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Sergei A Markov

Sergei Markov

Professor

Biology

 

  • Ph.D. Lomonosov Moscow State University (Microbiology)

  • M.S. Lomonosov Moscow State University (Physiology)

Microbiology, Bacteriology, Cells & Genes, Bioprocess Engineering

  • Biofuels Research: using algae for biofuel production and carbon mitigation (1) and molecular hydrogen production by microorganisms in bioreactors (2). 

  • Bacteriophage Research: isolation and genome annotation of bacteriophages

  • Markov S.A., Olusoga K.O., Oni P.O., Henderson G. A. Genome sequence of Microbacterium foliorum bacteriophage DumpQuist isolated from soil in Clarksville, TN (2023) Microbiol Resour Announc. 12 (12): e0092323

  • Markov S.A., Arms, N.L., Boyce, K.J., Cardona, M.R., Couch, A.M., Duncan, L.E., Enodiana, O.I., Gibson, J .N., Greer, K.J., Habib, C.M., Isaac, U.G., Johnson, T.C., Lewis, G., Long, S.K., Ogas, I.A., Olusoga, K.O., Oni, P.O., Victory, K.-N.H., Zimmer, R.J. Complete genome sequence of Microbacterium foliorum bacteriophage Librie. (2022) Microbiol Resour Announc. e00918-22 http://doi.org/10.1128/mra.00918-22

  • Markov S.A, Church J. C., Lee L., Bell C. M., Binkley S.D., Bouma K. M., Hutson K. M., Markov G.S., Mason E.C., Rueff G.B., Sennuga T.O., Simpson M.H., Zimmer R.J., Villalpando D.G. Complete genome sequences of Microbacterium bacteriophages Danno, Otwor and Scumberland isolated in Clarksville, Tennessee. (2021) Microbiol Resour Announc 10: e00209-21. http://doi.org/10.1128/MRA.00209-21

  • Markov S.A., Protasov E.S., Bybin V. A., Eivazova E.R. and Stom D. I. Using immobilized cyanobacteria and culture medium contaminated with ammonium for H2 production in a hollow-fiber photobioreactor (2015) Int. J. Hydrogen Energy, vol. 40, pp. 4752-4757.

  • Markov S.A., Protasov E.S., Bybin V. A. and Stom D. I. Hydrogen production by microorganisms and microbial fuel cells using wastewater and waste products (2013) International Scientific Journal for Alternative Energy and Ecology, vol. 118, n. 1 (2), p. 108-119.

  • Eivazova E.R and Markov S.A.  Conformational regulation of the hydrogenase gene expression in green alga Chlamydomonas reinhardtii (2012) Int. J. Hydrogen Energy, vol. 37, pp. 17778-17793.

  • Markov S.A. Hydrogen production in bioreactors:  current trends (2012) Energy Procedia, vol. 29, pp.394-400

  • Markov S.A. Lynn Margulis (2012) In:  Joseph L. Spradley (ed) Great Lives from History: Science and Scientists. EBSCO Publishing, Ipswich, MA, pp. 662-665

  • Markov S.A. Nitrogen Cycle (2012) In: Joe Spradley, David Kenneth Elliott, Steven I. Dutch and Dr. Margaret Boorstein (ed.) Earth Science. Water & Atmosphere. EBSCO Publishing, Ipswich, MA, pp. 347-350

  • Markov S. A. Biofuels and Synthetic Fuels (2012) In. Donald R. Franceschetti (Ed.) Applied Science. Salem Press (EBSCO), Ipswich, MA, Volume 1, pp. 199-204.

  • Markov S. A. Bioprocess Engineering (2012) In. Donald R. Franceschetti (Ed.) Applied Science.  Salem Press (EBSCO), Ipswich, MA, Volume 1, pp. 240-245.

  • Markov S. A. Industrial Fermentation. (2012) In. Donald R. Franceschetti (Ed.) Applied Science. Salem Press (EBSCO), Ipswich, MA, Volume 3, pp. 1037-1042.

  • Markov S.A., Averitt J. and Waldron B. Bioreactor for glycerol conversion into H2 by bacterium Enterobacter aerogenes (2011) Int. J. Hydrogen Energy, vol. 36, pp. 262-266.

  • Markov S. A. Biofuels Industry (2011) In.  Survey of American Industry and Careers. Salem Press. Pasadena, CA, pp. 177-196.

  • Markov S.A. and Waldron B. Hollow-fiber bioreactor for glycerin conversion into H2 by bacterium Enterobacter aerogenes.  (2010) International Scientific Journal for Alternative Energy and Ecology, vol. 88, n. 8, p. 130-134.

  • Markov S.A. Attention: algae (2009) International Scientific Journal for Alternative Energy and Ecology, vol. 72, n. 4, p. 8.

  • Markov S.A. Algae: hydrogen, biodiesel, carbon dioxide and water cleanup (2009) International Scientific Journal for Alternative Energy and Ecology, vol. 72, n. 4, p. 9-11.

  • Markov S.A. Potential of using microalgae for biofuel production and CO2 removal from atmosphere (2009). International Scientific Journal for Alternative Energy and Ecology, vol. 70, n. 2, pp. 83-91

  • Markov S.A., Weaver P.F. Bioreactors for H2 production by purple nonsulfur bacteria. (2008)  Appl. Biochem. Biotechnol., vol. 145, pp. 79-86.

  • Eivazova E. R., Markov S.A., Pirozhkova I., Lipinski M. and Vassetzky Y. S. Recruitment of RNA polymerase II in the Ifng gene promoter correlates with the nuclear matrix association in activated T helper cells (2007) J. Molecular Biology, vol. 371, pp. 317-322.

  • Markov S.A. Biohydrogen:  potential of using algae and bacteria for molecular hydrogen production (2007) International Scientific Journal for Alternative Energy and Ecology, n. 1, pp. 30-35.

  • Markov S.A., Eivazova E.R., and Greenwood J.  Photostimulation of H2 production in the green alga Chlamydomonas reinhardtii upon photoinhibition of its O2-evolving system  (2006) Int. J. Hydrogen Energy,  vol. 31, pp. 1314-1317.

  • Gaffney A.M., Markov S.A. and Gunasekaran M.  Utilization of cyanobacteria for orthophosphate removal from water (2001) Appl. Biochem. Biotechnol., vol. 91-93,  pp. 185-193.

  • Markov S.A.  Bioreactors for hydrogen production. (1998) In: O.R.Zaborsky (ed) Biohydrogen. Plenum, New York, pp. 383-390.

  • Markov S.A., Weaver P.F. and Seibert M. Spiral tubular bioreactors for hydrogen production by photosynthetic microorganisms: design and operation (1997) Appl. Biochem. Biotechnol., vol. 63-65, pp. 577-584.

  • Markov S.A., Thomas A.D., Bazin M.J. and Hall D.O. Photoproduction of hydrogen by cyanobacteria under partial vacuum in batch culture or in a photobioreactor (1997) Int. J. Hydrogen Energy, vol. 22, n.5, pp. 521-524.

  • Markov S.A., Bazin M.J. and Hall D.O. The efficiency of light energy conversion in hydrogen production by cyanobacterium Anabaena variabilis (1996) J.  Marine Biotechnology, vol. 4, pp. 57-60.

  • Hall D.O, Markov S.A., Watanabe Y. and Rao K.K. The potential application of cyanobacterial photosynthesis for clean technologies (1995) Photosynthesis research, vol. 46, pp.159-167.

  • Markov S.A., Bazin M.J. and Hall D.O. Potential of using cyanobacteria in photobioreactors for hydrogen production (1995) In: Fiechter A. (ed.) Advances in Biochemical Engineering/Biotechnology, Springer-Verlag, Berlin, vol. 52, pp. 59-86.

  • Markov S.A., Bazin M.J. and Hall D.O. Hydrogen photoproduction and carbon dioxide uptake by immobilized Anabaena variabilis in a hollow-fiber photobioreactor (1995) Enzyme and Microbial Technology, vol. 17, pp. 306-309.

  • Markov S.A. et al. A hollow-fiber photobioreactor for continuous production of hydrogen by immobilized cyanobacteria under partial vacuum (1993) Int. J. Hydrogen Energy, vol. 18, pp. 901-906.

  • Markov S.A. and Krasnovsky A.A.  Activation of nitrogenase in cyanobacteria upon photoinhibition of its oxygen-evolving system (1988) Biophysics, vol. 33, pp. 395-396.