Nucleotide sequence specificity of restriction endonucleases

Discovering DNA Methylation, the History and Future of the Writing on DNA

DNA methylation is a quintessential epigenetic mechanism. Widely considered a stable regulator of gene silencing, it represents a form of "molecular braille," chemically printed on DNA to regulate its structure and the expression of genetic information. However, there was a time when methyl groups simply existed in cells, mysteriously speckled across the cytosine building blocks of DNA. Why was the code of life chemically modified, apparently by "no accident of enzyme action" (Wyatt 1951)? If all cells in a body share the same genome sequence, how do they adopt unique functions and maintain stable developmental states? Do cells remember? In this historical perspective, I review epigenetic history and principles and the tools, key scientists, and concepts that brought us the synthesis and discovery of prokaryotic and eukaryotic methylated DNA. Drawing heavily on Gerard Wyatt's observation of asymmetric levels of methylated DNA across species, as well as to a pair of visionary 1975 DNA methylation papers, 5-methylcytosine is connected to DNA methylating enzymes in bacteria, the maintenance of stable cellular states over development, and to the regulation of gene expression through protein-DNA binding. These works have not only shaped our views on heritability and gene regulation but also remind us that core epigenetic concepts emerged from the intrinsic requirement for epigenetic mechanisms to exist. Driven by observations across prokaryotic and eukaryotic worlds, epigenetic systems function to access and interpret genetic information across all forms of life. Collectively, these works offer many guiding principles for our epigenetic understanding for today, and for the next generation of epigenetic inquiry in a postgenomics world.

The Dawn of Plant Molecular Biology: How Three Key Methodologies Paved the Way

The adoption of Arabidopsis thaliana in the 1980s as a universal plant model finally enabled researchers to adopt and take full advantage of the molecular biology tools and methods developed in the bacterial and animal fields since the early 1970s. It further brought the plant sciences up to speed with other research fields, which had been employing widely accepted model organisms for decades. In parallel with this major development, the concurrent establishment of the plant transformation methodology and the description of the cauliflower mosaic virus (CaMV) 35S promoter enabled scientists to create robust transgenic plant lines for the first time, thereby providing a valuable tool for studying gene function. The ability to create transgenic plants launched the plant biotechnology sector, with Monsanto and Plant Genetic Systems developing the first herbicide- and pest-tolerant plants, initiating a revolution in the agricultural industry. Here I review the major developments over a less than 10-year span and demonstrate how they complemented each other to trigger a revolution in plant molecular biology and launch an era of unprecedented progress for the whole plant field. © 2022 The Authors. Current Protocols published by Wiley Periodicals LLC.

In vitro Type II Restriction of Bacteriophage DNA With Modified Pyrimidines

To counteract host-encoded restriction systems, bacteriophages (phages) incorporate modified bases in their genomes. For example, phages carry in their genomes modified pyrimidines such as 5-hydroxymethyl-cytosine (5hmC) in T4gt deficient in α- and β-glycosyltransferases, glucosylated-5-hydroxymethylcytosine (5gmC) in T4, 5-methylcytosine (5mC) in Xp12, and 5-hydroxymethyldeoxyuridine (5hmdU) in SP8. In this work we sequenced phage Xp12 and SP8 genomes and examined Type II restriction of T4gt, T4, Xp12, and SP8 phage DNAs. T4gt, T4, and Xp12 genomes showed resistance to 81.9% (186 out of 227 enzymes tested), 94.3% (214 out of 227 enzymes tested), and 89.9% (196 out of 218 enzymes tested), respectively, commercially available Type II restriction endonucleases (REases). The SP8 genome, however, was resistant to only ∼8.3% of these enzymes (17 out of 204 enzymes tested). SP8 DNA could be further modified by adenine DNA methyltransferases (MTases) such as M.Dam and M.EcoGII as well as a number of cytosine DNA MTases, such as CpG methylase. The 5hmdU base in SP8 DNA was phosphorylated by treatment with a 5hmdU DNA kinase to achieve ∼20% phosphorylated 5hmdU, resulting resistance or partially resistant to more Type II restriction. This work provides a convenient reference for molecular biologists working with modified pyrimidines and using REases. The genomic sequences of phage Xp12 and SP8 lay the foundation for further studies on genetic pathways for 5mC and 5hmdU DNA base modifications and for comparative phage genomics.

Type I restriction systems: sophisticated molecular machines (a legacy of Bertani and Weigle)

Restriction enzymes are well known as reagents widely used by molecular biologists for genetic manipulation and analysis, but these reagents represent only one class (type II) of a wider range of enzymes that recognize specific nucleotide sequences in DNA molecules and detect the provenance of the DNA on the basis of specific modifications to their target sequence. Type I restriction and modification (R-M) systems are complex; a single multifunctional enzyme can respond to the modification state of its target sequence with the alternative activities of modification or restriction. In the absence of DNA modification, a type I R-M enzyme behaves like a molecular motor, translocating vast stretches of DNA towards itself before eventually breaking the DNA molecule. These sophisticated enzymes are the focus of this review, which will emphasize those aspects that give insights into more general problems of molecular and microbial biology. Current molecular experiments explore target recognition, intramolecular communication, and enzyme activities, including DNA translocation. Type I R-M systems are notable for their ability to evolve new specificities, even in laboratory cultures. This observation raises the important question of how bacteria protect their chromosomes from destruction by newly acquired restriction specifities. Recent experiments demonstrate proteolytic mechanisms by which cells avoid DNA breakage by a type I R-M system whenever their chromosomal DNA acquires unmodified target sequences. Finally, the review will reflect the present impact of genomic sequences on a field that has previously derived information almost exclusively from the analysis of bacteria commonly studied in the laboratory.

p53 mutations, methylation and genomic instability in the progression of chronic myeloid leukaemia

In chronic myeloid leukaemia (CML), as with other tumour types, mutations of the p53 gene are associated with disease progression. Changes in regional methylation of DNA with CML tumour development have also been demonstrated. Methylation is one mechanism by which gene expression is controlled and the CpG sites, which are the targets of DNA methylation, are also the sites of a number of the mutations found in the p53 gene. Cells harbouring mutant p53 have been shown to accumulate further genomic and genetic aberrations and methylation which alters the conformation of DNA is also believed to play a role in genomic stability. There appears to be an interplay between p53 deregulation and changing methylation patterns with the progression of CML. The cause and effect of changes in both of these critical gene regulating, DNA repair and genomic stability factors and their deviation during the progression of CML will be discussed.

The human genome project: genetic and physical mapping

The modern tools of molecular biology, recombinant DNA techniques, have given scientists the ability to isolate and study individual genes from even complex eukaryotic genomes. The availability of genes enables the study o f their structure and biologic function, and their role in normal and abnormal physiologic processes. A worldwide effort to study and understand the entire human genome is under way, which will result in information on the location of all genes, their sequences, and their complex regulation and interactions. As this knowledge becomes available, it will be rapidly applied to the practice of medicine through use in the development of diagnostic tests for genetic-based diseases and in the development of therapeutics.

The human genome project

The Human Genome Project in the United States is now well underway. Its programmatic direction was largely set by a National Research Council report issued in 1988. The broad framework supplied by this report has survived almost unchanged despite an upheaval in the technology of genome analysis. This upheaval has primarily affected physical and genetic mapping, the two dominant activities in the present phase of the project. Advances in mapping techniques have allowed good progress toward the specific goals of the project and are also providing strong corollary benefits throughout biomedical research. Actual DNA sequencing of the genomes of the human and model organisms is still at an early stage. There has been little progress in the intrinsic efficiency of DNA-sequence determination. However, refinements in experimental protocols, instrumentation, and project management have made it practical to acquire sequence data on an enlarged scale. It is also increasingly apparent that DNA-sequence data provide a potent means of relating knowledge gained from the study of model organisms to human biology. There is as yet little indication that the infusion of technology from outside biology into the Human Genome Project has been effectively stimulated. Opportunities in this area remain large, posing substantial technical and policy challenges.

Recombinant DNA and gene isolation

Although a formidable array of approaches fall under the broad umbrella of molecular genetics, the basic technology is elegant and conceptually simple (Watson et al. 1983, Roberts et al. 1992). It has enabled a reductionist approach to be applied to the study of genes and their sequences, as well as the transcripts that underlie organ development and function. Cardiovascular research has, in the past, utilized the systemic and integrative approaches that are inherent in the study of an organ system. Molecular genetics and recombinant DNA offer the cardiologist a complementary focus, as both normal and abnormal heart functions can be defined in terms of the underlying genetic complement and its regulation. One can approach heart function in terms of defining the basic components that participate in the developmental and functional processes of the heart at different developmental times. A future challenge will be to integrate the information regarding these different components with the heart's function in an intact biological system.

The corrected nucleotide sequences of the TaqI restriction and modification enzymes reveal a thirteen-codon overlap

The nucleotide sequence of the genes encoding methyltransferase TaqI (M.TaqI) and restriction endonuclease TaqI (R.TaqI) with the recognition sequence, TCGA, were analyzed in clones isolated from independent libraries. The genes, originally reported as 363 and 236 codons long [Slatko et al., Nucleic Acids Res. 15 (1987) 9781-9796] were redetermined as 421 and 263 codons long, respectively. The C terminus of the taqIM gene overlaps the N terminus of the taqIR gene by 13 codons, as observed with the isoschizomeric TthHB8I restriction-modification system [Barany et al., Gene 112 (1992) 13-20]. Removal of the overlapping codons did not interfere with in vivo M.TaqI activity. We postulate the overlap plays a role in regulating taqIR expression.

Cloning and sequencing of genes encoding the TthHB8I restriction and modification enzymes: comparison with the isoschizomeric TaqI enzymes

Genes encoding the TthHB8I restriction and modification (R-M) system from Thermus thermophilus HB8 (recognition sequence T decreases CGA) were cloned in Escherichia coli. The genes have the same transcriptional orientation, with the last 13 codons of the methyltransferase (MTase) overlapping the first 13 codons of the endonuclease (ENase). Nucleotide sequence analysis of the TthHB8I ENase revealed a single chain of 263 amino acid (aa) residues that share a 77% identity with the corrected isoschizomeric TaqI ENase. Likewise, the Tth MTase (428 aa) shares a 79% identity with the corrected sequence of the TaqI MTase. This high degree of aa conservation suggests a common origin between the Taq and Tth R-M systems. However, codon usage and G+C content for the R-M genes differed markedly from that of other cloned Thermus genes. This suggests that these R-M genes were only recently introduced into the genus Thermus.

Theory of molecular machines. II. Energy dissipation from molecular machines

Single molecules perform a variety of tasks in cells, from replicating, controlling and translating the genetic material to sensing the outside environment. These operations all require that specific actions take place. In a sense, each molecule must make tiny decisions. To make a decision, each "molecular machine" must dissipate an energy Py in the presence of thermal noise Ny. The number of binary decisions that can be made by a machine which has dspace independently moving parts is the "machine capacity" Cy = dspace log2 [(Py + Ny)/Ny]. This formula is closely related to Shannon's channel capacity for communications systems, C = W log2 [(P + N)/N]. This paper shows that the minimum amount of energy that a molecular machine must dissipate in order to gain one bit of information is epsilon min = kB T ln (2) joules/bit. This equation is derived in two distinct ways. The first derivation begins with the Second Law of Thermodynamics, which shows that the statement that there is a minimum energy dissipation is a restatement of the Second Law of Thermodynamics. The second derivation begins with the machine capacity formula, which shows that the machine capacity is also related to the Second Law of Thermodynamics. One of Shannon's theorems for communications channels is that as long as the channel capacity is not exceeded, the error rate may be made as small as desired by a sufficiently involved coding. This result also applies to the dissipation formula for molecular machines. So there is a precise upper bound on the number of choices a molecular machine can make for a given amount of energy loss. This result will be important for the design and construction of molecular computers.

Theory of molecular machines. I. Channel capacity of molecular machines

Like macroscopic machines, molecular-sized machines are limited by their material components, their design, and their use of power. One of these limits is the maximum number of states that a machine can choose from. The logarithm to the base 2 of the number of states is defined to be the number of bits of information that the machine could "gain" during its operation. The maximum possible information gain is a function of the energy that a molecular machine dissipates into the surrounding medium (Py), the thermal noise energy which disturbs the machine (Ny) and the number of independently moving parts involved in the operation (dspace): Cy = dspace log2 [( Py + Ny)/Ny] bits per operation. This "machine capacity" is closely related to Shannon's channel capacity for communications systems. An important theorem that Shannon proved for communication channels also applies to molecular machines. With regard to molecular machines, the theorem states that if the amount of information which a machine gains is less than or equal to Cy, then the error rate (frequency of failure) can be made arbitrarily small by using a sufficiently complex coding of the molecular machine's operation. Thus, the capacity of a molecular machine is sharply limited by the dissipation and the thermal noise, but the machine failure rate can be reduced to whatever low level may be required for the organism to survive.

A complex family of class-II restriction endonucleases, DsaI-VI, in Dactylococcopsis salina

A series of class-II restriction endonucleases (ENases) was discovered in the halophilic, phototrophic, gas-vacuolated cyanobacterium Dactylococcopsis salina sp. nov. The six novel enzymes are characterized by the following recognition sequences and cut positions: 5'-C decreases CRYGG-3' (DsaI); 5'-GG decreases CC-3' (DsaII); 5'-R decreases GATCY-3' (DsaIII); 5'-G decreases GWCC-3' (DsaIV); 5'-decreases CCNGG-3' (DsaV); and 5'-GTMKAC-3' (DsaVI), where W = A or T, M = A or C, K = G or T, and N = A, G, C or T. In addition, traces of further possible activity were detected. DsaI has a novel sequence specificity and DsaV is an isoschizomer of ScrFI, but with a novel cut specificity. A purification procedure was established to separate all six ENases, resulting in their isolation free of contaminating nuclease activities. DsaI cleavage is influenced by N6-methyladenine residues [derived from the Escherichia coli-encoded DNA methyltransferase (MTase) M.Eco damI] within the overlapping sequence, 5'-CCRYMGGATC-3'; DsaV hydrolysis is inhibited by a C-5-methylcytosine residue in its recognition sequence (5'-CMCNGG-3'), generated in some DsaV sites by the E. coli-encoded MTase, M.Eco dcmI.

Site-specific cleavage of a yeast chromosome by oligonucleotide-directed triple-helix formation

Oligonucleotides equipped with EDTA-Fe can bind specifically to duplex DNA by triple-helix formation and produce double-strand cleavage at binding sites greater than 12 base pairs in size. To demonstrate that oligonucleotide-directed triple-helix formation is a viable chemical approach for the site-specific cleavage of large genomic DNA, an oligonucleotide with EDTA-Fe at the 5' and 3' ends was targeted to a 20-base pair sequence in the 340-kilobase pair chromosome III of Saccharomyces cerevisiae. Double-strand cleavage products of the correct size and location were observed, indicating that the oligonucleotide bound and cleaved the target site among almost 14 megabase pairs of DNA. Because oligonucleotide-directed triple-helix formation has the potential to be a general solution for DNA recognition, this result has implications for physical mapping of chromosomes.

MamI, a novel class-II restriction endonuclease from Microbacterium ammoniaphilum recognizing 5'-GATNN decreases NNATC-3'

A new site-specific class-II restriction endonuclease, MamI, has been discovered in the nonsporulating Gram+ Microbacterium ammoniaphilum. MamI recognition sequence and cleavage positions were deduced using experimental and computer-assisted mapping and sequencing approaches. MamI cleavage specificity corresponds to: [formula: see text] The novel 43-kD enzyme recognizes a palindromic hexanucleotide interrupted by four ambiguous nucleotides. MamI cleavage positions are located in the center of the recognition sequence resulting in blunt-ended fragments after cleavage in the presence of Mg2+ ions. MamI is inhibited by N6-methyladenine residues. In case of overlapping sequences of MamI and Escherichia coli-coded DNA modification methyltransferase M.EcodamI (5'-[formula: see text]-3'), cleavage of DNA isolated from E. coli wild-type cells will be inhibited. By applying incubation conditions forcing star activity, relaxing of MamI sequence specificity is observed (MamI*).

A computer program to assist in the choice of restriction endonucleases for use in DNA analyses

Type II restriction endonucleases cleave double stranded DNA molecules at sites characterized by one or more sets of nucleotide pairs sequences. These digestions are essential in such procedures as DNA cloning, DNA sequencing and restriction fragment length polymorphism (RFLP) analyses. A large number of enzymes with different sequence specificities are available. To date, most choices of restriction endonucleases have been made by trial and error. A computer program, REDI, has been developed that predicts the ability of a particular restriction enzyme to detect mutations. Characteristics of both the restriction endonuclease used and the DNA being cut are incorporated as variables in the program. The program was tested using mouse mitochondrial DNA (mtDNA) and bacteriophage lambda DNA because these have been sequenced and are well characterized. REDI was strongly correlated (rs = +0.862, n = 11, P less than 0.001) with mouse mtDNA RFLP detected by Ferris et al. [1] (Genetics, 105 (1983) 681-721). Even though predictions may be altered by a non-random association of nucleotides, which varies among DNA molecules, the predictions increase the probability of selecting the most efficient enzymes for use in the analysis of a particular DNA molecule.

Observation of arginyl-deoxyoligonucleotide interactions in Taq I endonuclease by detection of specific 1H NMR signals from 140kD [N eta 1, N eta 2, 15N Arg]Taq I/oligomer complexes

Proton and nitrogen signals of the guanidinium amines in [N eta 1, N eta 2 15N Arg]Taq I endonuclease were observed using isotope filtered experiments and proton detected 1H[15N] heterocorrelated two dimensional NMR spectroscopy. These rapidly exchanging protons could be detected in the free enzyme only at pH 4.5; at pH 8.5, no signals were measured after extensive signal averaging. Addition of deoxyribonucleotide oligomers resulted in the appearance of two groups of signals at about 6.8 and 7.5 ppm. Since these signals are independent of the presence of cognate sequence or Mg2+, it is assumed they represent nonspecific arginyl-DNA interactions. This labeling/NMR approach provides a new method for investigating the role of arginine in protein-DNA interactions.

Genetic engineering of EcoRI mutants with altered amino acid residues in the DNA binding site: physicochemical investigations give evidence for an altered monomer/dimer equilibrium for the Gln144Lys145 and Gln144Lys145Lys200 mutants

We have genetically engineered the Arg200----Lys mutant, the Glu144Arg145----GlnLys double mutant, and the Glu144Arg145Arg200----GlnLysLys triple mutant of the EcoRI endonuclease in extension of previously published work on site-directed mutagenesis of the EcoRI endonuclease in which Glu144 had been exchanged for Gln and Arg145 for Lys [Wolfes et al. (1986) Nucleic Acids Res. 14, 9063]. All these mutants carry modifications in the DNA binding site. Mutant EcoRI proteins were purified to homogeneity and characterized by physicochemical techniques. All mutants have a very similar secondary structure composition. However, whereas the Lys200 mutant is not impaired in its capacity to form a dimer, the Gln144Lys145 and Gln144Lys145Lys200 mutants have a very much decreased propensity to form a dimer or tetramer depending on concentration as shown by gel filtration and analytical ultracentrifugation. This finding may explain the results of isoelectric focusing experiments which show that these two mutants have a considerably more basic pI than expected for a protein in which an acidic amino acid was replaced by a neutral one. Furthermore, while wild-type EcoRI and the Lys200 mutant are denatured in an irreversible manner upon heating to 60 degrees C, the thermal denaturation process as shown by circular dichroism spectroscopy is fully reversible with the Gln144Lys145 double mutant and the Gln144Lys145Lys200 triple mutant. All EcoRI endonuclease mutants described here have a residual enzymatic activity with wild-type specificity, since Escherichia coli cells overexpressing the mutant proteins can only survive in the presence of EcoRI methylase. The detailed analysis of the enzymatic activity and specificity of the purified mutant proteins is the subject of the accompanying paper [Alves et al. (1989) Biochemistry (following paper in this issue)].

Rapid separation of DNA restriction fragments using capillary electrophoresis

Open-tube capillary electrophoresis has been applied to the separation of restriction fragments of DNA with a Tris-borate buffer containing 7 M urea and 0.1% sodium dodecyl sulfate. The importance of sample pretreatment and of the injection of heated samples has been demonstrated. In one separation, a DNA restriction fragment mixture from 72 to 23,130 base pairs (DRIgestTM III) (molecular weight range from 4.6.10(4) to 1.5.10(7] has been electrophoresed in 10 min on a column of 15 cm effective length. Over 600,000 plates have been obtained for individual peaks. Several of the peaks have been identified, by spiking slab gel electrophoretically purified components. Other examples of restriction fragment separations are illustrated in this paper. The results of this study when further validated with full characterization of individual species, open up the possibility of rapid restriction enzyme mapping.

Location and methylation pattern of a nuclear matrix associated region in the human pro alpha 2(I) collagen gene

Using both a 25 mM Lithium di-iodosalicylic acid (LIS) and a 2M NaCl extraction procedure to extract nuclear matrices from white cells we have identified a 0.9 kb nuclear matrix associated region (MAR) in the human pro alpha 2(I) collagen gene. The MAR is located towards the 3' coding end of the gene, it is completely associated with the matrix in transcriptionally inactive white cells but is incompletely associated with the matrix in transcriptionally active fibroblasts. Furthermore the methylation state of the fibroblast gene in the region coinciding with the MAR showed unique differences when compared to adjacent sites in the fibroblast gene and corresponding sites of the white cell gene.

The TaqI 'star' reaction: strand preferences reveal hydrogen-bond donor and acceptor sites in canonical sequence recognition

TaqI endonuclease recognizes and cleaves its canonical sequence, TCGA, with complete fidelity under standard conditions. In the presence of some organic solvents, TaqI endonuclease introduced additional single-strand and double-strand cuts at sequences termed TaqI 'star' sites. Using 'middle-labeled' DNA, the relative rates of cleavage of each strand were simultaneously determined for several star sites. These star recognition sequences differed from the canonical sequence by a single base, and all potential star sites were either nicked or cleaved. Star sites within the middle labeled substrate represented ten of the twelve possible star sequences for each strand. For each group of identical star sites, one strand was consistently preferred for cleavage. Based on these preferences, a model for TaqI recognition of the TCGA sequence is proposed. According to this model, sequence discrimination is mediated by eight hydrogen bonds formed between TaqI and the cognate nucleotides within the major groove.

Determination of 5-methylcytosine by acid hydrolysis of DNA with hydrofluoric acid

Quantitation of 5-methylcytosine in DNA after acid hydrolysis has been inaccurate because deamination of cytosine and 5-methylcytosine occurs during the hydrolysis procedure. There is little information in the literature regarding the use of hydrofluoric acid (HF) for DNA hydrolysis and we have therefore undertaken a systematic study of this process. The deoxyribonucleotides of cytosine and 5-methylcytosine were shown not to undergo detectable levels of deamination during prolonged periods (up to 24 h) at 80 degrees C in 48% HF. Kinetic studies show that the release of purine and pyrimidine bases was complete by 4 h under these conditions. Analysis of the 5-methylcytosine content of DNA from various tissues gave levels that were very close to the values reported in the literature. This method is ideally suited for the determination of the overall cytosine methylation levels in DNA.

Sequence-specific cleavage of double helical DNA by triple helix formation

Homopyrimidine oligodeoxyribonucleotides with EDTA-Fe attached at a single position bind the corresponding homopyrimidine-homopurine tracts within large double-stranded DNA by triple helix formation and cleave at that site. Oligonucleotides with EDTA.Fe at the 5' end cause a sequence specific double strand break. The location and asymmetry of the cleavage pattern reveal that the homopyrimidine-EDTA probes bind in the major groove parallel to the homopurine strand of Watson-Crick double helical DNA. The sequence-specific recognition of double helical DNA by homopyrimidine probes is sensitive to single base mismatches. Homopyrimidine probes equipped with DNA cleaving moieties could be useful tools for mapping chromosomes.

Nucleotide sequence of the DdeI restriction-modification system and characterization of the methylase protein

The DdeI restriction-modification system was previously cloned and has been maintained in E. coli on two separate and compatible plasmids (1). The nucleotide sequence of the endonuclease and methylase genes has now been determined; it predicts proteins of 240 amino acids, Mr = 27,808, and 415 amino acids, Mr = 47,081, respectively. Inspection of the DNA sequence shows that the 3' end of the methylase gene had been deleted during cloning. The clone containing the complete methylase gene was made and compared to that containing the truncated gene; only clones containing the truncated form support the endonuclease gene in E. coli. Bal-31 deletion studies show that methylase expression in the Dde clones is also dependent upon orientation of the gene with respect to pBR322. The truncated and complete forms of the methylase protein were purified and compared; the truncated form appears to be more stable and active in vitro. Finally, comparison of the deduced amino acid sequence of M. DdeI with that of other known cytosine methylases shows significant regions of homology.

Promoter interaction of the E1A-inducible factor E2F and its potential role in the formation of a multi-component complex

The precise binding site in the adenovirus E2 promoter for the E1A-inducible factor E2F was determined. DNase footprinting revealed two distinct regions of protection which spanned sequences from -33 to -49 and from -53 to -71. Chemical modifications of DNA further delineated nucleotides involved in DNA-protein contacts in each binding region. The E2F binding sites are clearly distinct from the binding site for another E2 promoter binding factor, located at -68 to -80, previously described by SivaRaman et al. [(1986) Proc. Natl. Acad. Sci. USA, 83, 5914-5918]. As determined by DNase footprinting using crude nuclear extracts, both factors were present in extracts of Ad5-infected cells and were found to bind simultaneously to their respective sites on the promoter. In contrast, E2F was not evident in extracts of uninfected cells, whereas there was no difference in the -68 to -80 footprint as a function of the extract. Thus, although multiple factors interact with the E2 promoter, only the E2F factor is unique to the infected extract. The implications of the formation of a multi-factor promoter complex as a possible mechanism of transcriptional regulation are discussed.

The effects of DNA methylation by Hha I methylase on the cleavage reactions by Hae II, Aha II and Ban I endonucleases

The DNA methylated by Hha I methylase was resistant against cleavage of Hae II or Aha II endonuclease indicating that the methyl group of the C5 position of the inmost cytosine nucleotide interferes with the interaction between the enzyme and the hexameric recognition sequence. Considering that Hae II or Aha II methylase has not been isolated yet, the result explained above is a useful information for protecting a double stranded DNA from being cleaved by Hae II or Aha II endonuclease. In contrast to Hae II or Aha II endonuclease, Ban I endonuclease which also has Hha I sequence as its tetrameric core was able to cleave the same DNA normally. This result suggests that the C5 position of the inmost pyrimidine nucleotide is not an important contact point between Ban I endonuclease and its hexameric recognition sequence.

Helical repeat of DNA in solution. The V curve method

The V-like dependence of the electrophoretic mobility of small DNA rings on their topological constraint, which has been documented in a recent paper [Zivanovic et al. (1986), J. Mol. Biol., 192, 645-660], has been explored as a tool to measure the helical twist of the torsionally unstressed duplex. The method was applied to single mixed sequence fragments approximately 350 to 1400 base pairs in length, providing estimates of their average helical periodicity. It was also used to compare two DNA fragments, and to evaluate the helical repeat of poly(dA.dT).poly(dA.dT) and poly(dA).poly(dT) inserts, and the helix unwindings associated with dA and dC methylations by dam and Hhal methylases, respectively. Data were found to be highly reproducible and helical repeat estimates were in good agreement with those obtained from previous techniques.

Role of an adenovirus E2 promoter binding factor in E1A-mediated coordinate gene control

A product of the adenovirus gene E1A is responsible for the stimulation of transcription from six viral promoters as well as at least two cellular promoters. We have detected a HeLa cell factor, termed E2 promoter binding factor (E2F), that appears to mediate the transcriptional stimulation of the viral E2 promoter. Competition experiments revealed that E2F did not recognize and bind to the E1B, E3, E4, or major late promoter sequences. Furthermore, three additional promoters stimulated by E1A, heat shock protein 70, beta-globin, and early simian virus 40, do not bind E2F. In contrast, the factor does recognize sequences in the E1A enhancer, and within the E1A enhancer are duplicated binding sites for E2F. Finally, a single E2F binding site from the E1A enhancer can confer increased transcription to a mouse beta-globin promoter, dependent on the action of the E1A gene product. This stimulation requires binding of E2F since methylation of the binding site, which blocks binding in vitro, reduces transcription stimulation in vivo. We, therefore, conclude that E2F is likely to be responsible for the E1A-mediated stimulation of the E1A gene as well as the E2 gene but is not involved in the activation of the other E1A-inducible promoters.

DNA hybridization of cervical tissues

The increasing frequency of cervical neoplasia among younger women and the increased invasiveness of these tumors has led to a considerable growth in research into this disease. Conventional methods (epidemiology, cytology, and immunology), while being extremely useful, also have significant limitations. Recent advances in techniques for the manipulation of DNA now make it possible to analyze tissues for the presence of viral genomes. This review introduces these techniques and describes their application to the search for herpes simplex virus and human papillomavirus sequences in cervical tissue. The significance of the findings both for the mechanism of transmission of the disease, and also the consequences for early detection and hence more successful treatment, are also discussed.

Properties and uses of restriction endonucleases

It is clear that we have still not exhausted all the restriction endonuclease specificities to be found in nature. Recently discovered BsmI is the first endonuclease recognizing a nonpalindromic sequence that cleaves within the site. Certainly other endonucleases belonging to this class will soon be discovered. More endonucleases are now being sought that recognize longer recognition sequences, because large fragments can now be readily separated by pulse-field electrophoresis. New sources of endonucleases are also being found; for example, a group of viruses that grow on Chlorella algae produce type II-like site-specific endonucleases. As the number and variety of known restriction endonucleases increase, the number and variety of applications keep pace. There is still no end in sight.