Natural variations of lithium isotopes in a mammalian model.

Despite lithium's extensive clinical applications, the cellular and molecular basis for the therapeutic effects remains to be elucidated. The large difference in mass between the two lithium isotopes ((6)Li and (7)Li) has prompted biochemists to explore the metabolism of Li by using pure (6)Li and (7)Li labeled drugs. However, experiments were carried out at very high Li concentrations, which did not reflect natural conditions. In the present study, we consider, for the first time, the natural variations of the (7)Li/(6)Li ratio in the organs and body fluids of an animal model, sheep. Each organ seems to be characterized by a specific Li isotope composition. So far, the range of the (7)Li/(6)Li ratio in the sheep body, expressed as δ permil variations relative to the L-SVEC standard (δ(7)Li), is about 40‰, between muscles (∼40‰) and kidney (∼0‰). Relative to a dietary δ(7)Li value of ∼+17‰, serum, red blood cells, muscle, liver, brain and kidney have a (7)Li enrichment of -12‰, -14‰, +22‰, +5‰, -3‰ and -15‰, respectively. The Li isotope composition is likely to be fractionated during intestinal absorption, with a greater absorption of (6)Li relative to (7)Li. According to previous conclusions obtained with (6)Li and (7)Li labeled chemicals, (6)Li appears to diffuse into erythrocytes faster than does (7)Li. However, this does not hold for myocytes and hepatocytes, because these two tissues have a higher δ(7)Li level than serum. Purely diffusive isotopic fractionation would leave all organs (7)Li-depleted relative to the serum, which is not the case, suggesting that active, molecule-specific, isotopic fractionation occurs in the body. Our preliminary results suggest that natural Li isotope variations can shed light on its regulation in the body, being active or passive.

[1]  F. Albarède,et al.  Contrasting Cu, Fe, and Zn isotopic patterns in organs and body fluids of mice and sheep, with emphasis on cellular fractionation. , 2013, Metallomics : integrated biometal science.

[2]  V. Balter,et al.  Iron, copper and zinc isotopic fractionation up mammal trophic chains , 2013 .

[3]  R. Millot,et al.  Experimental determination of the role of diffusion on Li isotope fractionation during basaltic glass weathering , 2011 .

[4]  Carmay Lim,et al.  Competition between Li+ and Mg2+ in metalloproteins. Implications for lithium therapy. , 2011, Journal of the American Chemical Society.

[5]  F. Albarède,et al.  Bodily variability of zinc natural isotope abundances in sheep. , 2010, Rapid communications in mass spectrometry : RCM.

[6]  S. Gíslason,et al.  The relationship between riverine lithium isotope composition and silicate weathering rates in Iceland , 2009 .

[7]  T. Duka,et al.  α‐Synuclein contributes to GSK‐3β‐catalyzed Tau phosphorylation in Parkinson's disease models , 2009, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[8]  C. Scrimgeour,et al.  Effect of age and food intake on dietary carbon turnover recorded in sheep wool. , 2008, Rapid communications in mass spectrometry : RCM.

[9]  H. Möller,et al.  What is the optimal serum lithium level in the long-term treatment of bipolar disorder--a review? , 2008, Bipolar disorders.

[10]  Gabriele Siciliano,et al.  Lithium delays progression of amyotrophic lateral sclerosis , 2008, Proceedings of the National Academy of Sciences.

[11]  D. Rubinsztein,et al.  A rational mechanism for combination treatment of Huntington's disease using lithium and rapamycin. , 2008, Human molecular genetics.

[12]  R. Millot,et al.  Three Secondary Reference Materials for Lithium Isotope Measurements: Li7‐N, Li6‐N and LiCl‐N Solutions , 2007 .

[13]  C. Guerrot,et al.  Accurate and High‐Precision Measurement of Lithium Isotopes in Two Reference Materials by MC‐ICP‐MS , 2004 .

[14]  G. Schrauzer Lithium: Occurrence, Dietary Intakes, Nutritional Essentiality , 2002, Journal of the American College of Nutrition.

[15]  M. Palmer,et al.  The lithium isotope composition of international rock standards , 2000 .

[16]  D. DePaolo,et al.  Calcium isotope fractionation between soft and mineralized tissues as a monitor of calcium use in vertebrates. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[17]  Guang Chen,et al.  Lithium at 50: have the neuroprotective effects of this unique cation been overlooked? , 1999, Biological Psychiatry.

[18]  E. Smeraldi,et al.  Effects of Lithium on cAMP-Dependent Protein Kinase in Rat Brain , 1998, Neuropsychopharmacology.

[19]  J. Ávila,et al.  Lithium inhibits Alzheimer's disease‐like tau protein phosphorylation in neurons , 1997, FEBS letters.

[20]  D. Melton,et al.  A molecular mechanism for the effect of lithium on development. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[21]  E. Teisberg,et al.  The role of biomedical research in health care reform. , 1994, Science.

[22]  Michael J. Berridge,et al.  Inositol phosphates and cell signalling , 1989, Nature.

[23]  L. Munsell,et al.  Differential Uptake of Lithium Isotopes by Rat Cerebral Cortex and Its Effect on Inositol Phosphate Metabolism , 1984, Journal of neurochemistry.

[24]  G. Alexander,et al.  Stable isotopes of lithium: in vivo differential distribution between plasma and cerebrospinal fluid. , 1982, Biological psychiatry.

[25]  P. Mormède,et al.  Pharmacokinetics of lithium in sheep. , 1980 .

[26]  G. Alexander,et al.  Differential lethality of lithium isotopes in mice. , 1980, Biological psychiatry.

[27]  J. Kocsis,et al.  Characteristics of the uptake of lithium isotopes into erythrocytes. , 1979, Biological psychiatry.

[28]  J. Cade Lithium salts in the treatment of psychotic excitement. , 1949, The Medical journal of Australia.