Reproducibility of biological data is a significant problem in research today. One potential contributor to this, which has received little attention, is the over complication of enzyme kinetic inhibition models. The over complication of inhibitory models stems from the common use of the inhibitory term (1 + [I]/Ki), an equilibrium binding term that does not distinguish between inhibitor binding and inhibitory effect. Since its initial appearance in the literature, around a century ago, the perceived mechanistic methods used in its production have spurred countless inhibitory equations. These equations are overly complex and are seldom compared to each other, which has destroyed their usefulness resulting in the proliferation and regulatory acceptance of simpler models such as IC50s for drug characterization. However, empirical analysis of inhibitory data recognizing the clear distinctions between inhibitor binding and inhibitory effect can produce simple logical inhibition models. In contrast to the common divergent practice of generating new inhibitory models for every inhibitory situation that presents itself. The empirical approach to inhibition modeling presented here is broadly applicable allowing easy comparison and rational analysis of drug interactions. To demonstrate this, a simple kinetic model of DAPT, a compound that both activates and inhibits γ-secretase is examined using excel. The empirical kinetic method described here provides an improved way of probing disease mechanisms, expanding the investigation of possible therapeutic interventions.
References
[1]
Becker RE, Greig NH, Giacobini E, Schneider LS, Ferrucci L. 2014. A new roadmap for drug development for Alzheimer’s disease. Nature Reviews Drug Discovery 13:156-158
[2]
Bernett MJ, Blaber SI, Scarisbrick IA, Dhanarajan P, Thompson SM, Blaber M. 2002. Crystal structure and biochemical characterization of human kallikrein 6 reveals that a trypsin-like kallikrein is expressed in the central nervous system. The Journal of Biological Chemistry 277:24562-24570
[3]
Burnham KP, Anderson DR. 2002. Model selection and multimodel inference: a practical Q3 information-theoretic approach. New York, Inc: Springer-Verlag.
[4]
Burton CR, Meredith JE, Barten DM, Goldstein ME, Krause CM, Kieras CJ, Sisk L, Iben LG, Polson C, Thompson MW, Lin XA, Corsa J, Fiedler T, Pierdomenico M, Cao Y, Roach AH, Cantone JL, Ford MJ, Drexler DM, Olson RE, Yang MG, Bergstrom CP, McElhone KE, Bronson JJ, Macor JE, Blat Y, Grafstrom RH, Stern AM, Seiffert DA, Zaczek R, Albright CF, Toyn JH. 2008. The amyloid-beta rise and gamma-secretase inhibitor potency depend on the level of substrate expression. The Journal of Biological Chemistry 283:22992-23003
[5]
Dodgson KS, Spencer B, Williams K. 1956. Examples of anti-competitive inhibition. Nature 177:432-433
[6]
Dovey HF, John V, Anderson JP, Chen LZ, de Saint Andrieu P, Fang LY, Freedman SB, Folmer B, Goldbach E, Holsztynska EJ, Hu KL, Johnson-Wood KL, Kennedy SL, Kholodenko D, Knops JE, Latimer LH, Lee M, Liao Z, Lieberburg IM, Motter RN, Mutter LC, Nietz J, Quinn KP, Sacchi KL, Seubert PA, Shopp GM, Thorsett ED, Tung JS, Wu J, Yang S, Yin CT, Schenk DB, May PC, Altstiel LD, Bender MH, Boggs LN, Britton TC, Clemens JC, Czilli DL, Dieckman-McGinty DK, Droste JJ, Fuson KS, Gitter BD, Hyslop PA, Johnstone EM, Li WY, Little SP, Mabry TE, Miller FD, Audia JE. 2001. Functional gamma-secretase inhibitors reduce beta-amyloid peptide levels in brain. Journal of Neurochemistry 76:173-181
[7]
Faraway JJ. 2004. Linear models with R. Boca Raton, FL: Chapman & Hall/CRC.
[8]
Fontes R, Ribeiro JM, Sillero A. 2000. Inhibition and activation of enzymes. The effect of a modifier on the reaction rate and on kinetic parameters. Acta Biochimica Polonica 47:233-257
[9]
Kemmer G, Keller S. 2010. Nonlinear least-squares data fitting in Excel spreadsheets. Nature Protocols 5:267-281
[10]
McElroy WD. 1947. The mechanism of inhibition of cellular activity by narcotics. The Quarterly Review of Biology 22:25-58
[11]
Mitani Y, Yarimizu J, Saita K, Uchino H, Akashiba H, Shitaka Y, Ni K, Matsuoka N. 2012. Differential effects between γ-secretase inhibitors and modulators on cognitive function in amyloid precursor protein-transgenic and nontransgenic mice. The Journal of Neuroscience 32:2037-2050
[12]
Schneider LS, Mangialasche F, Andreasen N, Feldman H, Giacobini E, Jones R, Mantua V, Mecocci P, Pani L, Winblad B, Kivipelto M. 2014. Clinical trials and late-stage drug development for Alzheimer’s disease: an appraisal from 1984 to 2014. Journal of Internal Medicine 275:251-83
[13]
Segel IH. 1975. Enzyme kinetics: behavior and analysis of rapid equilibrium and steady-state enzyme systems. New York: John Wiley & Sons.
[14]
Sousa MO, Miranda TL, Costa EB, Bittar ER, Santoro MM, Figueiredo AF. 2001. Linear competitive inhibition of human tissue kallikrein by 4-aminobenzamidine and benzamidine and linear mixed inhibition by 4-nitroaniline and aniline. Brazilian Journal Of Medical and Biological Research 34:35-44
[15]
Spitzer M, Wildenhain J, Rappsilber J, Tyers M. 2014. BoxPlotR: a web tool for generation of box plots. Nature Methods 11:121-122
[16]
Svedruzic ZM, Popovic K, Sendula-Jengic V. 2013. Modulators of gamma-secretase activity can facilitate the toxic side-effects and pathogenesis of Alzheimer’s disease. PLoS ONE 8:e50759
[17]
Wadman M. 2013. NIH mulls rules for validating key results. Nature F500:14-16
[18]
Walsh R. 2012. Alternative perspectives of enzyme kinetic modeling. In: Ekinci D, ed. Medicinal chemistry and drug design. InTech. 357-372
[19]
Walsh R, Martin E, Darvesh S. 2011. Limitations of conventional inhibitor classifications. Integrative Biology 3:1197-1201
[20]
Yoshino M. 1987. A graphical method for determining inhibition parameters for partial and complete inhibitors. Biochemical Journal 248:815-820
