Effects induced by an actin-polymerizing peptide in goldfish mauthner neurons

In goldfishes, we studied (i) manifestations of functional activity of Mauthner neurons (MNs) reflected in motor behavior and (ii) changes in 3-D morphometry (ratio of volumes) and ultrastructure of MNs after applications of an actin-polymerizing peptide obtained from scorpion venom and after vestibular rotational stimulations (trainings) inducing natural modification of functions of the MNs (adaptation). In MNs subjected to application of the peptide, the increase in the functional resistance and morphological stability caused by long-lasting stimulation directly depended on the dose of the applied peptide or on the effectiveness of trainings, whereas in intact and control MNs such stimulation resulted in significant decreases in the activity and volumes of these cells. At the ultrastructure level, both applications of the peptide and trainings caused the formation of extensive bundles of actin filaments (“stress-fibers”) in the cytoplasm of MNs and led to an increase in the dimension of desmosome-like contacts (DLCs) in afferent synapses. At chemical synapses, the effect looked like a reciprocal decrease in the length of the active zones (a structural sign of long-term depression, LTD), while at mixed synapses this was manifested in an increase in the number of fibrillar bridges in the gaps of DLCs (a structural sign of long-term potentiation, LTP). The data obtained allow us to hypothesize that LTD of the efficacy of transmission through chemical synapses is involved in the formation of the adaptation state of the MNs and that polymerization of actin in the cytoplasm and DLCs underlies the mechanism of LTD and adaptation. The development of ultrastructural manifestations of LTP at mixed synapses after polymerization of actin by the peptide, which is related to a reciprocal increase in the efficacy of “mixed” afferent inputs, explains the maintenance of a high integral level of activity of the MNs, despite a drop in the functional activity of “ chemical” afferent inputs. Therefore, the actin cytoskeleton plays a clearly significant role in the maintenance of the balance of excitation at the neuronal level. Neirofiziologiya/Neurophysiology, Vol. 38, Nos. 5/6, pp. 389–401, September–December, 2006.     

Effects of optokinetic stimulation on motor asymmetry in the goldfish

In goldfish fries, we examined the effect of the optomotor reaction (drive to swim toward moving images of vertical dark bars) on the behavioral motor asymmetry. Contralateral optokinetic stimulation of fishes (rotation of the bars against the direction preferred by fishes in their turnings) gradually smoothed and, later on, inverted the motor asymmetry, while the asymmetry underwent no modifications in the case of ipsilateral optokinetic stimulation (rotation of the bars in the direction similar to that preferred for turnings). Contralateral optokinetic stimulation also induced long-lasting inversion of the motor asymmetry of immobilized fishes deprived of the possibility to follow the movement of bar images. Ipsilateral optokinetic stimulation of fishes with the enucleation of the ipsilateral eye enhanced their motor asymmetry, while contralateral stimulation either did not modify the motor asymmetry of such individuals or inverted this feature. These data agree with the concept that, in fishes, one eye dominates and more actively provides tracking of the movement of bars, while another eye is a subdominant one. In general, we first found that the use of specific visual stimulation allows one to modify for a long time the behavioral motor asymmetry of the fishes, which, as is known, correlates with the morphofunctional asymmetry of Mauthner neurons (MNs). Visual information that activates MNs influences mostly the ventral dendrites of these neurons; thus, our findings allow us to believe that stimulations, which initiate the optomotor reaction, can serve as an adequate physiological model of natural visual stimulation of MNs (with projection of the respective influences on the ventral dendrites of the above cells). The use of such an experimental paradigm opens up new possibilities for studies of the role of these dendrites in the functions of MNs and of the plasticity of morphofunctional organization of these cells. Neirofiziologiya/Neurophysiology, Vol. 39, No. 2, pp. 133–145, March–April, 2007.     

Biosemiosis and the Cellular Basis of Mind

The human brain is a complex organ made up of neurons and several other cell types, and whose role is processing information for use in elicitation of behaviors. To accomplish this, the brain requires large amounts of energy, and this energy is obtained by the oxidation of glucose (Glc). However, the question of how the oxidation of Glc by individual neurons in brain results in their collective ability to rapidly generate feats of cognition that allow them to recognize the nature of the universe in which they live and to communicate this information remains unclear. In this article, insights into this process are provided by first considering the brain’ s homeostatic “operating system” for supply of energy to stimulated neurons, and how this system defines the basic unit of brain “structure”. This is followed by consideration of the brain’s “two-cell” neuronal communication mechanism which defines the basic unit of brain “function”. Finally, an analysis of the nature of frequency-encoded “neuronal languages” that enable ensembles of neurons to translate energy derived from the oxidation of Glc into a collective “mind”, the aggregate of all brain processes including those involving perception, thought, insight, foresight, imagination and behavior.     

Receptive Fields of Visually Sensitive Neurons of the Extrastriate Associative Area 21b of the Cat Cerebral Cortex

Organization of the receptive fields (RFs) of neurons of the extrastriate associative region 21b of the cerebral cortex was studied in cats. Most neurons under study (63%) were “monocular,” while 37% of the cells were “binocular” units. Among 178 neurons examined in detail, heterogeneous RF functional organization was typical of about 76% of the units; point-to-point testing of the entire RF area by stationary stimuli resulted in the generation of various types of responses (on, off, or on-off). The rest of the neurons (24%) generated homogeneous responses. The dimension, form, and functional organization of RFs of the neurons under study depended to a certain extent on the parameters of visual stimuli used for the measurements. Examination of the influence of the visual space, which surrounded the RF, on responses of the neurons evoked by stimulation of the RF per se showed that darkening of the visual space adjacent to the RF inhibited neuronal responses to moving stimuli; in some cases the responses were totally suppressed. Analysis of spatial overlapping of the RF sequentially recorded in the course of each insertion of the electrode showed that the density of distribution of the overlapping RF areas of neighboring neurons with the RF of the examined neuron is irregular, and that the RF is of a mosaic nature. We hypothesize that the visual space surrounding the RF plays a significant role in the formation of responses of visually sensitive neurons to presentation of moving stimuli. Neirofiziologiya/Neurophysiology, Vol. 37, No. 3, pp. 223–234, May–June, 2005.     

Asymmetry of Motor Behavior of the Goldfish in a Narrow Channel

We studied swimming of goldfish fries about 3 cm long in a narrow channel by calculating the numbers of spontaneous turns on different sides. The ratio of fishes preferring to turn to the right vs to the left was 1.5:1.0, respectively; two-thirds of the fishes demonstrated an ambilateral behavior. Experiments with compulsory 10-min-long rotation of the fishes (clockwise around the longitudinal body axis for fishes preferring right-side turns and anticlockwise for fishes preferring left-side turns) showed that the behavioral asymmetry smoothed somewhat after such a procedure, and a greater number of the fishes became ambilateral in their preference to turn to one side or another. After a one- or two-day-long test, the initial asymmetry of motor behavior completely recovered. Compulsory rotation of similar fishes in the opposite direction exerted no influence on the asymmetry in the choice of the turning direction. Adaptation-induced training of the fishes (using fatiguing long-lasting vestibular stimulation) resulted in some smoothing of motor asymmetry but did not change its general pattern. Thus, our findings allow us to believe that a noticeable proportion of the goldfish individuals (similarly to other animals and humans) is characterized by an innate asymmetry of the motor function with a clear preference for either right- or left-side turnings. These relations can be smoothed under experimental influences but are recovered later on, i.e., they are stable and are not fundamentally transformed. We assume that the asymmetry of motor behavior of fishes in a narrow channel can be an adequate pre-requisite for further examination of the asymmetry of the brain and motor centers controlling changes in locomotion (body turnings)Neirofiziologiya/Neurophysiology, Vol. 37, No. 1, pp. 52–60, January–February, 2005.     

Methodological approach for estimating the functional state of the body by the degree of fatigue

The functional state of firefighter (rescuers) from operational units of the Ministry of the Russian Federation for Affairs of Civil Defense, Emergencies and Disaster Relief (persons of an extreme profession, men from health groups I–II, 20–45 years old; n= 136) has been monitored under the conditions of a 24-h workday (WD) in the framework of an integrated study. It has been shown that the signs of acute fatigue appear in individual systems, while general fatigue is formed in the body as a whole. A methodological approach has been developed for estimating their functional state by rating the “general fatigue of the body,” including six methodically different techniques.     

The pattern of sensory discharge can determine the motor response in young Xenopus tadpoles

Young Xenopus tadpoles were used to test whether the pattern of discharge in specific sensory neurons can determine the motor response of a whole animal. Young Xenopus tadpoles show two main rhythmic behaviours: swimming and struggling. Touch-sensitive skin sensory neurons in the spinal cord of immobilised tadpoles were penetrated singly or in pairs using microelectrodes to allow precise control of their firing patterns. A single impulse in one Rohon-Beard neuron (= light touch) could sometimes trigger “fictive” swimming. Two to six impulses at 30–50 Hz (= a light stroke) reliably triggered fictive swimming. Neither stimulus evoked fictive struggling. Twenty-five or more impulses at 30–50 Hz (= pressure) could evoke a pattern of rhythmic bursts, distinct from swimming and suitable to drive slower, stronger movements. This pattern showed some or all the characteristics of “fictive” struggling. These results demonstrate clearly that sensory neurons can determine the pattern of motor output simply by their pattern of discharge. This provides a simple form of behavioural selection according to stimulus. Accepted: 28 November 1996     

Activation of neurons of zone A5 of the rat brain upon hypoxic and thermonociceptive stimulation and switching off of the central respiratory generator

We recorded spike activity of noradrenergic neurons of zone A5 (n = 89) in the brain of anesthetized rats under conditions of hypoxic stimulation (breathing with pure N₂, 10 sec), thermonociceptive stimulation (tail-flick test), and reversible hypothermal blocking of the central respiratory activity. Hypoxic stimulation of peripheral O₂-sensitive chemoreceptors considerably increased the discharge frequency in all the examined neurons and induced tachypnea and a hypotensive reaction. Sixty-nine (77.5%) neurons of the studied group were tested using nociceptive stimulation (thermal stimulation of the tail); such stimulation resulted in a multifold increase in their discharge frequency. This was accompanied by tachypnea and a hypertensive response. Thus, we first demonstrated the role of nociception in the control of activity of noradrenergic neurons in zone A5 and the role of nociceptive afferent signals in the modulation of functions of the respiratory and cardiovascular systems mediated by neurons of the above zone. Under conditions of blocking of the central respiratory activity, we examined 36 (40.4%) neurons of zone A5 and first observed the effect of strong activation of a significant proportion of these cells upon switching off of respiration. This fact shows that there is an activating “respiratory” drive on neurons of zone A5 (probably, from the side of an expiratory neuronal population of the respiratory center) and allows us to hypothesize on the genesis of “respiratory” modulation of these cells. The activity of 16 (18.0%) cells was recorded under conditions of consecutive applications of the above stimuli; all the neurons were activated by the respective afferent influences. The simultaneously induced effects of hypoxic and nociceptive stimulations on the activity of neurons of zone A5 were additive. Thus, we first obtained proofs in favor of the multimodality of noradrenergic neurons of the above zone. This feature is a significant factor providing integrative interaction between the respiratory and cardiovascular systems and the system of nociception. Neirofiziologiya/Neurophysiology, Vol. 38, No. 4, pp. 305–313, July–August, 2006.     

Activity of neurons of the cerebral A5 zone of rat induced by adequate stimulation of muscle afferents: On the control of arterial pressure and respiration during muscle activity

In experiments on 24 anesthetized rats with preserved spontaneous respiration, we first recorded the volley impulse activity of neurons (n = 30) in the brainstem A5 zone, which was induced by periodical stretchings of the forelimb flexors and hindlimb extensors. The frequency of action potentials in such volleys was, on average, 99.7 ± 19.6 sec⁻¹. In the course of this kinesthetic stimulation, along with the activation of “proprioceptive” neurons of the A5 zone, we observed transitory drops in the arterial pressure and increases first recorded the activity of baroceptive neurons in subpial parts of the A5 zone (n = 4); the frequency of their background impulsation was, on average, 25.1 ± 0.8 sec⁻¹. This activity in all cases was transitorily suppressed both upon increases of the blood pressure caused by constriction of the carotid arteries or nociceptive tail stimulation, as well as upon stretching of skeletal muscles. Therefore, we first obtained direct proof that neuronal systems of the A5 zone are involved in integration of visceral and somatic proprioceptive afferent influences. We hypothesize that the physiological role of this mechanism of integration of somatic and visceral information at the level of the A5 zone is directed toward lowering of the arterial pressure and intensification of respiration within the period of intensified motor activity. This mechanism is based on the interaction between “proprioceptive,” baroceptive, and, perhaps, multiceptive neurons within the A5 zone. Neirofiziologiya/Neurophysiology, Vol. 39, No. 6, pp. 443–452, November–December, 2007.     

Slow modulation of synaptic transmission by brain-derived neurotrophic factor leads to the central sensitization associated with neuropathic pain

Chronic constriction injury (CCI) of the rat sciatic nerve increases the dorsal horn excitability. This “central sensitization” leads to behavioral manifestations analogous to those related to human neuropathic pain. We found, using whole-cell recording from acutely isolated spinal cord slices, that 7-to 10-day-long CCI increases excitatory synaptic drive to putative excitatory “delay”-firing neurons in the substantia gelatinosa but attenuates that to putative inhibitory “tonic”-firing neurons. A defined-medium organotypic culture (DMOTC) system was used to investigate the long-term actions of brain-derived neurotrophic factor (BDNF) as a possible instigator of these changes. When all five neuronal types found in the substantia gelatinosa were considered, BDNF and CCI produced similar patterns, or “footprints,” of changes across the whole population. This pattern was not seen with another putative “pain mediator,” interleukin 1β. Thus, BDNF decreased synaptic drive to “tonic” neurons and increased synaptic drive to “delay” neurons. Actions of BDNF on “delay” neurons were presynaptic and involved increased mEPSC frequency and amplitude without changes in the function of postsynaptic AMPA receptors. By contrast, BDNF exerted both pre-and post-synaptic actions on “ tonic” cells to reduce the mEPSC frequency and amplitude. These differential actions of BDNF on excitatory and inhibitory neurons contributed to a global increase in the dorsal horn network excitability as assessed by the amplitude of depolarization-induced increases in the intracellular [Ca²⁺]. Experiments with the BDNF-binding protein TrkB-d5 provided additional evidence for BDNF as a harbinger of neuropathic pain. Thus, the cellular processes altered by BDNF likely contribute to “central sensitization” and hence to the onset of neuropathic pain. Neirofiziologiya/Neurophysiology, Vol. 39, Nos. 4/5, pp. 315–326, July–October, 2007.     

Subpopulation of nestin positive glial precursor cells occur in primary adult human brain cultures

Glial fibrillary acidic protein (GFAP) is an intermediate filament protein considered to be the best astroglial marker. However, the predominant cell population in adult human brain tissue cultures does not express GFAP; these cells have been termed “glia-like” cells. The basic question about histological origin of adult human brain cultures remains unanswered. Some authors showed that “glia-like” cells in adult human brain cultures might be of non-glial origin. We examined primary explant tissue cultures derived from 70 adult human brain biopsies. Within first 5–10 days approximately 5–10% of the small explants became attached. Outgrowing cells were mostly flat cells. These cells formed confluent layer over 3–6 weeks in culture. At confluence the cultures contained 2–5% of microglial cells, 0.1% GFAP-positive astrocytes, less than 0.01% oligodendrocytes and 95–98% GFAP-negative “glia-like” cells. This population of flat “glia-like” cells was positively stained for vimentin, fibronectin, and 20–30% of these cells stained for nestin. Our findings revealed that 1 mM dibutyryl-cAMP addition, in serum free conditions, induced a reversible stellation in 5-10% of the flat “glia-like” cells but did not induce the expression of GFAP or nestin in morphologically changed stellate cells. These results demonstrate that “glia-like” cells in primary adult human brain cultures constitute heterogeneous cell populations albeit with similar morphological features. Two distinct subpopulations have been shown: (i) the one immunostained for nestin; and (ii) the other reactive for dibutyryl-cAMP treatment.     

From view cells and place cells to cognitive map learning: processing stages of the hippocampal system

 The goal of this paper is to propose a model of the hippocampal system that reconciles the presence of neurons that look like “place cells” with the implication of the hippocampus (Hs) in other cognitive tasks (e.g., complex conditioning acquisition and memory tasks). In the proposed model, “place cells” or “view cells” are learned in the perirhinal and entorhinal cortex. The role of the Hs is not fundamentally dedicated to navigation or map building, the Hs is used to learn, store, and predict transitions between multimodal states. This transition prediction mechanism could be important for novelty detection but, above all, it is crucial to merge planning and sensory–motor functions in a single and coherent system. A neural architecture embedding this model has been successfully tested on an autonomous robot, during navigation and planning in an open environment. Received: 28 June 1999 / Accepted in revised form: 26 April 2001     

Ultrastructural Changes in the Mixed Synapses of Mauthner Neurons Related to Long-Term Potentiation and Natural Modification of the Motor Function

We examined changes in the ultrastructure of afferent mixed synapses on the membrane of Mauthner neurons (M cells) of the goldfish, which were related to two functional states, long-term potentiation (LTP) of the electrotonic response (a model form of the memory trace) and adaptation (resistivity to fatigue resulting from long-lasting motor training and considered a natural form of the memory trace manifested on the neuronal level). LTP was induced in medullary slices using high-frequency electrical stimulation of the afferent input. Adaptation was produced using natural vestibular stimulation (everyday motor training, which modified motor behavior of the fish and function of the M cell). It was supposed that if the LTP phenomenon is involved in the formation of natural memory, both the adaptation and the LTP states should be accompanied by similar specific structural modifications. Indeed, it was found that in both cases the number of fibrillar bridges in the gaps of desmosome-like contacts (DLC) in the mixed synapses on the M cell surface demonstrated an about twofold increase. These bridges are known to include actin filaments, which function as conductors of cationic signals; thus, the LTP-related increase in the density of bridges corresponds to increased efficacy of electrotonic coupling via mixed synapses. Such a structural correlate of LTP, which probably has the same functional significance in mixed synapses of the adapted M cells, allows us to suppose that LTP is a natural property of the nervous system. The LTP-type intensification of the relay function of mixed synapses, which corresponds to adaptation, is probably a compensatory rearrangement allowing M cells to maintain some balance of the synaptic influences and, at the same time, to remain in a stable and plastic state; this is necessary for stable functioning under changing environmental conditions.     

Pioneer neurons: A basis or limiting factor of lophotrochozoa nervous system diversity?

It has been demonstrated by us and other authors that first nervous cells in developing larvae from various trochozoan groups differentiate at the periphery. These pioneer neurons are distinguished by the set of characters. They are located outside the forming central ganglia; outgrowing fibers of central neurons use their processes as a “scaffolding” transmitter expression in these neurons is transient. On the one hand, pioneer neurons mark the “frame” of the adult nervous system and thus play a limiting role. On the other hand, pioneering navigation provides possible mechanisms for evolutional plasticity of the nervous system in adults. In addition, pioneer neurons can underlie functional adaptation of trochophore animals, which minimizes fitness decrease during the transition from the larval to the adult form during metamorphosis.     

Morphological parameters of mauthner neurons of goldfishes with modified asymmetry of motor behavior

We examined the morphological peculiarities of Mauthner neurons, MNs, in goldfishes with a phenotypically different or an experimentally modified preference to perform rightward vs leftward turnings in the course of motor behavior; this preference was characterized by values of the motor asymmetry coefficient (MAC). 3D reconstruction of MNs was performed based on several histological sections; volumes of the soma, lateral and ventral dendrites (LD and VD, respectively), initial segment of the axon, as well as full volumes of the right and left neurons, were calculated. Differences between the above parameters were expressed as structural asymmetry coefficients (SACs). It was shown that clear orientation asymmetry of motor behavior of the fish is accompanied by differences in the dimensions of MNs and their compartments; MNs localized contralaterally with respect to the preferred turning side were considerably bigger than ipsilateral neurons. Experimental influences inducing inversion of the motor asymmetry of fishes inverted structural asymmetry of their MNs. In fishes with no phenotypical preference of the turning side and in individuals whose motor asymmetry was smoothed due to experimental influences (rotational stimulations), structural asymmetry of the MNs was also smoothed. Changes of the structural proportions developed, as a rule, due to decreases in the dimensions of one or both MNs and their compartments. The MAC value was in direct correlation with the value of SAC of the MNs and with values of this coefficient for the soma and the sum soma + LD. At the same time, reciprocal relations were found for the MAC and structural asymmetry of the VD; the decrease in the volume of VD was related to an increase in the preference of the contralateral turning side by the fish, and vice versa. In general, the results of our study demonstrate that both morphological and functional peculiarities of MNs correlate to a significant extent with such a form of motor behavior of fishes as realization of spontaneous turnings. Neirofiziologiya/Neurophysiology, Vol. 38, No. 1, pp. 18–31, January–February, 2006.     

Modifications of event-related evoked potentials in physiological and pathological aging of the brain

We compared the parameters of acoustic event-related evoked potentials (ERP; tone stimulation) in healthy young and healthy aged persons with those in patients suffering from Alzheimer’s disease (groups 1–3, respectively). It was found that the mean peak latencies (PL) of the components P1-N2 in group 1 were longer than those in group 2, and the absolute values of the amplitudes of these components were more negative. In Alzheimer patients (group 3), the PL of the components P1–P2 were much longer than those in group 2, and their peak-to-peak amplitudes dropped. The latencies of a simple sensorimotor reaction in groups 1–3 progressively increased (about three times). The ERP observed in two modes (“blackground” and “attention,” the latter with the performance of the sensorimotor reaction) were subjected to spectral analysis. Possible reasons for and mechanisms of those modifications of evoked potentials, which relate to physiological and pathological aging of the brain, are discussed.     

Multiform wave organization of neurophysiological processes-universal “language” of human brain in realization of informational-controlling functions

The paper summarizes literature data and results of many-year Laboratory studies disclosing principles of the multiform spatial-time organization of differing by rates of neurophysiologic brain processes as the universal “language” of its informational-controlling functions. There are considered current concepts of electrogenesis and physiological significance of ratios of gradual changes of biopotentials and impulse activity of neurons considered in studies of cerebral mechanisms of regulation of normal and pathological states, and organization of human psychic activity. Put forward and argumented are concepts of the probability principle of hierarchical organization of differing by rates of neurophysiologic processes brain zones, structures, and areas in formation of the brain systems participating in provision of the higher psychic functions and states. It is proposed to discuss the concept of the brain as the “swimming,” many-contour, neurodynamic informational-controlling suprasystem with universal, hierarchically organized neurodynamic structures—”functional organs” by A.A. Ukhtomskii (1978), of which formation provides large informational brain capacity and a wide specter of adaptive possibilities of the human organism.     

Schema design and implementation of the grasp-related mirror neuron system

 Mirror neurons within a monkey's premotor area F5 fire not only when the monkey performs a certain class of actions but also when the monkey observes another monkey (or the experimenter) perform a similar action. It has thus been argued that these neurons are crucial for understanding of actions by others. We offer the hand-state hypothesis as a new explanation of the evolution of this capability: the basic functionality of the F5 mirror system is to elaborate the appropriate feedback – what we call the hand state– for opposition-space based control of manual grasping of an object. Given this functionality, the social role of the F5 mirror system in understanding the actions of others may be seen as an exaptation gained by generalizing from one's own hand to an other's hand. In other words, mirror neurons first evolved to augment the “canonical” F5 neurons (active during self-movement based on observation of an object) by providing visual feedback on “hand state,” relating the shape of the hand to the shape of the object. We then introduce the MNS1 (mirror neuron system 1) model of F5 and related brain regions. The existing Fagg–Arbib–Rizzolatti–Sakata model represents circuitry for visually guided grasping of objects, linking the anterior intraparietal area (AIP) with F5 canonical neurons. The MNS1 model extends the AIP visual pathway by also modeling pathways, directed toward F5 mirror neurons, which match arm–hand trajectories to the affordances and location of a potential target object. We present the basic schemas for the MNS1 model, then aggregate them into three “grand schemas”– visual analysis of hand state, reach and grasp, and the core mirror circuit – for each of which we present a useful implementation (a non-neural visual processing system, a multijoint 3-D kinematics simulator, and a learning neural network, respectively). With this implementation we show how the mirror system may learnto recognize actions already in the repertoire of the F5 canonical neurons. We show that the connectivity pattern of mirror neuron circuitry can be established through training, and that the resultant network can exhibit a range of novel, physiologically interesting behaviors during the process of action recognition. We train the system on the basis of final grasp but then observe the whole time course of mirror neuron activity, yielding predictions for neurophysiological experiments under conditions of spatial perturbation, altered kinematics, and ambiguous grasp execution which highlight the importance of the timingof mirror neuron activity. Received: 6 August 2001 / Accepted in revised form: 5 February 2002     

Generalization and categorization of spectral colors in goldfish. II. Experiments with two and six training wavelengths

In part I of this study (Kitschmann and Neumeyer 2005), goldfish categorized spectral colors only in the sense that wavelengths in a range of about twice as large as the just noticeable difference were treated as similar to a given training wavelength. Now, we trained goldfish on more than one wavelength to prevent very accurate learning. In one experiment goldfish were trained on six adjacent wavelengths with equal numbers of rewards, and, thus, equal numbers of learning events. Generalization tests showed that some wavelengths were chosen more often than others. This indicated that certain spectral ranges are either more attractive or more easily remembered than others. As this is a characteristic of the “focal” colors or centers of color categories in human color vision, we interpret the findings in goldfish accordingly. We conclude (Figs. 5 and 6) that there are four categories in spectral ranges approximately coinciding with the maximal sensitivities of the four cone types, and three categories in-between. Experiments with two training colors indicate that there is no direct transition between categories analogous to human “green” and “red”, but that there is a color analogous to human “yellow” in-between (Figs. 2, 3; Table 1).