Summary
Photon emission from unicellular and multicellular organisms has been a subject of study for many decennia. In contrast to the well-known phenomenon of bioluminescence originating in luciferin-luciferase reactions, low intensity emission in the visible region of the electromagnetic spectrum has been found in almost every species studied so far. At present, the nomenclature of this phenomenon has not crystallized and it is referred to by a variety of names, such as mitogenetic radiation29, dark luminescence7, low-level chemiluminescence20, 36, and biophotons57. Particular attention has been focussed on the relationship between photon emission and the regulation of various aspects of cellular metabolism, although in many cases quantitative data are still lacking. Throughout the history of this field of research the question of a functional biological role of the low intensity emission has been repeatedly raised; this is reflected, for instance, in the heterogeneity of the terms used to describe it. The discussion concerns the possible participation of photons of low intensity in intra- and intercellular communication. This paper reviews literature on the metabolic regulation of low intensity emission, as well as the regulation of photon emission initiated by external light. Furthermore, recent data are discussed with respect to a possible biocommunicative function of low intensity photon emission.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adey, W. R., Tissue interactions with nonionizing electromagnetic fields. Physiol. Rev.61 (1981) 435–514.
Allen, R. C., and Loose, L. D., Phagocytic activation of a luminol-dependent chemiluminescence in rabbit alveolar and peritoneal macrophages. Biochem. biophys. Res. Commun.69 (1976) 245–252.
Allen, R. C., Yevich, S. J., Orth, R. W., and Steele, R. H., The superoxide anion and singlet molecular oxygen: their role in the microbicidal activity of the polymorphonuclear leucocyte. Biochem. biophys. Res. Commun.60 (1974) 909–917.
Ames, B. N., Cathcart, R., Schwiers, E., and Hochstein, P., Uric acid provides an antioxidant defense in humans against oxidant and radical-caused aging and cancer: A hypothesis. Proc. natl Acad. Sci. USA78 (1981) 6858–6862.
Artem'ey, V. V., Goldobin, A. S., and Gus'kov, L. N., Recording the optical emission of a nerve. Biophysics12 (1967) 1278–1280.
Badwey, J. A., and Karnovsky, M. L., Active oxygen species and the functions of phagocytic leucocytes. A. Rev. Biochem.49 (1980) 695–726.
Barenboim, G. M., Domanskii, A. N., and Turoverov, K. K., Luminescence of Biopolymers and Cells. Plenum Press, New York/London 1969.
Barsacchi, R., Camici, P., Bottigli, U., Salvadori, P. A., Pelosi, G., Maiorino, M., and Ursini, F., Correlation between hydroperoxide-induced chemiluminescence of the heart and its function. Biochim. biophys. Acta762 (1983) 241–247.
Blokha, V. V., Kossova, G. V., Sizov, A. D., Fedin, V. A., Kozlov, Yu. P., Kol's, O. R., and Tarusov, B. N., Detection of the ultraweak glow of muscles on stimulation. Biophysics13 (1968) 1084–1085.
Boveris, A., Chance, B., Filipkowski, M., Nakase, Y., and Paul, K. G., Enhancement of the chemiluminescence of perfused rat liver and of isolated mitochondria and microsomes by hydroperoxides, in: Frontiers of Biological Energetics, Electron to Tissues, vol. 2, pp. 975–984. Eds A. Scarpa, P. L. Duutton and J. S. Leigh, Jr. Academic Press, New York 1978.
Boveris, A., Cadenas, E., and Chance, B., Ultraweak chemiluminescence: a sensitive assay for oxidative radical reactions. Fed. Proc.40 (1981) 195–198.
Boveris, A., Cadenas, E., Reiter, R., Filipkowski, M., Nakase, Y., and Chance, B., Organ chemiluminescence: Noninvasive assay for oxidative radical reactions. Proc. natl Acad. Sci. USA77 (1980) 347–351.
Boveris, A., Sanchez, R. A., Varsavsky, A. I., and Cadenas, E., Spontaneous chemiluminescence of soybean seed. FEBS Lett.113 (1980) 29–32.
Cadenas, E., Arad, I. D., Boveris, A., Fisher, A. B., and Chance, B., Partial spectral analysis of the hydroperoxide-induced chemiluminescence of the perfused lung. FEBS Lett.111 (1980) 413–418.
Cadenas, E., Boveris, A., and Chance, B., Low-level chemiluminescence of bovine heart submitochondrial particles. Biochem. J.186 (1980) 659–667.
Cadenas, E., Boveris, A., and Chance, B., Hydroperoxide-dependent chemiluminescence of submitochondrial particles and its relationship to superoxide anion and other oxygen radicals, in: Developments in Biochemistry, vol. 11A, pp. 92–103. Eds J. V. Bannister and H. A. O. Hill. Elsevier, North Holland, New York 1980.
Cadenas, E., Daniele, R. P., and Chance, B., Low level chemiluminescence of alveolar macrophages. FEBS Lett.123 (1981) 225–228.
Cadenas, E., and Sies, H., Low level chemiluminescence of liver microsomal fractions initiated by tert-butyl hydroperoxide. Relation to microsomal hemoproteins, oxygen dependence, and lipid peroxidation. Eur. J. Biochem.124 (1982) 349–356.
Cadenas, E., Varsavsky, A. I., Boveris, E., and Chance, B., Oxygenor organic hydroperoxide-induced chemiluminescence of brain and liver homogenates. Biochem. J.198 (1981) 645–654.
Cadenas, E., Wefers, H., and Sies, H., Low-level chemiluminescence of isolated hepatocytes. Eur. J. Biochem.119 (1981) 531–536.
Cheng, B., Williams, M., and Chance, B., Effects of glucose, anoxia, and adriamycin on the chemiluminescence of Ehrlich ascites cells. FEBS Lett.160 (1983) 169–172.
Chwirot, W. B., New indication of possible role of DNA in ultraweak photon emission from biological systems. Cytobios (1988) in press.
Chwirot, W. B., Dygala, R. S., and Chwirot, S., Quasi-monochromatic-light-induced photon emission from microsporocytes of larch shows oscillating decay behaviour predicted by the electromagnetic model of differentiation. Cytobios,47 (1986) 137–146.
Cilento, G., Electronic excitation in dark biological processes, in: Chemical and Biological Generation of Excited States, pp. 277–307. Eds W. Adam and G. Cilento. Academic Press, New York 1982.
Colli, L., Facchini, U., Guidotti, G., Dugnani Lonati, R., Arsenigo, M., and Sommariva, O., Further measurements on the bioluminescence of the seedlings. Experientia11 (1955) 479–481.
Dahlgren, C., Magnusson, K. E., Stendahl, O., and Sundquist, T., Modulation of polymorphonuclear leukocyte chemiluminescence response to the chemoattractant f-Met-Leu-Phe. Int. Archs Allergy appl. Immun.68 (1982) 79–83.
Galeotto, T., Bartoli, G. M., Bartoli, S., and Bertoli, E., Superoxide radicals and lipid peroxidation in tumor microsomal membranes, in: Developments in Biochemistry, vol. 11B, pp. 106–117. Eds W. H. Bannister and J. V. Bannister. Elsevier, North Holland, New York 1980.
Gorts, C. P. M., Effect of different carbon sources on the regulation of carbohydrate metabolism inSaccharomyces cerevisiae. Antonie van Leeuwenhoek, J. Microbiol. Serol.33 (1967) 451–463.
Gurwitsch, A. G., and Gurwitsch, L. D., Die Mitogenetische Strahlung. VEB Gustav Fischer Verlag, Jena 1959.
Halliwell, B., Production of superoxide, hydrogen peroxide and hydroxyl radicals by phagocytic cells: a cause of chronic inflammatory disease. Cell Biol. int. Rep.6 (1982) 529–542.
Halliwell, B., and Gutteridge, J. M. C., Oxygen toxicity, oxygen radicals, transition metals and disease. Biochem. J.219 (1984) 1–14.
Hamman, J. P., Gorby, D. R., and Seliger, H. H., A new type of biological chemiluminescence: The microsomal chemiluminescence of benzo-a-pyrene arises from the diol epoxide product of the 7,8-dihydrodiol. Biochem. biophys. Res. Commun.75 (1977) 793–798.
Henkart, M., Light-induced changes in the structure of pigmented granules inAplysia neurons. Science188 (1975) 155–157.
Inaba, H., Yamagishi, A., Takyu, C., Yoda, B., Goto, Y., Miyazawa, T., Kaneda, T., and Saeki, A., Development of an ultra-high sensitive photon counting system and its application to biomedical measurements. Optics Lasers Engineering3 (1982) 125–130.
Johston, R. B. Jr, Pabst, R. J., and Sasada, M., The release of superoxide anion by macrophages and its relationship to phagocytic microbicidal activity, in: Developments in Biochemistry, vol. 11B, pp. 211–221. Eds W. H. Bannister and J. V. Bannister. Elsevier, North Holland, New York 1980.
Kakinuma, K., Cadenas, E., Boveris, A., and Chance, B., Low level chemiluminescence of intact polymorphonuclear leukocytes. FEBS Lett.102 (1979) 38–42.
Kochel, B., Grabikowski, E., and Slawinski, J., Analysis of photon counting series of low level luminescence from wheat leaves at high temperatures. Int. Symposium on Photon Emission From Biological Systems (IS-86), Wroclaw, Poland, in press.
Konev, S. V., Lyskova, T. I., and Nisenbaum, G. D., Very weak bioluminescence of cells in the ultraviolet region of the spectrum and its biological role. Biophysics11 (1966) 410–413.
Konig, H. L., Bioinformation-electrophysical aspects, in: Electromagnetic Bio-Information, pp. 25–54. Eds F. A. Popp, G. Becker, H. L. Konig and W. Peschka. Urban & Schwarzenberg, München 1979.
Li, K. H., and Popp, F. A., Non-exponential decay law of radiation systems with coherent light rescattering. Phys. Lett.93A (1983) 262–266.
Li, K. H., Popp, F. A., Nagl, W., and Klima, H., Indications of optical coherence in biological systems and its possible significance, in: Coherent Excitations in Biological Systems, pp. 117–122. Eds H. Fröhlich and F. Kremer. Springer-Verlag, Berlin/Heidelberg 1983.
Linnemans, W. A. M., Cell biological analysis of parasite-host cell interactions. I. Phagocytosis and endoparasitism, a review. Acta leidensia47 (1979) 1–21.
Lloyd, D., Boveris, A., Reiter, R., Filipkowski, M., Chance, B., Chemiluminescence ofAcanthamoeba castellanii. Biochem. J.184 (1979) 149–156.
Nagl, W., Chromatin organization and the control of gene activity. Int. Rev. Cytol.94 (1985) 21–56.
Nagl, W., and Popp, F. A., A physical (electromagnetic) model of differentiation. 1. Basic considerations. Cytobios37 (1983) 45–62.
Nakano, M., Noguchi, T., Sugioka, K., Fukuyama, H., Sato, M., Shimizu, Y., Tsuji, Y., and Inaba, H., Spectroscopic evidence for the generation of singlet oxygen in the reduced nicotinamide adenine dinucleotide phosphate-dependent microsomal lipid peroxidation system. J. biol. Chem.250 (1975) 2404–2406.
Ninnemann, H., Butler, W. L., and Epel, B. L., Inhibition of respiration in yeast by light. Biochim. biophys. Acta205 (1970) 499–506.
Oberley, L. W., and Buettner, G. R., Role of superoxide dismutase in cancer. A review. Cancer Res.39 (1979) 1141–1149.
Oura, E., The effect of aeration on the growth energetics and biochemical composition of baker's yeast. Thesis, Helsinki 1972.
Parks, P. J., Barna, B. P., Edinger, M. G., Deodhar, S. D., Monocyte interactions with solid substrates monitored by chemiluminescence. Biomat. Med. Dev., Art. Org.10 (1982) 41–53.
Parnham, M. J., Bittner, C., and Winkelmann, J., Macrophages from different sources, their production of chemiluminescence under various stimuli and the effects of PGE, and drugs. Agents Actions11 (1981) 617–619.
Perelygin, V. V., and Tarusov, B. N., Flash of very weak radiation on damage to living tissues. Biophysics11 (1966) 616–618.
Polakis, E. S., and Bartley, W., Changes in enzyme activities ofSaccharomyces cerevisiae during aerobic growth on different carbon sources. Biochem. J.97 (1965) 284–297.
Polakis, E. S., Bartley, W., and Meek, G. A., Changes in the structure and enzyme activity ofSaccharomyces cerevisiae in response to changes in the environment. Biochem. J.90 (1964) 369–374.
Popp, F. A., Li, K., and Nagl, W., A thermodynamic approach to the temperature response of biological systems as demonstrated by low level luminescence of cucumber seedlings. Z. Pflanzenphysiol.114 (1984) 1–13.
Popp, F. A., and Nagl, W., A physical (electromagnetic) model of differentiation. 2. Applications and examples. Cytobios37 (1983) 71–83.
Popp, F. A., Nagl, W., Li, K. H., Scholz, W., Weingartner, O., and Wolf, R., Biophoton emission. New evidence for coherence and DNA as source. Cell Biophys.6 (1984) 33–52.
Popp, F. A., Ruth, B., Bahr, R. W., Bohm, J., Grass, P., Grolig, G., Rattemeyer, M., Schmidt, H. G., and Wulle, P., Emission of visible and ultraviolet radiation by active biological systems. Coll. Phenomena3 (1981) 187–214.
Quickenden, T. I., and Que Hee, S. S., Weak luminescence from the yeastSaccharomyces cerevisiae and the existence of mitogenetic radiation. Biochem. biophys. Res. Commun.60 (1974) 764–770.
Quickenden, T. I., and Que Hee, S. S., The spectral distribution of the luminescence emitted during growth of the yeastSaccharomyces cerevisae and its relationship to mitogenetic radiation. Photochem. Photobiol.23 (1976) 201–204.
Quickenden, T. I., and Tilbury, R. N., Growth dependent luminescence from cultures of normal and respiratory deficientSaccharomyces cerevisiae. Photochem. Photobiol.37 (1983) 337–344.
Rattemeyer, M., and Popp, F. A., Evidence of photon emission from DNA in living systems. Naturwissenschaften68 (1981) 572–573.
Ruth, B., Experimental investigations on ultraweak photon emission, in: Electromagnetic Bio-Information, pp. 107–122. Eds F. A. Popp, G. Becker, H. L. Konig and W. Peschka. Urban & Schwarzenberg, München 1979.
Robinson, J. P., and Penny, R., Chemiluminescence in normal human phagocytes. II. Effect of paraproteins. J. clin. Lab. Immun.7 (1982) 219–221.
Schamhart, D. H. J., and Van Wijk, R., Photon emission and the degree of differentiation. Int. Symp. on Photon Emission From Biological Systems (IS-86), Wroclaw, Poland, in press.
Shlyakhtina, L. L., and Gurwitsch, A. A., Radiations from the mouse liver at normal temperatures and on cooling. Biophysics17 (1972) 1146–1150.
Shohet, S. B., Pitt, J., Baehner, R. L., and Poplack, D. G., Lipid peroxidation in the killing of phagocytized pneumococci. Infect. Immun.10 (1974) 1321–1328.
Shtrankfel'd, I. G., Klimensko, L. L., and Komarow, N. N., Very weak luminescence of muscles. Biophysics13 (1968) 1082–1084.
Slawinska, D., and Slawinski, J., Biological chemiluminescence. Photochem. Photobiol.37 (1983) 709–715.
Starkebaum, G., Stevens, D. L., Claude, H., and Gavin, S. E., Stimulation of human neutrofil chemiluminescence by soluble immune complexes and antibodies to neutrophils. J. Lab. clin. Med.98 (1981) 280–291.
Stauff, J., and Reske, G., Lumineszenz von Hefe. Naturwissenschaften51 (1964) 39.
Sugioka, K., and Nakano, M., A possible mechanism of the generation of singlet molecular oxygen in NADP-dependent microsomal lipid peroxidation. Biochim. biophys. Acta423 (1976) 203–216.
Sung, S-S., A possible biophotochemical mechanism for cell communication, in: Electromagnetic Bio-Information, pp. 151–174. Eds F. A. Popp, G. Becker, H. L. Konig and W. Peschka. Urban & Schwarzenberg, München 1979.
Trush, M. A., Wilson, M. E., and Van Dyke, K., The generation of chemiluminescence (CL) by phagocytic cells. Meth. Enzymol.57 (1978) 462–494.
Van de Poll, K. W., Kerkenaar, A., and Schamhart, D. H. J., Isolation of a regulatory mutant of fructose-1,6-diphosphatase inSaccharomyces carlsbergensis. J. Bact.117 (1974) 965–970.
Van Rijn, J., and Van Wijk, R., Differential sensitivities of the two malate dehydrogenases and the maltose permease to the effect of glucose inSaccharomyces carlsbergensis. J. Bact.110 (1972) 477–484.
Van Wijk, R., Glucosidase synthesis, respiratory enzymes and catabolite repression in yeast. Proc. K. ned. Akad. Wet.C 71 (1968) 129–146.
Van Wijk, R., Regulation of DNA synthesis in cultured rat hepatoma cells. Int. Rev. Cytol.85 (1983) 63–107.
Williams, M. D., and Chance, B., Spontaneous chemiluminescence of human breath. J. biol. Chem.258 (1983) 3628–3631.
Wright, J. R., Rumbaugh, R. C., Colby, H. D., and Miles, P. R., The relationship between chemiluminescence and lipid peroxidation in rat hepatic microsomes. Archs Biochem. Biophys.192 (1979) 344–351.
Yanai, M., and Quie, O., Chemiluminescence by polymorphonuclear leukocytes adhering to surfaces. Infect. Immun.32 (1981) 1181–1186.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Van Wijk, R., Schamhart, D.H.J. Regulatory aspects of low intensity photon emission. Experientia 44, 586–593 (1988). https://doi.org/10.1007/BF01953306
Published:
Issue Date:
DOI: https://doi.org/10.1007/BF01953306