The two-disulphide intermediates and the folding pathway of reduced pancreatic trypsin inhibitor.

We have studied bacteriophage λ head assembly under conditions in which the normal pathways for late phage DNA (concatemer) synthesis are blocked, and early (monomeric circular) DNA replication products accumulate. Our results show that under such conditions, the amount of late protein per amount of DNA is normal, but the amount of phage produced is not. Electron microscopic examination of thin sections of these bacteria shows that large numbers of “empty” head-shaped particles are produced. We conclude that the packaging of λ DNA depends on some structure (or property) possessed by DNA concatemers and absent in monomeric circular molecules and that the empty head-shaped particles which accumulate when concatemer production is blocked are head precursors which would normally accept concatemer DNA.These empty particles are the same size (approximately 550 Å vertex-to-vertex diameter) as the electron-dense, DNA-filled particles observed in similar sections of wild-type infected bacteria. In lysates the empty particles are approximately the same size as they are within the bacteria. However, filled heads observed in thin sections (or in negatively stained preparations) of lysates are larger than they are within the bacteria. This observation is contrary to what was previously suspected, since there seems to be little or no change in the size of intracellular λ capsids as a direct consequence of DNA packaging. Instead, an increase in the size of completed phage heads seems to take place as a consequence of cell lysis.     

Injection of DNA into liposomes by bacteriophage lambda

Small unilamellar vesicles (75-100 nm diameter) and large liposomes (greater than 1 micron in diameter) were prepared containing the lamB protein, an outer membrane protein of Escherichia coli and Shigella which serves as the receptor for bacteriophage lambda. Bacteriophage were observed to bind to these liposomes and vesicles by their tails and in most cases the heads of the bound bacteriophage appeared empty or partially empty of DNA. The lambda DNA was usually only partially ejected from the bacteriophage head when small unilamellar liposomes were used, presumably because the vesicles are too small to contain all the DNA. The partially ejected DNA was not susceptible to DNase unless the vesicle bilayer was first disrupted suggesting that DNA injection of phage DNA into the vesicle had occurred. After disruption of these vesicles on electron microscope grids, the bacteriophage are seen to have partially empty heads and a small mass of DNA associated with their tails. Using larger liposomes prepared by the fusion of lamB bearing vesicles with polyethylene glycol and n-hexyl bromide, the heads of most of the bound bacteriophage appeared to be completely empty of DNA. Disruption of these preparations on electron microscope grids revealed circular arrays of empty-headed bacteriophage surrounding DNA which had apparently been contained within the intact liposomes. These results indicate that high molecular weight DNA can be entrapped within liposomes with high efficiency by ejection from bacteriophage lambda. The possible use of these DNA-containing liposomes to facilitate gene transfer in eukaryotic cells is discussed.     

Mechanism of head assembly and DNA encapsulation in Salmonella phage p22. I. Genes, proteins, structures and DNA maturation

The functions of ten known late genes are required for the intracellular assembly of infectious particles of the temperate Salmonella phage P22. The defective phenotypes of mutants in these genes have been characterized with respect to DNA metabolism and the appearance of phage-related structures in lysates of infected cells. In addition, proteins specified by eight of the ten late genes were identified by sodium dodecyl sulfate/polyacrylamide gel electrophoresis; all but two are found in the mature phage particle. We do not find cleavage of these proteins during morphogenesis.The mutants fall into two classes with respect to DNA maturation; cells infected with mutants of genes 5, 8, 1, 2 and 3 accumulate DNA as a rapidly sedimenting complex containing strands longer than mature phage length. 5^? and 8^? lysates contain few phage-related structures. Gene 5 specifies the major head structural protein; gene 8 specifies the major protein found in infected lysates but not in mature particles. 1^?, 2^? and 3^? lysates accumulate a single distinctive class of particle (“proheads”), which are spherical and not full of DNA, but which contain some internal material. Gene 1 protein is in the mature particle, gene 2 protein is not.Cells infected with mutants of the remaining five genes (10, 26, 16, 20 and 9) accumulate mature length DNA. 10^? and 26^? lysates accumulate empty phage heads, but examination of freshly lysed cells shows that many were initially full heads. These heads can be converted to viable phage by in vitro complementation in concentrated extracts. 16^? and 20^? lysates accumulate phage particles that appear normal but are non-infectious, and which cannot be rescued in vitro.From the mutant phenotypes we conclude that an intact prohead structure is required to mature the virus DNA (i.e. to cut the overlength DNA concatemer to the mature length). Apparently this cutting occurs as part of the encapsulation event.     

Structure of the scaffold in bacteriophage lambda preheads removal of the scaffold leads to a change of the prehead shell

Small angle X-ray scattering was performed on unprocessed and processed preheads, intermediates in the morphogenesis of bacteriophage λ heads. Unprocessed preheads possess an internal structure (scaffold), necessary for efficient assembly of closed shells. Processed preheads, formed after removal of the scaffold, are able to pack and cut the viral DNA in vitro. Our data show that the scaffold fills out the inside of the shell in an almost (but not completely) homogeneous fashion; structures of the scaffold with the bulk of the mass in a small core inside the shell can be excluded. Unprocessed preheads are larger than processed ones. A change in shell architecture takes place upon transition from unprocessed to processed prehead; the shell becomes roughened up. Shrinking of the shell as well as roughening up can be triggered by accidental partial degradation of the scaffold. The lattice constant of type A polyheads is in agreement with the lattice constant derived from our icosahedral models of the shell, indicating a close relationship between processed preheads and type A polyheads. This observation, together with the type of subunit clustering found, leads us to propose a simple model for the interaction of prehead shell and protein pD, which stabilizes phage DNA after packaging.     

Development of Coliphage T5: Ultrastructural and Biochemical Studies

Electron microscopic studies of Escherichia coli infected with bacteriophage T5(+) have revealed that host nuclear material disappeared before 9 min after infection. This disappearance seemed to correspond to the breakdown of host deoxyribonucleic acid (DNA) into acid-soluble fragments. Little or no host DNA thymidine was reincorporated into phage DNA, except in the presence of 5-fluorodeoxyuridine (FUdR). Progeny virus particles were observed in the cytoplasm 20 min postinfection. Most of these particles were in the form of hexagonal-shaped heads or capsids, which were filled with electron-dense material (presumably T5 DNA). A small percentage (3 to 4%) of the phage heads appeared empty. On rare occasions, crystalline arrays of empty heads were observed. Nalidixic acid, hydroxyurea, and FUdR substantially inhibited replication of T5 DNA. However, these agents did not prevent virus-induced degradation of E. coli DNA. Most of the phage-specified structures seen in T5(+)-infected cells treated with FUdR or with nalidixic were in the form of empty capsids. Infected cells treated with hydroxyurea did not contain empty capsids. When E. coli F was infected with the DO mutant T5 amH18a (restrictive conditions), there was a small amount of DNA synthesis. Such cells contained only empty capsids, but their numbers were few in comparison to those in cells infected under permissive conditions or infected with T5(+). The cells also failed to lyse. These results confirm other reports which suggest that DNA replication is not required for the synthesis of late proteins. The data also indicate that DNA replication influences the quantity of viral structures being produced.     

Bacteriophage T4 head morphogenesis : On the nature of gene 49-defective heads and their role as intermediates

Following infection under non-permissive conditions, T4 mutants defective in gene 49 accumulate structures which appear in the electron microscope to be empty phage heads. These structures are seen in extracts prepared under a variety of conditions, as well as in sections of the mutant-infected cells. The 49-defective heads (300 s) can be separated from phage particles (1000 s) by sedimentation through a sucrose gradient. A temperature-sensitive gene 49 mutant, tsC9, accumulates 300 s heads following infection at 41.5 °C, but can be “rescued” by a shift-down to 25 °C during the latter half of the latent period. Evidence from pulse-chase isotopic labeling experiments suggests that the 49-defective heads are intermediates in head formation. ¹⁴C-Labeled lysine, incorporated into the 300 s fraction at 41.5 °C, is rapidly and almost quantitatively transferred into the 1000 s phage particle fraction following a chase with an excess of unlabeled lysine and a shift to low temperature. The same result is observed when puromycin (200 μg/ml.) or chloramphenicol (200 μg/ml.) is added to the culture before temperature shift, suggesting that the inactive gene 49 product produced at high temperature becomes active at low temperature. In pulse-chase experiments carried out with wild-type T4-infected cells during the latter half of the latent period, the labeling kinetics of the 300 s and phage particle fractions support a precursor-product relationship. Conservation of the 300 s head structures during conversion to phage is demonstrated by ¹³C-¹⁵N density labeling of tsC9-infected cells at 41.5 °C followed by transfer to ¹²C-¹⁴N medium, shift to low temperature, isolation and lysis of the phage particles formed and centrifugation of the phage ghosts to equilibrium in CsCl solution.     

Studies of DNA packaging into the heads of bacteriophage lambda

During the assembly of bacteriophage λ heads, a head-like, DNA-free structure called petite λ, is first constructed. Into this, λ DNA is then packaged. In this paper we examine early interactions between λ DNA and petite λ in a cell-free system. The two major findings of this paper are: (1) when seen through the electron microscope, an early petite λ-λ DNA complex appears with the circular petite λ having the DNA crossing through its center. These resemble a bead on a string or the Greek letter φ (hence they are called φ structures). The λ A protein is required in the formation of φ structures. Also, φ structures can be found in bacteria infected with phage λ. (2) The polyamine putrescine is required for phage head assembly. An earlier reported requirement for spermidine can be replaced by the addition of putrescine. Polyamine is required in the DNA packaging reaction after the packaging has begun.     

Morphogenesis of bacteriophage phi 29 of Bacillus subtilis: preliminary isolation and characterization of intermediate particles of the assembly pathway.

Three classes of particles have been identified in restrictive phi 29 suppressor-sensitive (sus) mutant infections of Bacillus subtilis, including DNA-containing heads or phage, prohead, and empty heads. Pulse-chase labeling experiments indicate that the prohead, the first particle assembled in 14-infected cells, is converted to DNA-filled heads and phi 29. In addition to the proteins Hd, P10, and F found in mature phi 29, the prohead contains a "core" protein P7 that exits as the prohead matures and appears to recycle during subsequent rounds of prohead assembly. Prohead-like structures accumulate in UV-irradiated cells and are present in restrictive infections with sus mutants of cistrons 9 and 16. Empty heads are observed only when infection results in the formation of DNA-containing particles; this and other evidence indicates that the empty heads are probably not true intermediates. Phage phi 29 assembly apparently occurs by a single pathway in which neck and tail components interact to stabilize the completed DNA-containing head.     

Morphogenesis of bacteriophage lambda deletion mutants. I. Abnormal head-related structures produced in normal Escherichia coli.

Late in the morphogenesis of bacteriophage lambda, DNA condenses into the nascent head and is cut from a concatemeric replicative intermediate by a nucleolytic function, Ter, acting at specific sites, called cos. As a result of this process, heads of lambda deletion mutants contain less DNA than those of the wild-type phage. It has been reported that phage with very large deletions (22% of the genome or more) grow poorly but that normal growth can be restored by the non-specific addition of DNA to the genome. This finding implies that DNA content may exert a physical effect on some stage of head assembly.We have investigated the effects of two long deletions, b221 and tdel33, on head assembly. Bacteria infected with the mutants were lysed with non-ionic detergent under conditions favoring stabilization of labile structures containing condensed DNA. It has proved possible to isolate two aberrant head-related structures produced by the deletion mutants. One of these (“overfilled heads”) contains DNA which is longer than the deletion mutant genome and is about the same size as that found in wild-type heads. These structures appear to be unable to attach tails. The second type of structure (“incompletely filled heads”) contains a short piece of DNA, 40% of the length of the mutant genome. The incompletely filled heads are found both with and without attached tails. Both of these abnormal structures are initially attached to the replicating DNA but are released by treatment with DNAase. The nature of these abnormal structures indicates that very small genomes affect a late stage of head morphogenesis, after the DNA is complexed with a capsid of normal size. The results presented suggest that underfilling of the capsid interferes with the ability of the Ter function to properly cleave cos.     

Stages of bacteriophage lambda head morphogenesis: physical analysis of particles in solution

Intermediates in the morphogenesis of bacteriophage lambda are characterized in solution by classical light-scattering, using a modified version of the Zimm plot procedure, by quasi-elastic light-scattering and analytical ultracentrifugation. Partial specific volumes are determined simultaneously with molecular weights by a variant of the conventional combination of sedimentation and diffusion constants. Our measurements were performed within a short time and allowed the characterisation of metastable intermediates.Comparison of hydration of DNA-containing and empty heads shows that dehydration plays a minor role in the stabilisation of the DNA within the heads. The molecular weight of the scaffolding protein is 4 × 10⁶, about twice the value estimated so far. Enlargement of preheads (21% and 13% increase in dry and hydrodynamic radius, respectively) leaves the molecular weight unchanged, whereas the volume of hydration water increases from 70% to 90% of the total hydrodynamic volume. Addition of protein pD to the enlarged preheads leads to a further increase in the radius, indicating that pD is attached to the outside of the protein shell.In order to determine simultaneously the molecular weight and the partial specific volume of large and sometimes labile structures, such as a virus, the conventional sedimentation-diffusion method is modified by measuring sedimentation and diffusion coefficients in buffers containing different amounts of ²H₂O. If diffusion coefficients are determined by quasi-elastic light-scattering, experiments can be performed in a few hours. In addition, the method allows a check on the sample for changes in the frictional coefficient due, for instance, to DNA abortively ejected from a virus preparation. This method is described in the Appendix.     

Bacteriophage lambda preconnectors. Purification and structure

The morphogenesis of bacteriophage lambda proheads is under the control of the four phage genes B, C, Nu3 and E, and the two Escherichia coli genes groEL and groES . It has been shown previously that extracts prepared from cells infected with a lambda C-E- mutant accumulate a gpB polymer, which behaves as a biologically active intermediate in prohead assembly. This gpB activity has been called a preconnector , as it is probably a precursor to the head-tail connector. We now report the partial purification of biologically active preconnectors and the characterization of its structure. In the electron microscope, preconnectors appear as donut -like structures composed of several subunits displaying radial symmetry. Optical filtration of periodic arrays of preconnectors showed that the structure has 12-fold rotational symmetry. Side views of the preconnector reveal that it resembles an asymmetrical dumbell . This information has been used to construct a three-dimensional model of the preconnector . The implications of this structure for prohead shape and function, and for DNA packaging are discussed.     

Structure and inherent properties of the bacteriophage lambda head shell. VI. DNA-packaging-defective mutants in the major capsid protein

Some amino acid substitutions in the major capsid protein (gene E product) of lambda phage are found to cause a defect in DNA packaging. These substitutions permit initiation of DNA packaging and expansion of the prohead. However, cleavage of the concatemer DNA at the cos site takes place only to a very small extent, and the capsid eventually becomes empty. Interestingly, the mutations are suppressed by a decrease of the DNA length between the cos sites by 8000 to 10,000 bases. These properties are similar to those of amber mutants in gene D, which codes for the capsid outer-surface protein. Studies on the E missense.D amber double mutant show that the E protein and the D protein contribute additively to the stabilization of the condensed form of the DNA molecule in phage heads.     

Electron microscopy study of viral DNA packaging with lambda head mutants

In a previous study, various intermediates in λ DNA packaging were visualized after lysis of λ-infected cells with osmotic shock and sedimentation through a sucrose formalin cushion onto electron microscope grids. Along this line, a systematic screening for intermediates accumulated in all head mutants available was performed. λA^?-infected cells accumulate only empty spherical protein shells (petit λ) bound at an intermediate point along the DNA thread. In situ digestion experiments with restriction endonuclease EcoRI show that the petit λ-DNA complexes are formed at a fixed point on the DNA concatemer. In $\text{λNu1}{}^{\mathrm{?}}\text{-}\text{infected}$ cells, however, most petit λ was not bound to DNA. In Fec^? cells, which are defective in formation of concatemers but normal in head protein synthesis, most petit λ did not sediment onto the carbon film of the grid. In $\text{D}{}^{\mathrm{?}}$ mutant, petit λ, partially full heads and empty heads with released DNA were observed. λFI^?-infected cells also accumulate petit λ and partially full heads. The present studies suggest that protein pNu1 is required for complex formation between head precursors and DNA concatemers, $\text{p}\text{A}$ for the initiation of DNA packaging, $\text{p}\text{D}$ and $\text{p}\text{F}$I for the promotion of DNA packaging, and $\text{p}\text{D}$ for stabilization of head structures. The results obtained with other head mutants involved in formation of mature proheads and head completion confirm earlier results obtained by different techniques.     

Mechanism of head assembly and DNA encapsulation in Salmonella phage P22. II. Morphogenetic pathway

We have identified and characterized structural intermediates in phage P22 assembly. Three classes of particles can be isolated from P22-infected cells: 500 S full heads or phage, 170 S empty heads, and 240 S “proheads”. One or more of these classes are missing from cells infected with mutants defective in the genes for phage head assembly. By determining the protein composition of all classes of particles from wild type and mutant-infected cells, and examining the time-course of particle assembly, we have been able to define many steps in the pathway of P22 morphogenesis.In pulse-chase experiments, the earliest structural intermediate we find is a 240 S prohead; it contains two major protein species, the products of genes 5 and 8. Gene 5 protein (p5) is the major phage coat protein. Gene 8 protein is not found in mature phage. The proheads contain, in addition, four minor protein species, PI, P16, P20 and PX. Similar prohead structures accumulate in lysates made with mutants of three genes, 1, 2 and 3, which accumulate uncut DNA. The second intermediate, which we identify indirectly, is a newly filled (with DNA) head that breaks down on isolation to 170 S empty heads. This form contains no P8, but does contain five of the six protein species of complete heads. Such structures accumulate in lysates made with mutants of two genes, 10 and 26.Experiments with a temperature-sensitive mutant in gene 3 show that proheads from such 3^? infected cells are convertible to mature phage in vivo, with concomitant loss of P8. The molecules of P8 are not cleaved during this process and the data suggest that they may be re-used to form further proheads.Detailed examination of 8^? lysates revealed aberrant aggregates of P5. Since P8 is required for phage morphogenesis, but is removed from proheads during DNA encapsulation, we have termed it a scaffolding protein, though it may have DNA encapsulation functions as well.All the experimental observations of this and the accompanying paper can be accounted for by an assembly pathway, in which the scaffolding protein P8 complexes with the major coat protein P5 to form a properly dimensioned prohead. With the function of the products of genes 1, 2 and 3, the prohead encapsulates and cuts a headful of DNA from the concatemer. Coupled with this process is the exit of the P8 molecules, which may then recycle to form further proheads. The newly filled heads are then stabilized by the action of P26 and gene 10 product to give complete phage heads.     

DNA packaging steps in bacteriophage lambda head assembly

Petit λ is an empty spherical shell of protein which appears wherever λ grows. If phage DNA and petit λ are added to a cell-free extract of induced lysogenic bacteria, then phage particles are formed that contain the DNA and protein from the petit λ. Petit λ is transformed, without dissociation, into a phage head by addition of DNA and more phage proteins.The products of ten genes, nine phage and one host, are required for λ head assembly. Among these, the products of four phage genes, E, B, C, and Nu3 and of the host gene groE are involved in the synthesis of petit λ, consequently these proteins are dispensable for head assembly in extracts to which petit λ has been added. The products of genes A and D allow DNA to combine with petit λ to form a head that has normal morphology. In an extract, DNA can react with A product and petit λ to become partially DNAase-resistant, as if an unstable DNA-filled intermediate were formed. ATP and spermidine are needed at this stage. This intermediate is subsequently stabilized by addition of D product. The data suggest a pathway for head assembly.     

The bacteriophage lambda terminase. Partial purification and preliminary characterization of properties

The maturation of bacteriophage lambda DNA and its packaging into preformed heads to produce infectious phage is under the control of the two leftmost genes on the lambda chromosome, i.e., Nu1 and A. Based on its ability to complement lambda A- phage-infected cell extracts for packaging of lambda DNA in vitro, a single protein, designated terminase (ter) has been extensively purified using adsorption, ion exchange, and affinity column chromatography. The final preparation represents an approximately 60,000-fold purification over the activity found in crude extracts and is about 30 to 80% homogeneous as judged by visualizing the protein after electrophoresis in sodium dodecyl sulfate-polyacrylamide gel. In addition to packaging, terminase can also catalyze the endonucleolytic cleavage of lambda cohesive-end site DNA; both of these reactions require ATP. In some preparations, certain terminase fractions of extreme purity require protein factors present in extracts of uninfected Escherichia coli in order to catalyze the cohesive-end site cleavage reaction. On ion exchange columns purified terminase co-chromatographs with a DNA-dependent ATPase activity, hydrolyzing ATP to ADP and Pi in the presence of any of several types of DNA tested including those of non-lambda origin. The molecular weight of the native enzyme is 117,000 and appears to be a hetero-oligomer composed of 2 nonidentical subunits. The most likely composition of terminase is one gpA (gene product of A), Mr = 74,000 and two gpNu1, Mr = 21,000.     

Assembly of the head of bacteriophage P22: X-ray diffraction from heads,proheads and related structures

We have used electron microscopy and small-angle X-ray diffraction to study the three principal structures found in the head assembly pathway of Salmonella phage P22. These structures are, in order of their appearance in the pathway: proheads, unstable filled heads (which lose their DNA and become empty heads upon isolation), and phage. In addition, we can convert proheads to an empty head-like form (the empty prohead) in vitro by treating them with 0.8% sodium dodecyl sulfate at room temperature.We have shown that proheads are composed of a shell of coat protein with a radius of 256 Å, containing within it a thick shell or a solid ball (outer radius 215 Å) of a second protein, the scaffolding protein, which does not appear in phage. The three other structures studied are all about 10% larger than proheads, having outer shells with radii of about 285 Å. Empty heads and empty proheads appear identical by small-angle X-ray diffraction to a resolution of 25 Å, both being shells about 40 Å thick. Phage appear to be made up of a protein shell identical to that in empty heads and empty proheads, within which is packed the DNA.Some details of the DNA packing are also revealed by the diffraction pattern of phage. The inter-helix distance is about 28 Å, and the hydration is about 1.5 g of water per g of DNA. Certain aspects of the pattern suggest that the DNA interacts in a specific mariner with the coat protein subunits on the inside edge of the protein shell.Thus, the prohead-to-head transformation involves, in addition to the loss of an internal scaffold and its replacement by DNA, a structural transition in the outer shell. Diffraction from features of the surface organization in these structures indicates that the clustering of the coat protein does not change radically during the expansion. The fact that the expansion occurs in vitro during the formation of empty proheads shows that it is due to the bonding properties of the coat protein alone, although it could be triggered in vivo by DNA -protein interactions. The significance of the structural transition is discussed in terms of its possible role in the control of head assembly and DNA packaging.     

The bacteriophage P4 alpha gene is the structural gene for bacteriophage P4-induced RNA polymerase

Two temperature-sensitive mutants of satellite phage P4 which do not synthesize P4 DNA at the nonpermissive temperature have been isolated. One of these phage is mutated in the P4 alpha gene. It complements a P4 delta mutant, but not a P4 alpha amber mutant; both mutants are phenotypically identical to alpha amber mutants in all properties studied. They synthesize P4 early proteins 1 and 2 as well as two additional P4-induced early proteins, 5 and 6, which are described here. P4 late proteins are not synthesized by these mutants and cannot be transactivated by helper phage P2. The mutants are unable to transactivate P2 late proteins from a P2 AB mutant. The P4 RNA polymerase activity which has been suggested to be involved in P4 DNA synthesis is not detected at the nonpermissive temperature. The P4 polymerase activity in partially purified extracts prepared from cells infected with the mutant at the permissive temperature is temperature sensitive. Reduced activity is found in vitro when these extracts are preincubated at 41 degrees C or assayed at temperatures higher than 37 degrees C. Thus, the P4 RNA polymerase is the product of the alpha gene. Temperature shift experiments show that the alpha gene product is required until late in the P4 cycle.     

Bacteriophage T4 Head Morphogenesis IV. Comparison of Gene 16-, 17-, and 49-Defective Head Structures2

Defective heads present in extracts of bacteriophage T4 gene 16, 17, or 49 mutant-infected cells have been characterized. All appeared as empty shells when examined by negative-stain electron microscopy and showed essentially the same polypeptide pattern on sodium dodecyl sulfate-acrylamide gels. However, when analyzed by several other methods, gene 16- and 17-defective heads were shown to differ markedly from phage heads present in gene 49-defective extracts. First, the gene 16- and 17-defective structures were found to possess a large number of attached tails (50%, rather than about 5%). Second, they contained less nuclease-resistant deoxyribonucleic acid (DNA) (3 versus 18% of a phage equivalent), had a smaller sedimentation coefficient (240 versus 315S), and a lighter density (1.31 vs. 1.34 g/ml) than gene 49-defective heads. Third, they were not attached to the intracellular DNA pool through a deoxyribonuclease-sensitive linkage. Finally, 8-nm diameter capsomers were clearly revealed on the surface of many gene 16- and 17-defective structures. There was a total of 305 ± 25 capsomers per particle, which yielded an approximate molecular weight of 84 × 10⁶ for these heads. The capsomers were presumably not seen on gene 49-defective heads because of the large amount (18%) of associated DNA.     

Double-Length, Circular, Single-Stranded DNA from Filamentous Phage

Wild-type and gene 3 mutant filamentous phage stocks, containing different relative amounts of multiple-length particles, were treated exhaustively with DNase and then were highly purified. The phage DNA was extracted and examined by electron microscopy. In all cases, about 0.03% of the molecules were circular dimers. (3)H-labeled phage DNA was separated as to size by sedimentation in a preformed CsCl density gradient. Individual fractions were then examined in the electron microscope, and the percentage of linear and circular monomer and dimer DNAs was determined. A peak of double-length, circular molecules (with the expected sedimentation constant of 38S) was found ahead of the 24S monomer peak. The double-length molecules had been purified 65-fold. As previously found for single-stranded DNA, the contour length of these molecules was strongly dependent upon ionic strength. Possible artifacts were ruled out, and it was shown that the double-length molecules arose from phage particles.