Liliane A. Dickinson

A tissue-specific MAR SAR DNA-binding protein with unusual binding site recognition

A human cDNA was cloned that encodes a DNA-binding protein (SATB1) that is expressed predominantly in thymus and binds selectively to the nuclear matrix/scaffold-associating DNAs (MARs/SARs). Missing nucleoside experiments showed that SATB1 selectively binds in a special AT-rich sequence context where one strand consists of mixed As, Ts, and Cs, excluding Gs (ATC sequences). When this feature is destroyed by mutation, SATB1 binding is greatly reduced even if the direct contact sequence remains intact. Conjunctional SATB1-binding sequences become stably unpaired in supercoiled DNA. Specific mutations that diminish the unwinding potential greatly reduce SATB1 binding. However, SATB1 does not bind single-stranded DNA. Chemical interference assays show that SATB1 binds along the minor groove with very little contact with the bases. This suggests that SATB1 recognizes the ATC sequence indirectly through the altered sugar-phosphate backbone structure present in the double-stranded DNA.

Nucleolin is a matrix attachment region DNA-binding protein that specifically recognizes a region with high base-unpairing potential.

A DNA affinity column containing a synthetic double-stranded nuclear matrix attachment region (MAR) was used to purify a 100-kDa protein from human erythroleukemia K562 cells. This protein was identified as nucleolin, the key nucleolar protein of dividing cells, which is thought to control rRNA gene transcription and ribosome assembly. Nucleolin is known to bind RNA and single-stranded DNA. We report here that nucleolin is also a MAR-binding protein. It binds double-stranded MARs from different species with high affinity. Nucleolin effectively distinguishes between a double-stranded wild-type synthetic MAR sequence with a high base-unpairing potential and its mutated version that has lost the unpairing capability but is still A+T rich. Thus, nucleolin is not merely an A+T-rich sequence-binding protein but specifically binds the base-unpairing region of MARs. This binding specificity is similar to that of the previously cloned tissue-specific MAR-binding protein SATB1. Unlike SATB1, which binds only double-stranded MARs, nucleolin binds the single-stranded T-rich strand of the synthetic MAR probe approximately 45-fold more efficiently than its complementary A-rich strand, which has an affinity comparable to that of the double-stranded form of the MAR. In contrast to the high selectivity of binding to double-stranded MARs, nucleolin shows only a small but distinct sequence preference for the T-rich strand of the wild-type synthetic MAR over the T-rich strand of its mutated version. The affinity to the T-rich synthetic MAR is severalfold higher than to its corresponding RNA and human telomere DNA. Quantitative cellular fractionation and extraction experiments indicate that nucleolin is present both as a soluble protein and tightly bound to the matrix, similar to other known MAR-binding proteins.

SATB1 Cleavage by Caspase 6 Disrupts PDZ Domain-Mediated Dimerization, Causing Detachment from Chromatin Early in T-Cell Apoptosis

ABSTRACT SATB1 is expressed primarily in thymocytes and orchestrates temporal and spatial expression of a large number of genes in the T-cell lineage. SATB1 binds to the bases of chromatin loop domains in vivo, recognizing a special DNA context with strong base-unpairing propensity. The majority of thymocytes are eliminated by apoptosis due to selection processes in the thymus. We investigated the fate of SATB1 during thymocyte and T-cell apoptosis. Here we show that SATB1 is specifically cleaved by a caspase 6-like protease at amino acid position 254 to produce a 65-kDa major fragment containing both a base-unpairing region (BUR)-binding domain and a homeodomain. We found that this cleavage separates the DNA-binding domains from amino acids 90 to 204, a region which we show to be a dimerization domain. The resulting SATB1 monomer loses its BUR-binding activity, despite containing both its DNA-binding domains, and rapidly dissociates from chromatin in vivo. We found this dimerization region to have sequence similarity to PDZ domains, which have been previously shown to be involved in signaling by conferring protein-protein interactions. SATB1 cleavage during Jurkat T-cell apoptosis induced by an anti-Fas antibody occurs concomitantly with the high-molecular-weight fragmentation of chromatin of ∼50-kb fragments. Our results suggest that mechanisms of nuclear degradation early in apoptotic T cells involve efficient removal of SATB1 by disrupting its dimerization and cleavage of genomic DNA into loop domains to ensure rapid and efficient disassembly of higher-order chromatin structure.

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 As, Ts, and Cs, excluding Gs (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.

An Atypical Homeodomain in SATB1 Promotes Specific Recognition of the Key Structural Element in a Matrix Attachment Region

SATB1 is a cell type-specific nuclear matrix attachment region (MAR) DNA-binding protein, predominantly expressed in thymocytes. We identified an atypical homeodomain and two Cut-like repeats in SATB1, in addition to the known MAR-binding domain. The isolated MAR-binding domain recognizes a certain DNA sequence context within MARs that is highly potentiated for base unpairing. Unlike the MAR-binding domain, the homeodomain when isolated binds poorly and with low specificity to DNA. However, the combined action of the MAR-binding domain and the homeodomain allows SATB1 to specifically recognize the core unwinding element within the base-unpairing region. The core unwinding element is critical for MAR structure, since point mutations within this core abolish the unwinding propensity of the MAR. The contribution of the homeodomain is abolished by alanine substitutions of arginine 3 and arginine 5 in the N-terminal arm of the homeodomain. Site-directed mutagenesis of the core unwinding element in the 3′ MAR of the immunoglobulin heavy chain gene enhancer revealed the sequence 5′-(C/A)TAATA-3′ to be essential for the increase in affinity mediated by the homeodomain. SATB1 may regulate T-cell development and function at the level of higher order chromatin structure through the critical DNA structural elements within MARs.

A Novel Matrix Attachment Region DNA Binding Motif Identified Using a Random Phage Peptide Library

SATB1 is a nuclear matrix attachment DNA (MAR)-binding protein which is predominantly expressed in thymocytes. This protein binds to the minor groove specifically recognizing an unusual DNA context exhibited by a specific MAR region with strong base-unpairing propensity. A phage library displaying nonamer random peptides without any built-in structure was used to identify a MAR binding motif of SATB1. One predominant cyclic peptide C1 of CRQNWGLEGC selected by a MAR-affinity column showed 50% identity with a segment in SATB1 (amino acids 355-363). Replacement of the C1 similarity segment in SATB1 by a random amino acid sequence or its truncation resulted in more than 80% reduction in MAR binding. In contrast, replacement of the same SATB1 segment with the C1 peptide restored full MAR binding activity and specificity as the wild-type protein. Single amino acid mutation of the conserved Arg or Glu residue to Ala greatly reduced MAR binding. Taken together our data show that a nine amino acid sequence in SATB1 represents a key MAR binding motif. Phage display may provide a general tool for rapid identification of DNA binding peptide motifs.

Identification of base-unpairing region-binding proteins and characterization of their in vivo binding sequences.

Publisher Summary This chapter discusses base-unpairing region (BUR) that is an important region of genomic DNA because SATB1 (a T cell factor) recognizes specifically BURs within matrix attachment regions (MAR) segments and this is also found to be true for Bright. Both SATB1 and Bright recognize a specific DNA context that consists of the clustering of ATC sequences where one strand is exclusively As, Ts, and Cs but not Gs. Clustering of ATC sequences corresponds to BURs. The recent results using SATB1 knockout mice showed that SATB1 is essential for proper T cell development and resistance to apoptosis. BUR is also a specific target for breast cancer-associated matrix attachment regions (MAR)-binding protein p114, the MAR-binding activity of which is detectable only in breast carcinoma but not in normal breast of benign breast lesions. The chapter discusses the identification of BURs, the utility of BUR with respect to identifying more BUR-recognizing proteins, and in vivo binding sequences for this new class of DNA binding proteins.