Transfection of Escherichia coli Spheroplasts I. General Facilitation of Double-Stranded Deoxyribonucleic Acid Infectivity by Protamine Sulfate

The addition of 25 mug of protamine sulfate per ml to lysozyme-ethylenediamine-tetraacetic acid spheroplasts of Escherichia coli stimulates transfection not only for T1 phage deoxyribonucleic acid (DNA; Hotz and Mauser, 1969) but also for the following phage DNA species: lambda, 10,000-fold to an efficiency of 10(-3) infective centers per DNA molecule; phiX174 replicative form, 300-fold to an efficiency of 5 x 10(-2); fd replicative form, 300-fold to 10(-6); T7, 300-fold to 3 x 10(-7). Three native phage DNA species were not infective at all in the absence of protamine sulfate but were infective in the presence of protamine sulfate with the following efficiencies: T4, 10(-5); T5, 3 x 10(-6); and P22, 3 x 10(-9). The effect of protamine sulfate is specific for double-stranded DNA. The application of infectivity assays to the study of phage DNA replication, recombination, prophage integration, prophage excision, and interspecies transfection are discussed.     

Transfection of Escherichia coli and Salmonella typhimurium Spheroplasts: Host-Controlled Restriction of Infective Bacteriophage P22 Deoxyribonucleic Acid

Under proper conditions, one infective center was obtained for 3 x 10(8) molecules of P22 phage deoxyribonucleic acid (DNA) when lysozyme-ethylenediaminetetraacetic acid spheroplasts of Escherichia coli were transfected in the presence of 25 mug of protamine sulfate per ml. A 3- to 50-fold B-specific and K-specific E. coli restriction of the incoming P22 DNA was observed. When P22 DNA-infected E. coli spheroplasts were plated with infertile r(LT) (+)m(LT) (+)Salmonella typhimurium indicator, an additional 70-fold restriction was observed. In the presence of protamine sulfate, penicillin spheroplasts of S. typhimurium SB1330 could be transfected b P22 DNA with efficiencies sometimes approaching those obtained with the E. coli spheroplasts; thus, facilitation of transfection by protamine sulfate is not limited to E. coli or to lysozyme-ethylenediaminetetraacetic acid spheroplasts. The application of these results to studies of transfection among other genuses and to studies of in vitro host-controlled restriction and modification for the two loci in S. typhimurium and the one locus in E. coli is discussed.     

Transfection of Escherichia coli Spheroplasts II. Relative Infectivity of Native, Denatured, and Renatured Lambda, T7, T5, T4, and P22 Bacteriophage DNAs

The change of infectivity of phage DNAs after heat and alkali denaturation (and renaturation) was measured. T7 phage DNA infectivity increased 4- to 20-fold after denaturation and decreased to the native level after renaturation. Both the heavy and the light single strand of T7 phage DNA were about five times as infective as native T7 DNA. T4 and P22 phage DNA infectivity increased 4- to 20-fold after denaturation and increased another 10- to 20-fold after renaturation. These data, combined with other authors' results on the relative infectivity of various forms of phiX174 and lambda DNAs give the following consistent pattern of relative infectivity. Covalently closed circular double-stranded DNA, nicked circular double-stranded DNA, and double-stranded DNA with cohesive ends are all equally infective and also most highly infectious for Escherichia coli lysozyme-EDTA spheroplasts; linear or circular single-stranded DNAs are about 1/5 to 1/20 as infective; double-stranded DNAs are only 1/100 as infective. Two exceptions to this pattern were noted: lambda phage DNA lost more than 99% of its infectivity after alkaline denaturation; this infectivity could be fully recovered after renaturation. This behavior can be explained by the special role of the cohesive ends of the phage DNA. T5 phage DNA sometimes showed a transient increase in infectivity at temperatures below the completion of the hyperchròmic shift; at higher temperatures, the infectivity was completely destroyed. T5 DNA denatured in alkali lost more than 99.9% of its infectivity; upon renaturation, infectivity was sometimes recovered. This behavior is interpreted in terms of the model of T5 phage DNA structure proposed by Bujard (1969). The results of the denaturation and renaturation experiments show higher efficiencies of transfection for the following phage DNAs (free of single-strand breaks): T4 renatured DNA at 10(-3) instead of 10(-5) for native DNA; renatured P22 DNA at 3 x 10(-7) instead of 3 x 10(-9) for native DNA; and denatured T7 DNA at 3 x 10(-6) instead of 3 x 10(-7) for native DNA.     

Relationship Between Competence for Transfection and for Transformation

Deoxyribonucleic acid (DNA) extracted from phage SPP1 is highly infectious on Bacillus subtilis competent cells; the efficiency of infection is 5 x 10(3) to 6 x 10(3) phage equivalents per plaque-forming unit. This DNA was used to study the relationship between competence for transfection and for transformation. The experiments were concerned with the frequency of infection and transformation in mutants exhibiting different levels of competence, the effect of periodate on competence for infection and for transformation, the competition between phage and bacterial DNA, the transformation of cells preinfected with phage DNA, and the infection of cells pretreated with bacterial DNA. The data show that B. subtilis cells competent for transformation are also competent for transfection and vice versa; transfection with phage DNA represents, therefore, a simple way to measure the total number of competent cells in a culture. The fraction of competent cells, determined by SPP1 DNA infection, varied from 10(-2) to 7 x 10(-2).     

Efficient transfection of the archaebacterium Halobacterium halobium.

We developed an efficient polyethylene glycol-mediated spheroplast transfection method for the extremely halophilic archaebacterium Halobacterium halobium. The 59-kilobase-pair linear phage phi H DNA molecule routinely produced between 5 X 10(6) and 2 X 10(7) transfectants per microgram of DNA. Between 0.5 and 1% of spheroplasts were transfected per microgram of luminal diameter H DNA. Under our conditions, survival and regeneration of H. halobium spheroplasts were also quite efficient, suggesting that this method will be useful for introducing other DNAs into these bacteria.     

Transfection of Mycobacterium smegmatis SN2 with mycobacteriophage I3 DNA

Mycobacterium smegmatis SN2 does not exhibit natural competence for the uptake of phage I3 DNA. Competence can artificially be induced by treatment with glycine or CaCl₂, and the combination of both is even more effective. The efficiency of transfection can be improved by inclusion of protamine sulphate and heterologous RNA in the system. From ³²P DNA uptake studies the major barrier for the entry of DNA has been found to be the complex cell wall. The efficiency of transfection calculated on the basis of fraction of DNA which has entered the cell is comparable to that of other bacterial systems. The phage development takes a longer time (7 h for one cycle) after transfection, as compared to infection (4 h).     

Interaction of the isolated DNA of lambda phage with spheroplasts of E. coli treated with sturine]

The method of centrifugation in sucrose density gradient (30-55%) of the spheroplast membrane preparations treated and untreated with sturine and infected with phage lambda DNA demonstrated that sturine, treatment increased the phage lambda DNA absorption three-fold. About 50% of the lambda DNA molecules adsorbed by spheroplasts are bound with the cytoplasmic membrane of spheroplasts treated with sturine; 50% of the lambda DNA molecules are bound with the cell wall membrane on the sturine-untreated spheroplasts. The data obtained allow to conclude that the stimulating effect of sturine in E. coli spheroplasts transfection by lambda DNA is connected with redistribution of phage DNA absorbed on spheroplasts from the cell wall to the cytoplasmic membrane facilitating the penetration of DNA and its fastening on the membrane.     

Study of the stimulating action of sturin, its fractions, and the internal protein of T2 phage in transfection of E. coli spheroplasts by Lambda phage DNA

The stimulating action of sturin and its fractions in the transfection of E. coli spheroplasts with DNA of phage lambda has been shown, and the optimum conditions for the infection of sturin-treated spheroplasts with phage DNa have been established. The biological effect was most pronounced in arginine-enriched low-molecular sturin fraction B. The treatment of spheroplasts with the internal protein of phage T2 did not stimulate transfection. These findings suggest that the specificity of the stimulating action of protamine depends on the peculiarities of its amino acid composition, viz. a high content of arginine which is present in protein molecules in the form of blocks made up of 2-6 amino acid residues.     

Multiplication of Bacteriophage P22 in Penicillin-Induced Spheroplasts of Salmonella typhimurium

The spheroplasts of Salmonella typhimurium (LT2) prepared by treatment with penicillin were capable of adsorbing phage P22 C(1). The normal multiplication of the phage took place, although the burst size was reduced to one-fourth of that in intact cells. Rate of incorporation of (14)C-thymidine into spheroplasts was increased severalfold on phage infection. Multiplication of C(+) also took place, but no lysogeny could be established in spheroplasts. Furthermore, spheroplasts prepared from cells lysogenized with wild-type phage, LT2 (C(+)), and a temperature-inducible C(2) mutant, LT2(tsC(2)), were not inducible. Unlike normal cells, both mitomycin C and actinomycin D interfered with the phage multiplication in spheroplasts. The spheroplast system offers great advantages in the study of the synthesis of nucleic acids and proteins in phage-infected LT2.     

Transfection of Escherichia coli spheroplasts. VI. Transfection of nonpermissive spheroplasts by T5 and BF23 bacteriophage DNA carrying amber mutations in DNA transfer genes.

DNA was extracted from T5 and BF23 phage carrying amber mutations in genes A2, A1, or D9 and tested for its ability to transfect su minus spheroplasts. DNA from T5 am231, defective in gene A2, transfects Escherichia coli su minus recB minus spheroplasts with an efficiency of 16% of that of wild-type T5 DNA, whereas DNA from T5 am16d or BF23 am57, both defective in gene A1 or its equivalent, transfects E. coli su minus recB minus spheroplasts with an efficiency of 1.4% of that of wild-type T5 DNA, provided E. coli su+ bacteria is used as the indicator in all cases. More than 95% of the progeny from the am231, am16d, and am57 DNA that transfects su minus recB minus spheroplasts is still amber mutant. From these efficiencies of transfection we conclude that the product of gene A2 functions mainly in the mechanism of transfer of phage DNA to intact host cells, and that this function is not essential for transfection of spheroplasts. We also conclude that gene A1 controls functions in addition to DNA transfer, in agreement with previous studies which show that mutations in gene A1 have a pleiotropic effect. Apparently, the absence of these additional functions controlled by gene A1 leads to a high frequency of abortive infection. DNA from amber mutants defective in either gene A1 or A2 does not appreciably transfect su minus rec+ spheroplasts, indicating that the products of these two genes may both be needed to protect T5 DNA from the very active rec BC nuclease in spheroplasts.     

Properties of Infectious T1 Deoxyribonucleic Acid

T1 deoxyribonucleic acid (DNA) infection of spheroplasts was characterized by the following. A small number of the DNA molecules initiated infectious centers, and a small number of the spheroplasts were infected by T1 DNA. Once a favorable encounter of T1 DNA with spheroplast occurred, a minimum of 20 to 30 min was required for T1 DNA to enter the spheroplast. The mature T1 particles produced in the infection of spheroplasts by T1 DNA were released in a burst, but the average burst size was quite small compared with a normal burst of the phage-infected bacteria. T1 DNA preparations, capable of causing viral growth in spheroplasts, did not require detectable amounts of protein for infectivity, were homogeneous in band and boundary sedimentation, and had a guanine plus cytosine content of 48% and a minimal molecular weight of 35 x 10(6). Denatured T1 DNA, like denatured lambdaDNA, did not infect spheroplasts. Renatured T1 DNA was not infectious; this was in marked contrast to renatured lambdaDNA.     

Enhancement of pneumococcal transfection by protamine sulfate.

Protamine sulfate enhanced transfection of Streptococcus pneumoniae by DNA of omega 3 phage by factors as large as 10(5)-fold, provided it was present at the time the cells were added to the DNA. For DNA concentrations well below 1 microgram/ml, the optimum amount of protamine sulfate was near 1 microgram/ml of cells. Higher DNA concentrations required more protamine for maximum effect, and in all cases transfection fell when protamine was in excess. Transformation was not enhanced by low protamine levels and was inhibited by higher levels. A recipient strain with low but finite endonuclease activity and normal transformability showed higher transfection than did the wild type at low DNA concentrations but less than did the wild type at high DNA concentrations. Protamine sulfate enhanced its transfection at low, but not high, DNA concentrations. The behavior of this strain and the enhancement of transfection by protamine sulfate of wild-type cells were each consistent with less cutting of the donor DNA at the cell surface, which is part of the normal entry process in naturally competent gram-positive bacteria. Less cutting would lead to entry of fewer but longer strands that would be more efficient in reconstruction of the 33-megadalton phage replicon. We suggest that in this system protamine enhances transfection by inhibition of the surface nuclease action that is part of the normal entry process.     

Transfection of Staphylococcus aureus with Bacteriophage Deoxyribonucleic Acid

Staphylococcus aureus cells of strain 8325 (N) are competent for phage deoxyribonucleic acid (DNA) when harvested in the early exponential growth phase. Phenotypic expression of the competence requires divalent cations, and calcium ions are most effective. Treatment of phage DNA with deoxyribonuclease completely destroys infectivity and heat-denaturated DNA is not infectious. The highest frequency of transfection is around 10(4) plaque-forming units per mug of DNA.     

Factors Affecting Transfection in Bacillus stearothermophilus

The conditions for the infection of Bacillus stearothermophilus 4S with TP-1C phage deoxyribonucleic acid (DNA) are described. Cells from log-phase cultures are the most susceptible to phage DNA infection (transfection). A cellular component (competence factor) which enhances transfection is released into the culture medium during the transition period between the log and stationary phase of growth. Transfection is stimulated in the order of decreasing effectiveness, by Fe(3+), Mn(2+), and Mg(2+). The efficiency of transfection is the highest in cells growing at 60.5 C and does not occur in cells growing at 67 C although the cells are growing normally. A cellular component (competence factor) of this organism, which is released into the culture medium, advances by 40 min some step in the uptake of phage DNA.     

Frequency of infection and efficiency of transfection of Rhizobium meliloti cells and spheroplasts.

Competent cultures of Rhizobium meliloti cells and spheroplasts obtained by various methods were infected with DNA of phage 1A. The Frequency of infection among the cells and spheroplasts was 2 X 10(-8)-5 X 10(-10). The efficiency of transfection calculated from the ratio of plaque forming units to infective DNA molecule of phage 1A was 5 X 10(-8) to 10(-10). Frequency of infection and efficiency of transfection among the competent cells were by one order of magnitude higher in the case of the spheroplasts. The use of various media did not noticeably alter the efficiency of transfection.     

Infectious DNA from coliphage T1

Summary Infectious DNA from phage T1 was inactivated by UV-light (2,537 Å). No effect of irradiation on the kinetics of the assay in a spheroplast system could be observed. UV-damaged molecules compete with unirradiated DNA for the infection. Infectious T1-DNA is subject to host-cell reactivation of UV-damage, the amount of which depends on the physiological conditions of the spheroplasts. Though UV-radiosensitivity of T1 particles is not influenced by the presence of the radical scavenging compound cysteamine, infectious DNA can be protected effectively by this chemical (0.01M) against UV-damage when HCR-negative spheroplasts are used for the assay. Incorporation of 5-bromouracil radiosensitizes infectious T1-DNA in the presence and absence of HCR. This effect can be eliminated when the DNA is irradiated in the presence of cysteamine. The mechanism of radioprotection is discussed.     

Synthesis of Protein and Nucleic Acid by Disrupted Spheroplasts of Pseudomonas schuylkilliensis

Osmotically shocked spheroplasts obtained from Pseudomonas schuylkilliensis strain P contained about 54, 32, 28, and 82% of the total cellular protein, ribonucleic acid (RNA), deoxyribonucleic acid (DNA), and phospholipid, respectively. This preparation was capable of incorporating (32)P-orthophosphate into RNA and DNA, (3)H-adenosine or (3)H-uridine into RNA, and (3)H-leucine or (14)C-phenylalanine into protein. These activities were not found in the cytoplasmic fraction which contained most of the glucose-6-phosphate dehydrogenase activity. The synthesis of RNA by intact and disrupted spheroplast preparations was sensitive to actinomycin D, chromomycin A(3), streptovaricin, rifampin, Lubrol W, Triton X-100, and sodium deoxycholate, whereas RNA synthesis by intact cells was insensitive to these agents. Ethylenediaminetetraacetic acid, porcine pancreatic lipase, the protoplast-bursting factor, high concentrations of salts, and washing the preparation inhibited the synthesis of RNA by disrupted spheroplasts but had little or no effect on intact spheroplasts. Most of the newly synthesized RNA made by disrupted spheroplasts had the characteristics of messenger RNA. The DNA present in this preparation functioned as a template for RNA synthesis; continued protein synthesis was dependent on concomitant RNA synthesis. An unusual feature of the preparation was the finding that the synthesis of macromolecules was completely dependent on oxidative phosphorylation.     

Isolation of Blue-Green Algal Spheroplasts by Penicillin-Lysozyme Method

Osmotic stabilizer used in present study consists of eight compounds, i.e. ammonium sulfate, ammonium tertrate, KH2PO4, sodium citrate, NH4NO3, NaNO3, KC1 and NaCl. Each of them was dissolved in to 0.5 mol then eight solutions were mixed in equal volume. A menbrane stabilizer CaC12(0.1%) was added to the mixed solution. The pH of the mixed solution was about 6.2. Blue-green algal trichomes for the spheroplast isolation were first treated with penicillin. Penicillin dosage and treating time were different according to different materials. After penicillin procedure, the materials were then treated with lysozyme (0.2%). Temperature of the treatment was 28–30℃, Spheroplast production started in 15 minutes after treatment and finished in 3 hours. The spheroplasts remained a chain form mostly and became single spheroi. d through centrifugation and resuspension. The spheroplasts were typical spherical, more transparent and sensitive to hypotonic condition or mechanical treatment.     

Transfection of Escherichia coli Spheroplasts IV. Transfection of rec+ and rec? Spheroplasts by Native,Denatured, and Renatured T5 Bacteriophage DNA After Repair of Single-Strand Breaks by Polynucleotide Ligase

Transfection of Escherichia coli spheroplasts by native T5 phage DNA was not affected by treatment with polynucleotide ligase. Denatured T5 phage DNA infectivity, only 0.1% of the native DNA level, was increased slightly by polynucleotide ligase treatment. Renatured T5 phage DNA infectivity was also increased slightly by polynucleotide ligase treatment. To form an infective center with rec(+) spheroplasts, 1.6 to 2.1 native T5 phage DNA molecules were required; however, 1.4 T5 phage DNA molecules were required to form an infective center with recA(-)B(-) spheroplasts, and one molecule was sometimes sufficient for rec B(-) spheroplasts. Polynucleotide ligase treatment of T5 phage DNA had no effect on these parameters. Thus, the single-strand interruptions of T5 phage DNA are probably not essential to the survival of the parental T5 phage DNA, and T5 phage DNA, especially the denatured form, is highly sensitive to some nucleases in E. coli spheroplasts.     

Transfection in Pneumococcus: Single-Strand Intermediates in the Formation of Infective Centers

Transfection has been found and characterized in pneumococcus. For replicating omega3 phage DNA extracted from infected cells, transfection was relatively efficient and rose linearly with DNA concentration and quadratically with time, according to T(T - 3.5) min(2). For mature DNA extracted from phage particles, transfection was hardly detectable below 1 mug/ml but increased about as the cube of the DNA concentration up to 100 mug/ml, and was still rising at concentrations over 200 mug/ml. The kinetics suggest a dependence on a mixed cubic function of the time of exposure of cells to mature DNA. Cell and phage DNAs competed with each other for transformation and transfection. Transfection was reduced much more strongly than transformation in cells that were deficient in the membrane-bound endonuclease required for conversion of donor duplex DNA to intracellular single strands; these data agree with the kinetic data in implying that independent entry of segments of two strands is necessary for transfection by replicating omega3 phage DNA and entry of at least three strands is necessary for transfection by mature DNA. To reconcile differing DNA concentration dependences of transfection and transformation with a common entry path, it was necessary to reexamine data on transformation and to recognize that this process continued to rise slowly through the concentration region usually described as "plateau." These results and the transfection data reflect multiple binding and nicking events that occurred on the cell surface before entry. Our conclusion is that transfection in pneumococcus occurs by association inside the cell of segments of single strands of phage DNA that have entered independently, creating gapped structures that need repair synthesis to create infective centers. Physical recombination is therefore automatically a prerequisite to transfection.