporation at each pause site showed that polymerization occurs with biphasic kinetics. A small percentage of DNA was bound productively, providing a small amplitude (1-3%) of a fast phase of polymerization, whereas most of the bound DNA (1-34%) was positioned at the pause site in a nonproductive manner and therefore elongated slowly (0.04-0.06 s-1). DNA substrates annealed to the cisplatin-modified template bind to HIV-1 RT with an affinity (10-20 nM) similar to that of unmodified substrates (6-9 nM). The cisplatin-DNA cross-link moderately weakened DNA binding to T7 DNA polymerase (12-115 nM) but significantly slowed the rate of incorporation of the next nucleotide (2-7 s-1 ), with larger effects closer to the cisplatin-DNA adduct. The crystal structure of the same cisplatin-DNA adduct [Takahara, P. M., Frederick, C. A., and Lippard, S. J. (1996) J. Am. Chem. Soc. 118, 12309-12321] reveals not only the bent DNA duplex but also the propeller twisted base pairs near the cisplatin-DNA adduct. The twisted base pairs may cause misalignment of the cisplatin-modified DNA at the binding cleft of T7 DNA polymerase and significantly slow the rate of the protein conformational change preceding polymerization, leading to the slight accumulation of intermediates within five base pairs of the adduct. The ground-state binding of the next correct nucleotide to the enzyme.DNA complex was weakened by the adduct with T7 DNA polymerase but unchanged with HIV-1 RT at sites other than the three strong pause sites. Nucleotide binding to both enzymes at the three strong pause sites was significantly weaker and less selective.