Shirley J. Hayes

Propagating the missing bacteriophages: a large bacteriophage in a new class

The number of successful propagations/isolations of soil-borne bacteriophages is small in comparison to the number of bacteriophages observed by microscopy (great plaque count anomaly). As one resolution of the great plaque count anomaly, we use propagation in ultra-dilute agarose gels to isolate a Bacillus thuringiensis bacteriophage with a large head (95 nm in diameter), tail (486 × 26 nm), corkscrew-like tail fibers (187 × 10 nm) and genome (221 Kb) that cannot be detected by the usual procedures of microbiology. This new bacteriophage, called 0305φ8-36 (first number is month/year of isolation; remaining two numbers identify the host and bacteriophage), has a high dependence of plaque size on the concentration of a supporting agarose gel. Bacteriophage 0305φ8-36 does not propagate in the traditional gels used for bacteriophage plaque formation and also does not produce visible lysis of liquid cultures. Bacteriophage 0305φ8-36 aggregates and, during de novo isolation from the environment, is likely to be invisible to procedures of physical detection that use either filtration or centrifugal pelleting to remove bacteria. Bacteriophage 0305φ8-36 is in a new genomic class, based on genes for both structural components and DNA packaging ATPase. Thus, knowledge of environmental virus diversity is expanded with prospect of greater future expansion.

Exclusion of spheres by agarose gels during agarose gel electrophoresis: dependence on the sphere's radius and the gel's concentration

Agarose gel electrophoresis of spheres (radius = R) has been used to determine the effective radius (PE) of the pores of an agarose gel (percentage of agarose in a gel = A). The value of PE at a given A was taken to be the R of the largest sphere that enters the gel. When log PE is plotted as a function of log A, the results can be represented by: PE = 118A-0.74 for 0.2 less than or equal to A less than or equal to 4.0 (PE in nm). However, the data suggest significant nonlinearity in this plot, the magnitude of the exponent of the PE vs A relationship increasing by about 20% as A increases from 0.2 to 4.0. From these data, PEs as big as 1500 nm and as small as 36 nm can be achieved with agarose gels formed with unmodified, unadulterated agarose and usable for electrophoresis.

Comparison of the physical properties and assembly pathways of the related bacteriophages T7, T3 and II*

To understand constraints on the evolution of bacteriophage assembly, the structures, electrophoretic mobilities (mu) and assembly pathways of the related double-stranded DNA bacteriophages T7, T3 and phi II, have been compared. The characteristics of the following T7, T3 and phi II capsids in these assembly pathways have also been compared: (1) a DNA-free procapsid (capsid I) that packages DNA during assembly; (b) a DNA packaging-associated conversion product of capsid I (capsid II). The molecular weights of the T3 and phi II genomes were 25.2 X 10(6) and 25.9 (+/- 0.2) X 10(6) (26.44 X 10(6) for T7, as previously determined), as determined by agarose gel electrophoresis of intact genomes. The radii of T7, T3 and phi II bacteriophages were indistinguishable by sieving during agarose gel electrophoresis (+/- 4%) and measurement of the bacteriophage hydration (+/- 2%) (30.1 nm for T7, as previously determined). Assuming a T = 7 icosahedral lattice for the arrangement of the major capsid subunits (p10A) of T7, T3 and phi II best explains these data and data previously obtained for T7. At pH 7.4 and an ionic strength of 1.2, the solid-support-free mu values (mu 0 values) of T7, T3 and phi II bacteriophages, obtained by extrapolation of mu during agarose gel electrophoresis to an agarose concentration of 0 and correction for electro-osmosis, were -0.71, -0.91 and -1.17(X 10(-4) cm2V-1 s-1. The mu 0 values of T7, T3 and phi II capsids I were -1.51, -1.58 and -2.07(X 10(-4] cm2V-1 s-1. For the capsids II, these mu 0 values were -0.82, -1.07 and -1.37(X 10(-4] cm2V-1 s-1. The tails of all three bacteriophages were positively charged and the capsid envelopes (heads) were negatively charged. In all cases the procapsid had a negative mu 0 value larger in magnitude than the negative mu 0 value for bacteriophage or capsid II. A trypsin-sensitive region in capsid I-associated, but not capsid II-associated, T3 p10A was observed (previously observed for T7). The largest fragment of trypsinized capsid I-associated p10A had the same molecular weight in T7 and T3, although the T3 p10A is 18% more massive than the T7 p10A. It is suggested that the trypsin-resistant region of capsid I-associated p10A determines the radius of the bacteriophage capsid.

Quantized viral DNA packaging revealed by rotating gel electrophoresis

Two classes of missense mutations in the bacteriophage T4 gene coding for the major head protein produce phage with different length heads. The pt (petite) mutations produce phage with normal, intermediate, and isometric heads, whereas ptg (petite and giant) mutations also produce greatly elongated (giant) heads. DNA from petite, normal, and giant particles was clearly resolved by discontinuous rotating gel electrophoresis, and several new species of headful length DNA were found. These results confirm the idea that the major stop points for head length regulation are at Q = 13, 17, and 21, and also show that minor stop points exist at Q = 16, 18 and 20. The existence of these well-defined classes of DNA that correlate with capsid structure suggest that a structural relationship between the scaffold protein and the capsid protein determines head length and thus DNA length.

Concatemerization and packaging of bacteriophage T7 DNA in vitro: determination of the concatemers' length and appearance kinetics by use of rotating gel electrophoresis

During its morphogenesis both in intact infected cells (in vivo) and in lysates of infected cells (in vitro), bacteriophage T7 forms end-to-end concatemers of its mature DNA, a linear, nonpermuted, terminally repetitious DNA. During morphogenesis, in vivo T7 concatemers are packaged in preformed capsids and cut to mature size. In the present study the lengths and appearance kinetics of concatemers formed in vitro from mature T7 DNA have been determined. The following procedures are used here for the first time: (a) 20-35% efficient in vitro concatemerization and packaging of T7 DNA; the mixture used for packaging contained two lysates that together had all T7 gene products, and (b) fractionation of concatemers by rotating gel electrophorsis (RGE), which improves the resolution by length of concatemer-length DNA. Concatemerization at 30 degrees was so fast that some other process must be rate limiting for packaging. The concatemers formed were linear and joined left-end to right-end by complementary base pairing, not by blunt-end ligation. Concatemers formed at 30 degrees were reconverted to mature DNA by packaging in vitro. Reducing the temperature to 0 degrees both slowed concatemerization to the time scale (minutes) needed for control of the extent of concatemerization and reduced packaging to insignificant levels, thereby also uncoupling packaging from concatemerization. At both 30 degrees and 0 degrees bands of discrete-length concatemers were observed by RGE. The lengths were n times the length of mature T7 DNA; n was found to be any integer from 2 to 15. The bands were stronger at 0 degrees than they were at 30 degrees in comparison to a background of heterogeneous DNA. No evidence for the favoring of any value of n was found. In addition, it was found by two-dimensional agarose gel electrophoresis that a comparatively small amount of circular DNA was produced in vitro.

Determination of a particle's radius by two-dimensional agarose gel electrophoresis.

Electrophoresis in an agarose gel dilute enough to be almost nonretarding, followed by electrophoresis in an orthogonal direction into a more concentrated agarose gel, has been developed as a procedure to determine the radius of spherical particles. Unlike procedures of unidirectional electrophoresis in a single gel, the above procedure can be used to compare the radii of particles that differ in solid-support-free electrophoretic mobility. Accuracy of 0.3 nm has been achieved with particles 30 nm in radius. It was found that the apparent radius of the spherical capsid of bacteriophage P22 decreased by 3% during elevated temperature-induced ejection of DNA from the capsid. Though originally designed for use with multimolecular particles, the procedure described here should also be useful with monomolecular particles.

Conformation of DNA packaged in bacteriophage T7: Analysis by use of ultraviolet light-induced DNA-capsid cross-linking☆

The conformation of the linear, double-stranded, 39,936 kilobase-pair DNA packaged in the protein capsid of bacteriophage T7 is investigated here by use of short wavelength ultraviolet light-induced DNA-capsid cross-linking. To detect both DNA-capsid and DNA-DNA cross-links, DNA is expelled from the T7 capsid and the products of expulsion are analyzed by use of Nycodenz buoyant density centrifugation, followed by either pulsed field gel electrophoresis or invariant field gel electrophoresis. Short wavelength ultraviolet light is found to progressively induce both DNA-DNA and DNA-protein cross-links in intact bacteriophage T7, but not in T7 from which DNA had been expelled before exposure to ultraviolet light. Protein-protein cross-links are not induced. When DNA expelled from previously cross-linked T7 is cleaved with restriction endonuclease (1 to 3 sites cleaved), analysis of the resulting fragments reveals no regions on T7 DNA that are excluded from cross-linking to the capsid. However, the efficiency of cross-linking decreases as the distance from the left end (last end packaged) of the packaged DNA increases. Electron microscopy of negatively stained capsid-DNA complexes reveals no DNA-retaining structure other than the outer shell of the capsid. Together with previously reported data that indicate lack of protein-based specificity for ultraviolet light-induced cross-linking, these observations are interpreted by the assumptions that, within the limits of resolution of these experiments: (1) no region of packaged T7 DNA is excluded from contact with the outer shell of the T7 capsid; (2) the probability of contacting the outer shell decreases as the distance from the left end of packaged T7 DNA increases. Thus, T7 DNA packaging concentrates the last end packaged near the inner surface of the outer shell of the T7 capsid.

Rapid detection and characterization of multimolecular cellular constituents by two-dimensional agarose gel electrophoresis

Abstract Agarose gel electrophoresis (best known for fractionating nucleic acids by length and conformation) may also be used for fractionating multimolecular complexes of either protein or protein together with other macromolecules. To improve analyses of such complexes, a procedure of two-dimensional agarose gel electrophoresis (2D-AGE) with the following capabilities has been developed: (1) the radius (R) of those spherical particles that form bands can be measured with an accuracy that can be as high as ±1%; (2) the solid-support-free electrophoretic mobility of band-forming particles can be measured; (3) the distribution of R in mixtures heterogeneous in R can be measured; and (4) complex mixtures can be analysed with separations that can be tuned to the R of particles of interest.

Partially Condensed DNA Conformations Observed by Single Molecule Fluorescence Microscopy

To detect partially condensed conformations of a double-stranded DNA molecule, single molecule fluorescence microscopy is performed here. The single DNA molecules are ethidium stained, 670 kilobase pair bacteriophage G genomes that are observed both during and after expulsion from capsids. Expulsion occurs in an agarose gel. Just after expulsion, the entire G DNA molecule typically has a partially condensed conformation not previously described (called a balloon). A balloon subsequently extrudes a filamentous segment of DNA. The filamentous segment becomes gently elongated via diffusion into the network that forms the agarose gel. The elongated DNA molecule usually has bright spots that undergo both appearance/disappearance and apparent motion. These spots are called dynamic spots. A dynamic spot is assumed to be the image of a zone of partially condensed DNA segments (globule). The positions of globules along an elongated DNA molecule 1) are restricted primarily to time-stable regions with comparatively high thermal motion-induced, micrometer-scale bending of the DNA molecule and 2) move within a given region on a time scale smaller than the time scale of recording. Less mobile globules are observed when either magnesium cation or ethanol is added before gel-embedding DNA molecules. These observations are explained by globules induced at equilibrium by a bending-dependent, inter-DNA segment force. Theory has previously predicted that globules are induced by electrostatic forces along an electrically charged polymer at equilibrium. The hypothesis is proposed that intracellular DNA globules assist action-at-a-distance during DNA metabolism.

Optimization of the in vitro packaging efficiency of bacteriophage T7 DNA: effects of neutral polymers

The in vitro DNA packaging of several DNA bacteriophages is stimulated by the presence of neutral polymers. To optimize bacteriophage T7 DNA packaging and to understand the basis for optimization, the efficiency of T7 DNA packaging has been determined at completion, as a function of the type, molecular mass, and concentration of the polymer added. When the polymer used was polyethylene glycol (PEG) of 0.2, 0.6 or 12.6 kDa, the efficiency of DNA packaging reached maximum at an intermediate concentration of polymer. The osmotic pressure (Pos) at maximum efficiency was either in, or close to, the range of colloid Pos measured for the intact host cell. The optimum Pos increased as the size of the polymer used decreased. PEG-100 (of 0.1 kDa) did not stimulate in vitro T7 DNA packaging. Dextran of 10 kDa also stimulated packaging and produced maximum efficiency at a physiological Pos. The degree of stimulation increases as DNA packaging extract concentration decreases; stimulation by as much as two to three orders of magnitude is observed. The presence of added polymer reduces fluctuations in DNA packaging efficiency caused by variability in the concentration of DNA packaging extracts. For reproducible and high efficiency packaging, the dextran was more reliable than the PEGs, possibly because the Pos of the dextran solutions is less sensitive to polymer concentration than is the Pos of PEG solutions. The optimum concentration of dextran at completion was also the optimum at all times before completion.