ABSTRACT
Both phototactic and photophobic responses of Chlamydomonas are mediated by a visual system comprising a rhodopsin photoreceptor. Suction pipette recordings have revealed that flash stimulation causes calcium currents into the eyespot and the flagella. These photocurrents have been suggested to be the trigger for all behavioral light responses of the cell. But this has never been shown experimentally. Here we describe a detection technique that combines electrical and optical measurements from individual algae held in a suction pipette. Thus it is possible to record photocurrents and flagellar beating simultaneously and establish a direct link between the two. We demonstrate that in Chlamydomonas only the photoreceptor current in conjuction with a fast flagellar current constitutes the trigger for photophobic responses. Within the time of the action-potential-like flagellar current, the flagella switch from forward to backward swimming, which constitutes the beginning of the photoshock reaction. The switch is accompanied by a complex frequency change and beating pattern modulation. The results are interpreted in terms of a general model for phototransduction in green algae (Chlorophyceae).
Subject(s)
Chlamydomonas/physiology , Flagella/physiology , Photoreceptor Cells/physiology , Rhodopsin/physiology , Animals , Calcium/metabolism , Cell Movement/drug effects , Flagella/drug effects , Light , Microscopy, Video/instrumentation , Microscopy, Video/methods , Potassium/pharmacology , Time FactorsABSTRACT
In the green alga Chlamydomonas chlamyrhodopsin fulfills its role as a light sensor by absorbing light and activating photoreceptor channels within the eyespot area. At intense light stimuli, the photoreceptor (P) current triggers a fast and a slow flagellar current that finally leads to backward swimming (stop response). Here we report about probing the photoreceptor current directly at the eyespot. This allows the detection of the whole P current with a size of above 50 pA. The P current appears with a delay of less than 50 microseconds, suggesting that rhodopsin and the P channel are closely coupled or form one ion channel complex. The Ca2+ dependence of the P current has been demonstrated with the established suction technique in a capacitive mode. The P current shows the maximum amplitude at only 300 nM Ca2+, and it gradually declines at higher Ca2+. In addition to Ca2+, the photoreceptor and the fast flagellar current can be carried by Sr2+ and Ba2+. Mg2+ is conducted less efficiently and at high concentrations blocks the photoreceptor channel. A motion analysis of the cells shows that only Ca2+ and Sr2+ can induce physiological stop responses, whereas the large Ba2+ currents cause abnormal long-lasting cell spiraling.
Subject(s)
Chlamydomonas/radiation effects , Rhodopsin/radiation effects , Animals , Biophysical Phenomena , Biophysics , Calcium/metabolism , Cations, Divalent/metabolism , Cell Movement/radiation effects , Chlamydomonas/chemistry , Chlamydomonas/metabolism , Electrochemistry , Ion Channels/metabolism , Ion Channels/radiation effects , Kinetics , Models, Biological , Photobiology , Photochemistry , Photoreceptor Cells, Invertebrate/chemistry , Photoreceptor Cells, Invertebrate/radiation effects , Rhodopsin/chemistry , Rhodopsin/metabolismABSTRACT
Chlamydomonas exhibits a sequence of a photoreceptor current and two flagellar currents upon stimulation with bright green flashes. The currents are thought to be a prerequisite for the well-known photophobic responses. In the preceding paper, we analyzed the kinetics of these currents and their dependence on extracellular divalent ions. Here, we show that the photoreceptor current can be carried by monovalent ions (K+ > NH4+ > Na+), provided that the driving force is high enough. The small residual photoreceptor current observed in the absence of Ca2+ is able to evoke flagellar currents at low extracellular pH. This demonstrates that signal transduction from the rhodopsin to the flagella is not inevitably dependent on extracellular Ca2+. Double-flash experiments exclude a contribution of intra-rhodopsin charge movements to the photoreceptor current signal. Evidence will be provided for the existence of nonlocalized K+ outward currents, which counterbalance the localized Ca2+ influx and repolarize the cell after a light flash. A model is presented that explains the different pathways for direction changes and phobic responses.
Subject(s)
Chlamydomonas/radiation effects , Rhodopsin/radiation effects , Animals , Biophysical Phenomena , Biophysics , Cations, Monovalent/metabolism , Chlamydomonas/chemistry , Chlamydomonas/metabolism , Electrochemistry , Flagella/chemistry , Flagella/metabolism , Flagella/radiation effects , Ion Transport , Kinetics , Models, Biological , Photic Stimulation , Photobiology , Photochemistry , Photoreceptor Cells, Invertebrate/chemistry , Photoreceptor Cells, Invertebrate/radiation effects , Potassium/metabolism , Rhodopsin/chemistry , Rhodopsin/metabolism , Signal TransductionABSTRACT
The paper describes a sensitive method for the detection of 7-chloro-2,3-dihydro-5-phenyl-1-(2-propinyl)-1H-1,4-benzodiazepine -2-one (pinazepam, Domar) and its major metabolites.
