Cationic metal-specific structures adopted by the poly(dG) region and the direct repeats in the chicken adult beta A globin gene promoter.

Naturally occurring contiguous deoxyguanine residues and their surrounding sequences in the chicken adult beta A globin gene promoter were analyzed for their inherent potential to adopt non-B DNA structures in supercoiled plasmid DNA. In particular, cationic effects on structure were studied by treating the supercoiled plasmid DNA harboring the chicken adult beta A globin 5' flanking sequence with an unpaired DNA base-specific probe, chloroacetaldehyde in the presence of either Mg++, Cu++, Zn++, Ca++ or Co++ ions. The chloroacetaldehyde-reactive bases were mapped at a single base resolution by a chemical cleavage method that specifically cleaves DNA at the chloroacetaldehyde modified sites. These experiments revealed that while Mg++ and Ca++ ions induce a dG.dG.dC triple helix structure at the contiguous dG residues, Zn++, Cu++ and Co++ ions induce yet another structure at the direct repeats immediately 5' of the dG residues. When Mg++ and Zn++ ions are both present, Zn++ inhibits the dG.dG.dC triplex at the contiguous dG residues and induces a particular non-B DNA structure at the adjacent direct repeats. The specific induction of non-B DNA structures by metal ions at the two adjacent sequences within the promoter region may be of biological significance.     

Intramolecular dG.dG.dC triplex detected in Escherichia coli cells.

The formation of an intramolecular dG.dG.dC triplex in Escherichia coli cells is demonstrated at single-base resolution. The intramolecular dG.dG.dC triplex structure was probed in situ for E. coli cells containing plasmid DNAs with varying lengths of poly(dG).poly(dC) tracts employing chloroacetaldehyde. This chemical probe reacts specifically with unpaired DNA bases. The triplex structure formed with the poly(dG).poly(dC) tracts of 35 and 44 base-pairs, but not with 25 base-pairs. The triplex was detected only one to two hours after the chloramphenicol treatment: the period at which the extracted plasmid DNA revealed the maximal superhelical density.     

Satb1 ablation alters temporal expression of immediate early genes and reduces dendritic spine density during postnatal brain development

Complex behaviors, such as learning and memory, are associated with rapid changes in gene expression of neurons and subsequent formation of new synaptic connections. However, how external signals are processed to drive specific changes in gene expression is largely unknown. We found that the genome organizer protein Satb1 is highly expressed in mature neurons, primarily in the cerebral cortex, dentate hilus, and amygdala. In Satb1-null mice, cortical layer morphology was normal. However, in postnatal Satb1-null cortical pyramidal neurons, we found a substantial decrease in the density of dendritic spines, which play critical roles in synaptic transmission and plasticity. Further, we found that in the cerebral cortex, Satb1 binds to genomic loci of multiple immediate early genes (IEGs) (Fos, Fosb, Egr1, Egr2, Arc, and Bdnf) and other key neuronal genes, many of which have been implicated in synaptic plasticity. Loss of Satb1 resulted in greatly alters timing and expression levels of these IEGs during early postnatal cerebral cortical development and also upon stimulation in cortical organotypic cultures. These data indicate that Satb1 is required for proper temporal dynamics of IEG expression. Based on these findings, we propose that Satb1 plays a critical role in cortical neurons to facilitate neuronal plasticity.     

A novel DNA-binding motif in the nuclear matrix attachment DNA-binding protein SATB1.

The nuclear matrix attachment DNA (MAR) binding protein SATB1 is a sequence context-specific binding protein that binds in the minor groove, making virtually no contact with the DNA bases. The SATB1 binding sites consist of a special AT-rich sequence context in which one strand is well-mixed A's, T's, and C's, excluding G's (ATC sequences), which is typically found in clusters within different MARs. To determine the extent of conservation of the SATB1 gene among different species, we cloned a mouse homolog of the human STAB1 cDNA from a cDNA expression library of the mouse thymus, the tissue in which this protein is predominantly expressed. This mouse cDNA encodes a 764-amino-acid protein with a 98% homology in amino acid sequence to the human SATB1 originally cloned from testis. To characterize the DNA binding domain of this novel class of protein, we used the mouse SATB1 cDNA and delineated a 150-amino-acid polypeptide as the binding domain. This region confers full DNA binding activity, recognizes the specific sequence context, and makes direct contact with DNA at the same nucleotides as the whole protein. This DNA binding domain contains a novel DNA binding motif: when no more than 21 amino acids at either the N- or C-terminal end of the binding domain are deleted, the majority of the DNA binding activity is lost. The concomitant presence of both terminal sequences is mandatory for binding. These two terminal regions consist of hydrophilic amino acids and share homologous sequences that are different from those of any known DNA binding motifs. We propose that the DNA binding region of SATB1 extends its two terminal regions toward DNA to make direct contact with DNA.     

Single-stranded DNA binding proteins isolated from mouse brain recognize specific trinucleotide repeat sequences in vitro.

Expansion of trinucleotide repeats (CAG)n and (CGG)n is found in genes responsible for certain human hereditary neurodegenerative diseases. By gel-mobility shift assay, we detected a single-stranded (AGC)n repeat-binding activity primarily in mouse brain extracts and very low or undetectable activity in other tissue extracts. Two (AGC)n-repeat binding proteins, with apparent molecular weights of 44 and 40 kDa, have been purified from mouse adult brain by a DNA affinity column and fast protein liquid chromatography. UV-cross linking of radiolabeled (AGC)n repeats with crude brain extracts and with purified two proteins of 44 and 40 kDa produced identical doublet bands, indicating that these proteins are in fact responsible for the (AGC)n-binding activity in brain extracts. We designated these two proteins TRIP-1 for the 44 kDa protein and TRIP-2 for the 40 kDa protein, where TRIP represents trinucleotide repeat-binding protein. TRIP-1 and TRIP-2 bind to a specific subset of trinucleotide repeat sequences including (AGC)n, (AGT)n, (GGC)n, and (GGT)n repeats but not to various other trinucleotide repeats. A minimum of eight (AGC) trinucleotide repeating units is required for TRIP-1 and -2 recognition and binding. The (AGC)n repeat-binding activity increases in the brain after birth and reaches a plateau within 3 weeks. In the brain, TRIP-1 and TRIP-2 may alter the function of the genes containing the expanded-trinucleotide repeats.     

Torsional stress stabilizes extended base unpairing in suppressor sites flanking immunoglobulin heavy chain enhancer

DNA sequences surrounding the immunoglobulin heavy chain (IgH) enhancer contain negative regulatory elements which are important for the tissue specificity of the enhancer. We have shown that sequences located both 5' and 3' of the enhancer, corresponding to the negative regulatory elements, become stably and uniformly unpaired over an extended length when subjected to torsional stress. These DNA sequences are also included within matrix association regions. The ability of the sequences to assume a stably unpaired conformation was shown by reactivity with chloroacetaldehyde which is specific for unpaired DNA bases, as well as two-dimensional gel electrophoresis of topoisomers. The sequences located 3' of the enhancer induce base unpairing in the direction of the enhancer. This unpaired region progressively expands to include as much as 200 base pairs as the ionic concentration decreases or superhelical density increases. When an ATATAT motif within a negative regulatory element located 3' of the enhancer was mutated, the extensive base-unpairing property was abolished. This base-unpairing property of DNA may be important for negative regulation of gene expression and attachment to the nuclear matrix.