14 research outputs found
Molecular Mechanisms Underlying Associative Learning
This thesis primarily attempts to solve some long standing issues regarding classical eyelid conditioning. More specifically, what is the specific role of cerebellar LTD in classical eyeblink conditioning, and how does the answer change the view on cerebellar functioning on associative motor learning. The approach used in this thesis is a combination of the above mentioned genetic approach with classical conditioning experiments. The genetic techniques are by far best possible in mice because of their fast breeding and the availability of genetically well characterized inbred strains. Often gene function is tested by creating transgenic or knockout mice. In transgenic mice, artificial DNA is introduced in the genome of a mouse, which will lead to expression of the transgene in the adult animal. In knockout mice a targeted gene is completely deleted from the genome. The protein that was coded by this gene will no longer be expressed. To be able to study the effect of genetic lesions on classical conditioning we needed a system that could reliably measure the performance of a mouse on such a learning task. Some studies using mice in eyeblink conditioning tasks already existed. All these studies used electromyographic (EMG) recordings of the MOO muscle to assess responsiveness on the training paradigm. Attempts to repeat this procedure led to the realization that to obtain reliable EMG recordings of the MOO muscle in a mouse over a number of consecutive days is close to impossible, simply because of the small size of a mouse eyelid. We therefore developed a new system that could reliably measure eyelid position over time in mice. Since it makes use of magnetism we called it the magnetic distance measurement technique (MDMT)
Lack of a bilateral projection of individual spinal neurons to the lateral reticular nucleus in the rat: A retrograde, non-fluorescent, double labeling study
The projection of spinal neurons to the lateral reticular nucleus of the rat was investigated with a non-fluorescent double retrograde tracing technique. Either a gold-lectin tracer or cholera toxin-b-subunit was injected into the lateral reticular nucleus on each side of the brain. Retrogradely labeled neurons were encountered bilaterally throughout the spinal cord. Double labeled neurons, however, were seldom seen (< 2% of the total number of labeled neurons) and those that were could, at least partly, be ascribed to inadvertent labeling of passing fibers. It is concluded that most spinoreticular neurons project to either the ipsi- or contralateral lateral reticular nucleus, suggesting that each side receives a unique spinal input
Association between dendritic lamellar bodies and complex spike synchrony in the olivocerebellar system
Dendritic lamellar bodies have been reported to be associated with
dendrodendritic gap junctions. In the present study we investigated this
association at both the morphological and electrophysiological level in
the olivocerebellar system. Because cerebellar GABAergic terminals are
apposed to olivary dendrites coupled by gap junctions, and because lesions
of cerebellar nuclei influence the coupling between neurons in the
inferior olive, we postulated that if lamellar bodies and gap junctions
are related, then the densities of both structures will change together
when the cerebellar input is removed. Lesions of the cerebellar nuclei in
rats and rabbits resulted in a reduction of the density of lamellar
bodies, the number of lamellae per lamellar body, and the density of gap
junctions in the inferior olive, whereas the number of olivary neurons was
not significantly reduced. The association between lamellar bodies and
electrotonic coupling was evaluated electrophysiologically in alert
rabbits by comparing the occurrence of complex spike synchrony in
different Purkinje cell zones of the flocculus that receive their climbing
fibers from olivary subnuclei with different densities of lamellar bodies.
The complex spike synchrony of Purkinje cell pairs, that receive their
climbing fibers from an olivary subnucleus with a high density of lamellar
bodies, was significantly higher than that of Purkinje cells, that receive
their climbing fibers from a subnucleus with a low density of lamellar
bodies. To investigate whether the complex spike synchrony is related to a
possible synchrony between simple spikes, we recorded simultaneously the
complex spike and simple spike responses of Purkinje cell pairs during
natural visual stimulation. Synchronous simple spike responses did occur,
and this synchrony tended to increase as the synchrony between the complex
spikes increased. This relation raises the possibility that synchronously
activated climbing fibers evoke their effects in part via the simple spike
response of Purkinje cells. The present results indicate that dendritic
lamellar bodies and dendrodendritic gap junctions can be downregulated
concomitantly, and that the density of lamellar bodies in different
olivary subdivisions is correlated with the degree of synchrony of their
climbing fiber activity. Therefore these data support the hypothesis that
dendritic lamellar bodies can be associated with dendrodendritic gap
junctions. Considering that the density of dedritic lamellar bodies in the
inferior olive is higher than in any other area of the brain, this
conclusion implies that electrotonic coupling is important for the
function of the olivocerebellar system
Monitoring kinetic and frequency-domain properties of eyelid responses in mice with magnetic distance measurement technique
Classical eye-blink conditioning in mutant mice can be used to study the
molecular mechanisms underlying associative learning. To measure the
kinetic and frequency domain properties of conditioned (tone - periorbital
shock procedure) and unconditioned eyelid responses in freely moving mice,
we developed a method that allows adequate, absolute, and continuous
determination of their eyelid movements in time and space while using an
electrical shock as the unconditioned stimulus. The basic principle is to
generate a local magnetic field that moves with the animal and that is
picked up by either a field-sensitive chip or coil. With the use of this
magnetic distance measurement technique (MDMT), but not with the use of
electromyographic recordings, we were able to measure mean latency, peak
amplitude, velocity, and acceleration of unconditioned eyelid responses,
which equaled 7.9 +/- 0.2 ms, 1.2 +/- 0.02 mm, 28.5 +/- 1 mm/s, and 637
+/- 22 mm/s(2), respectively (means +/- SD). During conditioning, the mice
reached an average of 78% of conditioned responses over four training
sessions, while animals that were subjected to randomly paired conditioned
and unconditioned stimuli showed no significant increases. The mean
latency of the conditioned responses decreased from 222 +/- 40 ms in
session 2 to 127 +/- 6 ms in session 4, while their mean peak latency
increased from 321 +/- 45 to 416 +/- 67 ms. The mean peak amplitudes, peak
velocities, and peak acceleration of these responses increased from 0.62
+/- 0.02 to 0.77 +/- 0.02 mm, from 3.9 +/- 0.3 to 7.7 +/- 0.5 mm/s, and
from 81 +/- 7 to 139 +/- 10 mm/s(2), respectively. Power spectra of
acceleration records illustrated that both the unconditioned and
conditioned responses of mice had oscillatory properties with a dominant
peak frequency close to 25 Hz that was not dependent on training session,
interstimulus interval, or response size. These data show that MDMT can be
used to measure the kinetics and frequency domain properties of
conditioned eyelid responses in mice and that these properties follow the
dynamic characteristics of other mammals
Evolving Models of Pavlovian Conditioning: Cerebellar Cortical Dynamics in Awake Behaving Mice
Three decades of electrophysiological research on cerebellar cortical activity underlying Pavlovian conditioning have expanded our understanding of motor learning in the brain. Purkinje cell simple spike suppression is considered to be crucial in the expression of conditional blink responses (CRs). However, trial-by-trial quantification of this link in awake behaving animals is lacking, and current hypotheses regarding the underlying plasticity mechanisms have diverged from the classical parallel fiber one to the Purkinje cell synapse LTD hypothesis. Here, we establish that acquired simple spike suppression, acquired conditioned stimulus (CS)-related complex spike responses, and molecular layer interneuron (MLI) activity predict the expression of CRs on a trial-by-trial basis using awake behaving mice. Additionally, we show that two independent transgenic mouse mutants with impaired MLI function exhibit motor learning deficits. Our findings suggest multiple cerebellar cortical plasticity mechanisms underlying simple spike suppression, and they implicate the broader involvement of the olivocerebellar module within the interstimulus interval. Purkinje cell simple spike suppression is a central driving mechanism in cerebellar conditioning. Here, ten Brinke etal. show how simple spike suppression, conditioned stimulus-related complex spikes, and molecular layer interneuron (MLI) activity correlate to conditioned eyelid behavior. Moreover, transgenic impairment of MLI input results in deficits in conditioned behavior
Functional Ultrasound (fUS) During Awake Brain Surgery: The Clinical Potential of Intra-Operative Functional and Vascular Brain Mapping
Background and Purpose: Oncological neurosurgery relies heavily on making continuous, intra-operative tumor-brain delineations based on image-guidance. Limitations of currently available imaging techniques call for the development of real-time image-guided resection tools, which allow for reliable functional and anatomical information in an intra-operative setting. Functional ultrasound (fUS), is a new mobile neuro-imaging tool with unprecedented spatiotemporal resolution, which allows for the detection of small changes in blood dynamics that reflect changes in metabolic activity of activated neurons through neurovascular coupling. We have applied fUS during conventional awake brain surgery to determine its clinical potential for both intra-operative functional and vascular brain mapping, with the ultimate aim of achieving maximum safe tumor resection. Methods: During awake brain surgery, fUS was used to image tumor vasculature and task-evoked brain activation with electrocortical stimulation mapping (ESM) as a gold standard. For functional imaging, patients were presented with motor, language or visual tasks, while the probe was placed over (ESM-defined) functional brain areas. For tumor vascular imaging, tumor tissue (pre-resection) and tumor resection cavity (post-resection) were imaged by moving the hand-held probe along a continuous trajectory over the regions of interest. Results: A total of 10 patients were included, with predominantly intra-parenchymal frontal and temporal lobe tumors of both low and higher histopathological grades. fUS was able to detect (ESM-defined) functional areas deep inside the brain for a range of functional tasks including language processing. Brain tissue could be imaged at a spatial and temporal resolution of 300 μm and 1.5–2.0 ms respectively, revealing real-time tumor-specific, and healthy vascular characteristics. Conclusion: The current study presents the potential of applying fUS during awake brain surgery. We i
Cerebellar potentiation and learning a whisker-based object localization task with a time response window
Whisker-based object localization requires activation and plasticity of somatosensory and motor cortex. These parts of the cerebral cortex receive strong projections from the cerebellum via the thalamus, but it is unclear whether and to what extent cerebellar processing may contribute to such a sensorimotor task. Here, we subjected knock-out mice, which suffer from impaired intrinsic plasticity in their Purkinje cells and long-term potentiation at their parallel fiber-to-Purkinje cell synapses (L7-PP2B), to an object localization task with a time response window (RW). Water-deprived animals had to learn to localize an object with their whiskers, and based upon this location they were trained to lick within a particular period ("go" trial) or refrain from licking ("no-go" trial). L7-PP2B mice were not ataxic and showed proper basic motor performance during whisking and licking, but were severely impaired in learning this task compared with wild-type littermates. Significantly fewer L7-PP2B mice were able to learn the task at long RWs. Those L7-PP2B mice that eventually learned the task made unstable progress, were significantly slower in learning, and showed deficiencies in temporal tuning. These differences became greater as theRWbecame narrower. Trained wild-type mice, but not L7-PP2B mice, showed a net increase in simple spikes and complex spikes of their Purkinje cells during the task. We conclude that cerebellar processing, and potentiation in particular, can contribute to learning a whisker-based object localization task when timing is relevant. This study points toward a relevant role of cerebellum- cerebrum interaction in a sophisticated cognitive task requiring strict temporal processing
Cerebellar control of gait and interlimb coordination
Synaptic and intrinsic processing in Purkinje cells, interneurons and granule cells of the cerebellar cortex have been shown to underlie various relatively simple, single-joint, reflex types of motor learning, including eyeblink conditioning and adaptation of the vestibulo-ocular reflex. However, to what extent these processes contribute to more complex, multi-joint motor behaviors, such as locomotion performance and adaptation during obstacle crossing, is not well understood. Here, we investigated these functions using the Erasmus Ladder in cell-specific mouse mutant lines that suffer from impaired Purkinje cell output (Pcd), Purkinje cell potentiation (L7-Pp2b), molecular layer interneuron output (L7-Δγ2), and granule cell output (α6-Cacna1a). We found that locomotion performance was severely impaired with small steps and long step times in Pcd and L7-Pp2b mice, whereas it was mildly altered in L7-Δγ2 and not significantly affected in α6-Cacna1a mice. Locomotion adaptation triggered by pairing obstacle appearances with preceding tones at fixed time intervals was impaired in all four mouse lines, in that they all showed inaccurate and inconsistent adaptive walking patterns. Furthermore, all mutants exhibited altered front–hind and left–right interlimb coordination during both performance and adaptation, and inconsistent walking stepping patterns while crossing obstacles. Instead, motivation and avoidance behavior were not compromised in any of the mutants during the Erasmus Ladder task. Our findings indicate that cell type-specific abnormalities in cerebellar microcircuitry can translate into pronounced impairments in locomotion performance and adaptation as well as interlimb coordination, highlighting the general role of the cerebellar cortex in spatiotemporal control of complex multi-joint movements
Spinal Autofluorescent Flavoprotein Imaging in a Rat Model of Nerve Injury-Induced Pain and the Effect of Spinal Cord Stimulation
Nerve injury may cause neuropathic pain, which involves hyperexcitability of spinal dorsal horn neurons. The mechanisms of action of spinal cord stimulation (SCS), an established treatment for intractable neuropathic pain, are only partially understood. We used Autofluorescent Flavoprotein Imaging (AFI) to study changes in spinal dorsal horn metabolic activity. In the Seltzer model of nerve-injury induced pain, hypersensitivity was confirmed using the von Frey and hotplate test. 14 Days after nerve-injury, rats were anesthetized, a bipolar electrode was placed around the affected sciatic nerve and the spinal cord was exposed by a laminectomy at T13. AFI recordings were obtained in neuropathic rats and a control group of naýve rats following 10 seconds of electrical stimulation of the sciatic nerve at C-fiber strength, or following non-noxious palpation. Neuropathic rats were then treated with 30 minutes of SCS or sham stimulation and AFI recordings were obtained for up to 60 minutes after cessation of SCS/sham. Although AFI responses to noxious electrical stimulation were similar in neuropathic and naýve rats, only neuropathic rats demonstrated an AFI-response to palpation. Secondly, an immediate, short-lasting, but strong reduction in AFI intensity and area of excitation occurred following SCS, but not following sham stimulation. Our data confirm that AFI can be used to directly visualize changes in spinal metabolic activity following nerve injury and they imply that SCS acts through rapid modulation of nociceptive processing at the spinal level
Axonal sprouting and formation of terminals in the adult cerebellum during associative motor learning
Plastic changes in the efficacy of synapses are widely regarded to represent mechanisms underlying memory formation. So far, evidence for learning-dependent, new neuronal wiring is limited. In this study, we demonstrate that pavlovian eyeblink conditioning in adult mice can induce robust axonal growth and synapse formation in the cerebellar nuclei. This de novo wiring is both condition specific and region specific because it does not occur in pseudoconditioned animals and is particularly observed in those parts of the cerebellar nuclei that have been implicated to be involved in this form of motor learning. Moreover, the number of new mossy fiber varicosities in these parts of the cerebellar nuclei is positively correlated with the amplitude of conditioned eyelid responses. These results indicate that outgrowth of axons and concomitant occurrence of new terminals may, in addition to plasticity of synaptic efficacy, contribute to the formation of memory