DNA-protein interactions in the Drosophila melanogaster mitochondrial genome as deduced from trimethylpsoralen crosslinking patterns

Mitochondrial DNA degradation: A quality control measure for mitochondrial genome maintenance and stress response

Mitochondria play a central role in bioenergetics, and fulfill a plethora of functions in cell signaling, programmed cell death, and biosynthesis of key protein cofactors. Mitochondria harbor their own genomic DNA, which encodes protein subunits of the electron transport chain and a full set of transfer and ribosomal RNAs. Mitochondrial DNA (mtDNA) is essential for cellular and organismal functions, and defects in mitochondrial genome maintenance have been implicated in common human diseases and mitochondrial disorders. mtDNA repair and degradation are known pathways to cope with mtDNA damage; however, molecular factors involved in this process have remained unclear. Such knowledge is fundamental to the understanding of mitochondrial genomic maintenance and pathology, because mtDNA degradation may contribute to the etiology of mtDNA depletion syndromes and to the activation of the innate immune response by fragmented mtDNA. This article reviews the current literature regarding the importance of mitochondrial DNA degradation in mtDNA maintenance and stress response, and the recent progress in uncovering molecular factors involved in mtDNA degradation. These factors include key components of the mtDNA replication machinery, such as DNA polymerase γ, helicase Twinkle, and exonuclease MGME1, as well as a major DNA-packaging protein, mitochondrial transcription factor A (TFAM).

Mitochondrial transcription in mammalian cells

As a consequence of recent discoveries of intimate involvement of mitochondria with key cellular processes, there has been a resurgence of interest in all aspects of mitochondrial biology, including the intricate mechanisms of mitochondrial DNA maintenance and expression. Despite four decades of research, there remains a lot to be learned about the processes that enable transcription of genetic information from mitochondrial DNA to RNA, as well as their regulation. These processes are vitally important, as evidenced by the lethality of inactivating the central components of mitochondrial transcription machinery. Here, we review the current understanding of mitochondrial transcription and its regulation in mammalian cells. We also discuss key theories in the field and highlight controversial subjects and future directions as we see them.

Transcription-generated torsional stress destabilizes nucleosomes

As RNA polymerase II (Pol II) transcribes a gene, it encounters an array of well-ordered nucleosomes. How it traverses through this array in vivo remains unresolved. One model proposes that torsional stress generated during transcription destabilizes nucleosomes ahead of Pol II. Here, we describe a method for high-resolution mapping of underwound DNA, using next-generation sequencing, and show that torsion is correlated with gene expression in Drosophila melanogaster cells. Accumulation of torsional stress, through topoisomerase inhibition, results in increased Pol II at transcription start sites. Whereas topoisomerase I inhibition results in increased nascent RNA transcripts, topoisomerase II inhibition causes little change. Despite the different effects on Pol II elongation, topoisomerase inhibition results in increased nucleosome turnover and salt solubility within gene bodies, thus suggesting that the elongation-independent effects of torsional stress on nucleosome dynamics contributes to the destabilization of nucleosomes.

Superresolution fluorescence imaging of mitochondrial nucleoids reveals their spatial range, limits, and membrane interaction

A fundamental objective in molecular biology is to understand how DNA is organized in concert with various proteins, RNA, and biological membranes. Mitochondria maintain and express their own DNA (mtDNA), which is arranged within structures called nucleoids. Their functions, dimensions, composition, and precise locations relative to other mitochondrial structures are poorly defined. Superresolution fluorescence microscopy techniques that exceed the previous limits of imaging within the small and highly compartmentalized mitochondria have been recently developed. We have improved and employed both two- and three-dimensional applications of photoactivated localization microscopy (PALM and iPALM, respectively) to visualize the core dimensions and relative locations of mitochondrial nucleoids at an unprecedented resolution. PALM reveals that nucleoids differ greatly in size and shape. Three-dimensional volumetric analysis indicates that, on average, the mtDNA within ellipsoidal nucleoids is extraordinarily condensed. Two-color PALM shows that the freely diffusible mitochondrial matrix protein is largely excluded from the nucleoid. In contrast, nucleoids are closely associated with the inner membrane and often appear to be wrapped around cristae or crista-like inner membrane invaginations. Determinations revealing high packing density, separation from the matrix, and tight association with the inner membrane underscore the role of mechanisms that regulate access to mtDNA and that remain largely unknown.

Following the Chromosome Path to the Garden of the Genome

I have been fascinated by chromosomes for longer than I care to mention; their beautiful structure, cell-type-specific changes in morphology, and elegant movements delight me. Shortly before I began graduate study, the development of nucleic acid hybridization made it possible to compare two nucleic acids whether or not their sequences were known. From this stemmed a progression of development in tools and techniques that continues to enhance our understanding of how chromosomes function. As my PhD project I contributed to this progression by developing in situ hybridization, a technique for hybridization to nucleic acids within their cellular context. Early studies with this technique initiated several lines of research, two of which I describe here, that I have pursued to this day. First, analysis of RNA populations by hybridization to polytene chromosomes (a proto-microarray-type experiment) led us to characterize levels of regulation during heat shock beyond those recognizable by puffing studies. We found also that one still-undeciphered major heat shock puff encodes a novel set of RNAs for which we propose a regulatory role. Second, localization of various multicopy DNA sequences has suggested roles for them in chromosome structure: Most recently we have found that Drosophila telomeres consist of and are maintained by special non-LTR (long terminal repeat) retrotransposons.

The mitochondrial DNA control region of Muscidae flies: evolution and structural conservation in a dipteran context

The structure and evolution of the mtDNA control region (CR) and its flanking genes in economically important dipterans from the family Muscidae (Brachycera: Calyptratae), Haematobia irritans, Musca domestica, Atherigona orientalis, and Stomoxys calcitrans are presented in this paper, along with the description of short noncoding intergenic regions possibly related to CR flanking sequences in Stomoxys calcitrans and Ophyra aenescens mtDNAs (ScIR and OaIR, respectively). S. calcitrans showed a large CR with an approximately 550-bp element tandemly repeated and a duplicated tRNA(Ile) gene. The characterization of H. irritans, M. domestica, A. orientalis, and S. calcitrans CR sequences led to the identification of seven conserved sequence blocks homologous to the elements previously described for Calliphoridae and Oestridae species (Brachycera: Calyptratae). Comparative analysis with Drosophila species (Brachycera: Acalyptratae) revealed four conserved regions. The putative functional roles of the conserved elements in the regulation of replication and transcription processes are addressed. The characterization of the structural organization of the mitochondrial genome CR demonstrates the plasticity of the mtDNA molecule in family Muscidae.

Mitochondrial transcription factor A (TFAM): Roles in maintenance of mtDNA and cellular functions

A growing body of evidence suggests that mammalian mitochondrial DNA takes on higher structure called nucleoid or mitochromosome corresponding to that of nuclear DNA. Mitochondrial transcription factor A (TFAM), which was cloned as a transcription factor for mitochondrial DNA, has known to be essential for the maintenance of mitochondrial DNA. Human TFAM has an ability to bind to DNA in a sequence-independent manner and is abundant enough to cover whole region of mitochondrial DNA, owing to which TFAM stabilizes mitochondrial DNA through formation of nucleoid and regulates (or titrates) the amount of mitochondrial DNA. Overexpression of human TFAM in mice increases the amount of mitochondrial DNA and dramatically ameliorates the cardiac dysfunctions caused by myocardial infarction. The maintenance of integrity of mitochondrial DNA is important for keeping proper cellular functions both under physiological and pathological conditions. TFAM may play a crucial role in maintaining mitochondrial DNA as a main component of the nucleoid.

Mitochondrial Transcription Factor A in the Maintenance of Mitochondrial DNA

Mitochondria have their own genome, which is essential for proper oxidative phosphorylation needed for a large part of ATP production in a cell. Although mitochondrial DNA-less (rho0) cells can survive under special conditions, the integrity of the mitochondrial genome is critical for survival of multicellular organisms. Mitochondrial transcription factor A (TFAM), originally cloned as transcription factor, is essential for the maintenance of mtDNA. Recently, it has become known that TFAM plays critical roles in multiple aspects to maintain the integrity of mitochondrial DNA: transcription, replication, nucleoid formation, damage sensing, and DNA repair. The effects of TFAM in these aspects are intimately related to each other and to function as a whole for the purpose of maintenance of mtDNA.

Replication origin of mitochondrial DNA in insects

The precise position of the replication origin (O(R)) of mtDNA was determined for insect species belonging to four different orders (four species of Drosophila, Bombyx mori, Triborium castaneum, and Locusta migratoria, which belong to Diptera, Lepidoptera, Coleoptera, and Orthoptera, respectively). Since the free 5' ends of the DNA strands of mtDNA are interpreted as the O(R), their positions were mapped at 1-nucleotide resolution within the A + T-rich region by using the ligation-mediated PCR method. In all species examined, the free 5' ends were found within a very narrow range of several nucleotides in the A + T-rich region. For four species of Drosophila, B. mori, and T. castaneum, which belong to holometabolous insects, although the O(R)'s were located at different positions, they were located immediately downstream of a series of thymine nucleotides, the so-called T-stretch. These results strongly indicate that the T-stretch is involved in the recognition of the O(R) of mtDNA at least among holometabolous insects. For L. migratoria (hemimetabolous insect), on the other hand, none of the long stretches of T's was found in the upstream portion of the O(R), suggesting that the regulatory sequences involved in the replication initiation process have changed through insect evolution.

DNA-binding proteins of mammalian mitochondria

Acid-soluble proteins were isolated from liver and spleen mitochondria and their ability to form complexes with DNA was investigated. According to electrophoresis data, acid-soluble proteins include about 20 polypeptides ranging in the molecular mass from 10 to 120 kDa. It was found that acid-soluble proteins form stable DNA-protein complexes at a physiological NaCl concentration. Different polypeptides possess different degrees of DNA affinity. There is no significant difference between DNA-binding proteins of mitochondria from liver and those from spleen as to their ability to form complexes with mtDNA and nDNA. In the presence of 5 microg of DNA most polypeptides were bound to DNA, and further increase in DNA amount affected little the binding of proteins to DNA. There was no distinct difference in DNA-protein complex formation of liver mitochondrial acid-soluble proteins with nDNA or mtDNA. Also, it was detected that with these mitochondrial acid-soluble proteins, proteases that specifically cleave these proteins are associated. It was shown for the first time that these proteases are activated by DNA. DNA-binding proteins including DNA-activated mitochondrial proteases are likely to participate in the regulation of the structural organization and functional activity of mitochondrial DNA.

Architectural role of mitochondrial transcription factor A in maintenance of human mitochondrial DNA

Mitochondrial transcription factor A (TFAM), a transcription factor for mitochondrial DNA (mtDNA) that also possesses the property of nonspecific DNA binding, is essential for maintenance of mtDNA. To clarify the role of TFAM, we repressed the expression of endogenous TFAM in HeLa cells by RNA interference. The amount of TFAM decreased maximally to about 15% of the normal level at day 3 after RNA interference and then recovered gradually. The amount of mtDNA changed closely in parallel with the daily change in TFAM while in organello transcription of mtDNA at day 3 was maintained at about 50% of the normal level. TFAM lacking its C-terminal 25 amino acids (TFAM-DeltaC) marginally activated transcription in vitro. When TFAM-DeltaC was expressed at levels comparable to those of endogenous TFAM in HeLa cells, mtDNA increased twofold, suggesting that TFAM-DeltaC is as competent in maintaining mtDNA as endogenous TFAM under these conditions. The in organello transcription of TFAM-DeltaC-expressing cells was no more than that in the control. Thus, the mtDNA amount is finely correlated with the amount of TFAM but not with the transcription level. We discuss an architectural role for TFAM in the maintenance of mtDNA in addition to its role in transcription activation.

Duplication and triplication with staggered breakpoints in human mitochondrial DNA

We identified a tandem duplication and triplication of a mitochondrial DNA (mtDNA) segment in the muscle of a 57-year-old man with no evidence of a neuromuscular disorder. A large triplication of a mtDNA coding region has not been previously reported in humans. Furthermore, the rearrangements (comprising 10-12% of the muscle mtDNA pool in the propositus) were unique because the breakpoints were staggered at both ends (between mtDNA positions 3263-3272 and 16,065-16,076) and contained no identifiable direct repeats. Both sides of the breakpoint were located approximately 35 bp downstream of regions that undergo frequent strand displacement by either transcription (positions 3263-3272) or replication (positions 16,065-16,076), suggesting that topological changes generated by the movement of RNA/DNA polymerases may be associated with the genesis of a subclass of mtDNA rearrangements. The presence of low levels of these rearrangements in other normal adults also suggest that these mutations are not rare. The characterization of these rearrangements shed light on potential alternative mechanisms for the genesis of mtDNA rearrangements.

Analysis of mitochondrial DNA nucleoids in wild-type and a mutant strain of Saccharomyces cerevisiae that lacks the mitochondrial HMG box protein Abf2p

DNA-protein complexes (nucleoids) are believed to be the segregating unit of mitochondrial DNA (mtDNA) in Saccharomyces cerevisiae. A mitochondrial HMG box protein, Abf2p, is needed for maintenance of mtDNA in cells grown on rich dextrose medium, but is dispensible in glycerol grown cells. As visualized by 4',6'-diamino-2-phenylindole staining, mtDNA nucleoids in mutant cells lacking Abf2p ( delta abf2) are diffuse compared with those in wild-type cells. We have isolated mtDNA nucleoids and characterized two mtDNA-protein complexes, termed NCLDp-2 and NCLDs-2, containing distinct but overlapping sets of polypeptides. This protocol yields similar nucleoid complexes from the delta abf2 mutant, although several proteins appear lacking from NCLDs-2. Segments of mtDNA detected with probes to COXII, VAR1 and ori5 sequences are equally sensitive to DNase I digestion in NCLDs-2 and NCLDp-2 from wild-type cells and from the delta abf2 mutant. However, COXII and VAR1 sequences are 4-to 5-fold more sensitive to DNase I digestion of mtDNA in toluene-permeabilized mitochondria from the delta abf2 mutant than from wild-type cells, but no difference in DNase I sensitivity was detected with the ori5 probe. These results provide a first indication that Abf2p influences differential organization of mtDNA sequences.

Drosophila melanogaster mitochondrial DNA: completion of the nucleotide sequence and evolutionary comparisons

The nucleotide sequence of the regions flanking the A+T region of Drosophila melanogaster mitochondrial DNA (mtDNA) has been determined. Included are the genes encoding the transfer RNAs for valine, isoleucine, glutamine and methionine, the small ribosomal RNA and the 5'-coding sequences of the large ribosomal RNA and NADH dehydrogenase subunit II. This completes the nucleotide sequence of the D. melanogaster mitochondrial genome. The circular mtDNA of D. melanogaster varies in size among different populations largely due to length differences in the control region (Fauron & Wolstenholme, 1976; Fauron & Wolstenholme, 1980a, b); the mtDNA region we have sequenced, combined with those sequenced by others, yields a composite genome that is 19,517 bp in length as compared to 16,019 bp for the mtDNA of D. yakuba. D. melanogaster mtDNA exhibits an extreme bias in base composition; it comprises 82.2% deoxyadenylate and thymidylate residues as compared to 78.6% in D. yakuba mtDNA. All genes encoded in the mtDNA of both species are in identical locations and orientations. Nucleotide substitution analysis reveals that tRNA and rRNA genes evolve at less than half the rate of protein coding genes.

Psoralen photofootprinting of protein-binding sites on DNA

Using a BAL31 exonuclease assay to determine the sites of 4,5',8-trimethylpsoralen photocrosslinking in DNA we have shown that 5'-TA sites which are accessible to psoralen DNA interstrand photocrosslinking in naked DNA become inaccessible when protein, in casu, lambda-repressor E. coli or RNA polymerase are bound at their recognition DNA sequences (OR1 operator or deo1 promoter, respectively). These results show that psoralens can be used as photofootprinting reagents to study specific protein-DNA interactions.

A DNA binding protein showing sequence specificity for a region containing the replication origin of Xenopus laevis mitochondrial DNA

In Xenopus laevis mitochondria up to 14 different polypeptides with affinity for the DNA, have been identified by the protein blotting technique. Under stringent binding conditions only one polypeptide displayed specific affinity for a restriction fragment containing the H strand origin of replication of the Xenopus laevis mt chromosome. The proteins were fractionated by double stranded DNA cellulose chromatography. Under conditions which favor high affinity interactions between proteins and DNA, a protein of the 2M NaCl step shows specific binding to the DNA fragments containing the D-loop region. Some physical properties of the protein have been studied. It has a MW of 21.5 Kd and a globular shape as can be inferred from the relationship between MW and sedimentation coefficient (2.7 S). It binds non cooperatively to DNA and forms relatively stable complexes as demonstrated by DNA competition experiments.

The rat liver mitochondrial DNA-protein complex: displaced single strands of replicative intermediates are protein coated

Mitochondrial DNA (mtDNA)-protein complexes were released from the organelles by sodium dodecyl sulfate-lysis and purified by Phenyl-Sepharose CL-4B chromatography. The mitochondrial DNA-binding protein P16 was the only detectable protein in the complex. Treatment of the complex with proteinase K, or subtilisin, revealed the presence of a protease-insensitive, submolecular domain (Mr approximately equal to 6,000) that retained the capacity to bind tenaciously to the DNA. Analysis of chemically fixed complexes by CsCl isopycnic gradient centrifugation showed that P16 was bound to a large subpopulation of mtDNA enriched in displacement loops (D-loops). Based upon the effective buoyant density of the complex in CsCl gradients and the molecular weights of P16 and mtDNA, it was estimated that a mean of 49 P16 molecules were bound per mtDNA. For this measurement, the variation in hydration of protein and DNA at different CsCl concentrations was ignored. Analysis of restriction endonuclease-digested complexes by glass fiber filters that bind only protein-associated DNA resulted in the retention of a single fragment regardless of the enzyme, or enzymes, used. In each case, the retained fragment was the D-loop-containing fragment. With direct electron microscopy, the protein was readily visualized on the displaced single strand portions of D-loops and expanding D-loops. The nucleoprotein fibers were approximately 12 nm in diameter without correcting for the thickness of tungsten coating and roughly 1/3 the length of the double strand segment of the corresponding D-loop structure. In addition, occasional molecules with the characteristics of gapped circles were seen exhibiting a nucleoprotein fibril, presumably containing the single strand gap segment, linking the ends of double strand DNA. P16 was not seen on the double strand portions in any of the complexes.

DNA-protein interactions in the Drosophila virilis mitochondrial chromosome

The location of proteins on the mitochondrial DNA (mtDNA) of Drosophila virilis was investigated by Me3 psoralen photoreaction of mitochondria isolated from embryos. After photoreaction the mtDNA was purified and the pattern of DNA cross-linking was determined by electron microscopy of the DNA under totally denaturing conditions. The transcribed regions of the mtDNA molecule contained some uncross-linked regions, but such regions were infrequent and randomly distributed. In contrast, the A + T-rich region around the origin of replication of the mtDNA was usually protected from psoralen cross-linking. The data were best fit by two protected sites, each approximately 400 base pairs, compared to the four 400 base pair sites observed in the equivalent region of D. melanogaster mtDNA [Potter et al. (1980) Proc. Nat. Acad. Sci. USA 77, 4118-4122]. Thus this region of the mtDNA appears to be involved in a DNA-protein structure that is highly conserved even though the DNA sequence has diverged rapidly relative to protein-coding sequences.

Mitochondrial DNA heteroplasmy in Drosophila mauritiana

Mitochondrial DNA extracted from an isofemale strain of Drosophila mauritiana (subgroup melanogaster) appeared to be heterogeneous in size. A short genome [S; 18,500 base pairs (bp)] and a longer one (L; 19,000 bp) coexist in the preparation. The additional 500 bp have been located within the A+T-rich region. Hpa I digest patterns suggest that the S genome may carry a duplication of a 500-bp sequence including an Hpa I site and that the L genome may carry a triplication of the same sequence. At the 30th generation of the isofemale strain, 60 female genotypes were examined individually. Half of the files were pure either for the S or the L DNA. The remaining 50% exhibited various degrees of heteroplasmy for the two DNA types. Among metazoan animals, this D. mauritiana strain offers an exceptional situation with regard to the number of individuals heterogeneous for mtDNA and the relative stability of heteroplasmy through generations.

Construction, replication, and chromatin structure of TRP1 RI circle, a multiple-copy synthetic plasmid derived from Saccharomyces cerevisiae chromosomal DNA

Transformation studies with Saccharomyces cerevisiae (bakers' yeast) have identified DNA sequences which permit extrachromosomal maintenance of recombinant DNA plasmids in transformed cells. It has been hypothesized that such sequences (called ARS for autonomously replicating sequence) serve as initiation sites for DNA replication in recombinant DNA plasmids and that they represent the normal sites for initiation of replication in yeast chromosomal DNA. We have constructed a novel plasmid called TRP1 R1 Circle which consists solely of 1,453 base pairs of yeast chromosomal DNA. TRP1 RI Circle contains both the TRP1 gene and a sequence called ARS1. This plasmid is found in 100 to 200 copies per cell and is relatively stable during both mitotic and meiotic cell cycles. Replication of TRP1 RI Circle requires the products of the same genes (CDC28, CDC4, CDC7, and CDC8) required for replication of chromosomaL DNA. Like chromosomal DNA, its replication does not occur in cells arrested in the B1 phase of the cell cycle by incubation with the yeast pheromone alpha-factor. In addition, TRP1 RI Circle DNA is organized into nucleosomes whose size and spacing are indistinguishable from that of bulk yeast chromatin. These results indicate that TRP1 RI Circle has the replicative and structural properties expected for an origin of replication from yeast chromosomal DNA. Thus, this plasmid is a suitable model for further studies of yeast DNA replication in both cells and cell-free extracts.

Construction, replication, and chromatin structure of TRP1 RI circle, a multiple-copy synthetic plasmid derived from Saccharomyces cerevisiae chromosomal DNA

Transformation studies with Saccharomyces cerevisiae (bakers' yeast) have identified DNA sequences which permit extrachromosomal maintenance of recombinant DNA plasmids in transformed cells. It has been hypothesized that such sequences (called ARS for autonomously replicating sequence) serve as initiation sites for DNA replication in recombinant DNA plasmids and that they represent the normal sites for initiation of replication in yeast chromosomal DNA. We have constructed a novel plasmid called TRP1 R1 Circle which consists solely of 1,453 base pairs of yeast chromosomal DNA. TRP1 RI Circle contains both the TRP1 gene and a sequence called ARS1. This plasmid is found in 100 to 200 copies per cell and is relatively stable during both mitotic and meiotic cell cycles. Replication of TRP1 RI Circle requires the products of the same genes (CDC28, CDC4, CDC7, and CDC8) required for replication of chromosomaL DNA. Like chromosomal DNA, its replication does not occur in cells arrested in the B1 phase of the cell cycle by incubation with the yeast pheromone alpha-factor. In addition, TRP1 RI Circle DNA is organized into nucleosomes whose size and spacing are indistinguishable from that of bulk yeast chromatin. These results indicate that TRP1 RI Circle has the replicative and structural properties expected for an origin of replication from yeast chromosomal DNA. Thus, this plasmid is a suitable model for further studies of yeast DNA replication in both cells and cell-free extracts.

In situ photochemical crosslinking of HeLa cell mitochondrial DNA by a psoralen derivative reveals a protected region near the origin of replication

The in vivo association with proteins of HeLa cell mitochondrial DNA (mtDNA) has been investigated by analyzing the pattern of in situ crosslinking of the DNA by 4'-hydroxymethyl-4, 5',8-trimethylpsoralen (HMT). Either isolated mitochondria or whole cells were irradiated with long wavelength UV light in the presence of ths psoralen derivative, and the mtDNA was then isolated and analyzed in the electron microscope under totally denaturing conditions. No evidence of nucleosomal structure was found. The great majority of the molecules (approximately 90%) had a double-stranded DNA appearance over most of their contour length, with one to several bubbles occupying the rest of the contour, while the remaining 10% of the molecules appeared to be double-stranded over their entire length. Analysis of restriction fragments indicated the presence, in approximately 80% of the molecules, of a protected segment (300 to 1500 bp long) in a region which was centered asymmetrically around the origin of replication so as to overlap extensively the D-loop. Control experiments showed that at most 30% of the bubbles found near the origin could represent D-loops or expanded D-loops: furthermore, it could be excluded that some sequence peculiarity would account for the preferential location of bubbles near the origin of replication. The data have been interpreted to indicate that, in at least 55% of HeLa cell mtDNA molecules, the region around the origin is protected from in situ psoralen crosslinking by proteins or protein complexes which are associated in vivo with the DNA.

Alkaline gel electrophoresis of deoxyribonucleic acid photoreacted with trimethylpsoralen: rapid and sensitive detection of interstrand cross-links

Restriction fragments of phage lambda and phi X174 deoxyribonucleic acid (DNA) were photoreacted with 4,5',8-trimethylpsoralen to various extents, and the amount of covalent cross-linking was determined by electron microscopy of the DNA under totally denaturing conditions. The DNA was then analyzed by electrophoresis in alkaline agarose gels. A single cross-link in a DNA molecule produced a large decrease in its electrophoretic mobility. With DNA fragments 0.3--4 kilobase pairs in size, the apparent Mr (molecular weight) of the cross-linked DNA was 2.0 +/- 0.1 times and Mr of the unreacted, single-stranded DNA. A single cross-link in a larger DNA molecule resulted in an even greater increase in apparent Mr. Further cross-linking produced a decrease in the apparent Mr of the DNA, reaching a plateau at a value of 1.4 +/- 0.1 times the Mr of the unreacted, single-stranded DNA over a large range of fragment sizes (0.6--10 kilobase pairs). The apparent Mr of the cross-linked DNA was weakly dependent on the percentage of agarose in the gel. Although highly sensitive to interstrand cross-links the electrophoretic mobilities appeared to be unaffected by low levels of monoadducts (trimethylpsoralen covalently bound to one strand of the DNA). The DNA bandwidths increased by as much as 4-fold at low extents of cross-linking, presumably due to heterogeneity in the locations of the cross-links in the DNA molecules. The bands became sharp again at high levels of reaction. These observations from the basis of a new assay for interstrand DNA cross-links that is both more sensitive and more convenient than previous methods.