Human SWI/SNF nucleosome remodeling activity is partially inhibited by linker histone H1

The physical structure and the compact nature of the eukaryotic genome present a functional barrier for any cellular process that requires access to the DNA. The linker histone H1 is intrinsically involved in both the determination of and the stability of higher order chromatin structure. Because histone H1 plays a pivotal role in the structure of chromatin, we investigated the effect of histone H1 on the nucleosome remodeling activity of human SWI/SNF, an ATP-dependent chromatin remodeling complex. The results from both DNase I digestion and restriction endonuclease accessibility assays indicate that the presence of H1 partially inhibits the nucleosome remodeling activity of hSWI/SNF. Neither H1 bound to the nucleosome nor free H1 affected the ATPase activity of hSWI/SNF, suggesting that the observed inhibition of hSWI/SNF nucleosome remodeling activity depends on the structure formed by the addition of H1 to nucleosomes.     

Disparity in the DNA translocase domains of SWI/SNF and ISW2

An ATP-dependent DNA translocase domain consisting of seven conserved motifs is a general feature of all ATP-dependent chromatin remodelers. While motifs on the ATPase domains of the yeast SWI/SNF and ISWI families of remodelers are highly conserved, the ATPase domains of these complexes appear not to be functionally interchangeable. We found one reason that may account for this is the ATPase domains interact differently with nucleosomes even though both associate with nucleosomal DNA 17–18 bp from the dyad axis. The cleft formed between the two lobes of the ISW2 ATPase domain is bound to nucleosomal DNA and Isw2 associates with the side of nucleosomal DNA away from the histone octamer. The ATPase domain of SWI/SNF binds to the same region of nucleosomal DNA, but is bound outside of the cleft region. The catalytic subunit of SWI/SNF also appears to intercalate between the DNA gyre and histone octamer. The altered interactions of SWI/SNF with DNA are specific to nucleosomes and do not occur with free DNA. These differences are likely mediated through interactions with the histone surface. The placement of SWI/SNF between the octamer and DNA could make it easier to disrupt histone–DNA interactions.     

BAF57 governs androgen receptor action and androgen-dependent proliferation through SWI/SNF

Androgen receptor (AR) activity is required for prostate cancer development and progression. Thus, there is a major impetus to understand the regulation of AR action. We and others have previously shown that AR transactivation potential is dependent on the presence of an active SWI/SNF chromatin remodeling complex. However, the mechanisms underlying SWI/SNF regulation of the AR remained unsolved. We show here that the BAF57 subunit, an accessory component of the remodeling complex, is a critical regulator of AR function. We show that BAF57 is expressed in the luminal epithelia of the prostate and is required for AR-dependent transactivation in prostatic adenocarcinoma cells. Our data reveal that BAF57 can directly bind to the AR and is recruited to endogenous AR targets upon ligand activation. Loss of BAF57 or inhibition of BAF57 function severely compromised AR activity, as observed with both exogenous and endogenous AR targets. Rescue of BAF57 function restored AR activity, thus demonstrating a specific requirement of BAF57 for AR activity. This action of BAF57 proved to be dependent on SWI/SNF ATPase function. BAF57 has previously been implicated in nuclear receptor coactivator function, and we show that, although BAF57 facilitated coactivator activity, only a selected subset required BAF57 for coactivator function. Lastly, we demonstrate that both BAF57 and BRM are required for the proliferation of AR-dependent prostatic adenocarcinoma cells. In summary, these findings identify BAF57 as a critical modulator of the AR that is capable of altering AR activity, coactivator function, and AR-dependent proliferation.     

Components of the SWI/SNF complex are required for asymmetric cell division in C. elegans

Asymmetric cell division is a fundamental process that produces cellular diversity during development. We have identified two mutants in C. elegans (psa-1 and psa-4) in which the asymmetry of T cell division is disrupted. psa-1 and psa-4 encode homologs of yeast SWI3 and SWI2/SNF2, respectively, which are components of the SWI/SNF complex. We show by RNA interference assay that homologs of other components of SWI/SNF are also involved in T cell division. psa-1 and psa-4 are likely to be required in the T cell during mitosis to cause asymmetric cell division. Because the SWI/SNF complex is required for asymmetric division in S. cerevisiae, these results demonstrate that at least some aspects of the mechanism of asymmetric cell division are conserved between yeast and a multicellular organism.     

Motifs Q and I are required for ATP hydrolysis but not for ATP binding in SWI2/SNF2 proteins

Active DNA-dependent ATPase A Domain (ADAAD) is a SWI2/SNF2 protein that hydrolyzes ATP in the presence of stem-loop DNA that contains both double-stranded and single-stranded regions. ADAAD possesses the seven helicase motifs that are a characteristic feature of all the SWI2/SNF2 proteins present in yeast as well as mammalian cells. In addition, these proteins also possess the Q motif ~17 nucleotides upstream of motif I. Using site-directed mutagenesis, we have sought to define the role of motifs Q and I in ATP hydrolysis mediated by ADAAD. We show that in ADAAD both motifs Q and I are required for ATP catalysis but not for ATP binding. In addition, the conserved glutamine present in motif Q also dictates the catalytic rate. The ability of the conserved glutamine present in motif Q to dictate the catalytic rate has not been observed in helicases. Further, the SWI2/SNF2 proteins contain a conserved glutamine, one amino acid residue downstream of motif I. This conserved glutamine, Q244 in ADAAD, also directs the rate of catalysis but is not required either for hydrolysis or for ligand binding. Finally, we show that the adenine moiety of ATP is sufficient for interaction with SWI2/SNF2 proteins. The γ-phosphate of ATP is required for inducing the conformational change that leads to ATPase activity. Thus, the SWI2/SNF2 proteins despite sequence conservation with helicases appear to behave in a manner distinct from that of the helicases.