Dr. Karl Kramer - Collaborator Biological Research Unit (BRU) Grain Marketing & Production Research Center (GMPRC)   1515 College Ave. Manhattan, KS 66502 Voice: (785) 776-2711 Fax: (785) 537-5584 karl.kramer@ars.usda.gov

Research Interests

Dr. Kramer is a biochemist internationally recognized for his comprehensive research program investigating insect cuticle structure, chitin metabolism, tanning chemistry, neuropeptides, molting, digestion, and the use of biopesticides and insect growth regulators for insect pest control. Results of his research have had major impact in insect molecular science and also preharvest and postharvest insect pest management programs including the development of insect growth regulators, biopesticides, transgenic plants and biological control agents by the agricultural biotechnology industry. Until his retirement in 2003, he was a research chemist at the ARS-USDA Grain Marketing and Production Research Center (GMPRC) and Adjunct Professor of Biochemistry at Kansas State University (KSU) in Manhattan, Kansas. Presently, he is a collaborator at GMPRC and Adjunct Professor Emeritus of Biochemistry at KSU.

Specific research projects include:

1. Insect cuticle structure and tanning metabolism. The insect exoskeleton or cuticle serves many functions including protection, locomotion, respiration and communication, and therefore must have very diverse mechanical and chemical properties to provide for optimization of each function. Kramer and his collaborators have elucidated many of the metabolic reactions responsible for the stabilization (sclerotization and biomineralization) and pigmentation of cuticular exoskeletons, including the quinone-mediated cross-linking of structural proteins. They characterized several regulatory enzymes and reaction mechanisms critical for cuticle tanning, and also delineated several of the hormonal mechanisms that help to regulate cuticle morphogenesis and recycling. Kramer's research group was the first to apply the noninvasive spectroscopic technique of solid state nuclear magnetic resonance for the compositional and structural analyses of many types of insect sclerotized structures including cuticles, egg cases, and cocoons. The results of these studies provided new knowledge about insect support structures and their mechanisms of stabilization and regulation, and also yielded new insights into how insects have evolved extracellular components with different properties, which contributed to their great diversity and success in nature. The information also is useful to scientists involved in the development of biotechnological methods of insect pest control, which are designed to disrupt insect cuticle physiology.

2. Insect chitin metabolism. Chitin is the major structural polysaccharide found in the exoskeleton and gut lining of insects. Kramer and his collaborators determined the properties of several chitinolytic enzymes, elucidated the mechanism and hormonal regulation of cuticular and gut chitin digestion by these enzymes, cloned several chitin synthesizing and chitinolytic enzyme genes, and transformed several plants and an entomopathogen with an insect chitinase gene. This effort has not only yielded knowledge about molting and digestive biochemistry and physiology but also demonstrated that expression of an insect chitinase gene in transgenic plants and microbial entomopathogens enhances host plant resistance and increases the efficacy of biological control agents for insect and fungal pests. A patent for the use of insect chitinase as a biocide was issued in 1999 and development of the this transgene as a defense gene in wheat, corn, rice, sorghum and other plants is ongoing. Kramer's research group also showed that chitin inhibitors such as diflubenzuron and other types of insect growth regulators are effective as stored product protectants against insect pests. These efforts helped to establish that chitinolytic enzymes and insect growth regulators that inhibit cuticle and gut physiology can be used to exploit chitin metabolism for insect control purposes.

3. Development of Bacillus thuringiensis toxins as biopesticides in transgenic plants. Proteinaceous insecticides from the bacterium Bacillus thuringiensis (Bt) disrupt insect gut physiology and are now being expressed in transgenic plants for insect control. Kramer was part of a team that determined the chemical and functional properties of the protoxins from this entomocidal bacterium and also helped to characterize the midgut proteinases from Bt-susceptible and Bt-resistant strains of insects, which process the protoxins to toxins. The team discovered a novel mechanism of insect resistance to Bt, which involves a change in gut proteinase activity and results in a diminished ability of the resistant insects to activate the protoxins. These studies provided pioneering knowledge about the structure, toxicological action, and insect resistance mechanisms of this ecologically safe microbial insecticide, and included the first evidence of multiple mechanisms of insect resistance to microbial insecticides. This information is important for the development of effective strategies using both Bt-based and other biopesticides in transgenic plants, and also for preventing insect adaptation to biopesticides used in pest management programs.

4. Development of chicken avidin as a biopesticide in transgenic corn. New biopesticides are needed for use in transgenic plants to enhance resistance to insects and pathogens. Kramer's research group has developed an insect gut-targeted biopesticide, the protein avidin from chicken, which causes a vitamin (biotin) deficiency in insects and ultimately leads to stunted growth and mortality. They demonstrated that avidin is an insecticidal and/or insect growth-inhibiting dietary protein for many species. In collaborative research with two biotechnology companies (ProdiGene/Pioneer), the gene for avidin was transferred to corn and the transgenic seed obtained was shown to be resistant to both internal and external grain-feeding insect pests. Avidin is a unique biopesticide whose effects can be completely reversed by supplementation with an antidote, biotin, or completely inactivated by heat treatment. Preliminary experiments showed that avidin corn was not toxic to mice. Development of this transgene as a defense gene in corn, wheat, rice, sorghum and other plants is ongoing. Potential applications of avidin grains include their use for resistance to field crop pests in addition to post-harvest pests. Alternatively, avidin grains may be used directly as insecticides as well as in bait programs for a variety of insect pests. See Avidin: An Egg-Citing Insecticidal Protein in Corn (also available in pdf).

5. Development of digestive enzyme inhibitors as potential biopesticides in transgenic plants. Amylases and proteinases in the insect digestive system are critical enzymes required for normal growth and development. Genes for amylase and proteinase inhibitors can be used to improve the resistance of cereals to storage pests via host plant resistance genetic engineering or traditional breeding programs. Kramer and his collaborators have characterized some of these digestive enzymes from stored product beetles, and several proteinaceous inhibitors from wheat, rice, corn, and beans have been isolated and characterized. Many of the inhibitors were selective for insect digestive enzymes and suppressed the growth of insects when administered in semi-artificial diets. These results provided knowledge at the molecular level about a natural defense mechanism used by plants to deter insect predation and also demonstrated that some of the amylase and proteinase inhibitors can be utilized as biopesticides in transgenic plants.

6. Development of insect growth regulators as grain protectants. Kramer's research group demonstrated that several juvenile hormone mimics, cuticle inhibitors, and other materials are effective as stored product protectants and also delineated the metabolism of juvenile hormone in several species of stored product insects. Two commercially available compounds, methoprene and fenoxycarb, were found to be very active towards stored product beetles and moths. Some of these data were utilized by Zoecon Corporation in 1988 and Maag Agrochemical Corporation in 1989 to support registrations of those compounds for stored product insect pest control. Kramer also helped to design and evaluate another compound, 5-([5-13-butyl-3-methyloxiranyl)-3-methyl-2 pentenyl] oxy)-2-ethylpyridine, that was one of the most active insect growth regulators ever produced. Kramer and his collaborators also evaluated projuvenoid derivatives of fenoxycarb that are metabolically activated by target insects. He and his colleagues also revealed how juvenile hormone titer is regulated during insect development by the interplay of specific hormone carrier proteins and both synthetic and hydrolytic enzymes. This research helped to establish that insect growth regulators of the juvenile hormone-type, cuticle inhibitor-type, and several natural products can be used to control stored product insect pests.

Project Information

Protection of Stored Corn From Insect Pests, Using a Two-Component Biological Control Method Consisting of a Hymenopteran Parasitoid, and Transgenic Avidin Corn Powder

The combination treatment of avidin corn powder plus the release of parasitoid wasps was superior to either treatment alone when tested against mixed populations of the internal feeder, S. zeamais, and the external feeders, T. castaneum and C. ferrugineus. Normally, multiple beetle species that are both external and internal feeders are found in stored grain. While avidin corn powder is fairly effective as an insecticide against the external feeders, it is not very effective against the internal feeders. By using the combination treatment, stored grain managers would be assured of protection from both internal and external feeders.
     Poster (PDF: 480KB)     Research Paper (PDF)

Agricultural Research Service (ARS) News

Magazine Articles

Avidin: An Egg-Citing Insecticidal Protein in Corn

News, Miscellaneous

Scientists Have Some "Egg-citing" News

How the Beetle Gets Its Shell

New Plants Put a Hurt on Pests

Selected Publications

Some reprints are available in PDF format. Click icon to View, Right-Click to Save. (Download Adobe Acrobat Reader if necessary).
If a PDF reprint is NOT available, click the 'Add' to the left of the item in the following list. This will add the reprint to a virtual basket. To request the selected reprints, follow the 'Check Out' link at the top of the publication listing. You may add reprints to the basket from anywhere on the BRU website, but you must remain on the website (and show activity every 20 minutes or so) for the basket to save your selections. Once you have selected all reprints you wish to request, click the link in the menubar of the header of the site that says 'X Publication(s)'. This will lead you through the process of checking out. It will collect and verify all information needed to get the proper materials to you. Selected reprints will be sent by mail. Please allow several weeks for delivery. Per-session cookies must be enabled for this function to work.

	Publications	Check Out
PDF	Arakane, Y., C.A. Specht, K.J. Kramer, S. Muthukrishnan, and R.W. Beeman. 2008. Chitin synthases are required for survival, fecundity and egg hatch in the red flour beetle, Tribolium castaneum. Insect Biochem. Mol. Biol. 38: 959-962.
PDF	Dixit, R., Y. Arakane, C.A. Specht, C. Richard, K.J. Kramer, R.W. Beeman, and S. Muthukrishnan. 2008. Domain organization and phylogenetic analysis of proteins from the chitin deacetylase gene family of Tribolium castaneum and three other species of insects. Insect Biochem. Mol. Biol. 38: 440-451.
	Furusawa, T., R. Rakwal, H.W. Nam, M. Hirano, J. Shibato, Y.S. Kim, Y. Ogawa, Y. Yoshida, K.J. Kramer, Y. Kouzuma, G.K. Agrawal, and M. Yonekura. 2008. Systematic investigation of the hemolymph proteome of Manduca sexta at the fifth instar larvae stage using one- and two-dimensional proteomics platforms. J. Proteome Res. 7: 938-959.
PDF	Hogenkamp, D.G., Y. Arakane, K.J. Kramer, S. Muthukrishnan, and R.W. Beeman. 2008. Characterization and expression of the B-N-Acetylhexosaminidase gene family of Tribolium castaneum. Insect Biochem. Mol. Biol. 38: 478-489.
PDF	Krizkova, S., V. Hrdinova, V. Adam, E.P.J. Burgess, K.J. Kramer, M. Masarik, and R. Kizek. 2008. Chip-based CE for avidin determination in transgenic tobacco and its comparison with square-wave voltammetry and standard gel electrophoresis. Chromatographia Supplement 67: S75-S81.
PDF	Tribolium Sequencing Consortium (includes R.W. Beeman, M.D. Lorenzen, B. Oppert, J. Lord, K. Kramer, Y. Arakane). 2008. The genome of the model beetle and pest Tribolium castaneum. Nature 452: 949-955.
PDF	Zhu, Q., Y. Arakane, K.J. Kramer, R.W. Beeman, and S. Muthukrishnan. 2008. Domain organization and phylogenetic analysis of the chitinase-like family of proteins in three species of insects. Insect Biochem. Mol. Biol. 38: 452-466.
PDF	Zhu, Q., Y. Arakane, R.W. Beeman, K.J. Kramer, and S. Muthukrishnan. 2008. Functional specialization among insect chitinase family genes revealed by RNA interference. Proc. Natl. Acad. Sci. USA 105: 6650-6655.
PDF	Zhu, Q., Y. Arakane, R.W. Beeman, K.J. Kramer, and S. Muthukrishnan. 2008. Characterization of recombinant chitinase-like proteins of Drosophila melanogaster and Tribolium castaneum. Insect Biochem. Mol. Biol. 38:467-477.
PDF	Miyaji, T., Y. Kouzuma, J. Yaguchi, R. Matsumoto, M.R. Kanost, K.J. Kramer, and M. Yonekura. 2007. Purification of a cysteine protease inhibitor from larval hemolymph of the tobacco hornworm (Manduca sexta) and functional expression of the recombinant protein. Insect Biochem. Mol. Biol. 37: 960-968.
	Petrlová, J., S. Krížková, V. Šupálková, M. Masarík, V. Adam, L. Havel, K.J. Kramer, and R. Kizek. 2007. The determination of avidin in genetically modified maize by voltammetric techniques. Plant Soil Environ. 53: 345-349.
	Vitacek, J., J. Petrlova, J. Petrek, V. Adam, L. Havel, K.J. Kramer, and R. Kizek. 2007. Application of fluorometric analysis of plant esterases to study of programmed cell death and effects of cadmium (II) ions. Biologia Plantarum 51: 551-555.
PDF	Vitecek, J., J. Petrlova, V. Adam, L. Havel, K.J. Kramer, P. Babula, and R. Kizek. 2007. A fluorimetric sensor for detection of one living cell. Sensors 7: 222-238.
	Eichler, C., J. Lomakin, Y. Arakane, K.J. Kramer, M.R. Kanost, and S.H. Gehrke. 2006. Insect cuticle as a biomimetic material. In: Proceedings AlChE Annual Meeting, October 30-November 4, 2005. American Institute of Chemical Engineers, New York, N.Y., pp 4309-4313.
PDF	Flinn, P.W., K.J. Kramer, J.E. Throne, and T.D. Morgan. 2006. Protection of stored maize from insect pests using a two-component biological control method consisting of a hymenopteran parasitoid, Theocolax elegans, and transgenic avidin maize powder. J. Stored Prod. Res. 42: 218-225.
PDF	Matsumiya, M., Y. Arakane, A. Haga, S. Muthukrishnan, and K.J. Kramer. 2006. Substrate specificity of chitinases from two species of fish, greenling, Hexagrammos otakii, and common mackerel, Scomber japonicus, and the insect, tobacco hornworm, Manduca sexta. Biosci. Biotechnol. Biochem. 70: 971-979.
PDF	Suderman, R.J., N.T. Dittmer, M.R. Kanost, and K.J. Kramer. 2006. Model reactions for insect cuticle sclerotization: Cross-linking of recombinant cuticular proteins upon their laccase-catalyzed oxidative conjugation with catechols. Insect Biochem. Mol. Biol. 36: 353-365.
PDF	Arakane, Y., S. Muthukrishnan, K.J. Kramer, C.A. Specht, Y. Tomoyasu, M.D. Lorenzen, M. Kanost, and R.W. Beeman. 2005. The Tribolium chitin synthase genes TcCHS1 and TcCHS2 are specialized for synthesis of epidermal cuticle and midgut peritrophic matrix. Insect Mol. Biol. 14: 453-463.
PDF	Arakane, Y., S. Muthukrishnan, R.W. Beeman, M.R. Kanost, and K.J. Kramer. 2005. Laccase 2 is the phenoloxidase gene required for beetle cuticle tanning. Proc. Natl. Acad. Sci. USA 102: 11337-11342.
PDF	Bolognesi, R., Y. Arakane, S. Muthukrishnan, K.J. Kramer, W.R. Terra, and C. Ferreira. 2005. Sequences of cDNAs and expression of genes encoding chitin synthase and chitinase in the midgut of Spodoptera frugiperda. Insect Biochem. Mol. Biol. 35: 1249-1259.
PDF	Hogenkamp, D.G., Y. Arakane, L. Zimoch, H. Merzendorfer, K.J. Kramer, R.W. Beeman, M.R. Kanost, C.A. Specht, and S. Muthukrishnan. 2005. Chitin synthase genes in Manduca sexta: characterization of a gut-specific transcript and differential tissue expression of alternatively spliced mRNAs during development. Insect Biochem. Mol. Biol. 35: 529-540.
PDF	Kizek, R., M. Masarik, K.J. Kramer, D. Potesil, M. Bailey, J.A. Howard, B. Klejdus, R. Mikelova, V. Adam, L. Trnkova, and F. Jelen. 2005. An analysis of avidin, biotin and their interaction at attomole levels by voltammetric and chromatographic techniques. Anal. Bioanal. Chem. 381: 1167-1178.
PDF	Oppert, B., T.D. Morgan, K. Hartzer, and K.J. Kramer. 2005. Compensatory proteolytic responses to dietary proteinase inhibitors in the red flour beetle, Tribolium castaneum (Coleoptera: Tenebrionidae). Comp. Biochem. Physiol. Part C 140: 53-58.
PDF	Petrek, J., J. Vitecek, H. Vlasinova, R. Kizek, K.J. Kramer, V. Adam, B. Klejdus, and L. Havel. 2005. Application of computer imaging, stripping voltammetry and mass spectrometry to study the effect of lead (Pb-EDTA) on the growth and viability of early somatic embryos of Norway spruce (Picea abies/L./Karst.). Anal. Bioanal. Chem. 383: 576-586.
PDF	Yoza, K., T. Imamura, K.J. Kramer, T.D. Morgan, S. Nakamura, K. Akiyama, S. Kawasaki, F. Takaiwa, and K. Ohtsubo. 2005. Avidin expressed in transgenic rice confers resistance to the stored-product insect pests Tribolium confusum and Sitotroga cerealella. Biosci. Biotechnol. Biochem. 69: 966-971.
PDF	Zimoch, L., D.G. Hogenkamp, K.J. Kramer, S. Muthukrishnan, and H. Merzendorfer. 2005. Regulation of chitin synthesis in the larval midgut of Manduca sexta. Insect Biochem. Mol. Biol. 35: 515-527.
PDF	Arakane, Y., D.G. Hogenkamp, Y.C. Zhu, K.J. Kramer, C.A. Specht, R.W. Beeman, M.R. Kanost, and S. Muthukrishnan. 2004. Characterization of two chitin synthase genes of the red flour beetle, Tribolium castaneum, and alternate exon usage in one of the genes during development. Insect Biochem. Mol. Biol. 34: 291-304.
PDF	Dittmer, N.T., R.J. Suderman, H. Jiang, Y.C. Zhu, M.J. Gorman, K.J. Kramer, and M.R. Kanost. 2004. Characterization of cDNAs encoding putative laccase-like multicopper oxidases and developmental expression in the tobacco hornworm, Manduca sexta, and the malaria mosquito, Anopheles gambiae. Insect Biochem. Mol. Biol. 34: 29-41.
	Kramer, K.J. 2004. Avidin: An egg-citing insecticidal protein in transgenic corn, pp. 119-130. In: G.H. Liang and D.Z. Skinner (Eds), Genetically Modified Crops: Their Development, Uses, and Risks. Haworth Press, Inc., Binghamton, N.Y.
PDF	Arakane, Y., Q. Zhu, M. Matsumiya, S. Muthukrishnan, and K. J. Kramer. 2003. Properties of catalytic, linker and chitin-binding domains of insect chitinase. Insect Biochem. Mol. Biol. 33: 631-648.
Show All Publications