{"id":109,"date":"2020-01-23T22:46:58","date_gmt":"2020-01-24T03:46:58","guid":{"rendered":"https:\/\/sciencescosmaincms.cm.ucf.edu\/chemistry\/nox-natural-products\/?page_id=109"},"modified":"2025-02-05T15:39:49","modified_gmt":"2025-02-05T20:39:49","slug":"publications","status":"publish","type":"page","link":"https:\/\/sciences.ucf.edu\/chemistry\/nox-natural-products\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

Links to all papers published by PI can be found at Google Scholar<\/a><\/p>\n

Publications from NOx Nation<\/em><\/h3>\n

28. Albert, T.; Kumar A.; Caranto, J.D.; Mo\u00ebnne-Loccoz, P.* Vibrational analyses of the reaction of oxymyoglobin with NO using a photolabile caged NO donor at cryogenic temperatures J. Inorg. Biochem. <\/em>2024, <\/strong>258, <\/em>112633.<\/p>\n

27.Strickland, K.A.; Martinez Rodriguez, B.; Holland, A.A.; Wagner, S.; Luna-Alva, M.; Graham, D.A.; Caranto. J.D.* Activity assays of NnlA homologs suggest the natural product N<\/em>-nitroglycine is degraded by diverse bacteria Beilstein J. Org. Chem.<\/em> 2024,<\/strong> 20,<\/em> 830-840.
\n\u2022 Invited article in Thematic Issue titled, \u201cYoung Investigators in Natural Products Chemistry, Biosynthesis, and Enzymology\u201d in Bielstein J. Org. Chem.<\/em><\/p>\n

26. Shultz-Johnson, L.R.; Chang, M.; Bisram, N.N.; Bryant, J.T.; Martin, C.P.; Rahmani, A.; Furst, J.I.; Caranto, J.D.; Banerjee, P.; Uribe-Romo, F.J.; Gamelin, D.R.; and Jurca, T. Multivariate Analysis on the Structure\u2212Activity Parameters for 2 Nano-CuOx\u2011Catalyzed Reduction Reactions <\/span> ACS Appl. Nano Mater.<\/em> 2024,<\/strong> Accepted.<\/em><\/p>\n

25. Bryant, J.T,; Logan, M.W.; Chen, X.; Djokic, M.; Cairnie, D.R.; Vazquez-Molina, D.A.; Nijamudheen, A.; Langlois, K.R.; Markley, M.J.; Pombar, G.; Holland, A.A.; Caranto, J.D.; Harper, J.K; Morris, A.J.;* Mendoza-Cortes, J.L.;* Jurca, T.;* Chapman, K.;* Uribe-Romo, F.J. Synergistic Steric and Electronic Effects on the Photoredox Catalysis by a Multivariate Library of Titania Metal\u2013Organic Frameworks<\/span> J. Am. Chem. Soc.<\/em> 2023,<\/strong> 145,<\/em> 4589-4600. DOI: 10.1021\/jacs.2c12147<\/a><\/p>\n

24. Nix, C.A.; Nottolini, I.; Caranto, J.D.; Gerasimova, Y.; Kolpashchikov, D.; Saitta, E.K.H. Championing the Involvement of Practitioners in the Biochemistry Educational Research Process: A Phenomenological View of the Early Stages of Collaborative Action Research.<\/span> Int. J. High. Educ.<\/em> 2022,<\/strong> 11,<\/em> 114-139.
\n\"\"<\/p>\n

23. Strickland, K.A.; Holland, A.A.; Trudeau, A.; Szlamkowicz, I.; Beazley, M.J.; Anagnostopoulos, V.A.; Graham, D.A.; Caranto. J.D. Reduction of a Heme Cofactor Initiates N-Nitroglycine Degradation by NnlA.<\/span> Appl. Environ. Microbiol.<\/em> 2022,<\/strong> 88,<\/em> e0102322. DOI: 10.1128\/aem.01023-22<\/a><\/p>\n

\"\"
\n22. Ma, Z; Holland, A.A.; Szlamkowicz, I.; Anagnostopoulos, V.A.; Caldas Nogueira, M.L.; Caranto, J.D.; Davidson, V.L. The hemerythrin-like diiron protein from Mycobacterium kansasii<\/em> is a nitric oxide peroxidase.<\/span> J. Biol. Chem.<\/em> 2022<\/strong>, 298<\/em>, 101696. DOI: 10.1016\/j.jbc.2022.101696<\/a>
\n\"Table<\/p>\n

21.\u00a0Martin, C.P.; Chen, M.; Martinez, M.F.; Ding, Y.; Caranto, J.D. The ferric-superoxo intermediate of the TxtE nitration pathway resists reduction, facilitating its reaction with nitric oxide.<\/span> Biochemistry<\/em> 2021,<\/strong> 60<\/em>, 2436\u20132446. DOI: 10.1021\/acs.biochem.1c00416<\/a><\/p>\n

<\/h5>\n

\"\"
\n20. Caranto, J.D. The emergence of nitric oxide in the biosynthesis of bacterial natural products<\/span>, Curr. Opin. Chem. Biol.<\/em> 2019<\/strong>, 49<\/em>, 130\u2013138. DOI: 10.1016\/j.cbpa.2018.11.007<\/a><\/p>\n

\n

Pre-independent career publications by the PI<\/em><\/h3>\n

The PI’s prior published work was performed in the labs of Dr. Jonathan King (Trinity University), Dr. Donald Kurtz (University of Texas at San Antonio) and Dr. Kyle Lancaster (Cornell University). Most of these works focused on metalloenzyme systems related to the nitrogen cycle, environmental impacts of fertilization, and bacterial nitrosative stress protections. A list of these works are listed below:<\/p>\n

19. Transue, W.J.; Snyder, R.A.; Caranto, J.D.; Kurtz, Jr., D.M.; Solomon, E.I. Particle Swarm Fitting of Spin Hamiltonians: Magnetic Circular Dichroism of Reduced and NO-Bound Flavodiiron Protein<\/span>, Inorg. Chem.<\/em> 2022<\/strong>, 61<\/em>, 1247-1250.<\/p>\n

18. Dong, M.; Kathiresan, V.; Fenwich, M.K.; Torelli, A.T.; Zhang, Y.; Caranto, J.D.; Dzikovski, B.; Lancaster, K.M.; Freed, J.H.; Ealick, S.E.; Hoffmann, B.M.; Lin, H. Organometallic and radical intermediates reveal the reaction mechanism for the diphthamide biosynthetic radical SAM enzyme<\/span>, Science<\/em> 2018<\/strong>, 359<\/em>, 16520\u201316527.<\/p>\n

17. Lancaster, K.M.; Caranto, J.D.; Majer, S.H.; Smith, M.A. Alternative bioenergy: Updates to and challenges in nitrification metalloenzymology<\/span>, Joule<\/em> 2018<\/strong>, 2<\/em>, 421-441.<\/p>\n

16. Vilbert, A.C.; Caranto, J.D.; Lancaster, K.M. The lysine cross-link to heme P460 obviates NO-dependent histidine-dissociation from Nitrosomonas europaea<\/em> cytochrome P460 {FeNO}7<\/sup><\/span>, Chem. Sci.<\/em> 2018<\/strong>, 9<\/em>, 368-379.<\/p>\n

15. Weitz, A.C; Giri, N.; Caranto, J.D.; Kurtz, D.M., Jr.; Bominaar, E.L.; Hendrich, M.P. Spectroscopy and DFT calculations of a flavo-diiron enzyme implicate new diiron site structures<\/span>, J. Am. Chem. Soc.<\/em> 2017<\/strong>, 139<\/em>, 12009\u201312019.<\/p>\n

14. Caranto, J.D.; Lancaster, K.M. Nitric oxide is an obligate bacterial nitrification intermediate produced by hydroxylamine oxidoreductase<\/span>, Proc. Natl. Acad. Sci. U.S.A.<\/em> 2017<\/strong>, 114<\/em>, 8217\u20138222.<\/p>\n

13. Caranto, J.D; Vilbert, A.C.; Lancaster, K.M. Nitrosomonas europaea<\/em> cytochrome P460 is a direct link between nitrification and nitrous oxide emission<\/span>, Proc. Natl. Acad. Sci. U.S.A.<\/em> 2016<\/strong>, 113<\/em>, 14704\u201314709.<\/p>\n

12. Frederick, R.E.; Caranto, J.D.; Masitas, C.A.; Gebhardt, L.L.; MacGowan, C.E.; Limberger, R.J.; Kurtz, D.M., Jr. Dioxygen and nitric oxide scavenging by Treponema denticola<\/em> flavo-diiron protein: A mechanistic paradigm for catalysis<\/span>, J. Biol. Inorg. Chem.<\/em> 2015<\/strong>, 20<\/em>, 603\u2013613.<\/p>\n

11. Caranto, J.D.; Weitz, A.; Giri, N.; Hendrich, M.P.; Kurtz, D.M., Jr. A diferrous-dinitrosyl intermediate in the N2<\/sub>O-generating pathway of a deflavinated flavo-diiron protein<\/span>, Biochemistry<\/em> 2014<\/strong>, 53<\/em>, 5631\u20135637.<\/p>\n

10. Caranto, J.D.; Weitz, A.; Hendrich, M.P.; Kurtz, D.M., Jr. The nitric oxide reductase mechanism of flavo-diiron protein: Identification of active-site intermediates and products<\/span>, J. Am. Chem. Soc.<\/em> 2014<\/strong>, 136<\/em>, 7981\u20137992.<\/p>\n

9. Meininger, D.J.; Caranto, J.D.; Arman, H.D.; Tonzetich, Z.J. Studies of Iron(III) Porphyrinates Containing Silanethiolate Ligands<\/span>, Inorg. Chem.<\/em> 2013<\/strong>, 52<\/em>, 12468\u201312476.<\/p>\n

8. Kurtz, D.M., Jr.; Boice, E.; Caranto, J.D.; Frederick, R.E.; Masitas, C.A.; Miner, K.D. Iron: Non-heme protein with diiron-carboxylate active sites<\/span>. In Encyclopedia of Inorganic and Bioinorganic Chemistry; Scott, R.A., Ed.; Wiley: New York, 2013.<\/p>\n

7. Fang, H.; Caranto, J.D.; Mendoza, R.; Taylor A.B.; Hart, P.J.; Kurtz, D.M., Jr. Histidine ligand variants of a flavo-diiron protein: effects on structure and activities<\/span>, J. Biol. Inorg. Chem.<\/em> 2012<\/strong>, 17<\/em>, 1231\u20131239.<\/p>\n

6. Caranto, J.D.; Gebhardt, L.L.; MacGowan, C.E.; Limberger, R.J.; Kurtz, D.M., Jr. Treponema denticola<\/em> superoxide reductase: In vivo role, in vitro reactivities and a novel [Fe(Cys)4<\/sub>] site<\/span>, Biochemistry<\/em> 2012<\/strong>, 51<\/em>, 5601\u20135610.<\/p>\n

5. Hayashi, T.; Caranto, J.D.; Matsumara, H.; Kurtz, D.M., Jr.; Mo\u00ebnne-Loccoz, P. Vibrational analysis of mononitrosyl complexes in hemerythrin and flavodiiron proteins: relevance to detoxifying NO reductase<\/span>, J. Am. Chem. Soc.<\/em> 2012<\/strong>, 134<\/em>, 6878\u20136884.<\/p>\n

4. Felhofer, J.L.; Caranto J.D.; Garcia C.D. Adsorption kinetics of catalase to thin-films of carbon nanotubes<\/span>, Langmuir<\/em> 2010<\/strong>, 26<\/em>, 17178\u201317183.<\/p>\n

3. Hayashi, T.; Caranto, J.D.; Wampler, D.A.; Kurtz, D.M., Jr.; Mo\u00ebnne-Loccoz, P. Insights into the nitric oxide reductase mechanism of flavo-diiron proteins from flavin-free enzyme<\/span>, Biochemistry<\/em> 2010<\/strong>, 49<\/em>, 7040\u20137049.<\/p>\n

2. Hillmann, F.; Riebe O.; Fischer R.; Mot A.; Caranto J.D.; Kurtz D.M., Jr.; Bahl, H. Reductive dioxygen scavenging by flavo-diiron proteins of Clostridium acetobutylicum<\/em><\/span>, FEBS Lett<\/em>. 2009<\/strong>, 583<\/em>, 241\u2013245.<\/p>\n

1. Leone, A.K.; Chun, J.A.; Koehler, C.L.; Caranto, J.D.; King, J.K. Effect of proinflammatory cytokines tumor necrosis factor-\u03b1 and interferon-\u03b3 on epithelial barrier function and matrix metalloproteinase-9 in Madin-Darby canine kidney cells<\/span>, Cell. Physiol. Biochem.<\/em> 2007<\/strong>, 19<\/em>, 99\u2013112.<\/p>\n","protected":false},"excerpt":{"rendered":"

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