Neural cell adhesion molecule (NCAM-/-) null mice show impaired sensitization of the startle response.

The neural cell adhesion molecule (NCAM) plays important roles in development of the nervous system and in synaptic plasticity and memory formation in the adult. The present study sought to further investigate the role of NCAM in learning by testing habituation and footshock sensitization learning of the startle response (SR) in NCAM null mutant (NCAM-/-) and wildtype littermate (NCAM+/+) mice. Whereas habituation is a form of non-associative learning, footshock sensitization is induced by rapid contextual fear conditioning. Habituation was tested by repetitive presentation of acoustic and tactile startle stimuli. Although NCAM-/- mice showed differences in sensitivity in both stimulus modalities, habituation learning was intact in NCAM-/- mice, suggesting that NCAM does not play a role in the mechanisms underlying synaptic plasticity in the startle pathway. Footshock sensitization was elicited by presentation of electric footshocks between two series of acoustic stimuli. In contrast to habituation, footshock sensitization learning was attenuated in NCAM-/- mice: the acoustic SR increase after the footshocks was lower in the mutant than in wildtype mice, indicating that NCAM plays an important role in the relevant brain areas, such as amygdala and/or the hippocampus.

Difference in anxiety and sensitization of the acoustic startle response between the two inbred mouse strains BALB/cAN and DBA/2N.

The inbred mouse strain BALB has been proposed to be an animal model for pathological anxiety. BALB exhibits a stronger acoustic startle response (ASR) than the 'less emotional' inbred strain DBA. Four experiments were conducted to determine whether this strong ASR is due to a higher anxiety level and/or to greater sensitization in BALB than in DBA, with the following results: (1) The ASR to the very first startle stimulus was found to be much stronger in BALB than in DBA, and freezing behavior evoked by startle stimuli was more pronounced in BALB than in DBA. These findings indicate a higher level of anxiety in this strain. (2) ASR amplitudes of BALB initially rose much higher during consecutive startle stimuli and remained at a high level much longer than in DBA. Thereafter, ASR amplitude dropped more slowly and to a lesser degree than in DBA. Startle amplitudes decreased similarly in both strains (strong exponential decrease) only when a low sound pressure level (SPL) was used which elicited approximately the same low ASR in both strains. These results can only be explained by increased sensitization in BALB. (3) The slope of the i/o-function, which represents the relation between sensory input and motor output, was steeper in BALB than in DBA. As it has been shown recently, sensitization increases the slope of the startle i/o-function indicating increased sensitization in BALB. It is discussed, however, whether anxiety also contributes to this effect. (4) Footshocks increased the ASR much less in BALB than in DBA, again showing increased sensitization in BALB. Both a higher level of anxiety and greater sensitization therefore determined the greater strength of the ASR in BALB than in DBA.

The acoustic startle response as an effective model for elucidating the effect of genes on the neural mechanism of behavior in mice.

One current approach in investigating the neural basis of behavior is to use mutant mice with specific genetic alterations which affect neural functions. We are convinced that this approach is only effective if a behavioral model with sufficiently known underlying neuronal mechanisms is used. We present a model system which is well-suited for the above approach. Because the neural basis is known in great detail, in the startle system behavioral results can be very well interpreted. This is demonstrated here by using footshock sensitization of the acoustic startle response (ASR) as an example. Sensitization is elicited by aversive stimuli such as electric footshocks and causes an increase in ASR amplitude. The present experiment showed that this ASR increase is not due to a drop in the startle threshold but to increased gain in the response to suprathreshold stimuli. This makes it possible to draw conclusions about the neuronal site of the startle threshold in the startle pathway and the synapse at which the gain shift during sensitization occurs. The possibility of interpreting behavioral output on a well known neural basis (as demonstrated here) makes the ASR a promising model system for investigating (neuro-) genetic influences of behavior.

Increased sensitization of acoustic startle response in spasmodic mice with a mutation of the glycine receptor alpha1-subunit gene.

The spontaneous mutant mouse spasmodic (spd) carries a missense mutation affecting the glycine receptor alpha1-subunit gene. This results in a decreased binding affinity to glycine. Spd mutants show exaggerated acoustic startle responses (ASR). The present study sought to elucidate whether this increased ASR is due to a changed auditory processing or to stronger motor output resulting from a disinhibited motor system or, alternatively, to changes in modulatory influences on the startle pathway, namely in the mechanisms underlying habituation and sensitization. We found that in homozygous spd/spd mutants the startle threshold was lower, and the recorded slope of input/output (i/o) function, which reflects the relation between sensory input and motor output, was steeper. During repetitive presentation of high sound pressure level (SPL) startle stimuli (25 dB above startle threshold), ASR amplitudes did not decrease in spd/spd mutants as they do in the wildtype. In contrast, ASR amplitudes decreased when low SPL startle stimuli were presented. Footshocks presented after high SPL startle stimuli did not cause a further increase in ASR amplitudes of spd/spd mutants as in the wildtype. In heterozygous spd/+ mutants all these parameters were between those of spd/spd mutants and wildtype mice but closer to those of the wildtype. The steeper slope of i/o function in spd/spd mutants may be caused by both an increased sensory input and an increased motor output. The altered course of ASR amplitudes during repetitive stimulation and the deficit in additional footshock sensitization, however, can only be explained by an increased sensitization level in the spd/spd mutants. In accordance with the "dual process theory" strong sensitization evoked by high SPL startle stimuli supposedly counteracts habituation, leading to a constant high ASR amplitude. Furthermore, additional footshock sensitization is prevented. The increased sensitization level may be due to a change in auditory processing leading to a stronger sensitizing effect of the startle stimuli with high SPL. Alternatively, glycinergic tonic inhibition of sensitizing structures (e.g. the amygdala) in the wildtype may be diminished in spd/spd mutants, thus leading to a high sensitization level.

The superior olivary complex is necessary for the full expression of the acoustic but not tactile startle response in rats.

The acoustic startle response (ASR) in rats is mediated by an oligosynaptic pathway from the cochlea via the brainstem to spinal and cranial motoneurons. The present study tested whether the superior olivary complex (SOC) plays a role in the mediation of the ASR. The SOC receives auditory information from the ventral cochlear nuclei and projects to the caudal pontine reticular nucleus (PnC), the sensorimotor interface of the ASR. Axon-sparing excitotoxic lesions of the SOC strongly reduced the ASR amplitude and slightly prolonged ASR onset and peak latencies. The integrity of PnC which is adjacent to the SOC was confirmed by testing the tactile startle response which was not affected by SOC lesions. We suggest that the SOC is necessary for a full expression of the ASR and discuss possible auditory input structures involved in the mediation of the ASR.

Interaction between acoustic and electric sensitization of the acoustic startle response in rats.

Sensitization is the general increase of responsiveness observed after aversive stimulation. Usually footshocks are used as aversive stimuli. According to the 'Dual Process Theory' by Groves and Thompson. Psychol. Rev. 1970;77:419-450, not only additional aversive stimuli but also the response-eliciting stimuli themselves have a sensitizing effect, the degree of sensitization depending upon the stimulus intensity. We tested this suggestion in the footshock sensitization paradigm of the acoustic startle response (ASR): (1) High SPL (sound pressure level) acoustic stimuli (119 dB SPL) presented instead of footshocks also elicited strong sensitization. (2) While footshocks presented after startle stimuli with low SPL (95 dB) were able to produce a strong further sensitization of the ASR, footshocks presented after startle stimuli with high SPL (110 dB) only caused a minor sensitization of the ASR. (3) Diazepam (3 mg/kg i.p.) decreased ASR to high SPL (115 dB) stimuli. In this case footshocks elicited significant sensitization of the ASR despite intense startle stimuli. The present results support the 'Dual Process Theory'. Furthermore we could show that acoustic and footshock sensitization interact. We therefore suggest that both, acoustic and footshock sensitization, are mediated partly via the same neural circuitry.

Comparison of two sensitization paradigms of the acoustic startle response in Wistar and Sprague-Dawley rats.

An increase in general responsiveness after aversive stimulation has provided a most widely accepted and well-understood sensitization paradigm. According to a second paradigm (based on the dual process theory of habituation and sensitization), not only additional aversive stimuli, but also the response-eliciting stimuli themselves, induce sensitization. To relate these two sensitization paradigms, we compared the course of startle response parameters during repetitive acoustic stimulation with the change in startle amplitude after electric footshocks in outbred Wistar and Sprague-Dawley rats. Compared to the Wistar rats used, the Sprague-Dawley rats showed a lower response decrement and a shortened latency during repetitive stimulation, both of which are indicators of increased sensitization by the startle-eliciting stimuli. In addition, the Sprague-Dawley rats also demonstrated a reduced increase in startle amplitude following footshock. This was postulated to be a consequence of the strong sensitization by startle-eliciting stimuli, which interferes with sensitization elicited by footshock. Because our Wistar and Sprague-Dawley rats did not differ in initial startle amplitude, but mainly in susceptibility to sensitization, further comparisons of these genetically different stocks of rats seem to be of potential value in studying differences in fear-motivated behavior.

Effect of the middle ear reflex on sound transmission to the inner ear of rat.

The effect of the acoustic middle ear reflex (MER) was quantified using electrodes chronically implanted in the middle ears of rats. Cochlear microphonics (CM) and middle ear muscle EMG were measured under light Ketamin anesthesia after stimulation with tone pulses of 5-20 kHz ranging between 75 and 120 dB SPL. With increasing intensity, the CM measured before the onset of the MER increased to a maximum amplitude and then decreased with higher SPLs. At 10 kHz this maximum was reached at 95 dB SPL, for other stimulus frequencies at higher SPLs. After a latency of 10-20 ms, CM to 10 kHz stimuli of 80-95 dB SPL were decreased by the attenuating action of the MER. The lowest threshold of the MER was also measured at 10 kHz (77 dB SPL in the mean). To stimuli greater than 100 dB SPL after a latency of 6-10 ms, the CM amplitude was increased. That this CM increase to intense stimuli is caused by the action of the MER was confirmed by control experiments such as cutting the tendons of the middle ear muscles. The CM decrease to stimuli below 100 dB SPL, as well as the increase to very intense stimuli, can be explained by sound attenuation caused by the MER, together with the nonlinear dependence of CM amplitude on stimulus level. The observed shift of the maxima of the CM input-output function by the MER to higher stimulus levels probably indicates an increase of the dynamic range of the ear.

The acoustic startle response in inbred Roman high- and low-avoidance rats.

To investigate the emotional reactions of two rat strains selectively bred for good and poor two-way avoidance acquisition (RHA/Verh and RLA/Verh), male animals of both strains were tested in an acoustic startle response test. They received 40 acoustic stimuli followed by 10 electric foot shocks and another 30 acoustic stimuli. RLA/Verh rats showed a significantly higher startle response compared to RHA/Verh animals, indicating a stronger emotional reaction to acoustic stimuli. In addition, the former showed a stronger response to foot shocks. Combined with earlier findings, we conclude that selection for two-way avoidance learning does not result in cognitive defects in the RLA/Verh strain but, rather, in stronger emotional reactions to fearful stimuli.

Lesions of the amygdala do not affect the enhancement of the acoustic startle response by background noise.

The acoustic startle response (ASR) is enhanced in the presence of loud background noise. We examined whether or not this increase of response strength is mediated by the amygdala, which is known to be involved in various phenomena of enhancement of the ASR. To achieve this aim, we tested whether or not amygdaloid lesions with the excitotoxin N-methyl-D-aspartate (NMDA) would abolish the enhancement of the ASR by background noise in 13 Wistar rats. Loss of foot-shock sensitization in these rats, as well as histological evaluation, proved the successful destruction of the amygdala. However, the enhancement by background noise of the ASR, which was observed in sham-operated controls, was not affected in amygdala-lesioned rats. Therefore, we conclude that the background noise facilitation does not involve emotional components that are mediated by the amygdala. On the basis of these findings, we differentiate between the startle-enhancing effect of background noise and the amygdala-mediated effect of foot shocks on the ASR.

Habituation and sensitization of the acoustic startle response in rats: amplitude, threshold, and latency measures.

The amplitude of the acoustic startle response habituates to repetitive stimulation. The input and output of the startle system were measured to determine if the decrease in startle amplitude during repetitive stimulation is due to an increase in the startle threshold. Two experimental approaches were used in 35 Sprague-Dawley rats to probe the relationship between the input (the sound pressure level of the stimulus) and the behavioral output (startle amplitude). The results show that the minimum threshold for a response does not change during habituation; rather, the slope of the dependence of startle amplitude on stimulus level decreases. Because habituation does not influence startle threshold we propose that the site for habituation is located in the neural circuitry downstream from the site for startle threshold. Besides amplitude and threshold, as an additional parameter we measured startle latency. In general, the latency of the acoustic startle response is negatively correlated with the response amplitude. This correlation has been repeatedly shown, therefore one would expect a latency increase during the amplitude decrease caused by habituation. However, the latency of the startle reaction also decreased during the course of repetitive stimulation. According to the dual process theory of habituation, a stimulus has both a response-decreasing, i. e., habituating, as well as a response-increasing, i.e., sensitizing, influence on a behavior (Groves & Thompson, 1970). Our explanation of the present results is that startle amplitude is reduced following repetitive stimulation because it is mainly influenced by habituation; latency, however, is shortened because it is mainly influenced by sensitization.

Frequency of the 22 kHz call of rats is modulated by the rhythm of the heart rate.

The 22 kHz calls of rats are rhythmically frequency modulated. To test whether these modulations are correlated with the action of the heart, ECG was chronically registered in 16 male Wistar rats. In 11 rats loud acoustic stimuli provoked emission of the long calls or 22 kHz calls. In 10 self-vocalizing rats, we observed small frequency modulations (SFMs) in the constant frequency component of these calls. On the average, 7 ms after the R-peak of the ECG the call frequency is lowered by 151 Hz. The heart rate and the rate of the SFMs are highly correlated (r = 0.997). Further, we show that the SFMs are produced by a reduction of call amplitude. The comparison with the course of the blood pressure in rats suggests that this change in call amplitude is caused by the blood pressure change during the action of the heart. Measuring SFMs offers a noninvasive way to determine the heart rate in vocalizing rats.

Acoustic startle response and habituation in freezing and nonfreezing rats.

Rats can be divided according to their responses to startle-eliciting stimuli into 2 groups with different emotional states. About half of the 54 female Sprague-Dawley rats showed long-lasting freezing behavior after 1-8 stimuli (10 kHz, 110 dB spl). In freezing rats the startle amplitude was higher than in nonfreezing rats, even on the very first startle response. This finding demonstrates that the anxiety state of these animals before the first startle-eliciting stimulus, and not just the aversiveness of the stimulus, contributes to freezing behavior. In addition, in freezing rats there was no influence of spontaneous motor activity or of adaptation time on startle amplitude. Only in nonfreezing rats were high motor activities correlated with lowered startle amplitudes, and only in these rats did the course of startle habituation depend on adaptation time.

Loss of the acoustic startle response following neurotoxic lesions of the caudal pontine reticular formation: possible role of giant neurons.

The effect of the excitotoxic N-methyl-D-aspartate agonist quinolinic acid in the caudal pontine reticular formation on the acoustic startle response was investigated in rats. Bilateral injections of 90 nmol of quinolinic acid led to large lesions in the reticular formation characterized by the loss of all neurons and a marked reduction or even abolition of the acoustic startle response; 18 nmol of quinolinic acid led to smaller lesions characterized by a selective loss of giant neurons within the caudal pontine reticular formation and a reduction of the startle amplitude. The partial correlation analysis revealed that the reduction of the amplitude of the acoustic startle response can be correlated with the loss of the giant neurons (r = 0.575; d.f. = 29; P less than 0.001) but not with the reduction of the number of all neurons (r = 0.207; d.f. = 29; P greater than 0.2) in the caudal pontine reticular formation. These findings were reconciled with electrophysiological and anatomical data indicating that the giant neurons in the caudal pontine reticular formation receive acoustic input and project to motoneurons of the spinal cord. It is concluded that the caudal pontine reticular formation is an important element of the startle pathway and that the giant reticulospinal neurons constitute an important part of the sensorimotor interface mediating this response.

Startle responses measured in muscles innervated by facial and trigeminal nerves show common modulation.

Electromyographic (EMG) potentials of several head muscles were recorded simultaneously in freely moving rats with chronically implanted electrodes. The startle responses of m. temporalis, m. levator auris, and m. levator labii superior were compared. All muscles showed a parallel decrease in latency and an increase in response elicitability and amplitude with an increase in stimulus intensity. A significant latency difference of about 1 ms existed between m. levator auris and m. temporalis. The shortest latency of the EMG response in m. levator auris was 5.5 ms (110 dB SPL). A common fluctuation in response amplitude and latency was found in simultaneous recordings of muscles innervated by the facial and trigeminal nerve, respectively. This shows a common modulatory input to the startle pathway to the cranial motor nuclei.

Comparative threshold studies of the acoustic pinna, jaw and startle reflex in the rat.

Electromyograms of M. Levator auris and M. Temporalis and movement produced by whole body startle were recorded simultaneously in awake, freely moving rats. Thresholds were 78 db SPL for the L. auris, 80 dB SPL for the ballistic and 81 dB SPL for the Temporalis. The rank ordering of the three thresholds was extremely strict, 188 suprathreshold M. L. auris responses could be observed without M. Temporalis responses, but only once was a M. Temporalis response observed without a M. L. auris response. Thresholds as well as amplitudes and latencies measured by the different methods show correlated fluctuations. While the rise in amplitude which accompanies increasing stimulus intensity is similar in the three measures, the latency decrease is not. The latency difference between M. Temporalis EMG and M. L. auris EMG is intensity dependent, increasing from 0 msec at 78 dB SPL to 1.1 msec at 115 dB SPL, with a faster response for the M. L. auris.

Acoustic startle threshold of the albino rat (Rattus norvegicus).

The startle threshold of the albino Sprague-Dawley rat runs parallel to the curve of the hearing threshold. The difference between the startle and hearing threshold is 87 dB (SPL) at a background noise level of 75 dB (SPL). At 110 dB (SPL), the threshold has a range from 2 kHz to 50 kHz with a minimum at 10 kHz and a second minimum at 40 kHz. Amplitude and latency of the startle response are not only dependent on the sensation level of the acoustic stimulus but also on the frequency. At threshold, only the head movement component of the startle response is elicited.