Infectious DNA from coliphage T1

Summary DNA isolated from coliphage T1 is infective in spheroplasts of E. coli K12/1. The efficiency of the assay amounts to approximately 10^-4 plaque-forming units per DNA molecule of 32·10⁶ daltons. A linear relationship between DNA concentration and total phage yield or infective centers, respectively, holds for native DNA. For heat-treated DNA, however, the co-operation of 1.4 molecules is required for successful infection. Beyond a critical concentration of about 0.1g/ml a self-inhibiting effect of infectious T1-DNA is observed. Breakage by shearing and denaturation of the DNA-molecules destroy their infectious activity. Renaturation, however, restores infectivity to 60–90 per cent of the original activity. Heat treatment of T1-DNA in M/5 NCE buffer results in narrow-coiled, mismatched molecules with partially denatured regions. Though the efficiency of infection of such molecules is reduced by about 30 per cent, the critical concentration of T1-DNA shifts to higher values by a factor of ten, thus giving an increase in the total plaque yield of the system. The effect is explained by the transition of native into narrow-coiled molecular configuration.     

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.     

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 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.     

UV-sensitivity and UV-mutability of infectious lambdaDNA: reactivation, protection and mutability in various assay systems

Summary The UV-sensitivity of phage and its infectious DNA have been compared in experiments involving infection of normal cells by phage and transfection of lysozyme-EDTA spheroplasts or Ca⁺⁺-treated cells by phage DNA. It is shown that UV-irradiated DNA undergoes extensive HCR. Since intact phage and free phage DNA have the same survival after UV-irradiation in Hcr^- spheroplasts and cells, resp., and since survival is also identical in Ca⁺⁺-treated Hcr⁺ cells it is concluded that DNA in solution or packaged in the phage head provides the same target for the induction of lethal UV lesions. This conclusion is supported by the observation that cysteamine provides a similar radioprotection to the intact phage and its free DNA. Spheroplasts of Hcr⁺ cells, however, have an HCR capacity reduced by about 20% when compared with normal or Ca⁺⁺-treated cells. Moreover, UV-reactivation of irradiated DNA, which is absent in spheroplasts, occurs efficiently in Ca⁺⁺-treated cells. Possible reasons for the physiological difference between spheroplasts and normal cells are discussed. c-mutations, which are readily induced by UV in phage assayed with E. coli mul ^-, could not be induced in DNA when assayed with spheroplasts or Ca⁺⁺-treated cells of this strain. No mutants were also found with DNA extracted from UV-irradiated phage. The significance of the mode of entry of UV-irradiated DNA into a cell for the production of mutations is discussed.     

Transforming activity of phage T4r+ DNA, treated with ultraviolet light, nitrous acid, hydroxylamine and visible light in the presence of methylene blue]

The efficiency of phages T4rIIB-638v+ and T4rIIB-638v- transformation by native and denatured DNA treated with UV, nitrous acid, hydroxylamine and visible light in the presence of methylene blue is studied. A greater transformation efficiency of UV-irradiated T4r+ phage native and denatured DNA was observed in the v+ recipient as compared with v- recipients. Denatured donor DNA treated with nitrous acid has higher transformation activity in spheroplasts infected with T4v+ phage than in those infected with T4v- phage. Native donor DNA, treated with methylene blue and visible light-irradiated, developed a decrease of the transformation activity in T4v- phage-infected spheroplasts as compared with T4v+ phage-infected spheroplasts. Hydroxylamine treatment of native and denatured donor DNA did not reveal any differences in the transforming activity for v+ and v- recipients. Denatured donor DNA was more resistant to the effect of hydroxylamine than native DNA.     

T2 DNA, modified by 2,2,6,6-tetramethyl-4-bromoacetooxypiperidine-i-oxyl as a template for RNA polymerase from E. coli B]

T2-DNA was modified by 2,2,6,6-tetramethyl-4-bromoacetooxypiperidine-1-oxyl (I) at different NaCl concentrations (10(-1) M NaCl--10(-4) M NaCl). Modified DNA were investigated as templates for the RNA-polymerase from E. coli B. It was shown that T2-DNA modified I in 0,1 M NaCl completely preserves the native secondary structure, has a low degree modification (1 molecule I per 1000-2000 nucleotide pairs), but is a noneffective template for the RNA-polymerase from E. coli B (20%-40% as compared with unmodified T2-DNA). Under these conditions the modification occurs probably at the "weakest" (readily melting) sites of DNA. The role of these "weak" sites on DNA as promotors is discussed. The modification of T2-DNA by reagnet I has a stronger inhibitory effect on the total RNA synthesis than on the RNA-synthesis stable to rifampicin. Possible existence of two kinds of "early" promotors on T2-DNA is assumed.     

Generation of glucocorticoid-responsive Moloney murine leukemia virus by insertion of regulatory sequences from murine mammary tumor virus into the long terminal repeat.

The glucocorticoid-regulatory sequences from the murine mammary tumor virus long terminal repeat (MMTV LTR) were introduced into the LTR of Moloney murine leukemia virus (M-MuLV) by recombinant DNA techniques. The site of insertion was in the M-MuLV LTR U3 region at -150 base pairs with respect to the RNA cap site. Infectious M-MuLVs carrying the altered LTRs (Mo + MMTV M-MuLVs) were recovered by transfection of proviral clones into NIH-3T3 cells. The Mo + MMTV M-MuLVs were hormonally responsive in that infection was 3 logs more efficient when performed in the presence of dexamethasone, irrespective of the orientation of the inserted MMTV sequences. However, even in the presence of hormone, the Mo + MMTV M-MuLVs were less infectious than wild-type M-MuLV. In contrast to the large effect on infectivity, dexamethasone induced virus-specific RNA levels in chronically Mo + MMTV M-MuLV-infected cells only two- to fourfold. Fusion plasmids between the altered LTRs and the bacterial chloramphenicol acetyltransferase gene allowed the investigation of LTR promoter strength by the transient chloramphenicol acetyltransferase expression assay. The chloramphenicol acetyltransferase assays indicated that the insertion of MMTV sequences into the M-MuLV LTR reduced promoter activity in the absence of glucocorticoids but that promoter activity could be induced two- to fivefold by dexamethasone. The Mo + MMTV M-MuLVs were also tested for the possibility that viral DNA synthesis or integration during initial infection was enhanced by dexamethasone. However, no significant difference was detected between cultures infected in the presence or absence of hormone. The insertion of MMTV sequences into an M-MuLV LTR deleted of its enhancer sequences did not yield infectious virus or active promoters, even in the presence of dexamethasone.     

Crystal structure of the coat protein of the flexible filamentous papaya mosaic virus

The terminase motors of bacteriophages have been shown to be among the strongest active machines in the biomolecular world, being able to package several tens of kilobase pairs of viral genome into a capsid within minutes. Yet, these motors are hindered at the end of the packaging process by the progressive buildup of a force-resisting packaging associated with already packaged DNA. In this experimental work, we raise the issue of what sets the upper limit on the length of the genome that can be packaged by the terminase motor of phage λ and still yield infectious virions and the conditions under which this can be efficiently performed. Using a packaging strategy developed in our laboratory of building phage λ from scratch, together with plaque assay monitoring, we have been able to show that the terminase motor of phage λ is able to produce infectious particles with up to 110% of the wild-type λ-DNA length. However, the phage production rate, and thus the infectivity, decreased exponentially with increasing DNA length and was a factor of 10(3) lower for the 110% λ-DNA phage. Interestingly, our in vitro strategy was still efficient in fully packaging phages with DNA lengths as high as 114% of the wild-type length, but these viruses were unable to infect bacterial cells efficiently. Further, we demonstrated that the phage production rate is modulated by the presence of multivalent ionic species. The biological consequences of these findings are discussed.     

Detection of infectious agents in heart valves during endocarditis using PCR technique

Infectious endocarditis can be caused by various microorganisms. Diagnostics of local infection by microbiological methods is not always effective. For that reason we performed a study aimed for direct detection of potential infectious agents by polymerase chain reaction in patients' heart valve tissue. DNA of infectious agents was revealed in 72% of heart valve tissue samples from patients with septic endocarditis; in studied samples, along with bacterial DNA, herpesviruses' DNA was detected. Obtained results confirm the presence of infection, which allows to perform specific diagnostics of infectious complications after implantation of prosthetic cardiac valves.     

Quantitative competitive-PCR assay to measure human parvovirus B19-DNA load in serum samples

The B19 virus can persist in immunocompromised patients for several months and sometimes even years because of impaired immune response. Viremia in persistent and recurrent infection may range from very low to high titers and may be associated with chronic clinical manifestations, such as chronic anemia. Several recently developed techniques that quantify B19-DNA have improved laboratory diagnosis of the infection and can help guide the choice of treatment in persistent infections (i.e., intravenous immunoglobulin (IVIG) treatment vs immunosuppression reduction). Here we describe the development of a reliable internally controlled quantitative competitive (QC)-polymerase chain reaction (PCR) assay that measures B19-DNA load in serum samples by densitometric analysis of the amplification products for monitoring B19 infection in high-risk patients. A retrospective quantification of B19-DNA in the serum samples from 48 anemic transplanted patients by the QC-PCR assay we developed in our laboratory confirmed the presence of B19-DNA in 11 of 48 samples and showed a viral DNA load between 10³ and 10⁸ B19-DNA copies/mL depending on the patients' serostatus (the highest viral load was found in IgM-positive/IgG-negative patients that is, in patients with active B19 infection at onset). The assay also confirmed B19-DNA negative patients. Our QC-PCR assay may be easily relation between active B19 infection and occurrence of anemia and to assess the efficacy of IVIG therapy or immunosuppression reduction in clearing the virus in high-risk patients.     

Sealing of chromosomal DNA nicks during nucleotide excision repair requires XRCC1 and DNA ligase III alpha in a cell-cycle-specific manner

Impaired gap filling and sealing of chromosomal DNA in nucleotide excision repair (NER) leads to genome instability. XRCC1-DNA ligase IIIalpha (XRCC1-Lig3) plays a central role in the repair of DNA single-strand breaks but has never been implicated in NER. Here we show that XRCC1-Lig3 is indispensable for ligation of NER-induced breaks and repair of UV lesions in quiescent cells. Furthermore, our results demonstrate that two distinct complexes differentially carry out gap filling in NER. XRCC1-Lig3 and DNA polymerase delta colocalize and interact with NER components in a UV- and incision-dependent manner throughout the cell cycle. In contrast, DNA ligase I and DNA polymerase varepsilon are recruited to UV-damage sites only in proliferating cells. This study reveals an unexpected and key role for XRCC1-Lig3 in maintenance of genomic integrity by NER in both dividing and nondividing cells and provides evidence for cell-cycle regulation of NER-mediated repair synthesis in vivo.     

Platinum determination in cis-dichlorodiammineplatinum(II)-DNA complexes by differential pulse polarography

A simple polarographic assay for platinum determination in cis-dichlorodiammineplatinum(II)-DNA complexes is described. The method makes it possible to determine the free (unbound) drug in the presence of DNA or platinum-DNA complex, i.e., without a separation of free drug and macromolecular components of the solution to be analyzed. This method is based on the polarographic activity of intact cis-dichlorodiammineplatinum(II) at ?1.5 V, which can be measured by differential pulse polarography even in the presence of DNA or platinum-DNA complex. The lower level of analytical utility of this method is ca. 1 × 10^?6m (195 ng of platinum/ml).     

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.     

Molecular beacons for isothermal fluorescence enhancement by the cleavage of RNase HII from Chlamydia pneumoniae

This article describes a new assay for isothermal enhancement of fluorescence intensity. The assay is based on the cleavage of duplexes formed by the chimeric DNA-rN(1)-DNA molecular beacon (cMB) and target DNA with Chlamydia pneumoniae RNase HII (CpRNase HII). The loop sequence of the cMB, which was designed according to the target sequence, contains a single ribonucleotide. The combination of CpRNase HII cleavage and cMB (RHMB) permitted a 90-fold increase in fluorescence intensity change compared with the hybridization reaction in the presence of the same amount of target DNA. These results indicate that the RHMB assay can enhance the fluorescence signal in real-time monitoring of the target DNA.     

Characterization of G-quadruplex antibody reveals differential specificity for G4 DNA forms

Accumulating evidence suggests that human genome can fold into non-B DNA structures, when appropriate sequence and favourable conditions are present. Among these, G-quadruplexes (G4-DNA) are associated with gene regulation, chromosome fragility and telomere maintenance. Although several techniques are used in detecting such structures in vitro, understanding their intracellular existence has been challenging. Recently, an antibody, BG4, was described to study G4 structures within cells. Here, we characterize BG4 for its affinity towards G4-DNA, using several biochemical and biophysical tools. BG4 bound to G-rich DNA derived from multiple genes that form G-quadruplexes, unlike complementary C-rich or random sequences. BLI studies revealed robust binding affinity (K_d = 17.4 nM). Gel shift assays show BG4 binds to inter- and intramolecular G4-DNA, when it is in parallel orientation. Mere presence of G4-motif in duplex DNA is insufficient for antibody recognition. Importantly, BG4 can bind to G4-DNA within telomere sequence in a supercoiled plasmid. Finally, we show that BG4 binds to form efficient foci in four cell lines, irrespective of their lineage, demonstrating presence of G4-DNA in genome. Importantly, number of BG4 foci within the cells can be modulated, upon knockdown of G4-resolvase, WRN. Thus, we establish specificity of BG4 towards G4-DNA and discuss its potential applications.     

In vivo effects of recBC DNase, exonuclease I, and DNA polymerases of Escherichia coli on the infectivity of native and single-stranded DNA of bacteriophage T7.

The effect of several enzymes of the DNA metabolism of Escherichia coli on the biological activity of native and single-stranded T7 DNA was studied by transfection of lysozyme-EDTA spheroplasts prepared from various E. coli mutants. It is shown that the presence of the recBC DNase in the recipient cells decreases the infectivity of native and denatured DNA by about 100- and 10-fold, respectively. Lack of exonuclease I did not stimulate transfection by single-stranded DNA. Separated light (l) and heavy (r) strands of T7 DNA are fully infective, with a linear dependence on DNA concentrations, whereas heat-denatured DNA shows a two-hit kinetics. Single-stranded DNA was observed to depend on a functional DNA polymerase III for infectivity in polAB cells, whereas transfection with native T7 DNA was independent of the host DNA polymerases. The results are discussed with respect to the mode of T7 DNA replication.     

Size of infectious DNA from human and murine cytomegaloviruses.

Viral DNA was isolated from human and murine cytomegalovirus by equilibrium centrifugation in cesium chloride gradients. The size of the DNA was measured relative to T4 DNA by velocity sedimentation in neutral glycerol gradients, and fractions were assayed for infectious DNA. Infectious murine cytomegalovirus DNA sedimented as a single peak with an estimated molecular weight of 136 X 10(6). Infectious human cytomegalovirus DNA was detected in two peaks with molecular weights of 130 X 10(6) and 150 X 10(6).     

TRF1 inhibits telomere C-strand DNA synthesis in vitro

Human TTAGGG repeat-binding factor 1 (TRF1) is involved in the regulation of telomere length in vivo, but the mechanism of regulation remains largely undefined. We have developed an in vitro system for assessing the effect of TRF1 on DNA synthesis using purified proteins and synthetic DNA substrates. Results reveal that TRF1, when bound to telomeric duplex DNA, inhibits DNA synthesis catalyzed by DNA polymerase alpha/primase (pol alpha). Inhibition required that TRF1 be bound to duplex telomeric DNA as no effect of TRF1 was observed on nontelomeric, random DNA substrates. Inhibition was shown to be dependent on TRF1 concentration and the length of the telomeric duplex region of the DNA substrate. When bound in cis to telomeric duplex DNA, TRF1 was also capable of inhibiting pol alpha-catalyzed DNA synthesis on nontelomeric DNA sequences from positions both upstream and downstream of the extending polymerase. Inhibition of DNA synthesis was shown to be specific for TRF1 but not necessarily for the DNA polymerase used in the extension reaction. In a series of control experiments, we assessed T7 DNA polymerase-catalyzed synthesis on a DNA template containing tandem gal4 operators. In these experiments, the addition of the purified Gal4-DNA binding domain (Gal4-DBD) protein has no effect on the ability of T7 polymerase to copy the DNA template. Interestingly, TRF1 inhibition was observed on telomeric DNA substrates using T7 DNA polymerase. These results suggest that TRF1, when bound to duplex telomeric DNA, serves to block extension by DNA polymerases. These results are discussed with respect to the role of TRF1 in telomere length regulation.