Sequence-dependent upstream DNA-RNA polymerase interactions in the open complex with lambdaPR and lambdaPRM promoters and implications for the mechanism of promoter interference.

Upstream interactions of Escherichia coli RNA polymerase (RNAP) in an open promoter complex (RPo) formed at the P(R) and P(RM) promoters of bacteriophage lambda have been studied by atomic force microscopy. We demonstrate that the previously described 30-nm DNA compaction observed upon RPo formation at P(R) [Rivetti, C., Guthold, M. & Bustamante, C. (1999). Wrapping of DNA around the E. coli RNA polymerase open promoter complex. EMBO J., 18, 4464-4475.] is a consequence of the specific interaction of the RNAP with two AT-rich sequence determinants positioned from -36 to -59 and from -80 to -100. Likewise, RPos formed at P(RM) showed a specific contact between RNAP and the upstream DNA sequence. We further demonstrate that this interaction, which results in DNA wrapping against the polymerase surface, is mediated by the C-terminal domains of alpha-subunits (carboxy-terminal domain). Substitution of these AT-rich sequences with heterologous DNA reduces DNA wrapping but has only a small effect on the activity of the P(R) promoter. We find, however, that the frequency of DNA templates with both P(R) and P(RM) occupied by an RNAP significantly increases upon loss of DNA wrapping. These results suggest that alpha carboxy-terminal domain interactions with upstream DNA can also play a role in regulating the expression of closely spaced promoters. Finally, a model for a possible mechanism of promoter interference between P(R) and P(RM) is proposed.

Upstream promoter sequences and alphaCTD mediate stable DNA wrapping within the RNA polymerase-promoter open complex.

We show that the extent of stable DNA wrapping by Escherichia coli RNA polymerase (RNAP) in the RNAP-promoter open complex depends on the sequence of the promoter and, in particular, on the sequence of the upstream region of the promoter. We further show that the extent of stable DNA wrapping depends on the presence of the RNAP alpha-subunit carboxy-terminal domain and on the presence and length of the RNAP alpha-subunit interdomain linker. Our results indicate that the extensive stable DNA wrapping observed previously in the RNAP-promoter open complex at the lambda P(R) promoter is not a general feature of RNAP-promoter open complexes.

DNA condensation and cell transfection properties of guanidinium calixarenes: dependence on macrocycle lipophilicity, size, and conformation.

Calix[n]arenes functionalized with guanidinium groups at the upper rim and alkyl chains at the lower rim bind to DNA, condense it, and in some cases, promote cell transfection depending on their structure and lipophilicity. Atomic force microscopy (AFM) studies indicate that upon DNA binding the hydrophobic association of the lipophilic chains of cone guanidinium calix[4]arenes drives the formation of intramolecular DNA condensates, characterized by DNA loops emerging from a dense core. Furthermore, hexyl and octyl chains confer to these calixarenes cell transfection capabilities. Conversely, larger and conformationally mobile calix[6]- and calix[8]arene methoxy derivatives form intermolecular aggregates characterized by "gorgonlike" structures composed of multiple plectomenes. These adducts, in which interstrand connections are dominated by electrostatic interactions, fail to promote cell transfection. Finally, calix[4]arenes in a 1,3-alternate conformation show an intermediate behavior because they condense DNA, but the process is driven by charge-charge interactions.

Structural and functional properties of lengsin, a pseudo-glutamine synthetase in the transparent human lens.

Lengsin (LGS) is an abundant transcript in the human lens, encoding a predicted polypeptide similar to glutamine synthetase (GS). We show that a major alternatively spliced product of LGS codes for a 57kDa polypeptide that assembles into a catalytically inactive dodecamer, cross-reacts with anti-GS antibodies, and is expressed at high levels in transparent, but not cataractous, human lenses. Based on this characteristic oligomeric organization, preferential expression in the transparent lens, and amyloid-beta association previously reported for GS, a potential chaperone-like role of LGS has been investigated. We find that LGS has six binding sites for the hydrophobic surface probe bis-ANS and relieves cellular toxicity caused by amyloid-beta expression in a folding-impaired yeast mutant. While documenting the structural similarity between LGS and prokaryotic GS-I, the data rule out any involvement of lengsin in glutamine biosynthesis and suggest an unrelated role that may be important for lens homeostasis and transparency.

DNA condensation and self-aggregation of Escherichia coli Dps are coupled phenomena related to the properties of the N-terminus.

Escherichia coli Dps (DNA-binding proteins from starved cells) is the prototype of a DNA-protecting protein family expressed by bacteria under nutritional and oxidative stress. The role of the lysine-rich and highly mobile Dps N-terminus in DNA protection has been investigated by comparing the self-aggregation and DNA-condensation capacity of wild-type Dps and two N-terminal deletion mutants, DpsDelta8 and DpsDelta18, lacking two or all three lysine residues, respectively. Gel mobility and atomic force microscopy imaging showed that at pH 6.3, both wild type and DpsDelta8 self-aggregate, leading to formation of oligomers of variable size, and condense DNA with formation of large Dps-DNA complexes. Conversely, DpsDelta18 does not self-aggregate and binds DNA without causing condensation. At pH 8.2, DpsDelta8 and DpsDelta18 neither self-aggregate nor cause DNA condensation, a behavior also displayed by wild-type Dps at pH 8.7. Thus, Dps self-aggregation and Dps-driven DNA condensation are parallel phenomena that reflect the properties of the N-terminus. DNA protection against the toxic action of Fe(II) and H2O2 is not affected by the N-terminal deletions either in vitro or in vivo, in accordance with the different structural basis of this property.

Imaging transcription complexes with the Atomic Force Microscope.

Recent developments in sample deposition and image analysis have shown that the Atomic Force Microscope is a valuable tool for the structural investigation of transcription complexes. When deposited under conditions that allow molecular equilibration onto the substrate, transcription complexes behave as worm-like chains and the mean square end-to-end distance can readily be used to determine the protein induced DNA bend angle. Measurements of the DNA contour length by means of accurate image processing procedures have revealed a DNA compaction in transcription complexes which is compatible with wrapping of the DNA against the surface of the RNA Polymerase. The methods presented have to be considered of general practical use for imaging protein-DNA complexes.