Ali Tavassoli

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Organization: University of Southampton , England

Department: 1 Chemistry

Title: Professor(PhD)

Chemicals
References

Reprogramming the Transcriptional Response to Hypoxia with a Chromosomally Encoded Cyclic Peptide HIF-1 Inhibitor

Co-reporter:Ishna N. Mistry and Ali Tavassoli

ACS Synthetic Biology March 17, 2017 Volume 6(Issue 3) pp:518-518

Publication Date(Web):November 23, 2016

DOI:10.1021/acssynbio.6b00219

The cellular response to hypoxia is orchestrated by HIF-1, a heterodimeric transcription factor composed of an α and a β subunit that enables cell survival under low oxygen conditions by altering the transcription of over 300 genes. There is significant evidence that inhibition of HIF-1 would be beneficial for cancer therapy. We recently reported a cyclic hexapeptide that inhibits the HIF-1α/HIF-1β protein–protein interaction in vitro and prevents HIF-1-mediated hypoxia-response signaling in cells. This cyclic peptide was identified from a library of 3.2 × 106 members generated using SICLOPPS split-intein mediated protein splicing. With a view to demonstrating the potential for encoding the production of a therapeutic agent in response to a disease marker, we have engineered human cells with an additional chromosomal control circuit that conditionally encodes the production of our cyclic peptide HIF-1 inhibitor. We demonstrate the conditional production of our HIF-1 inhibitor in response to hypoxia, and its inhibitory effect on HIF-1 dimerization and downstream hypoxia-response signaling. These engineered cells are used to illustrate the synthetic lethality of inhibiting HIF-1 dimerization and glycolysis in hypoxic cells. Our approach not only eliminates the need for the chemical synthesis and targeted delivery of our HIF-1 inhibitor to cells, it also demonstrates the wider possibility that the production machinery of other bioactive compounds may be incorporated onto the chromosome of human cells. This work demonstrates the potential of sentinel circuits that produce molecular modulators of cellular pathways in response to environmental or cellular disease stimuli.Keywords: cellular reprogramming; cyclic peptide; HIF-1; hypoxia; protein−protein interaction; SICLOPPS;

Traceless Production of Cyclic Peptide Libraries in E. coli

Co-reporter:Jaime E. Townend and Ali Tavassoli

ACS Chemical Biology 2016 Volume 11(Issue 6) pp:1624

Publication Date(Web):March 30, 2016

DOI:10.1021/acschembio.6b00095

Split intein circular ligation of peptides and proteins (SICLOPPS) is a genetically encoded method for the intracellular production of cyclic peptide libraries of around 100 million (108) members that utilizes the Synechocystis sp PCC6803 (Ssp) DnaE split inteins. However, Ssp inteins are relatively slow splicing and intolerant of amino acid variation around the splice junction, potentially limiting the utility and composition of SICLOPPS libraries. In contrast, Nostoc punctiforme (Npu) DnaE split inteins not only splice significantly faster, they are also much more tolerant of amino acid variation around their splice junctions. Here, we report the use of engineered Npu inteins in SICLOPPS for the generation of cyclic peptide libraries and cyclic proteins. Despite their superior splicing characteristics, however, we observed a high level of toxicity from the Npu SICLOPPS constructs in E. coli. The observed toxicity was overcome though incorporation of an SsrA tag to target the spliced Npu inteins to the ClpXP complex for degradation. The resulting traceless Npu SICLOPPS inteins showed no toxicity to E. coli, demonstrating their potential for the production of cyclic peptide libraries for use in a variety of high-throughput screens.

Post-translational control of protein function with light using a LOV-intein fusion protein

Co-reporter:D. C. Jones, I. N. Mistry and A. Tavassoli

Molecular BioSystems 2016 vol. 12(Issue 4) pp:1388-1393

Publication Date(Web):01 Mar 2016

DOI:10.1039/C6MB00007J

Methods for the post-translational control of protein function with light hold much value as tools in cell biology. To this end, we report a fusion protein that consists of DnaE split-inteins, flanking the light sensitive LOV2 domain of Avena sativa. The resulting chimera combines the activities of these two unrelated proteins to enable controlled formation of a functional protein via upregulation of intein splicing with blue light in bacterial and human cells.

AMPK Activation via Modulation of De Novo Purine Biosynthesis with an Inhibitor of ATIC Homodimerization

Co-reporter:Daniel J. Asby, Francesco Cuda, Maxime Beyaert, Franchesca D. Houghton, Felino R. Cagampang, Ali Tavassoli

Chemistry & Biology 2015 Volume 22(Issue 7) pp:838-848

Publication Date(Web):23 July 2015

DOI:10.1016/j.chembiol.2015.06.008

•AICAR transformylase is targeted in cells with an ATIC homodimerization inhibitor•The resulting increase in endogenous ZMP is sufficient to activate AMPK•Downstream AMPK signaling is also activated, significantly altering cell metabolism•A mouse model of metabolic syndrome is used to show therapeutic viability5-Aminoimidazole-4-carboxamide ribonucleotide (known as ZMP) is a metabolite produced in de novo purine biosynthesis and histidine biosynthesis, but only utilized in the cell by a homodimeric bifunctional enzyme (called ATIC) that catalyzes the last two steps of de novo purine biosynthesis. ZMP is known to act as an allosteric activator of the cellular energy sensor adenosine monophosphate-activated protein kinase (AMPK), when exogenously administered as the corresponding cell-permeable ribonucleoside. Here, we demonstrate that endogenous ZMP, produced by the aforementioned metabolic pathways, is also capable of activating AMPK. Using an inhibitor of ATIC homodimerization to block the ninth step of de novo purine biosynthesis, we demonstrate that the subsequent increase in endogenous ZMP activates AMPK and its downstream signaling pathways. We go on to illustrate the viability of using this approach to AMPK activation as a therapeutic strategy with an in vivo mouse model for metabolic disorders.Figure optionsDownload full-size imageDownload high-quality image (171 K)Download as PowerPoint slide

Probing the epigenetic regulation of HIF-1α transcription in developing tissue

Co-reporter:I. N. Mistry, P. J. S. Smith, D. I. Wilson and A. Tavassoli

Molecular BioSystems 2015 vol. 11(Issue 10) pp:2780-2785

Publication Date(Web):04 Jun 2015

DOI:10.1039/C5MB00281H

HIF-1 is the master regulator of cellular hypoxia response; the oxygen sensitive HIF-1α subunit transactivates its own expression in hypoxia via a hypoxia response element (HRE) in the promoter of the HIF-1α gene. This transactivation loop significantly contributes to the build up of HIF-1α at the onset of hypoxia, with the binding of HIF-1 to the HIF-1α promoter being dependent on the epigenetic status of a CpG dinucleotide in the upstream HRE. Given the central role played by HIF-1 in tissue development, we sought to probe the epigenetic status of the HIF-1α HRE and that of its downstream target EPO in embryonic tissue. Our data shows that the CpG dinucleotide in HIF-1α HRE is unmethylated in several embryonic tissue samples, suggesting that transactivation of HIF-1α plays a significant role in HIF-1 mediated hypoxia response during development.

A bidirectional fluorescent two-hybrid system for monitoring protein–protein interactions

Co-reporter:Ida Karin Nordgren and Ali Tavassoli

Molecular BioSystems 2014 vol. 10(Issue 3) pp:485-490

Publication Date(Web):29 Nov 2013

DOI:10.1039/C3MB70438F

Two-hybrid systems have been the cornerstone of research into protein–protein interactions, but these systems typically rely on life/death reporters that put additional selective pressure on the host organism, and potentially lead to false positives. Here we report a bidirectional fluorescence-based bacterial two-hybrid system that enables both the association and dissociation of a given protein–protein interaction to be monitored. The functionality of this system and its compatibility with FACS screening are demonstrated in the forward and reverse direction using known interacting protein-partners and their cyclic peptide inhibitors. The reported fluorescent two-hybrid system may be used in the forward direction for the identification of interacting protein partners, or as a reverse two-hybrid system for the high-throughput identification of protein–protein interaction inhibitors.

Transcription of Click-Linked DNA in Human Cells

Co-reporter:Dr. Charles N. Birts;Dr. A. Pia Sanzone;Dr. Afaf H. El-Sagheer;Dr. Jeremy P. Blaydes; Tom Brown;Dr. Ali Tavassoli

Angewandte Chemie International Edition 2014 Volume 53( Issue 9) pp:2362-2365

Publication Date(Web):

DOI:10.1002/anie.201308691

Abstract

Click DNA ligation promises an alternative to the current enzymatic approaches for DNA assembly, with the ultimate goal of using efficient chemical reactions for the total chemical synthesis and assembly of genes and genomes. Such an approach would enable the incorporation of various chemically modified bases throughout long stretches of DNA, a feat not possible with current polymerase-based methods. An unequivocal requirement for this approach is the biocompatibility of the resulting triazole-linked DNA. The correct function of this unnatural DNA linker in human cells is demonstrated here by using a click-linked gene encoding the fluorescent protein mCherry. Reverse transcription of mRNA isolated from these cells and subsequent sequencing of the mCherry cDNA shows error-free transcription. Nucleotide excision repair (NER) is shown to not play a role in the observed biocompatibility by using a NER-deficient human cell line. This is the first example of a non-natural DNA linker being functional in a eukaryotic cell.

Inside Back Cover: Transcription of Click-Linked DNA in Human Cells (Angew. Chem. Int. Ed. 9/2014)

Co-reporter:Dr. Charles N. Birts;Dr. A. Pia Sanzone;Dr. Afaf H. El-Sagheer;Dr. Jeremy P. Blaydes; Tom Brown;Dr. Ali Tavassoli

Angewandte Chemie International Edition 2014 Volume 53( Issue 9) pp:

Publication Date(Web):

DOI:10.1002/anie.201400939

Transcription of Click-Linked DNA in Human Cells

Co-reporter:Dr. Charles N. Birts;Dr. A. Pia Sanzone;Dr. Afaf H. El-Sagheer;Dr. Jeremy P. Blaydes; Tom Brown;Dr. Ali Tavassoli

Angewandte Chemie 2014 Volume 126( Issue 9) pp:2394-2397

Publication Date(Web):

DOI:10.1002/ange.201308691

Abstract

Innenrcktitelbild: Transcription of Click-Linked DNA in Human Cells (Angew. Chem. 9/2014)

Co-reporter:Dr. Charles N. Birts;Dr. A. Pia Sanzone;Dr. Afaf H. El-Sagheer;Dr. Jeremy P. Blaydes; Tom Brown;Dr. Ali Tavassoli

Angewandte Chemie 2014 Volume 126( Issue 9) pp:

Publication Date(Web):

DOI:10.1002/ange.201400939

A Cyclic Peptide Inhibitor of HIF-1 Heterodimerization That Inhibits Hypoxia Signaling in Cancer Cells

Co-reporter:Elena Miranda ; Ida K. Nordgren ; Abigail L. Male ; Charlotte E. Lawrence ; Franciane Hoakwie ; Francesco Cuda ; William Court ; Keith R. Fox ; Paul A. Townsend ; Graham K. Packham ; Suzanne A. Eccles

Journal of the American Chemical Society 2013 Volume 135(Issue 28) pp:10418-10425

Publication Date(Web):June 24, 2013

DOI:10.1021/ja402993u

Hypoxia inducible factor-1 (HIF-1) is a heterodimeric transcription factor that acts as the master regulator of cellular response to reduced oxygen levels, thus playing a key role in the adaptation, survival, and progression of tumors. Here we report cyclo-CLLFVY, identified from a library of 3.2 million cyclic hexapeptides using a genetically encoded high-throughput screening platform, as an inhibitor of the HIF-1α/HIF-1β protein–protein interaction in vitro and in cells. The identified compound inhibits HIF-1 dimerization and transcription activity by binding to the PAS-B domain of HIF-1α, reducing HIF-1-mediated hypoxia response signaling in a variety of cell lines, without affecting the function of the closely related HIF-2 isoform. The reported cyclic peptide demonstrates the utility of our high-throughput screening platform for the identification of protein–protein interaction inhibitors, and forms the starting point for the development of HIF-1 targeted cancer therapeutics.

A cyclic peptide inhibitor of C-terminal binding protein dimerization links metabolism with mitotic fidelity in breast cancer cells

Co-reporter:Charles N. Birts, Sharandip K. Nijjar, Charlotte A. Mardle, Franciane Hoakwie, Patrick J. Duriez, Jeremy P. Blaydes and Ali Tavassoli

Chemical Science 2013 vol. 4(Issue 8) pp:3046-3057

Publication Date(Web):04 Jun 2013

DOI:10.1039/C3SC50481F

Identification of direct modulators of transcription factor protein–protein interactions is a key challenge for ligand discovery that promises to significantly advance current approaches to cancer therapy. Here, we report an inhibitor of NADH-dependent dimerization of the C-terminal binding protein (CtBP) transcriptional repressor, identified by screening genetically encoded cyclic peptide libraries of up to 64 million members. CtBP dimers form the core of transcription complexes associated with epigenetic regulation of multiple genes that control many characteristics of cancer cells, including proliferation, survival and migration. CtBP monomers also have distinct and critical cellular function, thus current experimental tools that deplete all forms of a targeted protein (e.g. siRNA) do not allow the cellular consequences of this metabolically regulated transcription factor to be deciphered. The most potent inhibitor from our screen (cyclo-SGWTVVRMY) is demonstrated to disrupt CtBP dimerization in vitro and in cells. This compound is used as a chemical tool to establish that the NADH-dependent dimerization of CtBPs regulates the maintenance of mitotic fidelity in cancer cells. Treatment of highly glycolytic breast cancer cell lines with the identified inhibitor significantly reduced their mitotic fidelity, proliferation and colony forming potential, whereas the compound does not affect mitotic fidelity of cells with lower glycolytic flux. This work not only links the altered metabolic state of transformed cells to a key determinant of the tumor cell phenotype, but the uncovered compound also serves as the starting point for the development of potential therapeutic agents that target tumors by disrupting the CtBP chromatin-modifying complex.

The association of the cytoplasmic domains of interleukin 4 receptor alpha and interleukin 13 receptor alpha 2 regulates interleukin 4 signaling

Co-reporter:Allison-Lynn Andrews, Ida Karin Nordgren, Gemma Campbell-Harding, John W. Holloway, Stephen T. Holgate, Donna E. Davies and Ali Tavassoli

Molecular BioSystems 2013 vol. 9(Issue 12) pp:3009-3014

Publication Date(Web):17 Sep 2013

DOI:10.1039/C3MB70298G

Interleukin-4 (IL-4) and Interleukin-13 (IL-13), key cytokines in the pathogenesis of allergic inflammatory disease, mediate their effects via a receptor composed of IL-13Rα1 and IL-4Rα. A third (decoy) receptor called IL-13Rα2 regulates interleukin signaling through this receptor complex. We employed a variety of biophysical and cell-based techniques to decipher the role of this decoy receptor in mediating IL-4 signaling though the IL-4Rα–IL-13Rα1 receptor complex. Surface plasmon resonance (SPR) analysis showed that IL-13Rα2 does not bind IL-4, and does not affect binding of IL-4 to IL-4Rα. These results indicate that the extracellular domains of IL-4Rα and IL-13Rα2 are not involved in the regulation of IL-4 signaling by IL-13Rα2. We next used a two-hybrid system to show that the cytoplasmic domains of IL-4Rα and IL-13Rα2 interact, and that the secondary structure of the IL-13Rα2 intracellular domain is critical for this interaction. The cellular relevance of this interaction was next investigated. BEAS-2B bronchial epithelial cells that stably express full length IL-13Rα2, or IL-13Rα2 lacking its cytoplasmic domain, were established. Over expression of IL-13Rα2 attenuated IL-4 and IL-13 mediated STAT6 phosphorylation. IL-13Rα2 lacking its cytoplasmic domain continued to attenuate IL-13-mediated signaling, but had no effect on IL-4-mediated STAT6 signaling. Our results suggest that the physical interaction between the cytoplasmic domains of IL-13Rα2 and IL-4Rα regulates IL-4 signaling through the IL-4Rα–IL-13Rα1 receptor complex.

Targeting Tumour Proliferation with a Small-Molecule Inhibitor of AICAR Transformylase Homodimerization

Co-reporter:Dr. Ian B. Spurr;Dr. Charles N. Birts;Dr. Francesco Cuda; Stephen J. Benkovic;Dr. Jeremy P. Blaydes;Dr. Ali Tavassoli

ChemBioChem 2012 Volume 13( Issue 11) pp:1628-1634

Publication Date(Web):

DOI:10.1002/cbic.201200279

Abstract

Aminoimidazole carboxamide ribonucleotide transformylase/ inosine monophosphate cyclohydrolase (ATIC) is a bifunctional homodimeric enzyme that catalyzes the last two steps of de novo purine biosynthesis. Homodimerization of ATIC, a protein–protein interaction with an interface of over 5000 Å², is required for its aminoimidazole carboxamide ribonucleotide (AICAR) transformylase activity, with the active sites forming at the interface of the interacting proteins. Here, we report the development of a small-molecule inhibitor of AICAR transformylase that functions by preventing the homodimerization of ATIC. The compound is derived from a previously reported cyclic hexapeptide inhibitor of AICAR transformylase (with a K_i of 17 μM), identified by high-throughput screening. The active motif of the cyclic peptide is identified as an arginine-tyrosine dipeptide, a capped analogue of which inhibits AICAR transformylase with a K_i value of 84 μM. A library of nonnatural analogues of this dipeptide was designed, synthesized, and assayed. The most potent compound inhibits AICAR transformylase with a K_i value of 685 nM, a 25-fold improvement in activity from the parent cyclic peptide. The potential for this AICAR transformylase inhibitor in cancer therapy was assessed by studying its effect on the proliferation of a model breast cancer cell line. Using a nonradioactive proliferation assay and live cell imaging, a dose-dependent reduction in cell numbers and cell division rates was observed in cells treated with our ATIC dimerization inhibitor.

Targeting tumour angiogenesis with small molecule inhibitors of hypoxia inducible factor

Co-reporter:Ida Karin Nordgren and Ali Tavassoli

Chemical Society Reviews 2011 vol. 40(Issue 8) pp:4307-4317

Publication Date(Web):11 Apr 2011

DOI:10.1039/C1CS15032D

The adaptation of tumours to hypoxia is critical for their survival and growth. The high proliferation rate of solid tumours causes the continuous outstripping of the oxygen supply provided by the local vasculature, resulting in hypoxic regions within the tumour. Hypoxia inducible factor (HIF) is the key mediator of cellular response to hypoxia, activating the expression of multiple genes that participate in angiogenesis, iron metabolism, glycolysis, glucose transport and cell proliferation and survival. The critical role of the hypoxia response network and HIF in cancer has resulted in it being viewed as an ideal target for small molecule intervention. In this tutorial review we discuss the central role of HIF in the adaptation of tumours to a hypoxic environment, going on to describe recent attempts at developing small molecules that disrupt this pathway and their potential for use as the next generation anticancer therapeutics.

Deciphering interactions used by the influenza virus NS1 protein to silence the host antiviral sensor protein RIG-I using a bacterial reverse two-hybrid system

Co-reporter:Elena Miranda, Fedor Forafonov and Ali Tavassoli

Molecular BioSystems 2011 vol. 7(Issue 4) pp:1042-1045

Publication Date(Web):24 Jan 2011

DOI:10.1039/C0MB00318B

The majority of biological processes are controlled and regulated by an intricate network of thousands of interacting proteins. Identifying and understanding the key components of these protein networks, especially those that play a critical role in disease, is a challenge that promises to dramatically alter our current approach to healthcare. To facilitate this process, we have developed a method for the rapid construction of a chromosomally integrated, bacterial reverse two-hybrid system (RTHS) that enables the identification of interacting protein partners. Chromosomal integration of the RTHS enables stable protein expression, free of plasmid copy-number effects, as well as eliminating false positives arising from plasmid ejection. We have utilized this approach to identify the interactions used by the influenza virus NS1 protein to silence the host's antiviral defences.

A cyclic peptide inhibitor of C-terminal binding protein dimerization links metabolism with mitotic fidelity in breast cancer cells

Co-reporter:Charles N. Birts, Sharandip K. Nijjar, Charlotte A. Mardle, Franciane Hoakwie, Patrick J. Duriez, Jeremy P. Blaydes and Ali Tavassoli

Chemical Science (2010-Present) 2013 - vol. 4(Issue 8) pp:NaN3057-3057

Publication Date(Web):2013/06/04

DOI:10.1039/C3SC50481F

Targeting tumour angiogenesis with small molecule inhibitors of hypoxia inducible factor

Co-reporter:Ida Karin Nordgren and Ali Tavassoli

Chemical Society Reviews 2011 - vol. 40(Issue 8) pp:NaN4317-4317

Publication Date(Web):2011/04/11

DOI:10.1039/C1CS15032D