Tuning electrical spiking of Schizophyllum commune with light

When studying the split-gill fungus Schizophyllum commune, we observed that the growing colonies displayed endogenous spikes of electrical potential similar to the action potentials of neurons. In order to investigate the impact of light on the electrical activities of these colonies, we exposed them to intermittent stimulation with cold light (5800k) and later with blue (c. 470nm), red (c. 642nm) and green (c. 538nm) light. Our findings revealed spiking activity can be influenced using this input including observable responses with patterns of spiking at relatively high average amplitudes (>1mV) appearing consistently upon illumination of the sample. The response is likely related to the activity of fungal photoreceptors, including potential sensitisation to blue light in the cellular signalling pathways facilitated by white collar proteins (WC-1, WC-2) in S. commune. Based on these findings, we suggest that fungal photosensors and photonic computing substrates have the potential to enable applications beyond the scope of conventional electronics via relatively fast spiking responses to light tuned by external input stimulation. Further work should focus on identifying the signal transduction pathway for responses to different wavelengths of light and its role in translation into engineered ELMs to extend existing studies in fungal photobiology.

[1]  A. Adamatzky,et al.  Multiscalar electrical spiking in Schizophyllum commune , 2023, bioRxiv.

[2]  A. Adamatzky Language of fungi derived from their electrical spiking activity , 2022, Royal Society Open Science.

[3]  Andrew Adamatzky,et al.  Mining logical circuits in fungi , 2021, Scientific Reports.

[4]  A. Adamatzky,et al.  On electrical spiking of Ganoderma resinaceum , 2021, bioRxiv.

[5]  M. Levin Bioelectric signaling: Reprogrammable circuits underlying embryogenesis, regeneration, and cancer , 2021, Cell.

[6]  Alison Hanson Spontaneous electrical low-frequency oscillations: a possible role in Hydra and all living systems , 2021, Philosophical Transactions of the Royal Society B.

[7]  Mohammad Mahdi Dehshibi,et al.  Electrical activity of fungi: Spikes detection and complexity analysis , 2020, Biosyst..

[8]  Joel Zylberberg,et al.  The language of the brain: real-world neural population codes , 2019, Current Opinion in Neurobiology.

[9]  O. Ostroverkhova,et al.  Xylindein: Naturally Produced Fungal Compound for Sustainable (Opto)electronics , 2019, ACS omega.

[10]  M. Levin,et al.  Bioelectrical controls of morphogenesis: from ancient mechanisms of cell coordination to biomedical opportunities. , 2019, Current opinion in genetics & development.

[11]  Johannes L. Schönberger,et al.  SciPy 1.0: fundamental algorithms for scientific computing in Python , 2019, Nature Methods.

[12]  R. Fischer,et al.  Light sensing and responses in fungi , 2018, Nature Reviews Microbiology.

[13]  A. Adamatzky On spiking behaviour of oyster fungi Pleurotus djamor , 2018, Scientific Reports.

[14]  M. Levin,et al.  The bioelectric code: An ancient computational medium for dynamic control of growth and form , 2017, Biosyst..

[15]  H. Wösten,et al.  The blue light receptor complex WC-1/2 of Schizophyllum commune is involved in mushroom formation and protection against phototoxicity. , 2013, Environmental microbiology.

[16]  T. Shibata,et al.  Hierarchical organization of noise generates spontaneous signal in Paramecium cell. , 2011, Journal of theoretical biology.

[17]  Vincent Lombard,et al.  Genome sequence of the model mushroom Schizophyllum commune , 2010, Nature Biotechnology.

[18]  Morris H. Baslow,et al.  The Languages of Neurons: An Analysis of Coding Mechanisms by Which Neurons Communicate, Learn and Store Information , 2009, Entropy.

[19]  M. Levin Bioelectric mechanisms in regeneration: Unique aspects and future perspectives. , 2009, Seminars in cell & developmental biology.

[20]  J. Fromm,et al.  Electrical signals and their physiological significance in plants. , 2007, Plant, cell & environment.

[21]  Jennifer J. Loros,et al.  Light-induced resetting of a circadian clock is mediated by a rapid increase in frequency transcript , 1995, Cell.

[22]  Carver A. Mead,et al.  Analog VLSI Phototransduction by continuous-time, adaptive, logarithmic photoreceptor circuits , 1995 .

[23]  F. Laeri,et al.  Analog Optical Computing , 1987, Other Conferences.

[24]  V. Russo,et al.  PHOTOINDUCTION OF PROTOPERITHECIA IN NEUROSPORA CRASSA BY BLUE LIGHT , 1983, Photochemistry and photobiology.

[25]  C. Slayman,et al.  "Action potentials" in Neurospora crassa, a mycelial fungus. , 1976, Biochimica et biophysica acta.

[26]  R. Eckert,et al.  Sensory Mechanisms in Paramecium , 1972 .

[27]  M. Bingley Membrane potentials in Amoeba proteus. , 1966, The Journal of experimental biology.

[28]  N. Kamiya,et al.  Bioelectric phenomena in the myxomycete plasmodium and their relation to protoplasmic flow , 1950 .

[29]  W. A. Dorfman Electrical polarity of the amphibian egg and its reversal through fertilization , 1934, Protoplasma.

[30]  R. Beutner,et al.  The relation of life to electricity , 1933, Protoplasma.

[31]  R. Beutner Source of Bioelectricity, Investigated by the Relation Between Stainability and Electric Charges in Tissues and Artificial Models , 1929 .

[32]  Sylvain Barbay,et al.  Photonic Computing With Single and Coupled Spiking Micropillar Lasers , 2020, IEEE Journal of Selected Topics in Quantum Electronics.

[33]  Axel Mithöfer,et al.  Electrical long distance signaling in plants , 2013 .

[34]  František Baluška,et al.  Long-Distance Systemic Signaling and Communication in Plants , 2013, Signaling and Communication in Plants.

[35]  E. Król,et al.  Electrical Signals in Long-Distance Communication in Plants , 2006 .

[36]  B. Hansson,et al.  Action potential-like activity found in fungal mycelia is sensitive to stimulation , 2005, Naturwissenschaften.

[37]  J. Wessels Fruiting in the higher fungi. , 1993, Advances in microbial physiology.

[38]  T. Iwamura,et al.  Correlations between protoplasmic streaming and bioelectric potential of a slime mold, Physarum polycephalum , 1949 .