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Reprogramming the transcriptional response to hypoxia with a chromosomally encoded cyclic peptide HIF-1 inhibitor

Reprogramming the transcriptional response to hypoxia with a chromosomally encoded cyclic peptide HIF-1 inhibitor
Reprogramming the transcriptional response to hypoxia with a chromosomally encoded cyclic peptide HIF-1 inhibitor
The cellular response to hypoxia is orchestrated by HIF-1, a heterodimeric transcription factor composed of an and 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-1/HIF-1 protein-protein interaction in vitro and prevents HIF-1-mediated hypoxia-response signalling in cells. This cyclic peptide was identified from a library of 3.2 x 106 members generated using SICLOPPS split-intein mediated protein splicing. With a view to demonstrating the potential for encoding the production of a therapeutic agents 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 signalling. 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.
518-527
Mistry, Ishna
70e94cae-a95e-44f8-b1f3-3218d6d278cf
Tavassoli, Ali
d561cf8f-2669-46b5-b6e1-2016c85d63b2
Mistry, Ishna
70e94cae-a95e-44f8-b1f3-3218d6d278cf
Tavassoli, Ali
d561cf8f-2669-46b5-b6e1-2016c85d63b2

Mistry, Ishna and Tavassoli, Ali (2017) Reprogramming the transcriptional response to hypoxia with a chromosomally encoded cyclic peptide HIF-1 inhibitor. ACS Synthetic Biology, 6 (3), 518-527. (doi:10.1021/acssynbio.6b00219).

Record type: Article

Abstract

The cellular response to hypoxia is orchestrated by HIF-1, a heterodimeric transcription factor composed of an and 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-1/HIF-1 protein-protein interaction in vitro and prevents HIF-1-mediated hypoxia-response signalling in cells. This cyclic peptide was identified from a library of 3.2 x 106 members generated using SICLOPPS split-intein mediated protein splicing. With a view to demonstrating the potential for encoding the production of a therapeutic agents 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 signalling. 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.

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Accepted/In Press date: 10 November 2016
e-pub ahead of print date: 23 November 2016
Published date: 16 March 2017
Related URLs:
Organisations: Chemical Biology Group

Identifiers

Local EPrints ID: 403009
URI: http://eprints.soton.ac.uk/id/eprint/403009
DOI: doi:10.1021/acssynbio.6b00219
PURE UUID: c425140c-d240-4434-ae15-fbcfee26f7a4
ORCID for Ali Tavassoli: ORCID iD orcid.org/0000-0002-7420-5063

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Date deposited: 21 Nov 2016 16:19
Last modified: 16 Mar 2024 03:51

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Contributors

Author: Ishna Mistry
Author: Ali Tavassoli ORCID iD

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