Methylphosphate Capping Enzyme Research Articles

Unraveling the role of ubiquitin C-terminal hydrolase L1 in high grade serous ovarian cancer pathogenesis.

e15078 Background: High grade serous ovarian cancer (HGSOC) is the most lethal of all gynecologic malignancies, due to the fact that the majority of patients are diagnosed at an advanced stage and eventually develop chemoresistant disease 12-18 months following completion of frontline therapy. Therefore, novel targeted therapies are urgently needed to combat chemoresistance and improve patient clinical outcomes. Ubiquitin C-terminal hydrolase L1 (UCHL1) is a deubiquitinating enzyme that plays a vital role in protein homeostasis and is highly overexpressed in HGSOC. It was previously uncovered that targeting UCHL1 with small molecule inhibition reduced cell viability in a chemoresistant ovarian cancer cell line. Methods: Comparative-label free proteomic analysis was used to uncover significant changes in HGSOC cell line OVCAR8WT following treatment with UCHL1 small molecule inhibitor, LDN-5744 or corresponding DMSO control. Significant pathway changes were determined by KEGG analysis. Matched chemosensitive and resistant HGSOC cells PEA1 and PEA2 were treated in combination with LDN-5744 and carboplatin, with cell viability was determined by an MTS assay. Furthermore, western blot analysis was employed to compare common cell growth pathway changes as a result of UCHL1 inhibition in HGSOC cells. Results: Proteomic analysis revealed a significant (p<0.05) upregulation in methyl phosphate capping enzyme (MEPCE) (4.9-fold), asparagine synthetase (ASNS) (2.5-fold), Phosphoserine aminotransferase 1 (PSAT1) (1.7-fold), and downregulation in centrosomal protein 55 (CEP55) (-7.2-fold), These identified proteomic changes were confirmed by western blot. KEGG pathways analysis using all significantly (p<0.05) differentially expressed proteins showcased significant (p<0.05) enrichment in amino acid biosynthesis, and metabolism, and chemical carcinogenesis-reactive oxygen species. Chemoresistant PEA2 cells treated in combination with LDN-5744 and carboplatin demonstrated a 59% reduction in cell viability, significantly (p<0.001) lower than the 13% and 22%, that was observed from UCHL1 and carboplatin treatment alone, respectively. Conversely, PEA1, the chemosensitive counterpart to PEA2 demonstrated a significant (p<0.001) 37% increase in cell viability upon combinatorial treatment compared with carboplatin alone, indicating that UCHL1 inhibition rescues the cells from chemotherapy induced cell death. Finally, LDN-5744 treatment in PEA2 led to a reduction in levels of phospho-(p-)AKT, p-STAT3, and p-ERK, while conversely in PEA1 cells levels of these proteins were increase or unchanged. Conclusions: Our findings demonstrate that targeting UCHL1 results in prominent metabolic changes in HGSOC cells and that the efficacy of UCHL1 inhibition is heavily dependent upon platinum status. Overall, this study highlights UCHL1’s novel therapeutic role in the recurrent HGSOC.

Catalytic activity of the Bin3/MePCE methyltransferase domain is dispensable for 7SK snRNP function in Drosophila melanogaster.

Methylphosphate Capping Enzyme (MePCE) monomethylates the gamma phosphate at the 5' end of the 7SK noncoding RNA, a modification thought to protect 7SK from degradation. 7SK serves as a scaffold for assembly of a snRNP complex that inhibits transcription by sequestering the positive elongation factor P-TEFb. While much is known about the biochemical activity of MePCE in vitro, little is known about its functions in vivo, or what roles-if any-there are for regions outside the conserved methyltransferase domain. Here, we investigated the role of Bin3, the Drosophila ortholog of MePCE, and its conserved functional domains in Drosophila development. We found that bin3 mutant females had strongly reduced rates of egg-laying, which was rescued by genetic reduction of P-TEFb activity, suggesting that Bin3 promotes fecundity by repressing P-TEFb. bin3 mutants also exhibited neuromuscular defects, analogous to a patient with MePCE haploinsufficiency. These defects were also rescued by genetic reduction of P-TEFb activity, suggesting that Bin3 and MePCE have conserved roles in promoting neuromuscular function by repressing P-TEFb. Unexpectedly, we found that a Bin3 catalytic mutant (Bin3Y795A) could still bind and stabilize 7SK and rescue all bin3 mutant phenotypes, indicating that Bin3 catalytic activity is dispensable for 7SK stability and snRNP function in vivo. Finally, we identified a metazoan-specific motif (MSM) outside of the methyltransferase domain and generated mutant flies lacking this motif (Bin3ΔMSM). Bin3ΔMSM mutant flies exhibited some-but not all-bin3 mutant phenotypes, suggesting that the MSM is required for a 7SK-independent, tissue-specific function of Bin3.

Excessive transcription-replication conflicts are a vulnerability of BRCA1-mutant cancers.

BRCA1 mutations are associated with increased breast and ovarian cancer risk. BRCA1-mutant tumors are high-grade, recurrent, and often become resistant to standard therapies. Herein, we performed a targeted CRISPR-Cas9 screen and identified MEPCE, a methylphosphate capping enzyme, as a synthetic lethal interactor of BRCA1. Mechanistically, we demonstrate that depletion of MEPCE in a BRCA1-deficient setting led to dysregulatedRNA polymerase II (RNAPII) promoter-proximal pausing, R-loop accumulation,and replication stress, contributing to transcription-replication collisions. These collisions compromise genomic integrity resulting in loss of viability of BRCA1-deficient cells. We also extend these findings to another RNAPII-regulating factor, PAF1. This study identifies a new class of synthetic lethal partners of BRCA1 that exploit the RNAPII pausing regulation and highlight the untapped potential of transcription-replication collision-inducing factors as unique potential therapeutic targets for treating cancers associated with BRCA1 mutations.

Structural basis of RNA conformational switching in the transcriptional regulator 7SK RNP.

7SK non-coding RNA (7SK) negatively regulates RNA polymerase II (Pol II) elongation by inhibiting positive transcription elongation factor b (P-TEFb), and its ribonucleoprotein complex (RNP) is hijacked by HIV-1 for viral transcription and replication. Methylphosphate capping enzyme (MePCE) and La-related protein 7 (Larp7) constitutively associate with 7SK to form a core RNP, while P-TEFb and other proteins dynamically assemble to form different complexes. Here, we present cryo-EM structures of 7SK core RNP formed with two 7SK conformations, circular and linear, and uncover a common RNA-dependent MePCE-Larp7 complex. Together with NMR, biochemical, and cellular data, these structures reveal the mechanism of MePCE catalytic inactivation in the core RNP; unexpected interactions between Larp7 and RNA that facilitate a role as an RNP chaperone; and that MePCE-7SK-Larp7 core RNP serves as a scaffold for switching between different 7SK conformations essential for RNP assembly and regulation of P-TEFb sequestration and release.

Structural basis of RNA conformational switching in the transcriptional regulator 7SK RNP

7SK non-coding RNA (7SK) negatively regulates RNA polymerase II (RNA Pol II) elongation by inhibiting positive transcription elongation factor b (P-TEFb), and its ribonucleoprotein complex (RNP) is hijacked by HIV-1 for viral transcription and replication. Methylphosphate capping enzyme (MePCE) and La-related protein 7 (Larp7) constitutively associate with 7SK to form a core RNP, while P-TEFb and other proteins dynamically assemble to form different complexes. Here, we present the cryo-EM structures of 7SK core RNP formed with two 7SK conformations, circular and linear, and uncover a common RNA-dependent MePCE-Larp7 complex. Together with NMR, biochemical, and cellular data, these structures reveal the mechanism of MePCE catalytic inactivation in the core RNP, unexpected interactions between Larp7 and RNA that facilitate a role as an RNP chaperone, and that MePCE-7SK-Larp7 core RNP serves as a scaffold for switching between different 7SK conformations essential for RNP assembly and regulation of P-TEFb sequestration and release.

The methyl phosphate capping enzyme Bmc1/Bin3 is a stable component of the fission yeast telomerase holoenzyme

The telomerase holoenzyme is critical for maintaining eukaryotic genome integrity. In addition to a reverse transcriptase and an RNA template, telomerase contains additional proteins that protect the telomerase RNA and promote holoenzyme assembly. Here we report that the methyl phosphate capping enzyme (MePCE) Bmc1/Bin3 is a stable component of the S. pombe telomerase holoenzyme. Bmc1 associates with the telomerase holoenzyme and U6 snRNA through an interaction with the recently described LARP7 family member Pof8, and we demonstrate that these two factors are evolutionarily linked in fungi. Our data suggest that the association of Bmc1 with telomerase is independent of its methyltransferase activity, but rather that Bmc1 functions in telomerase holoenzyme assembly by promoting TER1 accumulation and Pof8 recruitment to TER1. Taken together, this work yields new insight into the composition, assembly, and regulation of the telomerase holoenzyme in fission yeast as well as the breadth of its evolutionary conservation.

A putative cap binding protein and the methyl phosphate capping enzyme Bin3/MePCE function in telomerase biogenesis

Telomerase reverse transcriptase (TERT) and the noncoding telomerase RNA (TR) subunit constitute the core of telomerase. Additional subunits are required for ribonucleoprotein complex assembly and in some cases remain stably associated with the active holoenzyme. Pof8, a member of the LARP7 protein family is such a constitutive component of telomerase in fission yeast. Using affinity purification of Pof8, we have identified two previously uncharacterized proteins that form a complex with Pof8 and participate in telomerase biogenesis. Both proteins participate in ribonucleoprotein complex assembly and are required for wildtype telomerase activity and telomere length maintenance. One factor we named Thc1 (Telomerase Holoenzyme Component 1) shares structural similarity with the nuclear cap binding complex and the poly-adenosine ribonuclease (PARN), the other is the ortholog of the methyl phosphate capping enzyme (Bin3/MePCE) in metazoans and was named Bmc1 (Bin3/MePCE 1) to reflect its evolutionary roots. Thc1 and Bmc1 function together with Pof8 in recognizing correctly folded telomerase RNA and promoting the recruitment of the Lsm2-8 complex and the catalytic subunit to assemble functional telomerase.

Long non‑coding RNA ST8SIA6‑AS1 promotes the migration and invasion of hypoxia‑treated hepatocellular carcinoma cells through the miR‑338/MEPCE axis.

Hepatocellular carcinoma (HCC) is one of the most prevalent types of cancer worldwide. Long non-coding RNAs (lncRNAs) have been reported to frequently participate in the carcinogenesis and development of various types of cancer, including HCC. However, the molecular mechanisms of lncRNA ST8SIA6-AS1 in HCC remain poorly understood. The present study performed bioinformatics analysis, in addition to using reverse transcription-quantitative PCR (RT-qPCR), nuclear-cytoplasmic fractionation, RNA immunoprecipitation, and Transwell, wound healing, and dual-luciferase reporter assays, to determine the biological role and regulatory mechanisms of ST8SIA6-AS1 in HCC. The results revealed that the expression levels of ST8SIA6-AS1 were upregulated in HCC tissues and cell lines, which were associated with a poor prognosis. Moreover, the genetic knockdown of ST8SIA6-AS1 inhibited the hypoxia-induced HCC cell migration and invasion. Additionally, microRNA (miR)-338, which exhibited downregulated expression levels in HCC tissues and cell lines, was discovered to bind with ST8SIA6-AS1. The inhibition of miR-338 partially reversed the inhibitory effects of ST8SIA6-AS1-knockdown on the migration and invasion of HCC cells under hypoxia. Subsequently, methylphosphate capping enzyme (MEPCE) was identified to be targeted and negatively regulated by miR-338. Notably, the overexpression of MEPCE recovered the inhibitory influence over the migratory and invasive abilities of hypoxia-treated HCC cells promoted by ST8SIA6-AS1 inhibition. In conclusion, the findings of the present study suggest that lncRNA ST8SIA6-AS1 may promote the migration and invasion of hypoxia-induced HCC cells via the miR-338/MEPCE axis, indicating a potential diagnostic or therapeutic marker for HCC treatment.

JMJD6 cleaves MePCE to release positive transcription elongation factor b (P-TEFb) in higher eukaryotes.

More than 30% of genes in higher eukaryotes are regulated by promoter-proximal pausing of RNA polymerase II (Pol II). Phosphorylation of Pol II CTD by positive transcription elongation factor b (P-TEFb) is a necessary precursor event that enables productive transcription elongation. The exact mechanism on how the sequestered P-TEFb is released from the 7SK snRNP complex and recruited to Pol II CTD remains unknown. In this report, we utilize mouse and human models to reveal methylphosphate capping enzyme (MePCE), a core component of the 7SK snRNP complex, as the cognate substrate for Jumonji domain-containing 6 (JMJD6)'s novel proteolytic function. Our evidences consist of a crystal structure of JMJD6 bound to methyl-arginine, enzymatic assays of JMJD6 cleaving MePCE in vivo and in vitro, binding assays, and downstream effects of Jmjd6 knockout and overexpression on Pol II CTD phosphorylation. We propose that JMJD6 assists bromodomain containing 4 (BRD4) to recruit P-TEFb to Pol II CTD by disrupting the 7SK snRNP complex.

Structural Basis of 7SK RNA 5′-Gamma-Phosphate Methylation and Retention by MePCE

7SK non-coding RNA is an essential regulator of eukaryotic transcription elongation through dynamic RNP assemblies that sequester or release the positive transcription elongation factor b (P-TEFb). All 7SK RNPs include a core comprising 7SK RNA, methylphosphate capping enzyme (MePCE), and La-related protein 7 (Larp7). In addition to its non-enzymatic role as a core component of 7SK RNPs, MePCE catalyzes the formation of a gamma-phosphate monomethylation cap, unique to 7SK and U6 in humans. How MePCE can specifically recognize and modify its RNA substrate and remain bound to 7SK to form the core 7SK RNP has not been previously known. We report 2.0 and 2.1 Å X-ray crystal structures of human MePCE methyltransferase domain bound to S-adenosylhomocysteine (SAH) and uncapped or capped 7SK substrates, respectively. We find that 7SK recognition is achieved by an extensive network of protein contacts to a 5' hairpin-single-stranded RNA region, involving the triphosphate group, two terminal basepairs and six single-stranded nucleotides, thus explaining MePCE specificity for 7SK and U6. The large size of the RNA binding site required for recognition and catalysis is unique among RNA methyltransferases studied to date. The structures reveal SAH and product RNA in a near-transition state geometry, where the cofactor SAH is buried inside the active site by the RNA-interacting residues. Unexpectedly, binding experiments show that MePCE has higher affinity for capped vs uncapped 7SK, with kinetic data supporting a slow product release model. Taken together, these data describe the features of an unusual RNA capping enzyme, and reveal the molecular mechanism of methyl transfer and 7SK retention by MePCE for subsequent assembly of the core 7SK RNP.

Structural basis of 7SK RNA 5'-γ-phosphate methylation and retention by MePCE.

Among RNA 5′-cap structures, γ-phosphate monomethylation is unique to a small subset of noncoding RNAs, 7SK and U6 in humans. 7SK is capped by methylphosphate capping enzyme (MePCE), which has a second non-enzymatic role as a core component of the 7SK RNP that is an essential regulator of RNA transcription. We report 2.0 and 2.1 Å X-ray crystal structures of human MePCE methyltransferase domain bound to S-adenosylhomocysteine (SAH) and uncapped or capped 7SK substrates, respectively. 7SK recognition is achieved by protein contacts to a 5′ hairpin-single-stranded RNA region, explaining MePCE specificity for 7SK and U6. The structures reveal SAH and product RNA in a near-transition state geometry. Surprisingly, binding experiments show that MePCE has higher affinity for capped vs uncapped 7SK, with kinetic data supporting a slow product release model. This work reveals the molecular mechanism of methyl transfer and 7SK retention by MePCE for subsequent assembly of 7SK RNP.

Human METTL16 is a N6-methyladenosine (m6A) methyltransferase that targets pre-mRNAs and various non-coding RNAs.

N6-methyladenosine (m6A) is a highly dynamic RNA modification that has recently emerged as a key regulator of gene expression. While many m6A modifications are installed by the METTL3-METTL14 complex, others appear to be introduced independently, implying that additional human m6A methyltransferases remain to be identified. Using crosslinking and analysis of cDNA (CRAC), we reveal that the putative human m6A "writer" protein METTL16 binds to the U6 snRNA and other ncRNAs as well as numerous lncRNAs and pre-mRNAs. We demonstrate that METTL16 is responsible for N6-methylation of A43 of the U6 snRNA and identify the early U6 biogenesis factors La, LARP7 and the methylphosphate capping enzyme MEPCE as METTL16 interaction partners. Interestingly, A43 lies within an essential ACAGAGA box of U6 that base pairs with 5' splice sites of pre-mRNAs during splicing, suggesting that METTL16-mediated modification of this site plays an important role in splicing regulation. The identification of METTL16 as an active m6A methyltransferase in human cells expands our understanding of the mechanisms by which the m6A landscape is installed on cellular RNAs.

Human BCDIN3D monomethylates cytoplasmic histidine transfer RNA

Human RNA methyltransferase BCDIN3D is overexpressed in breast cancer cells, and is related to the tumorigenic phenotype and poor prognosis of breast cancer. Here, we show that cytoplasmic tRNAHis is the primary target of BCDIN3D in human cells. Recombinant human BCDIN3D, expressed in Escherichia coli, monomethylates the 5΄-monophosphate of cytoplasmic tRNAHis efficiently in vitro. In BCDN3D-knockout cells, established by CRISPR/Cas9 editing, the methyl moiety at the 5΄-monophosphate of cytoplasmic tRNAHis is lost, and the exogenous expression of BCDIN3D in the knockout cells restores the modification in cytoplasmic tRNAHis. BCIDN3D recognizes the 5΄-guanosine nucleoside at position −1 (G−1) and the eight-nucleotide acceptor helix with the G−1–A73 mis-pair at the top of the acceptor stem of cytoplasmic tRNAHis, which are exceptional structural features among cytoplasmic tRNA species. While the monomethylation of the 5΄-monophosphate of cytoplasmic tRNAHis affects neither the overall aminoacylation process in vitro nor the steady-state level of cytoplasmic tRNAHisin vivo, it protects the cytoplasmic tRNAHis transcript from degradation in vitro. Thus, BCDIN3D acts as a cytoplasmic tRNAHis-specific 5΄-methylphosphate capping enzyme. The present results also suggest the possible involvement of the monomethylation of the 5΄-monophosphate of cytoplasmic tRNAHis and/or cytoplasmic tRNAHis itself in the tumorigenesis of breast cancer cells.

7SK small nuclear RNA transcription level down-regulates in human tumors and stem cells.

The small nuclear noncoding RNA (snRNA) 7SK is a highly conserved noncoding RNA of 331 nucleotides in animals, which is present in a nuclear ribonucleoprotein complex with proteins such as methylphosphate capping enzyme (MePCE), hexamethylene bisacetamide-inducible proteins 1 and 2 (HEXIM1 and HEXIM2) and La-related protein 7 (Larp7). Regulating the activity of the positive transcription elongation factor b (P-TEFb) is the key function of 7SK noncoding RNA. Recently, we have shown that 7SK snRNA over-expression reduces human embryonic kidney 293T cell line viability. Here, we attempt to monitor the expression level of 7SK snRNA in different human cell lines and cancer tissues. Examination of 7SK transcription either in cell lines or in different malignant tissues including blood (CML), breast and colon showed that 7SK expression significantly down-regulated in cancer. Similar to human cancer tissues and cell lines, 7SK transcriptional level decreased in stem cells in comparison with differentiated cell types. In this regard, over-expression of 7SK snRNA might be a powerful tool for blocking cancer progression by controlling the activity of P-TEFb.

Release of Positive Transcription Elongation Factor b (P-TEFb) from 7SK Small Nuclear Ribonucleoprotein (snRNP) Activates Hexamethylene Bisacetamide-inducible Protein (HEXIM1) Transcription

By phosphorylating negative elongation factors and the C-terminal domain of RNA polymerase II (RNAPII), positive transcription elongation factor b (P-TEFb), which is composed of CycT1 or CycT2 and CDK9, activates eukaryotic transcription elongation. In growing cells, it is found in active and inactive forms. In the former, free P-TEFb is a potent transcriptional coactivator. In the latter, it is inhibited by HEXIM1 or HEXIM2 in the 7SK small nuclear ribonucleoprotein (snRNP), which contains, additionally, 7SK snRNA, methyl phosphate-capping enzyme (MePCE), and La-related protein 7 (LARP7). This P-TEFb equilibrium determines the state of growth and proliferation of the cell. In this study, the release of P-TEFb from the 7SK snRNP led to increased synthesis of HEXIM1 but not HEXIM2 in HeLa cells, and this occurred only from an unannotated, proximal promoter. ChIP with sequencing revealed P-TEFb-sensitive poised RNA polymerase II at this proximal but not the previously annotated distal HEXIM1 promoter. Its immediate upstream sequences were fused to luciferase reporters and were found to be responsive to many P-TEFb-releasing compounds. The superelongation complex subunits AF4/FMR2 family member 4 (AFF4) and elongation factor RNA polymerase II 2 (ELL2) were recruited to this proximal promoter after P-TEFb release and were required for its transcriptional effects. Thus, P-TEFb regulates its own equilibrium in cells, most likely to maintain optimal cellular homeostasis.

RNA elements directing in vivo assembly of the 7SK/MePCE/Larp7 transcriptional regulatory snRNP

Through controlling the nuclear level of active positive transcription elongation factor b (P-TEFb), the 7SK small nuclear RNA (snRNA) functions as a key regulator of RNA polymerase II transcription. Together with hexamethylene bisacetamide-inducible proteins 1/2 (HEXIM1/2), the 7SK snRNA sequesters P-TEFb into transcriptionally inactive ribonucleoprotein (RNP). In response to transcriptional stimulation, the 7SK/HEXIM/P-TEFb RNP releases P-TEFb to promote polymerase II-mediated messenger RNA synthesis. Besides transiently associating with HEXIM1/2 and P-TEFb, the 7SK snRNA stably interacts with the La-related protein 7 (Larp7) and the methylphosphate capping enzyme (MePCE). In this study, we used in vivo RNA–protein interaction assays to determine the sequence and structural elements of human 7SK snRNA directing assembly of the 7SK/MePCE/Larp7 core snRNP. MePCE interacts with the short 5′-terminal G1-U4/U106-G111 helix-tail motif and Larp7 binds to the 3′-terminal hairpin and the following U-rich tail of 7SK. The overall RNA structure and some particular nucleotides provide the information for specific binding of MePCE and Larp7. We also demonstrate that binding of Larp7 to 7SK is a prerequisite for in vivo recruitment of P-TEFb, indicating that besides providing stability for 7SK, Larp7 directly participates in P-TEFb regulation. Our results provide further explanation for the frequently observed link between Larp7 mutations and cancer development.

The Bin3 RNA methyltransferase targets 7SK RNA to control transcription and translation

Bicoid-interacting protein 3 (Bin3) is a conserved RNA methyltransferase found in eukaryotes ranging from fission yeast to humans. It was originally discovered as a Bicoid (Bcd)-interacting protein in Drosophila, where it is required for anterior-posterior and dorso-ventral axis determination in the early embryo. The mammalian ortholog of Bin3 (BCDIN3), also known as methyl phosphate capping enzyme (MePCE), plays a key role in repressing transcription. In transcription, MePCE binds the non-coding 7SK RNA, which forms a scaffold for an RNA-protein complex that inhibits positive-acting transcription elongation factor b, an RNA polymerase II elongation factor. MePCE uses S-adenosyl methionine to transfer a methyl group onto the γ-phosphate of the 5' guanosine of 7SK RNA generating an unusual cap structure that protects 7SK RNA from degradation. Bin3/MePCE also has a role in translation regulation. Initial studies in Drosophila indicate that Bin3 targets 7SK RNA and stabilizes a distinct RNA-protein complex that assembles on the 3'-untranslated region of caudal mRNAs to prevent translation initiation. Much remains to be learned about Bin3/MeCPE function, including how it recognizes 7SK RNA, what other RNA substrates it might target, and how widespread a role it plays in gene regulation and embryonic development.

Systematic Analysis of the Protein Interaction Network for the Human Transcription Machinery Reveals the Identity of the 7SK Capping Enzyme

We have performed a survey of soluble human protein complexes containing components of the transcription and RNA processing machineries using protein affinity purification coupled to mass spectrometry. Thirty-two tagged polypeptides yielded a network of 805 high-confidence interactions. Remarkably, the network is significantly enriched in proteins that regulate the formation of protein complexes, including a number of previously uncharacterized proteins for which we have inferred functions. The RNA polymerase II (RNAP II)-associated proteins (RPAPs) are physically and functionally associated with RNAP II, forming an interface between the enzyme and chaperone/scaffolding proteins. BCDIN3 is the 7SK snRNA methylphosphate capping enzyme (MePCE) present in an snRNP complex containing both RNA processing and transcription factors, including the elongation factor P-TEFb. Our results define a high-density protein interaction network for the mammalian transcription machinery and uncover multiple regulatory factors that target the transcription machinery.