A new electron microscopic method for studying protein-nucleic acid interactions

Extrachromosomal plasmids in the plant pathogenic fungus Rhizoctonia solani

Extrachromosomal DNA elements were found in field isolates of Rhizoctonia solani belonging to anastomosis groups (AG) 1-5. An isolate of AG-5 (Rh41) contains a 3.6-kbp plasmid (pRS188) which has a similar A+T content to mitochondrial DNA. pRS188 is linear and has knob structures at its ends, as revealed by electron microscopy. Exonuclease digestions show that the linear ends of pRS188 are protected, and remain protected even after proteinase K digestion. pRS188 does not hybridise to nuclear or mitochondrial DNAs of its host isolate (Rh41), to total DNAs of other plasmid-less AG-5 isolates, or to total DNA of plasmid-harbouring isolates belonging to different AGs. Cellular-fractionation experiments suggest that pRS188 is associated with mitochondria, but it remains undecided whether this occurs inside or outside of the organelles. The nucleotide sequence of about 60% of the plasmid has been determined, revealing no open reading frame longer than 91 amino acids, and no known gene or genetic element is detected in the sequence contigs of 300-1572 bp length. Similar studies were performed with the plasmid pRS104 present in an isolate of AG-4 (Rh36), the sequence of which exhibits essentially the same features as pRS188 except that its A+T content resembles that of nuclear DNA. Pathogenicity tests reveal that the isolates Rh41 and R36 are as virulent as the plasmid-less isolates of AG-4 and -5, indicating that the plasmids do not play any role in pathogenicity.

Quantitative electron microscopic analysis of DNA-protein interactions

Electron microscopy offers a unique potentiality to visualize individual molecules. For the last 30 years it has been used to study the structure and the interactions of various biological macromolecules. The contribution of electron microscopy is important because of its capacity to demonstrate the existence of conformational structures such as kinks, bents, loops, etc., either on naked DNA, or on DNA associated with various proteins or ligands. Increasing interest was given to such observations when it was found that they provide a direct visualization of interacting molecules involved in DNA metabolism and gene regulation. Technical advances in the preparation of the specimens, their observation in the electron microscope, and the image processing by computers have allowed the shifting from qualitative to quantitative analysis, as illustrated by a few examples from our laboratory.

DNA of the Streptomyces phage SH10: binding sites for Escherichia coli RNA polymerase and denaturation map

Escherichia coli RNA polymerase bound to Streptomyces phage SH10 DNA was visualized by electron microscopy. Six specific binding sites were observed at map units 53, 85, 93, 97, 98, and 99 on the physical map of the 48 kb long genome. Electron microscopy of partially denatured SH10 DNA revealed a characteristic melting pattern of A + T-rich regions around map units 1, 3, 48, 52, and 99. A comparison of the denaturation map with the RNA polymerase binding sites indicates that three binding sites are located in the most A + T-rich regions, two in other early melting regions and one in a segment of higher DNA helix stability.

Mammalian cells contain a DNA-recombining activity that can be dissociated from topoisomerase activity

The role of the topoisomerase enzyme in DNA recombination was investigated by extracting chromosomal deoxyribonucleoproteins from a variety of cultured mammalian cells and assaying for the formation of recombinant DNA structures. Although each of the crude deoxyribonucleoprotein preparations contained topoisomerase activity, they did not all contain DNA-recombining activity. A distinct, perhaps novel, enzyme may therefore promote DNA recombination in these cell-free systems.

DNA electron microscopy

In recent years DNA electron microscopy has become a tool of increasing interest in the fields of molecular genetics and molecular and cell biology. Together with the development of in vitro recombination and DNA cloning, new electron microscope techniques have been developed with the aim of studying the structural and functional organization of genetic material. The most important methods are based on nucleic acid hybridizations: DNA-DNA hybridization (heteroduplex, D-loop), RNA-DNA hybridization (R-loop), or combinations of both (R-hybrid). They allow both qualitative and quantitative analysis of gene organization, position and extension of homology regions, and characterization of transcription. The reproducibility and resolution of these methods make it possible to map a specific DNA region within 50 to 100 nucleotides. Therefore they have become a prerequisite for determining regions of interest for subsequent nucleotide sequencing. Special methods have been developed also for the analysis of protein-DNA interaction: e.g., direct visualization of specific protein-DNA complexes (enzymes, regulatory proteins), and analysis of structures with higher complexity (chromatin, transcription complexes).

A computational procedure for the analysis of electron images of nucleic acid molecules

A new procedure is described for analyzing electron images of labeled nucleic acid molecules. The method makes use of one-dimensional digital image information and determines the best relative orientation of the linear molecules. The analysis is performed with the computer program CLUSTER, which combines the information from each molecule stepwise in an iterative procedure, so that finally a label distribution is obtained, which is the combination of all information available. The rationale behind the analysis is the calculation of similarity coefficients, which are a measure of the probability for the relative orientation of each molecule pair. The method has been thoroughly tested and compared with other procedures described in the literature in order to indicate its performance and power. A biological application concerning the distribution of the protein RNA-polymerase on DNA of phage Mu is presented.

Isolation of E.coli promoters from the late region of bacteriophage T7 DNA

Promotor sequences recognized by Escherichia coli RNA polymerase have been isolated from bacteriophage T7 DNA using the plasmid pBRH4. T7 DNA was digested with the restriction endonuclease Hae III, Alu I, and Eco RI* and the products of these digestions were ligated into the EcoRI site of pBRH4. Cloning of Hae III and Alu I-digested T7 DNA was achieved by blunt-end ligation of these fragments to the polymerized ends of Eco-RI-cleaved pBRH4. This converts blunt-end Eco RI fragments of T7 DNA into cohesive-end EcoRI fragments. Promoter-containing T7 restriction fragments were selected by activation of the tetracycline-resistance gene located on the plasmid vector. The genomic location of each T7 insert was determined and Hpa I-cleaved T7 DNA. Two promoter-active restriction fragments are thought to contain the C and E promoters of T7. However, the majority, of the promoter-active fragments cloned map within the late gene region of T7. In vitro binding studies indicate that E. coli RNA polymerase can form heparin resistant complexes with the cloned T7 DNA promoter fragments. These results suggest that while E. coli RNA polymerase may not participate directly in the transcription of late T7 genes, promoters for this enzyme are present in this region of the DNA.

Electron microscopic mapping and sequence analysis of the terminator for the early message of E. coli phage T7

The terminator position of T7 early messenger RNA was determined by electron microscopic measurements. The end of the RNA was mapped at a position 18.9% from the left end of T7 DNA, and 145 +/- 25 nucleotides from the right end of the Hpa I fragment Q. The sequence of the Hpa I Q fragment was determined around this position, and a terminator-like structure was detected in position 193 to 169 from the right end of fragment Q.