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Construction of fluorescent analogs to follow the uptake and distribution of cobalamin (vitamin B12) in bacteria, worms, and plants

Construction of fluorescent analogs to follow the uptake and distribution of cobalamin (vitamin B12) in bacteria, worms, and plants
Construction of fluorescent analogs to follow the uptake and distribution of cobalamin (vitamin B12) in bacteria, worms, and plants
Vitamin B12 is made by only certain prokaryotes yet is required by a number of eukaryotes such as mammals, fish, birds, worms, and Protista, including algae. There is still much to learn about how this nutrient is trafficked across the domains of life. Herein, we describe ways to make a number of different corrin analogs with fluorescent groups attached to the main tetrapyrrole-derived ring. A further range of analogs were also constructed by attaching similar fluorescent groups to the ribose ring of cobalamin, thereby generating a range of complete and incomplete corrinoids to follow uptake in bacteria, worms, and plants. By using these fluorescent derivatives we were able to demonstrate that Mycobacterium tuberculosis is able to acquire both cobyric acid and cobalamin analogs, that Caenorhabditis elegans takes up only the complete corrinoid, and that seedlings of higher plants such as Lepidium sativum are also able to transport B12.
2451-9456
941-951.e6
Lawrence, Andrew D.
ce503b40-0155-486f-bb1d-26830b61b5f1
Nemoto-Smith, Emi
6057717d-27ec-46a4-a079-49eac626068e
Deery, Evelyne
16c10c8d-1383-4ce6-95dd-dfcfa0168875
Baker, Joseph A.
43b9b92e-a52e-4916-99d7-afc5b1a42198
Schroeder, Susanne
3bc51fbe-9fa2-4aec-b946-f2d5760a1129
Brown, David G.
19cdf1b4-33ae-479c-94d6-1f874ea59693
Tullet, Jennifer M.A.
bf834087-ea85-4840-8f3f-ced76bcfb6b2
Howard, Mark J.
780e29b9-d377-47aa-b39c-18f8591fa73f
Brown, Ian R.
ec0e3bc2-6a06-44b6-95b2-7ab7b6574829
Smith, Alison G.
2f820588-24d8-447e-add4-98d37b14c765
Boshoff, Helena I.
26b1bac8-cdcb-4548-be4d-8a31a4650c73
Barry, Clifton E.
76e544c8-07e0-41a7-b991-82c88f4e217e
Warren, Martin J.
0cbcb371-89aa-4405-afa3-e0b13c359623
et al.
Lawrence, Andrew D.
ce503b40-0155-486f-bb1d-26830b61b5f1
Nemoto-Smith, Emi
6057717d-27ec-46a4-a079-49eac626068e
Deery, Evelyne
16c10c8d-1383-4ce6-95dd-dfcfa0168875
Baker, Joseph A.
43b9b92e-a52e-4916-99d7-afc5b1a42198
Schroeder, Susanne
3bc51fbe-9fa2-4aec-b946-f2d5760a1129
Brown, David G.
19cdf1b4-33ae-479c-94d6-1f874ea59693
Tullet, Jennifer M.A.
bf834087-ea85-4840-8f3f-ced76bcfb6b2
Howard, Mark J.
780e29b9-d377-47aa-b39c-18f8591fa73f
Brown, Ian R.
ec0e3bc2-6a06-44b6-95b2-7ab7b6574829
Smith, Alison G.
2f820588-24d8-447e-add4-98d37b14c765
Boshoff, Helena I.
26b1bac8-cdcb-4548-be4d-8a31a4650c73
Barry, Clifton E.
76e544c8-07e0-41a7-b991-82c88f4e217e
Warren, Martin J.
0cbcb371-89aa-4405-afa3-e0b13c359623

Lawrence, Andrew D., Nemoto-Smith, Emi and Deery, Evelyne , et al. (2018) Construction of fluorescent analogs to follow the uptake and distribution of cobalamin (vitamin B12) in bacteria, worms, and plants. Cell Chemical Biology, 25 (8), 941-951.e6. (doi:10.1016/j.chembiol.2018.04.012).

Record type: Article

Abstract

Vitamin B12 is made by only certain prokaryotes yet is required by a number of eukaryotes such as mammals, fish, birds, worms, and Protista, including algae. There is still much to learn about how this nutrient is trafficked across the domains of life. Herein, we describe ways to make a number of different corrin analogs with fluorescent groups attached to the main tetrapyrrole-derived ring. A further range of analogs were also constructed by attaching similar fluorescent groups to the ribose ring of cobalamin, thereby generating a range of complete and incomplete corrinoids to follow uptake in bacteria, worms, and plants. By using these fluorescent derivatives we were able to demonstrate that Mycobacterium tuberculosis is able to acquire both cobyric acid and cobalamin analogs, that Caenorhabditis elegans takes up only the complete corrinoid, and that seedlings of higher plants such as Lepidium sativum are also able to transport B12.

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More information

Accepted/In Press date: 11 April 2018
e-pub ahead of print date: 17 May 2018
Published date: 16 August 2018
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Identifiers

Local EPrints ID: 488473
URI: http://eprints.soton.ac.uk/id/eprint/488473
DOI: doi:10.1016/j.chembiol.2018.04.012
ISSN: 2451-9456
PURE UUID: e3c7e9a9-fe40-4164-b267-09c212fdd071
ORCID for Andrew D. Lawrence: ORCID iD orcid.org/0000-0002-5853-5409

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Date deposited: 22 Mar 2024 18:01
Last modified: 23 Mar 2024 03:10

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Contributors

Author: Andrew D. Lawrence ORCID iD
Author: Emi Nemoto-Smith
Author: Evelyne Deery
Author: Joseph A. Baker
Author: Susanne Schroeder
Author: David G. Brown
Author: Jennifer M.A. Tullet
Author: Mark J. Howard
Author: Ian R. Brown
Author: Alison G. Smith
Author: Helena I. Boshoff
Author: Clifton E. Barry
Author: Martin J. Warren
Corporate Author: et al.

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