DNA and RNA binding by the mitochondrial lon protease is regulated by nucleotide and protein substrate

The ATP-dependent Lon protease belongs to a unique group of proteases that bind DNA. Eukaryotic Lon is a homo-oligomeric ring-shaped complex localized to the mitochondrial matrix. In vitro, human Lon binds specifically to a single-stranded GT-rich DNA sequence overlapping the light strand promoter of human mitochondrial DNA (mtDNA). We demonstrate that Lon binds GT-rich DNA sequences found throughout the heavy strand of mtDNA and that it also interacts specifically with GU-rich RNA. ATP inhibits the binding of Lon to DNA or RNA, whereas the presence of protein substrate increases the DNA binding affinity of Lon 3.5-fold. We show that nucleotide inhibition and protein substrate stimulation coordinately regulate DNA binding. In contrast to the wild type enzyme, a Lon mutant lacking both ATPase and protease activity binds nucleic acid; however, protein substrate fails to stimulate binding. These results suggest that conformational changes in the Lon holoenzyme induced by nucleotide and protein substrate modulate the binding affinity for single-stranded mtDNA and RNA in vivo. Co-immunoprecipitation experiments show that Lon interacts with mtDNA polymerase gamma and the Twinkle helicase, which are components of mitochondrial nucleoids. Taken together, these results suggest that Lon participates directly in the metabolism of mtDNA.     

Interaction of a protein factor within a thyroid hormone-sensitive region of rat alpha-myosin heavy chain gene

Using a gel mobility-shift assay, a nuclear protein factor was identified in cardiac myocyte which binds specifically to a DNA fragment from the 5' region of the alpha-myosin heavy chain gene shown previously to contain a thyroid hormone-sensitive element. Methylation interference experiments located the binding site within a 24-base pair sequence from positions -599 to -576. A double-stranded synthetic oligonucleotide containing this 24-base pair sequence bound to the factor and effectively competed with the natural binding site for factor binding. The factor was present in rat and human fibroblasts, and rat GH1 cells as well as L6E9 myoblasts and myotubes. The specificity with which this factor binds to DNA suggests that it could be involved in regulation of the alpha-myosin heavy chain gene.     

Self-organisation of an oligodeoxynucleotide containing the G- and C-rich stretches of the direct repeats of the human mitochondrial DNA

Stretches of cytosines and guanosines have been shown in vitro to adopt non-canonical structures known as i-motifs and G-quartets, respectively. When combined, such sequences are expected to either retain their structure or form duplexes or triple helices. All these structures may occur in vivo whenever the sequence criteria are met. Such stretches are present in the circular genome of human mitochondria, as two 10 nucleotide-long perfect tandem direct repeats (DR1 and DR2). The DR1 and DR2 repeats are G-rich on the heavy strand and C-rich on the light strand. Previous results suggested that during replication, transient formation of a parallel GGC triple helix between the neo-synthesised G-rich DR1 and the double-stranded homologous DR2 could be involved in a rearrangement process leading to genome instability. In order to get structural insights into the interaction between the two repeats, we have studied by nuclear magnetic resonance (NMR) the assembly properties of a 24-mer oligodeoxyribonucleotide in which the C- and G-rich segments of the DRs are covalently tethered by a TTTT linker. We show here that this 24-mer self-associates into a triplex-containing symmetrical tetramer. The core of the structure is composed of anti-parallel Watson-Crick (WC) base pairs. Two additional strands are hydrogen-bonded to the Hoogsteen side of the Gs, thus forming CGC(+) triple helices, with G-rich ends folding into G-quartets. These results suggest that such structures could occur when the two DRs are put to close proximity in a biological context.     

GRSF-1: a poly(A)+ mRNA binding protein which interacts with a conserved G-rich element.

Computer predictions identified similarities to a 14-base G-rich element in numerous mRNAs at a variety of locations. A Northwestern screening strategy was used to obtain a cDNA clone from a HeLa cell library using the G-rich RNA element as a probe. A cellular protein (called GRSF-1), which was encoded by this cDNA, binds RNAs containing the G-rich element. GRSF-1 was distinct from DSEF-1, a nuclear protein we have previously identified that interacts with the G-rich element, based on differences in molecular weight and partial peptide maps, as well as the lack of cross-reactivity with GRSF-1 specific monoclonal antibodies. Using indirect immunofluorescence microscopy, we localized GRSF-1 to the cytoplasm. In vivo UV cross-linking further demonstrated that GRSF-1 was bound to poly(A)+ mRNA in living human cells. Western blot analysis revealed four cytoplasmic proteins which expressed GRSF-1 specific epitopes. GRSF-1 contains three potential RNA recognition motifs and two auxiliary domains. Curiously, the domain organization of GRSF-1 is similar to the RNA binding proteins PUB1, ELAV, HuD, Hel-N1, mcs94-1 and RBP9.     

Interactions of the human telomeric DNA with terbium-amino acid complexes

The human telomeric DNA can form four-stranded structures: the G-rich strand adopts a G-quadruplex conformation stabilized by G-quartets and the C-rich strand may fold into an I-motif based on intercalated C.C(+) base pairs. There is intense interests in the design and synthesis of compounds which can target telomeric DNA and inhibit the telomerase activity. Here we report the thermodynamic studies of the two newly synthesized terbium-amino acid complexes bound to the human telomeric G-quadruplex and I-motif DNA which were studied by means of UV-Visible, DNA meltings, fluorescence and circular dichroism. These two complexes can bind to the human telomeric DNA and have shown different features on DNA stability, binding stoichiometry, and sequence-dependent fluorescence enhancement. To our knowledge, this is the first report to show terbium-amino acid complexes can interact with the human telomeric DNA.     

DNA binding activities of c-Myc purified from eukaryotic cells.

c-Myc is a nuclear phosphoprotein which contains both a leucine zipper and a helix-loop-helix dimerization motif. These are adjacent to a basic region believed to make specific contacts with DNA upon dimerization. We report the purification of full-length c-Myc to near homogeneity from two independent eukaryotic systems: the baculovirus overexpression system using an insect cell host, and Chinese hamster ovary cells containing heat-inducible c-myc genes. The DNA binding capabilities of these preparations were characterized. Both preparations contain two distinct activities that bind specifically to sequences with a core of CACGTG. The Myc protein is solely responsible for one of these binding activities. Specific sequences that bound to c-Myc were selected from a large pool of random DNA sequence. Sequencing of individual binding sites selected by this procedure yielded a 12-base consensus, PuACCACGTGCTC, for c-Myc binding. Both protein preparations additionally demonstrated a distinct complex, containing both c-Myc and a copurifying 26-29-kDa protein, that bound to DNA with higher affinity than Myc alone. Selection of specific DNA sequences by this complex revealed a consensus binding site similar to the 12-base consensus described above. These data demonstrate that c-Myc isolated from eukaryotic cells is capable of sequence-specific DNA binding and further refine the optimal sequence for c-Myc binding. These protein preparations should prove useful in further characterizing the biochemical properties of c-Myc.     

Ku binds telomeric DNA in vitro.

Ku is a heterodimeric protein with high binding affinity for ends, nicks, and gaps in double-stranded DNA. Both in mammalian cells and in budding yeast, Ku plays a role in nonhomologous end joining in the double strand break repair pathway. However, Ku has a more significant role in DNA repair in mammalian cells compared with yeast, in which a homology-dependent pathway is the predominant one. Recently Ku has been shown to be a likely component of the telomeric complex in yeast, suggesting the possibility of a similar role for Ku at mammalian telomeres. However, long single-stranded G-rich overhangs are continuously present at mammalian but not at yeast telomeres. These overhangs have the potential to fold in vitro into G-G base-paired conformations, such as G-quartets, that might prevent Ku from recognizing telomeric ends and thus offer a mechanism to sequester the telomere from the prevalent double strand break repair pathway in mammals. We show here that Ku binds to mammalian telomeric DNA ends in vitro and that G-quartet conformations are unable to prevent Ku from binding with high affinity to the DNA. Our results indicate that the DNA binding characteristics of Ku are consistent with its direct interaction with telomeric DNA in mammalian cells and its proposed role as a telomere end factor.     

The same CCAAT box-binding factor binds to the promoter of two coordinately regulated major histocompatibility complex class II genes.

Using competition mobility shift, methylation interference, and proteolytic clipping DNA binding assays, we demonstrate that the protein binding the major histocompatibility complex A beta CCAAT box is indistinguishable from the protein previously named NF-Y, which binds the major histocompatibility complex E alpha CCAAT box. Although the two CCAAT boxes share the same 10-base core sequence, termed the Y box, their flanking sequences, known to be important for binding, are very different.     

A human DNA-binding protein is methylation-specific and sequence-specific.

A nuclear protein isolated from human placenta, methylated DNA-binding protein (MDBP), binds selectively to DNA enriched in 5-methylcytosine. We now demonstrate that MDBP is a sequence-specific, as well as methylation-specific, DNA-binding protein. From ten restriction fragments of pBR322 DNA methylated with human DNA methyltransferase, one was bound to MDBP very much more strongly than any of the others. For this preferential binding to MDBP, the DNA had to be methylated. By a DNase I protection experiment (DNase I footprinting), a 22-base sequence within this methylated restriction fragment was shown to be specifically protected by MDBP. The sequence-specificity of MDBP coupled with its dependence on DNA methylation suggests that this is one of the proteins which modulates important functions of human DNA methylation in vivo.     

Energetic basis for selective recognition of T*G mismatched base pairs in DNA by imidazole-rich polyamides

To complement available structure and binding results and to develop a detailed understanding of the basis for selective molecular recognition of T·G mismatches in DNA by imidazole containing polyamides, a full thermodynamic profile for formation of the T·G–polyamide complex has been determined. The amide-linked heterocycles f-ImImIm and f-PyImIm (where f is formamido group, Im is imidazole and Py is pyrrole) were studied by using biosensor-surface plasmon resonance (SPR) and isothermal titration calorimetry (ITC) with a T·G mismatch containing DNA hairpin duplex and a similar DNA with only Watson–Crick base pairs. Large negative binding enthalpies for all of the polyamide–DNA complexes indicate that the interactions are enthalpically driven. SPR results show slower complex formation and stronger binding of f-ImImIm to the T·G than to the match site. The thermodynamic analysis indicates that the enhanced binding to the T·G site is the result of better entropic contributions. Negative heat capacity changes for the complex are correlated with calculated solvent accessible surface area changes and indicate hydrophobic contributions to complex formation. DNase I footprinting analysis in a long DNA sequence provided supporting evidence that f-ImImIm binds selectively to T·G mismatch sites.     

Effects of inorganic polyphosphate on the proteolytic and DNA-binding activities of Lon in Escherichia coli

Lon belongs to a unique group of proteases that bind to DNA and is involved in the regulation of several important cellular functions, including adaptation to nutritional downshift. Previously, we revealed that inorganic polyphosphate (polyP) increases in Escherichia coli in response to amino acid starvation and that it stimulates the degradation of free ribosomal proteins by Lon. In this work, we examined the effects of polyP on the proteolytic and DNA-binding activities of Lon. An order-of-addition experiment suggested that polyP first binds to Lon, which stimulates Lon-mediated degradation of ribosomal proteins. A polyP-binding assay using Lon deletion mutants showed that the polyP-binding site of Lon is localized in the ATPase domain. Because the same ATPase domain also contains the DNA-binding site, polyP can compete with DNA for binding to Lon. In fact, an equimolar amount of polyP almost completely inhibited DNA-Lon complex formation, suggesting that Lon binds to polyP with a higher affinity than it binds to DNA. Collectively, our results showed that polyP may control the cellular activity of Lon not only as a protease but also as a DNA-binding protein.     

TraJ protein of plasmid RP4 binds to a 19-base pair invert sequence repetition within the transfer origin

Transfer of plasmid RP4 during bacterial conjugation requires the plasmid-encoded TraJ protein, which binds to the transfer origin (Fürste, J. P., Pansegrau, W., Ziegelin, G., Kr?ger, M., and Lanka, E. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 1771-1775). As indicated by traJ mutants, the TraJ protein is a constituent of the relaxosome, the initiation complex of transfer DNA replication. The traJ gene maps adjacent to the transfer origin (oriT). The structural gene consists of a 372-base pair sequence encoding a polypeptide of 122 amino acids (13,282 Da). TraJ was purified from an Escherichia coli strain overproducing the protein. DNA footprinting experiments involving DNase I demonstrated that the purified protein binds to the right arm of a 19-base pair inverted repeat within oriT. Hydroxyl radical footprints of the DNA-protein complex revealed that TraJ protein is bound to only one side of the DNA helix.     

DNA-binding specificity of the Lon protease α-domain from Brevibacillus thermoruber WR-249

Lon protease has been well studied in many aspects; however, the DNA-binding specificity of Lon in prokaryotes has not been clearly identified. Here we examined the DNA-binding activity of Lon protease α-domains from Brevibacillus thermoruber (Bt), Bacillus subtilis (Bs), and Escherichia coli (Ec). MALDI-TOF mass spectroscopy showed that the α-domain from Bt-Lon binds to the duplex nucleotide sequence 5′-CTGTTAGCGGGC-3′ (ms1) and protected it from DNase I digestion. Surface plasmon resonance showed that the Bt-Lon α-domain binds with ms1 double-stranded DNA tighter than Bs- and Ec-Lon α-domains, whereas the Bt-Lon α-domain has dramatically lower affinity for double-stranded DNA with 0 and 50% identity to the ms1 binding sequence. Our results indicated that Bt-Lon α-domain plays a critical role with ms1 sequence in the DNA-binding specificity.