Project description:The allosteric mechanisms that control the different functional and conformational states of oncogenic kinases, and how these molecular switches can be targeted and therapeutically exploited remains largely unexplored. Here we show that c-terminal Tyr 530 is a de facto c- Src auto-phosphorylation site with slow time-resolution kinetics and strong intermolecular component. On the contrary, activation-loop Tyr 419 undergoes fast kinetics and a cis-to-trans phosphorylation-switch that controls c-terminal Tyr 530 phosphorylation, enzyme specificity and strikingly, c-Src non-catalytic function as a substrate. In line with this, we visualize by X-ray crystallography a snapshot of c-terminal Tyr 530 intermolecular phosphorylation between the enzyme and susbtrate acting kinases, and identify a functionally relevant c-terminal palindromic phospho-motif flanking Tyr 530 making important contacts at the interface. Perturbation of this phospho-motif accounts for c-Src disfunction in cancer, as indicated by viral and a colorectal cancer (CRC) associated c-terminal deleted variants. We show that c-terminal residues 531 to 536 are required for c-Src Tyr 530 auto-phosphorylation and overall phospho-tyrosine activity. However, c-terminal truncated forms display a minor delay in the capacity to phosphorylate intact c-Src substrates surrogates. On the contrary, when these c-terminal variants were used as intact substrate surrogates themselves, they were equally and efficiently phosphorylated, but strikingly they resulted in the allosteric inhibition of the active kinase. Our work reveals a bi-directional crosstalk between activation and c-terminal segments driven by auto-phosphorylation that controls the allosteric interplay between enzyme and susbtrate acting kinases. These findings have important implications for the drug-design and development of next generation c-Src inhibitors targeting non-catalytic and/or allosteric vulnerabilities.

Project description:Specificity of target RNA recovery by thCHART was compared to CHART and other strategies.

Project description:Allosteric communication between distant sites in proteins is central to nearly all biological regulation but still poorly characterised for most proteins, limiting conceptual understanding, biological engineering and allosteric drug development. Typically only a few allosteric sites are known in model proteins, but theoretical, evolutionary and some experimental studies suggest they may be much more widely distributed. An important reason why allostery remains poorly characterised is the lack of methods to systematically quantify long-range communication in diverse proteins. Here we address this shortcoming by developing a method that uses deep mutational scanning to comprehensively map the allosteric landscapes of protein interaction domains. The key concept of the approach is the use of ‘multidimensional mutagenesis’: mutational effects are quantified for multiple molecular phenotypes—here binding and protein abundance—and in multiple genetic backgrounds. This is an efficient experimental design that allows the underlying causal biophysical effects of mutations to be accurately inferred en masse by fitting thermodynamic models using neural networks. We apply the approach to two of the most common human protein interaction domains, an SH3 domain and a PDZ domain, to produce the first global atlases of allosteric mutations for any proteins. Allosteric mutations are widely dispersed with extensive long-range tuning of binding affinity and a large mutational target space of network-altering ‘edgetic’ variants. Mutations are more likely to be allosteric closer to binding interfaces, at Glycines in secondary structure elements and at particular sites including a chain of residues connecting to an opposite surface in the PDZ domain. This general approach of quantifying mutational effects for multiple molecular phenotypes and in multiple genetic backgrounds should allow the energetic and allosteric landscapes of many proteins to be rapidly and comprehensively mapped.

Project description:Long non-coding RNAs (lncRNAs) have important regulatory roles and can function at the level of chromatin. To determine where lncRNAs bind to chromatin, we developed CHART, a hybridization-based technique that specifically enriches endogenous RNAs along with their targets from reversibly-crosslinked chromatin extracts. CHART was used to enrich the DNA and protein targets of endogenous lncRNAs from fly and human. This analysis was extended to genome-wide mapping of roX2, a well-studied ncRNA involved in dosage-compensation in Drosophila. CHART revealed that roX2 binds at specific genomic sites that coincide with the binding sites of proteins from the MSL-complex that affects dosage compensation. These results reveal the genomic targets of roX2 and demonstrate how CHART can be used to study RNAs in a manner analogous to ChIP for proteins. Examination of the binding sites of roX2 ncRNA from S2 cells using two different elution strategies compared with a sense control or input control. Processed data file 'roX2.2.peaks.bed' (for roX2 CHART RNase eluted, combined replicates) linked below as supplementary file.

Project description:Long noncoding RNAs (lncRNAs) are important regulators of chromatin; however, the mechanistic roles for many lncRNAs are poorly understood in part because their direct interactions with genomic loci and proteins are difficult to assess. We used CHART-seq to map the genomic binding sites for two highly expressed human lncRNAs, NEAT1 and MALAT1, which localize within the nucleus to paraspeckles and nuclear speckles, respectively. We show that NEAT1 and MALAT1 localize to hundreds of genomic sites in human cells, primarily over active genes. NEAT1 and MALAT1 exhibit colocalization to many of these loci, but display distinct gene body binding patterns at these sites, suggesting independent but complementary functions for these RNAs. Protein mass spectrometry analysis of CHART-enriched material (CHART-MS) identified numerous proteins enriched by both lncRNAs, supporting complementary binding and function, in addition to unique associated proteins. Transcriptional inhibition or stimulation affects the localization of NEAT1 to active chromatin sites, implying that DNA sequence itself does not target NEAT1 to chromatin and that localization responds to cues involved in the transcription process. Paired-end CHART-seq was performed for a single replicate of each capture oligonucleotide in untreated MCF-7 cells to establish binding sites of these RNAs, for a total of 6 samples. To investigate the effects of transcriptional inhibition and E2 stimulation on the localization of these RNAs, we performed paired-end CHART-seq with each capture oligonucleotide for two biological replicates of flavopiridol- and vehicle (DMSO)-treated MCF-7 cells and for two biological replicates of E2- and vehicle (ethanol)-treated MCF-7 cells. To establish the overlap of NEAT1 and MALAT1 binding sites with a known component of paraspeckles (NEAT1-containing subnuclear body), we performed paired-end ChIP-seq for the paraspeckle component PSF in MCF-7 cells, as well as a single-end biological replicate.

Project description:SRC-1 affects the expression of complex I of the mitochondrial electron transport chain, a set of enzymes responsible for the conversion of NADH to NAD(+). NAD(+) and NADH were subsequently identified as metabolites that underlie SRC-1's response to glucose deprivation. Knockdown of SRC-1 in glycolytic cancer cells abrogated their ability to grow in the absence of glucose consistent with SRC-1's role in promoting cellular adaptation to reduced glucose availability RNA profiling was used to examine the effects of SRC-1 perturbation on gene expression in the absence or presence of glucose.

Project description:We present evidence of mechanistically diverse allosteric relays converging on a few peptidyltransferase center (PTC) nucleotides, and propose a general model of antibiotic resistance mediated by these ARE-ABCFs

Project description:Identifying LINC00899 binding sites in HeLa cells with CHART-seq

Project description:Long non-coding RNAs (lncRNAs) have important regulatory roles and can function at the level of chromatin. To determine where lncRNAs bind to chromatin, we developed CHART, a hybridization-based technique that specifically enriches endogenous RNAs along with their targets from reversibly-crosslinked chromatin extracts. CHART was used to enrich the DNA and protein targets of endogenous lncRNAs from fly and human. This analysis was extended to genome-wide mapping of roX2, a well-studied ncRNA involved in dosage-compensation in Drosophila. CHART revealed that roX2 binds at specific genomic sites that coincide with the binding sites of proteins from the MSL-complex that affects dosage compensation. These results reveal the genomic targets of roX2 and demonstrate how CHART can be used to study RNAs in a manner analogous to ChIP for proteins.

Project description:SRC-1 affects the expression of complex I of the mitochondrial electron transport chain, a set of enzymes responsible for the conversion of NADH to NAD(+). NAD(+) and NADH were subsequently identified as metabolites that underlie SRC-1's response to glucose deprivation. Knockdown of SRC-1 in glycolytic cancer cells abrogated their ability to grow in the absence of glucose consistent with SRC-1's role in promoting cellular adaptation to reduced glucose availability