Double minute chromosomes can be produced from precursors derived from a chromosomal deletion.

Recent experiments have shown that gene amplification can be mediated by submicroscopic, autonomously replicating, circular extrachromosomal molecules. We refer to those molecules as episomes (S. Carroll, P. Gaudray, M. L. DeRose, J. F. Emery, J. L. Meinkoth, E. Nakkim, M. Subler, D. D. Von Hoff, and G. M. Wahl, Mol. Cell. Biol. 7:1740-1750, 1987). The experiments reported in this paper explore the way episomes are formed and their fate in the cell over time. The data reveal that in our system the episomes are initially 250 kilobases, but gradually enlarge until they become double minute chromosomes. In addition, we show that episomes or double minute chromosomes can integrate into chromosomes. Our results also suggest that episomes can be produced by deletion of the corresponding sequences from the chromosome.

Construction and characterization of a site-directed CC-1065-N3-adenine adduct within a 117 base pair DNA restriction fragment.

The design, construction, and characterization of a site-directed CC-1065-N3-adenine adduct in a 117 base pair segment of M13mpI DNA are described. CC-1065 is an extremely potent antitumor antibiotic produced by Streptomyces zelensis. Previous studies have demonstrated that the cyclopropyl ring of CC-1065 reacts quite specifically with N3 of adenine in double-stranded DNA to form a CC-1065-DNA adduct. Following alkylation, the drug molecule lies snugly within the minor groove of DNA, overlapping with five base pairs for which a marked sequence preference exists [Hurley, L. H., Reynolds, V. R., Swenson, D. H., Petzold, G. L., & Scahill, T. A. (1984) Science (Washington, D.C.) 226, 843-844]. On the basis of the unique characteristics of the reaction of CC-1065 with DNA and the structure of the resulting DNA adduct, we have designed a general strategy to construct a site-directed CC-1065-DNA adduct in a restriction fragment. The presence of unique AluI and HaeIII restriction enzymes sites on each side of a high-affinity CC-1065 binding sequence (5'-GATTA) permitted the preparation of a partial duplex DNA molecule containing the CC-1065 binding sequence in the duplex DNA region. Since CC-1065 only binds to duplex DNA, potential CC-1065 binding sequences in the long single-stranded regions were protected from drug binding during the construction process.(ABSTRACT TRUNCATED AT 250 WORDS)

Demonstration of the asymmetric effect of CC-1065 on local DNA structure using a site-directed adduct in a 117-base-pair fragment from M13mp1.

Using DNase I and Alu I endonuclease analysis of a site-directed CC-1065-[N3-adenine]DNA adduct in a 117-base-pair fragment from M13mp1 DNA, we have demonstrated that CC-1065 produces an asymmetric effect on DNA conformation that extends more than one helix turn to the 5' side of the covalently modified adenine. CC-1065 is a potent antitumor antibiotic produced by Streptomyces zelensis, which is believed to mediate its cytotoxic effects through covalent binding to DNA. Previous studies have demonstrated that CC-1065 binds covalently to N3 of adenine and lies within the minor groove of DNA spanning a 4-base-pair sequence to the 5' side of the modified adenine. DNase I footprinting of this site-directed CC-1065-DNA adduct on the noncovalently modified strand shows that inhibition of cleavage occurs over a 12-base region, which is bordered on the 3' side by a site of 2-fold enhancement of cleavage. On the covalently modified strand a much less pronounced inhibition/enhancement pattern of cleavage occurs as far as 11 bases to the 5' side of the covalently modified adenine. While Hae III is able to cleave the DNA on both strands on the 3' side of the covalently modified adenine, Alu I is only able to cleave the covalently modified strand on the 5' side of the adduct. By taking into account the recently published structure of DNase I, we are able to interpret these results and develop a model for the effect of CC-1065 on local DNA structure. In this model, we propose selective drug-induced distortion of the covalently modified strand as a consequence of the alkylation of adenine by CC-1065.

Recognition and repair of the CC-1065-(N3-adenine)-DNA adduct by the UVRABC nucleases.

The recognition and repair of the helix-stabilizing and relatively nondistortive CC-1065-(N3-adenine)-DNA adduct by UVRABC nuclease has been investigated both in vivo with phi X174 RFI DNA by a transfection assay and in vitro by a site-directed adduct in a 117 base pair fragment from M13mp1. CC-1065 is a potent antitumor antibiotic produced by Streptomyces zelensis which binds within the minor groove of DNA through N3 of adenine. In contrast to the helix-destabilizing and distortive modifications of DNA caused by ultraviolet light or N-acetoxy-2-(acetylamino)fluorene, CC-1065 increases the melting point of DNA and decreases the S1 nuclease activity. Using a viral DNA-Escherichia coli transfection system, we have found that the uvrA, uvrB, and uvrC genes, which code for the major excision repair proteins for UV- and NAAAF-induced DNA damage, are also involved in the repair of CC-1065-DNA adducts. In contrast, the uvrD gene product, which has been found to be involved in the repair of UV damage, has no effect in repairing CC-1065-DNA adducts. Purified UVRA, UVRB, and UVRC proteins must work in concert to incise the drug-modified phi X174 RFI DNA. Using a site-directed and multiple CC-1065 modified (MspI-BstNI) 117 base pair fragment from M13mp1, we have found that UVRABC nuclease incises at the eighth phosphodiester bond on the 5' side of the CC-1065-DNA adduct on the drug-modified strand.(ABSTRACT TRUNCATED AT 250 WORDS)

Amplified human MYC oncogenes localized to replicating submicroscopic circular DNA molecules.

Amplification of genes can sometimes be detected by molecular hybridization but not by cytogenetic methods, suggesting that in some cases the units of amplification may be too small to be detected by light microscopy. The experiments reported here investigate whether submicroscopic amplification units are present in early passages of the human tumor cell lines HL-60 and COLO 320. The results show that such cells do contain submicroscopic, extrachromosomal, supercoiled circular molecules harboring MYC genes. The molecules in HL-60 are approximately 250 kilobase pairs (kbp), while those in COLO 320 are 120-160 kbp. The extrachromosomal molecules in HL-60 are shown to replicate semiconservatively and approximately once in one cell cycle. We propose that these submicroscopic elements are precursors of double-minute chromosomes, the usual extrachromosomal manifestation of gene amplification, since both are structurally similar and replicate autonomously.

Characterization of an adduct between CC-1065 and a defined oligodeoxynucleotide duplex.

CC-1065 is a potent antitumor antibiotic produced by Streptomyces zelensis. The drug binds covalently through N-3 of adenine and lies within the minor groove of DNA. Previous studies indicated that CC-1065 reacted with adenine in DNA to yield a thermally labile product that could be used to reveal its sequence specificity. These studies also provided insight into a DNA sequence (5'-CGGAGTTAGGGGCG-3') which should bind one molecule of CC-1065 in an unambiguous manner. This sequence, which contains the CC-1065 adenine binding site within the sequence 5'-TTA-3' was chemically synthesized together with the complementary strand. CC-1065 reacted with the oligoduplex to give an adduct that maintained the B-DNA form and had a final CD spectrum similar to those of the CC-1065 complexes formed with calf thymus DNA. The above 14mer was 5' end-labelled with 32P, annealed with its complementary strand, reacted with CC-1065 and heated. Drug-mediated strand breakage was evaluated on a sequencing gel. A single break occurred in the labelled strands to give a fragment that migrated as an 8.5mer; subsequent piperidine treatment produced a fragment that migrated as a 7mer, which is the size expected from the known binding of CC-1065 at adenine in 5'-TTA-3' sequences.