Michael T. Marr

The genome of the choanoflagellate Monosiga brevicollis and the origin of metazoans

Choanoflagellates are the closest known relatives of metazoans. To discover potential molecular mechanisms underlying the evolution of metazoan multicellularity, we sequenced and analysed the genome of the unicellular choanoflagellate Monosiga brevicollis. The genome contains approximately 9,200 intron-rich genes, including a number that encode cell adhesion and signalling protein domains that are otherwise restricted to metazoans. Here we show that the physical linkages among protein domains often differ between M. brevicollis and metazoans, suggesting that abundant domain shuffling followed the separation of the choanoflagellate and metazoan lineages. The completion of the M. brevicollis genome allows us to reconstruct with increasing resolution the genomic changes that accompanied the origin of metazoans.

E. coli Transcription repair coupling factor (Mfd protein) rescues arrested complexes by promoting forward translocation.

Transcription and DNA repair are coupled in E. coli by the Mfd protein, which dissociates transcription elongation complexes blocked at nonpairing lesions and mediates recruitment of DNA repair proteins. We show that Mfd influences the elongation state of RNA polymerase (RNAP); transcription complexes that have reverse translocated into the backtracked position, a potentially important intermediate in RNA proofreading and repair, are restored to the forward position by the activity of Mfd, and arrested complexes are rescued into productive elongation. Mfd may act through a translocase activity that rewinds upstream DNA, leading either to translocation or to release of RNA polymerase when the enzyme active site cannot continue elongation.

Nascent-seq indicates widespread cotranscriptional pre-mRNA splicing in Drosophila.

To determine the prevalence of cotranscriptional splicing in Drosophila, we sequenced nascent RNA transcripts from Drosophila S2 cells as well as from Drosophila heads. Eighty-seven percent of the introns assayed manifest >50% cotranscriptional splicing. The remaining 13% are cotranscriptionally spliced poorly or slowly, with ∼3% being almost completely retained in nascent pre-mRNA. Although individual introns showed slight but statistically significant differences in splicing efficiency, similar global levels of splicing were seen from both sources. Importantly, introns with low cotranscriptional splicing efficiencies are present in the same primary transcript with efficiently spliced introns, indicating that splicing is intron-specific. The analysis also indicates that cotranscriptional splicing is less efficient for first introns, longer introns, and introns annotated as alternative. Finally, S2 cells expressing the slow RpII215(C4) mutant show substantially less intron retention than wild-type S2 cells.

Regulatory diversity among metazoan co-activator complexes

Transcription is a stepwise process that involves many specialized proteins and protein complexes, all of which must work together to express a given gene in a spatially and temporally regulated manner. An integral step in this regulatory process is carried out by large, multisubunit co-activator complexes, which have diverse roles in transcriptional control. Their diversity and large size allows for many potential regulatory inputs, but how is the versatility and specificity of these co-activator complexes determined?

MyoD targets TAF3 /TRF3 to activate Myogenin transcription

Skeletal muscle differentiation requires a cascade of transcriptional events to control the spatial and temporal expression of muscle-specific genes. Until recently, muscle-specific transcription was primarily attributed to prototypic enhancer-binding factors, while the role of core promoter recognition complexes in directing myogenesis remained unknown. Here, we report the development of a purified reconstituted system to analyze the properties of a TAF3/TRF3 complex in directing transcription initiation at the Myogenin promoter. Importantly, this new complex is required to replace the canonical TFIID to recapitulate MyoD-dependent activation of Myogenin. In vitro and cell-based assays identify a domain of TAF3 that mediates coactivator functions targeted by MyoD. Our findings also suggest changes to CRSP/Mediator in terminally differentiated myotubes. This switching of the core promoter recognition complex during myogenesis allows a more balanced division of labor between activators and TAF coactivators, thus providing another strategy to accommodate cell-specific regulation during metazoan development.

TAF4 nucleates a core subcomplex of TFIID and mediates activated transcription from a TATA-less promoter

Activator-dependent recruitment of TFIID initiates formation of the transcriptional preinitiation complex. TFIID binds core promoter DNA elements and directs the assembly of other general transcription factors, leading to binding of RNA polymerase II and activation of RNA synthesis. How TATA box-binding protein (TBP) and the TBP-associated factors (TAFs) are assembled into a functional TFIID complex with promoter recognition and coactivator activities in vivo remains unknown. Here, we use RNAi to knock down specific TFIID subunits in Drosophila tissue culture cells to determine which subunits are most critical for maintaining stability of TFIID in vivo. Contrary to expectations, we find that TAF4 rather than TBP or TAF1 plays the most critical role in maintaining stability of the complex. Our analysis also indicates that TAF5, TAF6, TAF9, and TAF12 play key roles in stability of the complex, whereas TBP, TAF1, TAF2, and TAF11 contribute very little to complex stability. Based on our results, we propose that holo-TFIID comprises a stable core subcomplex containing TAF4, TAF5, TAF6, TAF9, and TAF12 decorated with peripheral subunits TAF1, TAF2, TAF11, and TBP. Our initial functional studies indicate a specific and significant role for TAF1 and TAF4 in mediating transcription from a TATA-less, downstream core promoter element (DPE)-containing promoter, whereas a TATA-containing, DPE-less promoter was far less dependent on these subunits. In contrast to both TAF1 and TAF4, RNAi knockdown of TAF5 had little effect on transcription from either class of promoter. These studies significantly alter previous models for the assembly, structure, and function of TFIID.

Function of Transcription Cleavage Factors GreA and GreB at a Regulatory Pause Site

Gre proteins of prokaryotes, and SII proteins of eukaryotes and archaea, are transcription elongation factors that promote an endogenous transcript cleavage activity of RNA polymerases; this process promotes elongation through obstructive regions of DNA, including transcription pauses that act as sites of genetic regulation. We show that a regulatory pause in the early part of the late gene operon of bacteriophage lambda is subject to such cleavage and resynthesis. In cells lacking the cleavage factors GreA and GreB, the pause is prolonged, and RNA polymerase occupies a variant position at the pause site. Furthermore, GreA and GreB are required to mediate efficient function of the lambda gene Q antiterminator at this site. Thus, cleavage factors are necessary for the natural progression of RNA polymerase in vivo.

TBP, Mot1, and NC2 establish a regulatory circuit that controls DPE-dependent versus TATA-dependent transcription

The RNA polymerase II core promoter is a structurally and functionally diverse transcriptional module. RNAi depletion and overexpression experiments revealed a genetic circuit that controls the balance of transcription from two core promoter motifs, the TATA box and the downstream core promoter element (DPE). In this circuit, TBP activates TATA-dependent transcription and represses DPE-dependent transcription, whereas Mot1 and NC2 block TBP function and thus repress TATA-dependent transcription and activate DPE-dependent transcription. This regulatory circuit is likely to be one means by which biological networks can transmit transcriptional signals, such as those from DPE-specific and TATA-specific enhancers, via distinct pathways.

Restructuring of an RNA polymerase holoenzyme elongation complex by lambdoid phage Q proteins

The structure of an intermediate in the initiation to elongation transition of Escherichia coli RNA polymerase has been visualized through region-specific DNA cleavage by the hydroxyl radical reagent FeBABE. FeBABE was tethered to specific sites of the σ70 subunit and incorporated into two specialized paused elongation complexes that obligatorily retain the σ70 initiation subunit and are targets for modification by lambdoid phage late gene antiterminators. The FeBABE cleavage pattern reveals structures similar to open complex, except for notable changes to region 3 of σ70 that might reflect the presence of stably bound transcript. Binding of the antiterminator protein Q displaces the reactivity of FeBABE conjugated to region 4 of σ70, suggesting that σ70 subunit rearrangement is a step in conversion of RNAP to the antiterminating form.

Single nucleotide in the MTF-1 binding site can determine metal-specific transcription activation

Cells respond to changes in environment by shifting their gene expression profile to deal with the new conditions. The cellular response to changes in metal homeostasis is an important example of this. Transition metals such as iron, zinc, and copper are essential micronutrients but other metals such as cadmium are simply toxic. The cell must maintain metal concentrations in a window that supports efficient metabolic function but must also protect against the damaging effects of high concentrations of these metals. One way a cell regulates metal homeostasis is to control genes involved in metal mobilization and storage. Much of this regulation occurs at the level of transcription and the protein most responsible for this is the conserved metal responsive transcription factor 1 (MTF-1). Interestingly, the nature of the changes in the gene expression profile depends on the type of exposure. The cell somehow senses the kind of the metal challenge and responds appropriately. We have been using the Drosophila system to try to understand the mechanism of this metal discrimination. Using genome-wide mapping of MTF-1 binding under different metal stresses we find that, surprisingly, MTF-1 chooses different DNA binding sites depending on the specific nature of the metal insult. We also find that the type of binding site chosen is an important component of the capability to induce the metal-specific transcription activation.