CAES: Neil P. Schultes

Neil P. Schultes

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Department of Plant Pathology and Ecology
The Connecticut Agricultural Experiment Station
123 Huntington Street
P.O. Box 1106
New Haven, CT 06504-1106
Voice: (203) 974-8464 Fax: (203) 974-8502
E-mail: Neil.Schultes@ct.gov


Expertise:
Dr. Schultes is a molecular biologist studying aspects of metabolism in plants and disease causing microorganisms.

Education:
A.B., Biology, Harvard University 1983
Ph.D., Department of Genetics, Harvard University Medical School 1990
Post-doctoral Fellowship, Biology, Yale University 1990-1994

Station Career:
Assistant Scientist, 1994-2001
Associate Agricultural Scientist 2001-present

Past Research:
Dr. Schultes has worked on the mechanism of gene conversion at the ARG4 locus in yeast, and cloning the gene encoding the large subunit of ribulose bisphosphate carboxylase from the cyanobacterium Fremyella diplosiphon.  Other research includes investigating the role of photorespiration in C4 photosynthesis in maize, using transposable element mutagenesis in maize genetics and studying the role of LHCB7 and PsbS genes in photosynthesis in the experimental plant Arabidopsis thaliana.

Current Research:

Dr. Schultes current work involves the genetics and molecular biology of nucleobase transporters in plants and disease causing microorganisms. The transport of nucleobases across biological membranes is essential to plant biochemistry. Nucleobases – also known as purines and pyrimidines - constitute the building blocks for DNA and RNA and are important molecules in plant nitrogen and secondary metabolism. Dr. Schultes and colleagues are also investigating nucleobase transporters from disease-causing bacteria Paenibacillus larvae and Erwinia amylovoraP. larvae is the causal agent of American foulbrood in honey bees and E. amylovora causes Fire blight on apples and pears.  In both organisms the transport of nucleobases and nucleobase-derivatives is involved in disease establishment.


Memberships:

Fellow of the Linnean Society of London

Sigma Xi – Quinnipiac Chapter

Research Associate Depart of Molecular, Cellular and Developmental Biology, Yale University

 

Selected publications available from the author, Neil.Schultes@ct.gov

  • Alexander, C., Dingman, D.W., Mourad, G.S., Schultes, N.P. The solute transport profile of two Aza-guanine transporters from the Honeybee pathogen Paenibacillus larvae. FEMS Microbiol. Letts. (submitted 2017).
  • Stoffer, A.J., Dingman, D.W., Mourad, G.S., Schultes, N.P. The solute transport and binding profile of a novel nucleobase cation symporter 2 from the Honeybee pathogen Paenibacillus larvae. J. of Microbiol. (submitted 2017).
  • Stoffer, A.J., Dingman, D.W., Mourad, G.S., Schultes N.P. Functional characterization of the uracil transporter from Honeybee pathogen Paenibacillus larvae. Arch. Microbiol. (submitted 2017).
  • Li D-W., Schultes N.P., Chen, J-Y., Wang, Y-X., Castañeda-Ruiz, R.F. Circinotrichum sinense, a new asexual fungus from Hubei, China. Botany (under review 2017)
  • Schultes, N.P., Murtishi, B., Li, D-W. Phylogenetic relationships and revision of Harzia, Olpitrichum, Chlamydomyces and their sexual allies. Fungal Biology (under review 2017)

  • Lehner, B.L., Schultes N.P., Dingman, D.W.  Paenibacillus larvae subspecies with dissimilar virulence patterns also group by vegetative growth characteristics and enolase isozyme biochemical properties. Agri Gene (under review 2017)

  • Nguyen, J. Hunt, K., Nalam, V., Schultes N. P., Mourad, G.S.,  Nucleobase Cation Symporter 1 function for Nicotiana sylvestris. Biologia Plantarum (under review 2017)
  • Peterson, R.B., Schultes, N.P.,  McHale, N.A., Zelitch, I. (2016) Evidence for a role for NAD(P)H dehydrogenase in concentration of CO2 in the bundle sheath cell of Zea mays. Plant Physiol. 171: 125-138. (PDF)
  • Li, D.W., Schultes, N.P., Vossbrinck, C. (2016) Olpitrichum sphaerospora Matsush., a new record in the USA and its phylogenetic position. Mycotaxon 131: 123-133.
  • Rapp, M., Schein, J., Hunt, K.A., Nalam, V., Mourad, G.S., Schultes, N.P. (2015) The solute specificity profiles of nucleobase cation symporter 1 (NCS1) from Zea mays and Setaria viridis illustrate functional flexibility. Protoplasma 253: 611-623. (PDF)
  • Peterson, R.B., Schultes, N.P. McHale, N.A., Zelitch, I. Evidence for a role for NAD(P)H dehydrogenase in concentration of CO2 in the bundle sheath cell of Zea mays. Plant Physiol. under review 2016 (PDF)
  • Li, D.W., Schultes, N.P., Vossbrinck, C. Olpitrichum sphaerospora Matsush., a new record in the USA and its phylogenetic position. Mycotaxon 131: 123-133. (PDF)
  • Rapp, M., Schein, J., Hunt, K.A., Nalam, V., Mourad, G.S., Schultes, N.P. (2015) The solute specificity profiles of nucleobase cation symporter 1 (NCS1) from Zea mays and Setaria viridis illustrate functional flexibility. Protoplasma 253: 611-623.
  • Peterson RP and Schultes NP (2014) Light-harvesting complex B7 shifts the irradiance response of photosynthetic light-harvesting regulation in leaves of Arabidopsis thaliana. J. Plant Physiol. 171:311-318. (PDF)
  • Peterson RP, Eichelmann H, Oja V, Laisk A, Talts E, Schultes NP (2013) Functional Aspects of Silencing and Transient Expression of PsbS in Nicotiana benthamiana. Am. J. Plant Sci. 4: 1521-1532. (PDF)

  • Schein J, Hunt KA, Minton J, Schultes NP, Mourad GS (2013) The nucleobase cation symporter 1 from Chlamydomonas reinhardtii and the evolutionary distant Arabidopsis thaliana  share function and establish a plant-specific solute transport profile. Plant Physiol. & Biochem. 70: 52-60. (PDF)

  • Mourad G S, Tippmann-Crosby J, Hunt KA, Gicheru Y, Bade K, Mansfield TA, Schultes NP (2012) Genetic and molecular characterization reveals a unique nucleobase cation symporter 1 in Arabidopsis. Fed. Euro. Biol. Soc. Lett. 586: 1370-1378. (PDF)

  • Mansfield TA, Schultes NP, Mourad GS (2009) AtAzg1 and AtAzg2 comprise a novel family of purine transporters in Arabidopsis. Fed. Euro. Biol. Soc. Lett. 583: 481-486.  (PDF)

  • Zelitch I, Schultes NP, Peterson RB, Brown P, Brutnell TP (2009) High glycolate oxidase activity is required for survival of maize in normal air.  Plant Physiology 149: 195-204. (PDF)

  • Schultes NP and Peterson RB (2007) Phylogeny-directed structural analysis of the Arabidopsis PsbS protein. Biochem. Biophy. Res. Comm. 335: 464-470. (PDF)

  • Mourad G S, Snook B M, Prabhakar JT, Mansfield TA, Schultes NP (2006) A fluoroorotic acid-resistant mutant of Arabidopsis defective in the uptake of uracil. J. Exp. Botany 57:3563-3573. (PDF)

  • Aylor DE, Schultes NP, Shields EJ (2003) An aerobiological framework for assessing cross-pollination in maize. Agric. For. Meteorol. 119: 111-129. (PDF)

  • White J C, Wang X, Gent MPN, Wagner LT, Iannucci-Berger W, Eitzer BD, Schultes NP, Arienzo M, Incorvia Mattina M-J (2003) Subspecies-level Variation in Phytoextraction of Weathered p,p’-DDE by Cucurbita pepo. Environmental Science & Technology 37: 4368-4373. (PDF)

  • Qi L and Schultes NP (2002) Arabidopsis thaliana locus At5g62890, a nucleobase-ascorbate transporter family member, is preferentially expressed in carpel transmitting tract and tapetal cells. Plant Science 163: 233-240. (PDF)

  • Argyrou E, Sophianopoulou V, Schultes N, Diallinas G (2001) Functional characterization of a maize purine transporter by expression in Aspergillus nidulans. Plant Cell 13: 953-964. (PDF)

  • Schultes NP, Sawers, RJH, Brutnell TP, Krueger RW (2000) Maize high chlorophyll fluorescent 60 mutation is caused by an Ac disruption of the gene encoding the chloroplast ribosomal small subunit protein 17. Plant Journal 21: 317–328. (PDF)

  • Timmermans M, Schultes NP, Jankovsky J, Nelson T (1998) Leafbladeless1 is required for dorsoventrality of lateral organs in maize. Development 125: 2813-2823. (PDF)

  • Timmermans M, Schultes NP, Martienssen R, Nelson T (1997) Leafbladeless1 is allelic to raggedseedling1 and is required for dorsal cell identity. Maize Genet. Coop. News Lett. 71:66.

  • Schultes NP Cloning corn genes today for future crop improvements. Frontiers of Plant Science (Spr 1996)

  • Schultes NP, Brutnell TP, Allen A, Dellaporta SL, Nelson T, Chen J. (1996) Leaf permease1 gene of maize is required for chloroplast development. Plant Cell 8: 463-475. (PDF)

  • Schultes NP, Zelitch I, McGonigle B, Nelson T (1994) The primary leaf catalase gene from Nicotiana tabacum and Nicotiana sylvestris.  Plant Physiology 106: 399-400. (PDF)




Content Last Modified on 6/30/2017 12:08:20 PM