MiR-27b targets PPARγ to inhibit growth, tumor progression and the inflammatory response in neuroblastoma cells.

The peroxisome proliferators-activated receptor (PPAR)γ pathway is involved in cancer, but it appears to have both tumor suppressor and oncogenic functions. In neuroblastoma cells, miR-27b targets the 3' untranslated region of PPARγ and inhibits its mRNA and protein expression. miR-27b overexpression or PPARγ inhibition blocks cell growth in vitro and tumor growth in mouse xenografts. PPARγ activates expression of the pH regulator NHE1, which is associated with tumor progression. Lastly, miR-27b through PPARγ regulates nuclear factor-κB activity and transcription of inflammatory target genes. Thus, in neuroblastoma, miR-27b functions as a tumor suppressor by inhibiting the tumor-promoting function of PPARγ, which triggers an increased inflammatory response. In contrast, in breast cancer cells, PPARγ inhibits NHE1 expression and the inflammatory response, and it functions as a tumor suppressor. We suggest that the ability of PPARγ to promote or suppress tumor formation is linked to cell type-specific differences in regulation of NHE1 and other target genes.

TFIIS enhances transcriptional elongation through an artificial arrest site in vivo.

Transcriptional elongation by RNA polymerase II has been well studied in vitro, but understanding of this process in vivo has been limited by the lack of a direct and specific assay. Here, we designed a specific assay for transcriptional elongation in vivo that involves an artificial arrest (ARTAR) site designed from a thermodynamic theory of DNA-dependent transcriptional arrest in vitro. Transcriptional analysis and chromatin immunoprecipitation experiments indicate that the ARTAR site can arrest Pol II in vivo at a position far from the promoter. TFIIS can counteract this arrest, thereby demonstrating that it possesses transcriptional antiarrest activity in vivo. Unexpectedly, the ARTAR site does not function under conditions of high transcriptional activation unless cells are exposed to conditions (6-azauracil or reduced temperature) that are presumed to affect elongation in vivo. Conversely, TFIIS affects gene expression under conditions of high, but not low, transcriptional activation. Our results provide physical evidence for the discontinuity of transcription elongation in vivo, and they suggest that the functional importance of transcriptional arrest sites and TFIIS is strongly influenced by the level of transcriptional activation.

Multiple functions of the nonconserved N-terminal domain of yeast TATA-binding protein.

The TATA-binding protein (TBP) is composed of a highly conserved core domain sufficient for TATA-element binding and preinitiation complex formation as well as a highly divergent N-terminal region that is dispensable for yeast cell viability. In vitro, removal of the N-terminal region domain enhances TBP-TATA association and TBP dimerization. Here, we examine the effects of truncation of the N-terminal region in the context of yeast TBP mutants with specific defects in DNA binding and in interactions with various proteins. For a subset of mutations that disrupt DNA binding and the response to transcriptional activators, removal of the N-terminal domain rescues their transcriptional defects. By contrast, deletion of the N-terminal region is lethal in combination with mutations on a limited surface of TBP. Although this surface is important for interactions with TFIIA and Brf1, TBP interactions with these two factors do not appear to be responsible for this dependence on the N-terminal region. Our results suggest that the N-terminal region of TBP has at least two distinct functions in vivo. It inhibits the interaction of TBP with TATA elements, and it acts positively in combination with a specific region of the TBP core domain that presumably interacts with another protein(s).

Histone acetylation at promoters is differentially affected by specific activators and repressors.

We analyzed the relationship between histone acetylation and transcriptional regulation at 40 Saccharomyces cerevisiae promoters that respond to specific activators and repressors. In accord with the general correlation between histone acetylation and transcriptional activity, Gcn4 and the general stress activators (Msn2 and Msn4) cause increased acetylation of histones H3 and H4. Surprisingly, Gal4-dependent activation is associated with a dramatic decrease in histone H4 acetylation, whereas acetylation of histone H3 is unaffected. A specific decrease in H4 acetylation is also observed, to a lesser extent, at promoters activated by Hap4, Adr1, Met4, and Ace1. Activation by heat shock factor has multiple effects; H4 acetylation increases at some promoters, whereas other promoters show an apparent decrease in H3 and H4 acetylation that probably reflects nucleosome loss or gross alteration of chromatin structure. Repression by targeted recruitment of the Sin3-Rpd3 histone deacetylase is associated with decreased H3 and H4 acetylation, whereas repression by Cyc8-Tup1 is associated with decreased H3 acetylation but variable effects on H4 acetylation; this suggests that Cyc8-Tup1 uses multiple mechanisms to reduce histone acetylation at promoters. Thus, individual activators confer distinct patterns of histone acetylation on target promoters, and transcriptional activation is not necessarily associated with increased acetylation. We speculate that the activator-specific decrease in histone H4 acetylation is due to blocking the access or function of an H4-specific histone acetylase such as Esa1.

Yeast NC2 associates with the RNA polymerase II preinitiation complex and selectively affects transcription in vivo.

NC2 (Dr1-Drap1 or Bur6-Ydr1) has been characterized in vitro as a general negative regulator of RNA polymerase II (Pol II) transcription that interacts with TATA-binding protein (TBP) and inhibits its function. Here, we show that NC2 associates with promoters in vivo in a manner that correlates with transcriptional activity and with occupancy by basal transcription factors. NC2 rapidly associates with promoters in response to transcriptional activation, and it remains associated under conditions in which transcription is blocked after assembly of the Pol II preinitiation complex. NC2 positively and negatively affects approximately 17% of Saccharomyces cerevisiae genes in a pattern that resembles the response to general environmental stress. Relative to TBP, NC2 occupancy is high at promoters where NC2 is positively required for normal levels of transcription. Thus, NC2 is associated with the Pol II preinitiation complex, and it can play a direct and positive role at certain promoters in vivo.

Region of yeast TAF 130 required for TFIID to associate with promoters.

TFIID, a multiprotein complex comprising the TATA-binding protein (TBP) and TBP-associated factors (TAFs), associates specifically with core promoters and nucleates the assembly the RNA polymerase II transcription machinery. In yeast cells, TFIID is not generally required for transcription, although it plays an important role at many promoters. Understanding of the specific functions and physiological roles of individual TAFs within TFIID has been hampered by the fact that depletion or thermal inactivation of individual TAFs generally results in dissociation of the TFIID complex. We describe here C-terminally deleted derivatives of yeast TAF130 that assemble into normal TFIID complexes but are transcriptionally inactive in vivo. In vivo, these mutant TFIID complexes are dramatically reduced in their ability to associate with all promoters tested. In vitro, a TFIID complex containing a deleted form of TAF130 associates poorly with DNA, but it is unaffected for interacting with transcriptional activation domains. These results suggest that the C-terminal region of TAF130 is required for TFIID to associate with promoters.

Enzymatic labeling of DNA.

This appendix describes the preparation of uniformly labeled radioactive probes by nick translation and random oligonucleotide-primed synthesis, as well as the end-labeling of oligonucleotides by T4 polynucleotide kinase. Accompanying these protocols are methods for removing unincorporated dNTP precursors with spin columns and for measuring the specific activity of a probe by acid precipitation.

Introduction of plasmid DNA into cells.

This appendix presents a procedure for transformation using calcium chloride, and also an alternate procedure for one-step preparation and transformation of competent cells.

Introduction of plasmid DNA into cells.

This appendix presents a procedure for transformation using calcium chloride, and also an alternate procedure for one-step preparation and transformation of competent cells.

Hybridization analysis of DNA blots.

Restriction endonucleases recognize short DNA sequences and cleave double-stranded DNA at specific sites within or adjacent to the recognition sequences. Restriction endonuclease cleavage of DNA into discrete fragments is one of the most basic procedures in molecular biology. This appendix describes restriction endonucleases and their properties.

Introduction of plasmid DNA into cells.

Transformation of E. coli can be achieved using any of the four protocols in this unit. The first method using calcium chloride gives good transformation efficiencies, is simple to complete, requires no special equipment, and allows storage of competent cells. The alternate one-step method is considerably faster and also gives good transformation efficiencies (although they are somewhat lower). If considerably higher transformation efficiencies are needed, the third method using electroporation is simple, fast, and reliable. As in the calcium chloride protocol, prepared cells can be stored. The final method described is an adaptation of the electroporation protocol that allows direct transfer of vector DNA from yeast into E. coli.

Synthesizing proteins in vitro by transcription and translation of cloned genes.

Immunoprecipitation is a technique in which an antigen is isolated by binding to a specific antibody attached to a sedimentable matrix. It is also used to analyze protein fractions separated by other biochemical techniques such as gel filtration or density gradient sedimentation. The source of antigen for immunoprecipitation can be unlabeled cells or tissues, metabolically or intrinsically labeled cells, or in vitro-translated proteins. This unit describes a wide range of immunoprecipitation techniques, using either suspension or adherent cells lysed by various means (e.g., with and without detergent, using glass beads, etc.). Flow charts and figures give the user a clear-cut explanation of the options for employing the technology.

Methylation and uracil interference assays for analysis of protein-DNA interactions.

Interference assays identify specific residues in the DNA binding site that, when modified, interfere with binding of the protein. The protocols use end-labeled DNA probes that are modified at an average of one site per molecule of probe. These probes are incubated with the protein of interest, and protein-DNA complexes are separated from free probe by the mobility shift assay. A DNA probe that is modified at a position that interferes with binding will not be retarded in this assay; thus, the specific protein-DNA complex is depleted for DNA that contains modifications on bases important for binding. After gel purification, the bound and unbound DNA are specifically cleaved at the modified residues and the resulting products analyzed by electrophoresis on polyacrylamide sequencing gels and autoradiography. In the methylation interference protocol presented here, probes are generated by methylating guanines (at the N-7 position) and adenines (at the N-3 position) with DMS; these methylated bases are cleaved specifically by piperidine. In the uracil interference protocol, probes are generated by PCR amplification in the presence of a mixture of TTP and dUTP, thereby producing products in which thymine residues are replaced by deoxyuracil residues (which contains hydrogen in place of the thymine 5-methyl group). Uracil bases are specifically cleaved by uracil-N-glycosylase to generate apyrimidinic sites that are susceptible to piperidine. These procedures provide complementary information about the nucleotides involved in protein-DNA interactions.

Analysis of DNA-protein interactions using proteins synthesized in vitro from cloned genes.

To detect DNA binding activity, radiolabeled protein is incubated with specific DNA fragments, and protein-DNA complexes are separated from free protein by electrophoresis in native acrylamide gels. Unlike the more conventional mobility shift assay which utilizes (32)P-labeled DNA and unlabeled protein, the assay described here generally utilizes (35)S-labeled protein and unlabeled DNA. Major advantages of this method are that any desired mutant protein can be tested for its DNA-binding properties simply by altering the DNA template, and the subunit structure (e.g., dimer, tetramer) can be determined.

Endonucleases.

Reaction conditions for numerous endonucleases are detailed in this unit along with discussions of potential applications. Specific enzymes include BAL 31 nuclease, S1 nuclease, mung bean nuclease, micrococcal nuclease and DNase I.

Ribonucleases.

Ribonucleases (RNases) with different sequence specificities are used for a variety of analytical purposes, including RNA sequencing, mapping, and quantitation. One very common application for RNase A is presented in this unit and involves hydrolyzing RNA that contaminates DNA preparations. Two other commonly used RNases, RNase H and RNase T1, are also described. In addition, many commercially available RNases are sequence-specific endoribonucleases, a property has been used for enzymatic sequencing of RNA.

Subcloning of DNA fragments.

The essence of recombinant DNA technology is the joining of two or more separate segments of DNA to generate a single DNA molecule that is capable of autonomous replication in a given host. The simplest constructions of hybrid DNA molecules involve the cloning of insert sequences into plasmid or bacteriophage cloning vectors. The insert sequences can derive from essentially any organism, and they may be isolated directly from the genome, from mRNA, or from previously cloned DNA segments (in which case, the procedure is termed subcloning). Alternatively, insert DNAs can be created directly by DNA synthesis. This unit provides protocols for the subcloning of DNA fragments and ligation of DNA fragments in gels.

Reagents and radioisotopes used to manipulate nucleic acids.

This unit provides recipes and instructions for preparing many common and useful solutions that are used in nucleic acids research. Included are enzyme buffers, reaction conditions for many restriction enzymes, stock solutions of nucleoside triphosphates, as well as numerous procedures for isolating and quantifying the radioactivity of various radioisotopes.

DNA-dependent DNA polymerases.

This unit presents characteristics and reaction conditions of the DNA-dependent DNA polymerases, including E. coli DNA polymerase I, Klenow fragment of E. coli DNA polymerase I, T4 DNA polymerase, native and modified T7 DNA polymerase, and Taq DNA polymerase.