Is the In?Vitro Ejection of Bacteriophage DNA Quasistatic? A Bulk to Single Virus Study

Bacteriophage T5 DNA ejection is a complex process that occurs on several timescales in vitro. By using a combination of bulk and single phage measurements, we quantitatively study the three steps of the ejection—binding to the host receptor, channel-opening, and DNA release. Each step is separately addressed and its kinetics parameters evaluated. We reconstruct the bulk kinetics from the distribution of single phage events by following individual DNA molecules with unprecedented time resolution. We show that, at the single phage level, the ejection kinetics of the DNA happens by rapid transient bursts that are not correlated to any genome sequence defects. We speculate that these transient pauses are due to local phase transitions of the DNA inside the capsid. We predict that such pauses should be seen for other phages with similar DNA packing ratios.     

Real-time imaging of DNA ejection from single phage particles

Infection by tailed dsDNA phages is initiated by release of the viral DNA from the capsid and its polarized injection into the host. The driving force for the genome transport remains poorly defined. Among many hypothesis [1], it has been proposed that the internal pressure built up during packaging of the DNA in the capsid is responsible for its injection [2-4]. Whether the energy stored during packaging is sufficient to cause full DNA ejection or only to initiate the process was tested on phage T5 whose DNA (121,400 bp) can be released in vitro by mere interaction of the phage with its E. coli membrane receptor FhuA [5-7]. We present a fluorescence microscopy study investigating in real time the dynamics of DNA ejection from single T5 phages adsorbed onto a microfluidic cell. The ejected DNA was fluorescently stained, and its length was measured at different stages of the ejection after being stretched in a hydrodynamic flow. We conclude that DNA release is not an all-or-none process but occurs in a stepwise fashion and at a rate reaching 75,000 bp/sec. The relevance of this stepwise ejection to the in vivo DNA transfer is discussed.     

A kinetic analysis of DNA ejection from tailed phages revealing the prerequisite activation energy

All tailed bacteriophages follow the same general scheme of infection: they bind to their specific host receptor and then transfer their genome into the bacterium. DNA translocation is thought to be initiated by the strong pressure due to DNA packing inside the capsid. However, the exact mechanism by which each phage controls its DNA ejection remains unknown. Using light scattering, we analyzed the kinetics of in vitro DNA release from phages SPP1 and λ (Siphoviridae family) and found a simple exponential decay. The ejection characteristic time was studied as a function of the temperature and found to follow an Arrhenius law, allowing us to determine the activation energy that governs DNA ejection. A value of 25-30 kcal/mol is obtained for SPP1 and λ, comparable to the one measured in vitro for T5 (Siphoviridae) and in vivo for T7 (Podoviridae). This suggests similar mechanisms of DNA ejection control. In all tailed phages, the opening of the connector-tail channel is needed for DNA release and could constitute the limiting step. The common value of the activation energy likely reflects the existence for all phages of an optimum value, ensuring a compromise between efficient DNA delivery and high stability of the virus.     

Bacteriophage T5 DNA ejection under pressure

The transfer of the bacteriophage genome from the capsid into the host cell is a key step of the infectious process. In bacteriophage T5, DNA ejection can be triggered in vitro by simple binding of the phage to its purified Escherichia coli receptor FhuA. Using electrophoresis and cryo-electron microscopy, we measure the extent of DNA ejection as a function of the external osmotic pressure. In the high pressure range (7-16 atm), the amount of DNA ejected decreases with increasing pressure, as theoretically predicted and observed for λ and SPP1 bacteriophages. In the low and moderate pressure range (2-7 atm), T5 exhibits an unexpected behavior. Instead of a unique ejected length, multiple populations coexist. Some phages eject their complete genome, whereas others stop at some nonrandom states that do not depend on the applied pressure. We show that contrarily to what is observed for the phages SPP1 and λ, T5 ejection cannot be explained as resulting from a simple pressure equilibrium between the inside and outside of the capsid. Kinetics parameters and/or structural characteristics of the ejection machinery could play a determinant role in T5 DNA ejection.     

Conformational Changes Leading to T7 DNA Delivery upon Interaction with the Bacterial Receptor

The majority of bacteriophages protect their genetic material by packaging the nucleic acid in concentric layers to an almost crystalline concentration inside protein shells (capsid). This highly condensed genome also has to be efficiently injected into the host bacterium in a process named ejection. Most phages use a specialized complex (often a tail) to deliver the genome without disrupting cell integrity. Bacteriophage T7 belongs to the Podoviridae family and has a short, non-contractile tail formed by a tubular structure surrounded by fibers. Here we characterize the kinetics and structure of bacteriophage T7 DNA delivery process. We show that T7 recognizes lipopolysaccharides (LPS) from Escherichia coli rough strains through the fibers. Rough LPS acts as the main phage receptor and drives DNA ejection in vitro. The structural characterization of the phage tail after ejection using cryo-electron microscopy (cryo-EM) and single particle reconstruction methods revealed the major conformational changes needed for DNA delivery at low resolution. Interaction with the receptor causes fiber tilting and opening of the internal tail channel by untwisting the nozzle domain, allowing release of DNA and probably of the internal head proteins.     

Langevin dynamics simulation of DNA ejection from a phage

We have performed Langevin dynamics simulations of a coarse-grained model of ejection of dsDNA from Φ29 phage. Our simulation results show significant variations in the local ejection speed, consistent with experimental observations reported in the literature for both in vivo and in vitro systems. In efforts to understand the origin of such variations in the local speed of ejection, we have investigated the correlations between the local ejection kinetics and the packaged structures created at various motor forces and chain flexibility. At lower motor forces, the packaged DNA length is shorter with better organization. On the other hand, at higher motor forces typical of realistic situations, the DNA organization inside the capsid suffers from significant orientational disorder, but yet with long orientational correlation times. This in turn leads to lack of registry between the direction of the DNA segments just to be ejected and the direction of exit. As a result, a significant amount of momentum transfer is required locally for successful exit. Consequently, the DNA ejection temporarily slows down exhibiting pauses. This slowing down occurs at random times during the ejection process, completely determined by the particular starting conformation created by prescribed motor forces. In order to augment our inference, we have additionally investigated the ejection of chains with deliberately changed persistence length. For less inflexible chains, the demand on the occurrence of large momentum transfer for successful ejection is weaker, resulting in more uniform ejection kinetics. While being consistent with experimental observations, our results show the nonergodic nature of the ejection kinetics and call for better theoretical models to portray the kinetics of genome ejection from phages.     

Saturation of DNA repair measured by alkaline elution

To determine whether the half-times (T1/2) of the DNA repair processes measured by alkaline elution increased in a dose-dependent manner, exponentially growing 9L/Ro rat brain tumor cells were irradiated with doses of 15-50 Gy, and their DNA repair kinetics was measured by alkaline elution. At 15 Gy, the DNA repair kinetics was biphasic with the fast phase having a T1/2 approximately 6 min and the slow phase having a T1/2 approximately 42 min. As the dose was increased to 50 Gy, the fast-phase T1/2 remained at approximately 6 min, but the slow-phase T1/2 increased to approximately 87 min. Although a dose-dependent increase in the T1/2 of the slow phase of DNA repair (saturation) was measured by alkaline elution, both the absolute value of the slow-phase T1/2 and the dependency of the slow-phase T1/2 on dose were less than those measured by alkaline sucrose gradient sedimentation in zonal rotors with slow reorienting gradient capability. Thus these two techniques appear either to depend on different hydrodynamic properties of the DNA or to have different coefficients of dependency for the same hydrodynamic properties of the DNA. The lower sensitivity for detection of the dose dependency of DNA repair makes it unlikely that the alkaline elution technique will be useful for quantitatively relating the shape of mammalian cell survival curves to the doses at which saturation of a DNA repair process occurs.     

Roles of cell surface components of Escherichia coli K-12 in bacteriophage T4 infection: interaction of tail core with phospholipids.

The cell surface of Escherichia coli K-12, reconstituted from the OmpC protein, lipopolysaccharide, and the peptidoglycan layer, was active as a receptor for phage T4, resulting in the contraction of the tail sheath and the penetration of the core through the cell surface (Furukawa et al., J. Bacteriol. 140:1071--1080, 1979). In the present work the process of DNA ejection from the contracted T4 phage particle was studied. Contracted phage particles were adsorbed to phospholipid liposomes by the core tip. This adsorption resulted in ejection of phage DNA. Either phosphatidylglycerol or cardiolipin was active for the DNA ejection. A proton motive force across the liposome membrane was not required for these processes. The process of DNA ejection, however, was temperature dependent, whereas the adsorption of the core tip to liposomes took place at 4 degrees C. Based on these observations together with those in the previous paper, the process of T4 infection of E. coli K-12 cells is discussed with special reference to the roles of cell surface components.     

Kinetic and spectrophotometric studies on the renaturation of deoxyribonucleic acid

The kinetics of the renaturation of Escherichia coli DNA in 0.4-1.0m-sodium chloride at temperatures from 60 degrees to 90 degrees have been studied. The extent of renaturation was a maximum at 65 degrees to 75 degrees and increased with ionic strength, and the rate constant increased with both ionic strength and temperature. The energy and entropy of activation of renaturation were calculated to be 6-7kcal.mole(-1) and -40cal.deg.(-1)mole(-1) respectively. It has been shown that renaturation is a second-order process for 5hr. under most conditions. The results are consistent with a reaction in which the rate-controlling step is the diffusion together of two separated complementary DNA strands and the formation of a nucleus of base pairs between them. The kinetics of the renaturation of T7-phage DNA and Bordetella pertussis DNA have also been studied, and their rates of renaturation related quantitatively to the relative heterogeneity of the DNA samples. By analysis of the spectra of DNA at different stages during renaturation it was shown that initially the renatured DNA was rich in guanine-cytosine base pairs and non-random in base sequence, but that, as equilibrium was approached, the renatured DNA gradually resembled native DNA more closely. The rate constant for the renaturation of guanine-cytosine base pairs was slightly higher than for adenine-thymine base pairs.     

Biophysics of T5, IRA phages, Escherichia coli outer membrane protein FhuA and T5-FhuA interaction

In spite of the similarities in a structural organization of T5 and IRA phages their thermal and hydrodynamical peculiarities are completely different. One of the significant differences is observed in temperature value at which thermally induced DNA ejection starts. If in the case of physiological conditions this difference equals to 30°С, then it decreases as ionic strength of the solvent decreases. Also, from our experimental results follows that in the opening of phage tail channel for T5 phage (at pH7) significant role-play electrostatic forces. In spite of that both of these phages grow on the same Escherichia coli strain, we have shown that these phages need different receptors to penetrate into the bacterial cell precisely FhuA serves as receptor only for T5 phage. The higher FhuA concentration in T5 phage suspension is, the more intensive DNA ejection in environment is. The minimal FhuA/T5 ratio, which is 300/1, correspondingly, necessary for effective DNA ejection from the phage head was experimentally determined. For the first time the ejection of T5 phage DNA induced by FhuA was observed in an incessant regime. The deconvolution of calorimetric curve of FhuA’s denaturation has been shown that in a chosen condition there are four thermodynamically independent domains in the structure of FhuA.     

Bacteriophage DNA reptation]

The kinetics of reptation process of dsDNA leaving the phage head is analysed theoretically. It is assumed that the process is caused by DNA free energy decrease when it is leaving the head (DNA has to be in a globular state) for its surroundings where it is transformed into a coil state. For the analysis we have used the results of previous paper on equilibrium theory of DNA intraphage globule. Three possible cases for the ejection process friction are considered: friction in the tail-part channel, that of DNA segments with each other in the whole globule volume (it is essential for the collective way of the globule decondensation with simultaneous movement of all the loops--the first type way), the globule friction with internal capsid surface (it is most essential for the decondensation by the way of the globule rotation as a whole "spool"--the second type way). The first way would correspond to the greatest ejection time. The known experimental data on distinguishing ejection kinetics for phages with short and long tail-parts allow us to formulate arguments in favor of realization of the second way in nature.     

Assessing the Conformational Changes of pb5, the Receptor-binding Protein of Phage T5, upon Binding to Its Escherichia coli Receptor FhuA

Within tailed bacteriophages, interaction of the receptor-binding protein (RBP) with the target cell triggers viral DNA ejection into the host cytoplasm. In the case of phage T5, the RBP pb5 and the receptor FhuA, an outer membrane protein of Escherichia coli, have been identified. Here, we use small angle neutron scattering and electron microscopy to investigate the FhuA-pb5 complex. Specific deuteration of one of the partners allows the complete masking in small angle neutron scattering of the surfactant and unlabeled proteins when the complex is solubilized in the fluorinated surfactant F₆-DigluM. Thus, individual structures within a membrane protein complex can be described. The solution structure of FhuA agrees with its crystal structure; that of pb5 shows an elongated shape. Neither displays significant conformational changes upon interaction. The mechanism of signal transduction within phage T5 thus appears different from that of phages binding cell wall saccharides, for which structural information is available.     

Analysis of the coliphage T5 DNA ejection process with free and liposome-associated TonA protein.

Outer membrane protein TonA, the receptor for coliphage T5, has been partially purified and incorporated into the phospholipid bilayer of liposomes. Adsorption of the phage to its receptor in either a free or liposome-associated form is fast and sufficient to trigger the ejection of encapsidated DNA. In both in vitro systems the exit of DNA from the phage capsid is a very slow process. Ejected DNA can partially accumulate inside the liposome aqueous compartment, but the transfer from the phage head to the liposome internal space is never complete, perhaps because the liposome volume is too small. The presence of polyamines or divalent cations (magnesium) or both in the incubation medium diminished the extent of DNA ejection, possibly by stabilizing DNA inside the head. DNA movement was slowed as the temperature was decreased from 37 to 18 degrees C. Furthermore, incubation at 4 degrees C totally prevented this DNA movement, even if a large part of the DNA had already exited the capsid.     

Dual parameter flow cytometric analysis of DNA content, activation antigen expression, and T cell subset proliferation in the human mixed lymphocyte reaction

This study provides direct correlation via dual parameter flow cytometry (simultaneous assessment of immunofluorescence and DNA content) between mixed lymphocyte reaction (MLR) responder cell entry into the S/G2/M phases of the cell cycle with the kinetics of expression of two activation-associated cell surface proteins, Tac (IL 2 receptor) and 4F2 (unknown metabolic function). A small population of activated cells was identifiable by expression of both Tac and 4F2 antigens before peak DNA synthesis in the MLR. This population of activation antigen-positive cells expanded linearly in size from days 3 to 7 of culture. Treatment of immature MLR cultures with anti-4F2 Mab and complement (C) before DNA synthesis (treatment on day 3, peak DNA synthesis on days 5 to 6) resulted in blunted proliferation and activation antigen expression when the same culture was analyzed after maturation on day 6, indicating that the activated population had been previously detected and removed by anti-4F2 Mab + C. The 4F2 antigen was expressed on a greater percentage of cells in the MLR at all times (days 3 to 9) than was Tac, was present on virtually all S/G2/M phase responder cells, and a large fraction of cells remained intensely 4F2+ subsequent to peak DNA synthesis. In contrast, after initially preceding responder cell entry into the S phase of the cell cycle, the kinetics of Tac antigen expression closely paralleled the kinetics of responder cell proliferation. A subpopulation of cycling responder cells was noted in all MLR cultures studied that expressed Tac antigen weakly or not at all. Cells within both T4 and T8 cell subsets proliferate with similar kinetics in response to alloantigen. The possibility that activation antigens can be utilized to study effector cell generation in the MLR and that this flow cytometric technique may be utilized to analyze the response to various alloantigens is discussed.     

Der Einfluss extrazellul?rer UV-Bestrahlung des Phagen T2 auf die Replikation Seiner DNA

Summary The effects of extracellular UV-irradiation on the replication of DNA were tested with phage T2. Cells ofE. coli B/1 were multiply infected with UV-irradiated T2. The kinetics of P³²-incorporation into phage DNA were significantly different from the unirradiated control.With unirradiated phages the time curve is linear during the second half of the latent period after as short nonlinear increase. With UV-irradiated phages however the amount of DNA increases exponentially during the whole latent period. Such kinetics might be expected from semiconservative DNA-replication if templates were limiting. The reported findings suggest that other regulatory mechanisms normally limiting DNA-synthesis are inactivated by UV. The kinetics determined by semiconservative replication could then be clearly observed with irradiated phages. The nature of the normally regulating mechanisms is discussed.

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A unified theory of nucleation-rate-limited DNA renaturation kinetics

DNA renaturations under nucleation-rate-limiting conditions on simple DNA such as bacterial and bacteriophage DNA show significant deviation from ideal second-order kinetics when followed by optical density measurements at 260 nm. Ideal second-order kinetics yield linear plots when the data is plotted in the standard reciprocal second-order (RSO) manner. The observed deviations from ideal second-order behavior take the form of steadily downward-curving RSO plots. In this paper, experiments are presented for E. coli and T2 DNA documenting this non-ideal behavior. Since experiments using T4, T5 and B, subtilis DNA yield identical non-ideal behavior, this behavior appears to be a property of DNA renaturation followed by optical density, not a peculiarity of a particular DNA. Identical non-ideal behavior is also seen in kinetics followed by S1 nuclease assay. A theory is developed to explain this deviation from ideal second-order kinetics. The theory also explains why kinetics followed by hydroxyapatite chromatography show nearly ideal second-order kinetics. In contrast to the approach taken by others in developing equations that describe S1 nuclease monitored reactions, our view is that nonideal second-order kinetics are fundamentally due to the reacton of free single strands to yield partially helical duplex species. Later reactions of these species tend to reduce the deviations from non-ideal second-order kinetics.     

Tail morphology controls DNA release in two Salmonella phages with one lipopolysaccharide receptor recognition system

Bacteriophages use specific tail proteins to recognize host cells. It is still not understood to molecular detail how the signal is transmitted over the tail to initiate infection. We have analysed in vitro DNA ejection in long-tailed siphovirus 9NA and short-tailed podovirus P22 upon incubation with Salmonella typhimurium lipopolysaccharide (LPS). We showed for the first time that LPS alone was sufficient to elicit DNA release from a siphovirus in vitro. Crystal structure analysis revealed that both phages use similar tailspike proteins for LPS recognition. Tailspike proteins hydrolyse LPS O antigen to position the phage on the cell surface. Thus we were able to compare in vitro DNA ejection processes from two phages with different morphologies with the same receptor under identical experimental conditions. Siphovirus 9NA ejected its DNA about 30 times faster than podovirus P22. DNA ejection is under control of the conformational opening of the particle and has a similar activation barrier in 9NA and P22. Our data suggest that tail morphology influences the efficiencies of particle opening given an identical initial receptor interaction event.