Santosh A. Helekar

Prolyl isomerase requirement for the expression of functional homo-oligomeric ligand-gated ion channels

Ligand-gated ion channel subunits show a striking abundance of highly conserved proline residues. We, therefore, tested the hypothesis that peptidyl-prolyl isomerases may be involved in the maturation of these channels. Cyclosporin A, a selective blocker of a ubiquitous isomerase cyclophilin, reduced the surface expression in Xenopus oocytes of functional homo-oligomeric receptors containing nicotinic acetylcholine receptor subunit alpha 7 without blocking alpha 7 polypeptide synthesis. This effect could be generalized to the homo-oligomeric 5-hydroxytryptamine type 3 receptor but not to the hetero-oligomeric muscle nicotinic receptor. An alpha 7 receptor could be rescued from cyclosporin A blockade by coexpressed muscle non-alpha subunits. The effect of cyclosporin A was reversed by overexpression of exogenous rat brain cyclophilin. These findings indicate that cyclophilins may play a critical role in the maturation of homo-oligomeric receptors, acting directly or indirectly as prolyl isomerases or as molecular chaperones.

Functional MRI of the zebra finch brain during song stimulation suggests a lateralized response topography

Electrophysiological and activity-dependent gene expression studies of birdsong have contributed to the understanding of the neural representation of natural sounds. However, we have limited knowledge about the overall spatial topography of song representation in the avian brain. Here, we adapt the noninvasive functional MRI method in mildly sedated zebra finches (Taeniopygia guttata) to localize and characterize song driven brain activation. Based on the blood oxygenation level-dependent signal, we observed a differential topographic responsiveness to playback of birds own song, tutor song, conspecific song, and a pure tone as a nonsong stimulus. The birds own song caused a stronger response than the tutor song or tone in higher auditory areas. This effect was more pronounced in the medial parts of the forebrain. We found left–right hemispheric asymmetry in sensory responses to songs, with significant discrimination between stimuli observed only in the right hemisphere. This finding suggests that perceptual responses might be lateralized in zebra finches. In addition to establishing the feasibility of functional MRI in sedated songbirds, our results demonstrate spatial coding of song in the zebra finch forebrain, based on developmental familiarity and experience.

Functional Brain Network Changes Associated with Maintenance of Cognitive Function in Multiple Sclerosis

In multiple sclerosis (MS) functional changes in connectivity due to cortical reorganization could lead to cognitive impairment (CI), or reflect a re-adjustment to reduce the clinical effects of widespread tissue damage. Such alterations in connectivity could result in changes in neural activation as assayed by executive function tasks. We examined cognitive function in MS patients with mild to moderate CI and age-matched controls. We evaluated brain activity using functional magnetic resonance imaging (fMRI) during the successful performance of the Wisconsin card sorting (WCS) task by MS patients, showing compensatory maintenance of normal function, as measured by response latency and error rate. To assess changes in functional connectivity throughout the brain, we performed a global functional brain network analysis by computing voxel-by-voxel correlations on the fMRI time series data and carrying out a hierarchical cluster analysis. We found that during the WCS task there is a significant reduction in the number of smaller size brain functional networks, and a change in the brain areas representing the nodes of these networks in MS patients compared to age-matched controls. There is also a concomitant increase in the strength of functional connections between brain loci separated at intermediate-scale distances in these patients. These functional alterations might reflect compensatory neuroplastic reorganization underlying maintenance of relatively normal cognitive function in the face of white matter lesions and cortical atrophy produced by MS.

Development and adult phase plasticity of syllable repetitions in the birdsong of captive zebra finches (Taeniopygia guttata)

Oscines learn their birdsongs from tutors. The authors found that a small fraction (approximately 7%) of captive male zebra finches (Taeniopygia guttata) produce variant acoustic birdsong profiles consisting of repetitions of single song syllables at high frequencies. Juvenile offspring of nonrepeaters can selectively learn the syntactic rule or habit of repeating syllables from repeaters. Adult tutored syllable repeaters, unlike spontaneous repeaters, undergo a form of song plasticity involving progressive reduction of the mean number and variance of repeated syllables as a function of long-term exposure to nonrepeater songs without altering the number or sequence of syllables within motifs. These findings suggest that aspects of song syntax or temporal frame can be acquired independently of song syllable or spectral content, and plasticity involving restorative alteration of acquired variant temporal frames can occur after the closure of the critical period for song learning.

On the Possibility of Universal Neural Coding of Subjective Experience

Various neurophysiological experiments have revealed remarkable correlations between cortical neuronal activity and subjective experiences. However, the mere presence of neuronal electrical activity does not appear to be sufficient to produce these experiences. It has been suggested that the explanation for the neural basis of consciousness might lie in understanding the reason that some types of neuronal activity possess subjective correlates and others do not. Here I propose and develop the idea that this difference may be caused by the existence of an elementary nonarbitrary linkage between temporal or spatiotemporal patterns of neuronal activity and their subjective attributes. I also show how cortical neural circuits capable of generating experience-coding patterns could emerge during evolution and brain development, due to the presence of spontaneous stochastic neuronal activity and activity-dependent synaptic plasticity. This hypothesis leads to several testable predictions, principal among which is the idea that the neural correlates of consciousness are essentially innate and universal.

Altered Auditory BOLD Response to Conspecific Birdsong in Zebra Finches with Stuttered Syllables

How well a songbird learns a song appears to depend on the formation of a robust auditory template of its tutors song. Using functional magnetic resonance neuroimaging we examine auditory responses in two groups of zebra finches that differ in the type of song they sing after being tutored by birds producing stuttering-like syllable repetitions in their songs. We find that birds that learn to produce the stuttered syntax show attenuated blood oxygenation level-dependent (BOLD) responses to tutors song, and more pronounced responses to conspecific song primarily in the auditory area field L of the avian forebrain, when compared to birds that produce normal song. These findings are consistent with the presence of a sensory song template critical for song learning in auditory areas of the zebra finch forebrain. In addition, they suggest a relationship between an altered response related to familiarity and/or saliency of song stimuli and the production of variant songs with stuttered syllables.

Acoustic pattern variations in the female-directed birdsongs of a colony of laboratory-bred zebra finches.

The acoustic profile of the zebra finch song is characterized by a series of identical repeating units, each comprising a distinctive sequence of acoustic elements, called syllables. Here, we perform an analysis of song pattern deviations caused by variabilities in the production of song syllables. Zebra finches produce four different kinds of syllable variabilities-syllable deletions, single or double syllable insertions, syllable alterations, and syllable repetitions. All these variabilities, with the exception of repetitions, are present in songs of more than two-thirds of the normal adult birds; repetitions are present in less than one-fifth of birds. The frequency of occurrence of these variabilities is independent of the amount of singing, suggesting that they are unlikely to result simply from singing-induced physiological changes such as fatigue. Their frequencies in tutor-deprived birds are not significantly different from those in normal birds, indicating that they are unlikely to be acquired due to deficiencies in tutor-dependent learning. The types, patterns of occurrence and relative frequencies of these song syllable variabilities might reveal insights into the functioning of the song motor control pathway.

Nicotine-mediated plasticity in robust nucleus of the archistriatum of the adult zebra finch

Activation of neuronal nicotinic acetylcholine receptors (nAChRs) modulates the induction of long-term potentiation (LTP), a possible cellular mechanism for learning. This study was undertaken to determine the effects of activation of nAChRs by nicotine on long-term plasticity in the songbird zebra finch, which is a valuable model to study synaptic plasticity and its implications to behavioral learning. Electrophysiological recordings in the robust nucleus of the archistriatum (RA) in adult zebra finch brain slices reveal that tetanic stimulation alone does not produce LTP. However, LTP is induced by such stimulation in the presence of nicotine. The nicotine-mediated LTP is blocked by dihydro-beta-erythroidine (DHbetaE, 1 microM), an antagonist having a greater effect against nAChRs containing the alpha 4 subunit. In the presence of methyllcaconitine (MLA, 10 nM), an antagonist of nAChRs containing the alpha 7 subunit, a long-term depression (LTD) is unmasked, implicating a bi-directional type of plasticity in the zebra finch RA, which is modulated by differential activation of nAChR subtypes. Intracellular recordings from single neurons show a depression of the afterhyperpolarization (AHP) and an increase in frequency of evoked and spontaneous action potentials in the presence of nicotine. These results suggest that nicotinic cholinergic mechanisms may play a critical role in synaptic plasticity in the zebra finch song system and thereby influence song learning and plasticity.

A burst-dependent hippocampal excitability defect elicited by potassium at the developmental onset of spike-wave seizures in the Tottering mutant

Hippocampal CA3 pyramidal neurons in the adult epileptic mutant mouse tottering (tg) show normal intrinsic membrane properties, yet fire abnormally prolonged paroxysmal depolarizing shifts (PDS) during in vitro exposure to elevated extracellular potassium solutions. Intracellular recordings in immature mutants reveal that this network burst abnormality is present during the developmental period that coincides with the onset of seizures in the mutant (19-20 postnatal days), and is significantly more pronounced at this age than at adulthood. These data are inconsistent with the hypothesis that the mutant PDS prolongation represents a secondary consequence of a prolonged history of repeated seizures and suggest that it may reflect a cellular epileptogenic phenotype more directly related to the primary neuropathological expression of the tg gene.

Proteomics of the nucleus ovoidalis and field L brain regions of zebra finch

The purpose of present study is to analyze the brain proteome of the nucleus ovoidalis (OV) and Field L regions of the zebra finch (Taeniopygia guttata). The OV and Field L are important brain nuclei in song learning in zebra finches; their analyses identified a total of 79 proteins. The zebra finch brain proteome analyses are poised to provide clues about cell and circuit layout as well as possible circuit function.