ORIGINAL RESEARCH ARTICLE
published: 25 July 2014

doi: 10.3389/fnins.2014.00216

Origin and function of short-latency inputs to the neural
substrates underlying the acoustic startle reflex
Ricardo Gómez-Nieto1,2,3, José de Anchieta C. Horta-Júnior1,4, Orlando Castellano1,2,3,

Lymarie Millian-Morell 1,3, Maria E. Rubio5 and Dolores E. López1,2,3*

1 Neuroscience Institute of Castilla y León, University of Salamanca, Salamanca, Spain
2 Department of Cell Biology and Pathology, University of Salamanca, Salamanca, Spain
3 Institute of Biomedical Research of Salamanca (IBSAL), University of Salamanca, Salamanca, Spain
4 Department of Anatomy, Biosciences Institute, São Paulo State University Botucatu, São Paulo, Brazil
5 Department of Otolaryngology, University of Pittsburgh, Pittsburgh, PA, USA

Edited by:

Monica Munoz-Lopez, University of
Castilla-La Mancha, Spain

Reviewed by:

Alicia Mohedano-Moriano,
University of Castilla-La Mancha,
Spain
Antonio Viñuela, SECUGEN SL,
Spain

*Correspondence:

Dolores E. López, Neuroscience
Institute of Castilla y León,
University of Salamanca, C/Pintor
Fernando Gallego, 1, 37007
Salamanca, Spain
e-mail: lopezde@usal.es

The acoustic startle reflex (ASR) is a survival mechanism of alarm, which rapidly alerts
the organism to a sudden loud auditory stimulus. In rats, the primary ASR circuit
encompasses three serially connected structures: cochlear root neurons (CRNs), neurons
in the caudal pontine reticular nucleus (PnC), and motoneurons in the medulla and spinal
cord. It is well-established that both CRNs and PnC neurons receive short-latency auditory
inputs to mediate the ASR. Here, we investigated the anatomical origin and functional
role of these inputs using a multidisciplinary approach that combines morphological,
electrophysiological and behavioral techniques. Anterograde tracer injections into the
cochlea suggest that CRNs somata and dendrites receive inputs depending, respectively,
on their basal or apical cochlear origin. Confocal colocalization experiments demonstrated
that these cochlear inputs are immunopositive for the vesicular glutamate transporter 1
(VGLUT1). Using extracellular recordings in vivo followed by subsequent tracer injections,
we investigated the response of PnC neurons after contra-, ipsi-, and bilateral acoustic
stimulation and identified the source of their auditory afferents. Our results showed
that the binaural firing rate of PnC neurons was higher than the monaural, exhibiting
higher spike discharges with contralateral than ipsilateral acoustic stimulations. Our
histological analysis confirmed the CRNs as the principal source of short-latency acoustic
inputs, and indicated that other areas of the cochlear nucleus complex are not likely
to innervate PnC. Behaviorally, we observed a strong reduction of ASR amplitude in
monaural earplugged rats that corresponds with the binaural summation process shown
in our electrophysiological findings. Our study contributes to understand better the role of
neuronal mechanisms in auditory alerting behaviors and provides strong evidence that the
CRNs-PnC pathway mediates fast neurotransmission and binaural summation of the ASR.

Keywords: alertness system, binaural summation, cochlear root neurons, extracellular recordings, neuronal

tracers, pontine reticular formation, rat, vglut1-auditory nerve

INTRODUCTION
The acoustic startle reflex (ASR) is a survival mechanism of alarm,
which rapidly alerts and arouses organisms to a sudden loud audi-
tory stimulus. Behaviorally, the ASR involves a rapid and sequen-
tial activation of muscles along the length of the body as well as
an autonomic physiological response (Prosser and Hunter, 1936;
Szabo, 1964; Hoffman and Ison, 1980). The ASR and its modula-
tions, which are sensible to a variety of experimental approaches,
can be easily tested in humans and rodents (Braff and Geyer, 1990;
Lehmann et al., 1999). Thus, the ASR has been consolidated as an
important research tool for studying brain mechanisms of learn-
ing, memory, emotions, sensory gating, and movement control
(Davis and Sheard, 1974; Davis, 1990; Lang et al., 1990; Yeomans
and Frankland, 1996; Koch, 1999; Swerdlow et al., 2001). The rat
is an excellent animal model to study the ASR, and hence, the
neuronal circuits underlying the ASR in rats are of great interest.

It is well established that a relatively simple pathway in the brain-
stem mediates the ASR (Figure 1). The cochlear root neurons
(CRNs), true sentinels of the rodent auditory pathway, are the
first brainstem neurons receiving direct input from spiral gan-
glion cells (Harrison et al., 1962; Merchán et al., 1988; Osen et al.,
1991; López et al., 1993, 1999). Collectively, they comprise the
so-called cochlear root nucleus, and are morphologically charac-
terized by their large cell body and thick dendrites that distribute
among the eighth nerve fibers (Merchán et al., 1988; López et al.,
1993). The thick myelinated axons of CRNs course through the
trapezoid body (TB) to innervate neurons in the caudal pontine
reticular nucleus (PnC) on both sides of the brainstem, with a
clear contralateral predominance (López et al., 1999; Nodal and
López, 2003). Finally, the acoustically driven PnC neurons project
to facial, cranial and spinal motoneurons that rapidly activate
the muscle contractions (Lingenhöhl and Friauf, 1994; Lee et al.,

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FIGURE 1 | Schematic drawing of the primary acoustic startle reflex in

the rat brainstem based on the referred studies. First, a sudden loud
sound activates the auditory receptors in the cochlea. Next, auditory nerve
fibers synapse cochlear root neurons (CRNs) which exhibit a secure
response with first-spike latencies of approximately 2.2 ms (López et al.,
1999; Sinex et al., 2001; Gómez-Nieto et al., 2010, 2013). This short-latency
acoustic input is rapidly conducted to giant neurons in the pontine reticular
formation (PnC) which respond with short-latencies of 5.2 ms (Lingenhöhl
and Friauf, 1994; Lee et al., 1996; López et al., 1999). Finally, the
acoustically driven PnC neurons send axons that contact motoneurons in

the spinal cord to elicit an acoustic startle reflex with electromyographic
latencies of 6–10 ms (Ison et al., 1973; Davis et al., 1982; Caeser et al.,
1989). The line width represents side predominance within the circuit
which is shown in coronal brainstem sections. Notice the axons of CRNs
course through the trapezoid body (TB) to target preferentially contralateral
PnC neurons (López et al., 1999; Nodal and López, 2003). Arrowheads
indicate the flow of acoustic information within the circuit. Projections
from CRNs to other non-auditory nuclei which participate in the full
expression of the acoustic and pinna reflexes are not shown in this
scheme (see details in López et al., 1999; Horta-Júnior et al., 2008).

1996; Yeomans and Frankland, 1996; Koch and Schnitzler, 1997).
The electromiographic latencies of the muscles during the ASR
are extremely short (6–10 ms) (Ison et al., 1973; Davis et al., 1982;
Caeser et al., 1989). Such short-latency motor response is con-
sistent with the neuronal latencies observed in the primary ASR
mediating circuit (Figure 1). Thus, CRNs exhibit a secure elec-
trophysiological response to tone burst, with first-spike latencies
of approximately 2.2 ms (Sinex et al., 2001; Gómez-Nieto et al.,
2010, 2013), and giant PnC neurons that receive acoustic inputs
show first-spike latencies of 5.2 ms (Lingenhöhl and Friauf, 1994).
The main purpose of this study is to reappraise the anatomical
origin of short-latency auditory inputs to CRNs and PnC neu-
rons and investigate whether the CRNs-PnC neuronal pathway
is responsible for the binaural summation that occurs during
the ASR. Although much is currently known about the cochlear
nerve projection to the cochlear root nucleus (Harrison et al.,
1962; Merchán et al., 1988; Osen et al., 1991; López et al., 1993,
1999), the neuroanatomical and neurochemical mechanisms by
which CRNs integrate fast and frequency-specific acoustic infor-
mation has not been clearly established. The rats are extremely
sensitive to high frequency sounds, and the amplitude of the
ASR depends on sound features such as intensity, duration and

frequency (Gourevitch and Hack, 1966; Błaszczyk and Tajchert,
1997). Since the characteristic frequency of CRNs is approxi-
mately 30 kHz (Sinex et al., 2001; Gómez-Nieto et al., 2013),
we aimed to determine whether auditory nerve afferents tono-
topically innervate CRNs. The primary auditory afferents use
glutamate as neurotransmitter (Hackney et al., 1996; Furness and
Lawton, 2003; Rubio and Juiz, 2004) and their endings contain
the vesicular glutamate transporter 1 (VGLUT1) as it has shown
in other areas of the cochlear nucleus complex (Zhou et al.,
2007; Gómez-Nieto and Rubio, 2009). Here, we demonstrated
that VGLUT1 is also associated with auditory nerve afferents that
terminate onto CRNs, which suggests a fast mechanism of con-
trolling and securing excitatory transmission in the cochlear root
nucleus. Additionally, there are two questions that have been
raised about the primary ASR circuit at the level of the PnC.
One question is whether, in addition to the CRNs, other neuronal
types within the cochlear nucleus complex provide short-latency
acoustic inputs to PnC neurons, as proposed by other researchers
(Davis et al., 1982; Kandler and Herbert, 1991; Lingenhöhl and
Friauf, 1994; Meloni and Davis, 1998). The other question relates
to the neuronal bases underlying the binaural summation of the
startle reflex, which has yet to be elucidated (Marsh et al., 1973;

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Gómez-Nieto et al. New insights into the ASR circuit

Li and Frost, 1996; Yeomans et al., 2002). To address these issues,
we used extracellular recordings in vivo followed by subsequent
tracer injections to investigate the sound evoked responses of PnC
neurons after contra-, ipsi-, and bilateral stimulation, and iden-
tify the source of their auditory afferents. Our electrophysiological
study combined with neuronal tracing indicated the existence of
a binaural summation process in the pontine reticular formation,
and demonstrated that CRNs are the main source of short-latency
acoustic inputs to PnC neurons. Additional anterogradely tracing
experiments were also performed to verify whether neurons of
the dorsal and ventral cochlear nucleus (DCN and VCN, respec-
tively) innervate PnC neurons. Furthermore, we correlated our
electrophysiological findings with changes in the ASR behavioral
performance of monaural earplugged rats. Monaural earplugging
reduces auditory nerve activity and affects processing through
the auditory pathways (Potash and Kelly, 1980). Since the star-
tle depends on normal binaural auditory interaction (reviewed in
Yeomans et al., 2002), we found a reduction of the ASR amplitude
in rats under monaural sound-deprivation conditions, which
was consistent with the PnC neurons’ response to monaural
acoustic stimulation. Our study provides convergent anatomi-
cal, electrophysiological and behavioral evidence for the role of
the CRNs-PnC projection in fast neurotransmission and binaural
summation of the ASR and offers new insights into the structure
and function of the primary ASR neuronal circuit.

MATERIALS AND METHODS
EXPERIMENTAL ANIMALS
In total, 36 adult female Wistar rats (Charles River Laboratories)
weighing 165–320 g were used in this study. The animals
were randomly housed and maintained under normal 12/12 h
light/dark cycle (lights on at 07:00 h) in a temperature -and
humidity-controlled environment. The rats were given ad libitum
access to food and water over the study period. The experiments
were conducted in compliance with the guidelines for the use
and care of laboratory animals of the European Communities
Council Directive (2010/63/EU), the current Spanish legislation
(RD 1201/05), and with those established by the Institutional
Bioethics Committee. All efforts were made to minimize the
number of animals used. For the surgical procedures, the animals
were deeply anesthetized with a mixture of ketamine (40 mg/kg
body weight) and xylazine (7 mg/kg body weight). The suffering
of the animals was minimized during the surgery by monitoring
the depth of anesthesia carefully. Supplementary doses of anes-
thetic were administrated as required to maintain deep anesthesia
throughout the duration of the experiment.

NEUROANATOMICAL EXPERIMENTS: SURGERY, TRACER INJECTIONS,
AND TISSUE PROCESSING
A total of 17 animals were used in the neuroanatomical exper-
iments with the aim of studying the source of acoustic inputs
to CRNs and PnC Neurons. To investigate the distribution of
cochlear nerve inputs on CRNs, 4 rats received anterograde
horseradish peroxidase (HRP, type VI, Sigma, St Louis, MO)
injections into basal and apical regions of the cochlea following
the procedure described by Osen et al. (1991). Once anesthetized,
the tympanic bulla was exposed and a small orifice was made

in the lateral wall of the cochlea at various apico-basal levels.
HRP (20% in distilled water) was pressure-injected through a
glass micropipette for 10–20 min, and a second micropipette was
placed in the oval window for fluid removal. After the wound
was washed and sutured, the animals were allowed to recover for
2 days. In cases with electrophysiological recordings in the right
PnC (see below), we injected the bidirectional tracer, biotinylated
dextran amine (BDA, 10,000 MW; #D-1956; Molecular Probes,
Eugene, OR) to verify the recording site and investigate the source
of cochlear nucleus inputs to PnC neurons. In another set of
experiments, 6 rats received unilaterally injections of BDA into
the left DCN and VCN. All surgical and stereotaxic procedures
for injecting the BDA were identical to that used in our previous
studies (Gómez-Nieto et al., 2008a, 2013; Horta-Júnior et al.,
2008). BDA (10% in distilled water) were injected iontophoret-
ically via a glass micropipette (25 μm tip diameter), with 3 μA
positive current pulses (7 s on/7 s off) for a period of 15 min. The
stereotaxic coordinates for the right PnC was based on previous
reports which studied afferent projections from auditory brain-
stem nuclei into the PnC (Lingenhöhl and Friauf, 1994; Lee et al.,
1996; López et al., 1999; Nodal and López, 2003). The coordi-
nates for the left VCN were precisely the same as those used by
(Gómez-Nieto et al., 2013). All sterotaxic coordinates, including
those for the DCN, were obtained from the atlas of the rat brain
(Paxinos and Watson, 2009), using an electrode angle calibrator
(David Kopf Instruments). After the tracer injection, the scalp was
sutured and the animal was allowed to recover for a minimum of 7
days. Tissue preparation for light microscopy included: perfusion
of the animals, brain dissection and subsequent cryoprotection
with sucrose, freezing and serially slicing at 40 μm thickness along
parasagittal and coronal planes, visualization of HRP and BDA
neurotracers, and calbindin protein-D28K (CaBP) immunohisto-
chemistry. All these techniques were applied in a manner identical
to that used in our previous reports (Osen et al., 1991; López
et al., 1993, 1999; Gómez-Nieto et al., 2008a, 2013). In cases with
HRP injections, we followed a standard immunostaining proto-
col to visualize CaBP as described by Gómez-Nieto et al. (2008a).
CaBP immunoreactivity has been extensively utilized for detect-
ing the cell body and dendrites of the CRNs (López et al., 1993;
Gómez-Nieto et al., 2008a, 2013). Thus, nickel-intensified per-
oxidase reaction was developed for HRP visualization in order
to distinguish from CaBP immunohistochemistry without heavy
metal intensification of diaminobenzidine (Gómez-Nieto et al.,
2008a). Detailed information of the antibodies and dilutions used
for CaBP immunohistochemistry is shown in Table 1. All sec-
tions processed for light microscopic analysis were mounted on
slides and 4 alternate series were counterstained with cresyl vio-
let to highlight cytoarchitectonic divisions; the other sections
were dehydrated in ethanol and coverslipped with Entellan Neu
(#107961; Merck, Darmstadt, Germany).

Double fluorescent tract-tracing experiments
To label CRNs and the cochlear nerve, we used identical pro-
cedures to those used in our previous studies (Gómez-Nieto
et al., 2008b; Gómez-Nieto and Rubio, 2009). Three animals
received a unilateral injection of the fluorescent tracer, dextran
fluorescein isothiocyanate (D-FITC; #D-1820; Molecular Probes,

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Gómez-Nieto et al. New insights into the ASR circuit

Table 1 | List of antibodies and dilutions used in the immunohistochemistry techniques.

Antigen Primary Catalog/Brand* Dilution Secondary Dilution Catalog/Brand* Processing‡ References

antibody† antibody

CaBP Mouse
anti-CaBP

#C-8666/Sigma 1:200 Biotinylated
horse
anti-mouse

1:200 #BA-2000/Vector LM Gómez-Nieto
et al., 2008a,b,
2013

VGLUT1 Rabbit
anti-VGLUT1

#135-302/Synaptic
Systems

1:1000 Cy3 goat
anti-rabbit

1:200 #111-165-003/JI CM Gómez-Nieto
et al., 2008b;
Gómez-Nieto
and Rubio, 2009

Cy5 goat
anti-rabbit

1:200 #115-175-003/JI

c-Fos Rabbit
anti-c Fos

#SC-52/SCB 1:2500 Biotinylated goat
anti-rabbit

1:200 #BA-1000/Vector LM Castellano et al.,
2009, 2013

*Antibody manufacturers: JI, Jackson Immunoresearch, West Grove, PA, USA; SCB, Santa Cruz Biotechnology (Santa Cruz, CA, USA); Synaptic Systems, Göttingen,

Germany; Sigma, Sigma-Aldrich, St Louis, MO, USA; Vector, Vector Laboratories, Burlingame, CA, USA.
†Specificity and immunogen sequence of primary antibodies: (1) The anti-CaBP was a mouse IgG isotype produced by hybridization of mouse myeloma cells with

spleen cells from mice immunized with calbindin D-28k purified from chicken gut. The antibody specifically stains the 45Ca-binding spot of the calbindin D-28k (MW

28 kDa) of tissue originating from rat brain in two-dimensional immunoblots; (2) The anti-VGLUT1 is a polyclonal antibody generated in rabbits against Strep-Tag fusion

protein containing amino acid residues 456–560 of rat VGLUT1. This antibody has been tested in preadsorption experiments that blocked efficiently and specifically

the corresponding signals (manufacturer’s technical information; see also Zhou et al., 2007); (3) The anti-c Fos is a is a rabbit polyclonal antibody produced against a

epitope mapping at the N-terminus of c-Fos of human origin (see details in manufacturer’s technical information).
‡ Tissue processed for light microscopy (LM) or confocal microscopy (CM).

Eugene, OR), into the left TB to label CRNs retrogradely. The
stereotaxic coordinates targeted the course of CRN axons which
project to PnC neurons via the TB (López et al., 1999). A vol-
ume of 0.15–0.2 μl of D-FITC (10% in distilled water) were
pressure-delivered with a Hamilton syringe (#710; Hamilton Co.,
Reno, NV) attached to a Stereotaxic Injector (Stoelting Co., Wood
Dale, IL). After the scalp was sutured, the animals were allowed
to recover for 4–7 days. Then, the animals were deeply anes-
thetized and perfused through the heart with 0.5% paraformalde-
hyde (PFA) in 0.1 M phosphate buffer, pH 7.4. The cochlea
was removed, and crystals of the lipophylic dye DiI (#D-3911;
1.1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine perchlo-
rate; Molecular Probes) were placed on the exposed auditory
nerve. The brains were stored in 4% PFA for approximately 30
days at room temperature protected from light and were pro-
cessed for confocal microscopy as described by Gómez-Nieto and
Rubio (2009).

VGLUT1 immunofluorescence and colocalization experiments
Two rats were used to identify VGLUT1 immunopositive termi-
nals in the cochlear root nucleus. The immunofluorescence was
performed following the same protocol described by Gómez-
Nieto and Rubio (2009). After obtaining the brain tissue, free-
floating sections (40 μm in thickness) were pretreated with
phosphate buffer saline (PBS) 0.3% TritonX-100, and blocked
for 1h at room temperature with 6% normal goat serum (#S-
1000, Vector Laboratories) in PBS. Subsequently, the brain slices
followed overnight incubation at 4◦C with the primary anti-
body (see Table 1 for complete information of antibodies).
Thereafter, the sections were rinsed extensively in PBS and incu-
bated for 1 h at room temperature with their corresponding
fluorophore conjugated secondary antibody (Table 1). In another
set of experiments, we studied the codistribution of cochlear

nerve terminals and VGLUT1 on CRNs retrogradely labeled with
D-FITC. For this purpose, we analyzed 2 animals from our pre-
vious studies in which a triple-labeling procedure was designed
to detect colocalization of VGLUT1 with auditory nerve termi-
nals on bushy cells dendrites (Gómez-Nieto and Rubio, 2009).
These animals received an injection of D-FITC in the TB and
insertions of DiI crystals in the cochlear nerve root, and finally
the brainstem sections were processed for VGLUT1 immunofluo-
rescence as described above. In these colocalization experiments,
we used Cy5 goat anti-rabbit (blue emission) to distinguish the
signal from the DiI (red emission)-labeled auditory nerve end-
ings. Finally, all sections were rinsed extensively in PBS, dipped
briefly in distilled water, mounted onto fluorescence-free slides,
air-dried, and coverslipped with ProLong Antifade Kit (#P7481;
Molecular Probes) to prevent photobleaching. In all immunoflu-
orescence experiments, negative controls were not treated with
primary antibodies, and this resulted in the complete absence of
immunolabeling.

ELECTROPHYSIOLOGY EXPERIMENTS COMBINED WITH BDA
INJECTIONS
Seven rats were used for extracellular multi-unit recordings of
acoustically driven PnC neurons, and subsequent neuronal tract-
tracing study. The animal’s body temperature was monitored
and maintained at 38◦C by a thermostatically controlled electri-
cal blanket. Once anesthetized, each animal was placed inside a
sound-attenuated room in a stereotaxic frame in which the ear
bars were replaced by a hollow speculum coupled to a sound
delivery system (Sony MDR E-868 earphones). The output of the
system at each ear was calibrated in situ using a DI-2200 spectrum
analyzer and a Brüel and Kjær 4134 microphone. This standard
calibration was used to set the levels of tones and white noise in
all experiments. Both pure tones and bursts of white noise were

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Gómez-Nieto et al. New insights into the ASR circuit

generated using a waveform generator (Hewlett Packard-8904A
multifunction synthesizer) controlled by a computer. Acoustic
stimuli were delivered to the ears monaurally, ipsi- and contralat-
eral to the recording site, as well as binaurally. After craniotomy
and brain surface exposure, a glass micropipette with the tip
broken to a diameter of 10 μm was filled with 10% of BDA
in 2M NaCl (15–25 M�) and lowered through the brainstem
using a piezoelectric microdrive (Burleigh 6000 ULN, Burleigh
Instruments, Fishers, NY) with a resolution of 1 μm. The elec-
trode was aimed to target PnC neurons in the right side of
the brainstem following the same stereotaxic approach described
above. As the micropipette was advanced into the brainstem, we
used white noise as search stimuli. Extracellularly recorded action
potentials were amplified (×10,000; BAK MDA-4I), filtered (0.3–
3 kHz), discriminated (BAK DIS-I) and time-stamped with an
accuracy of 10 μs by a CED-1401plus Laboratory Interface
(Cambridge Electronic Design). Once significant evoked activity
was detected, bursts of white noise and pure tones were used as
experimental stimuli to assess the modifications of PnC neural
responses at different conditions (intensity, frequency and side
of stimuli presentation). Stimuli were 100 presentations of 75 ms
pure tones (5 ms rise/fall time) or noise bursts at a rate of 2/s.
Sound level was varied from 60 to 90 dB in 10-dB steps and fre-
quency from 0.5 to 35 kHz. These intensity and frequency ranges
were chosen based on the high firing thresholds and broad fre-
quency tuning of PnC neurons (Lingenhöhl and Friauf, 1994).
The spikes times evoked by the different stimuli were stored and
were used to calculate the response magnitude (spikes per ms)
and first spike latencies. The integration window to calculate the
mean firing rate was the first 25 ms after stimuli presentation. For
each recording, we obtained peristimulus time histograms to dis-
play the responses to the stimuli. Data from first spike latencies
and responses of PnC neurons were pooled for statistical compar-
ison between stimulation with pure tones and noise bursts as well
as the side of stimuli presentation. At the end of each experiment,
BDA was injected iontophoretically following the same procedure
described above. Finally, the animal was allowed to recover for a
minimum of 7 days and followed the histological procedure to
visualize the neuronal tracer at light microscopy (López et al.,
1999; Gómez-Nieto et al., 2008a, 2013).

BEHAVIORAL EXPERIMENTS
A total of 12 rats were used to study the behavioral paradigm
of the ASR under monaural sound-deprivation conditions. The
animals were randomly divided into one experimental group
with monaural earplugging (n = 6) and an intact control group
(n = 6). The ASR amplitude was assessed in rats from the
experimental group prior to and following 4 days of monaural
earplugging, and their ASR was compared with those from the
control group. After the behavioral test, the animals were kept at
rest during 60 min, and then followed the tissue preparation to
detect c-Fos immunoreactivity at light microscopy (see below).

ASR apparatus (system) and procedure
Before testing, the rats were habituated to the experimental con-
ditions, especially to their placement into the ASR apparatus.
All testing was carried out between 9:00 A.M. and 11:00 A.M,

using the SR-LAB system (SDI, San Diego, CA, USA) as described
by Castellano et al. (2009). The acoustic startle reflexes were
measured in six identical startle response systems (SR-LAB).
Acoustic stimulus intensities and response sensitivities were cal-
ibrated (using an SR-LAB Startle Calibration System) to be nearly
identical in each of the six SR-LAB systems (maximum variabil-
ity <1% of stimulus range and <5% of response ranges). Each
system consisted of a nonrestrictive Plexiglas cylinder, 8.7 cm
in internal diameter and 20.5 cm long, mounted on a platform
which was located in a ventilated, sound-attenuated chamber.
Cylinder movements were detected by a piezoelectric accelerom-
eter mounted under each platform and were digitized and stored
by an interfacing computer assembly. A loudspeaker mounted
14.5 cm above the cylinder provided the broadband background
noise and acoustic stimuli. Each testing session consisted of an
acclimatization period of 5 min and 64 trials with a 30 s interval
between them. The trials were a single noise pulse (20 ms bursts of
white noise) presented at different intensities (95, 105, and 115 dB
SPL) in a random manner. Whole body ballistic movements cor-
responding to startling responses were collected and analyzed by
the SR-LAB system providing two main values of interest: Vmax

and Tmax. The Vmax represents the peak startle response (ASR
amplitude) that occurs during each trial while Tmax is the time
from stimulus to the peak startle response (ASR latency). The
background noise of 65 dB SPL was generated throughout the
entire session in order to avoid interference from external noise
and ensure equal experimental conditions.

Monoaural earplugging
After ASR testing, animals from the experimental group were
anesthetized and put on a warm blanket under a stereomicro-
scope. The skin was disinfected and foam earplugs (Moldex®,
Culver City, CA) were cut to appropriate size and introduced
into the right external canal as described by Whiting et al.
(2009). Once the ear canal was sealed, the animal was main-
tained under normal conditions for 4 days until the ASR was
measured again. After earplugging, the animals showed no symp-
toms of stress or infection, and kept their weight steady (see table
in Supplemental Figure 6). Acoustic effects of monaural earplug-
ging in rats include attenuation of approximately 40 dB on the
same side to the earplug as well as modifications of the thresh-
old, amplitude and latency of acoustic brain response waveforms
(Whiting et al., 2009; Popescu and Polley, 2010; Wang et al.,
2011).

Fos immunohistochemistry
Once the behavioral tests were completed, animals from the con-
trol and the monaural experimental group were processed to
detect c-Fos immunoreactivity in the auditory pathway, and more
specifically in the inferior colliculus (IC). The noise bursts used
to measure the ASR served to induce the c-Fos expression in the
auditory pathway. Since c-Fos protein has been widely used as a
marker of early neuronal activation (Sagar et al., 1988; Dragunow
and Faull, 1989; Murphy and Feldon, 2001), the quantification c-
Fos immunoreactivity in the IC allowed us to check the efficiency
of the earplugging. Perfusion of the animals, serial brain slic-
ing into 40 μm coronal sections and c-Fos immunohistochemical

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staining protocol was described in detail elsewhere (Castellano
et al., 2009, 2013). Sections were incubated in primary anti-
serum against c-Fos protein for 72 h at 4◦C. The tissue was
then washed and incubated with its corresponding biotinylated
secondary antibody for 2 h at room temperature, and finally
visualized with the avidin-biotin-peroxidase complex procedure
(Vectastain, Vector Labs.) and histochemistry for peroxidase
without heavy-metal intensification. Complete information of the
primary and secondary antibodies used for c-Fos immunohisto-
chemistry is provided in Table 1. Immunolabeling was abolished
by omission of the primary antibody. For each brain, all sec-
tions were mounted on slides, dehydrated and coverslipped as
described above.

IMAGE, DATA, AND STATISTICAL ANALYSIS
The sections processed for light microscopy were examined on an
upright brightfield microscope (#BX5; Olympus, Center Valley,
PA, USA) equipped with a digital camera (SpotRt®; Diagnostic
Instruments, Sterling Heights, MI, USA). Low-magnification
images were taken with the 4×, 10×, or 20× objective lens,
and high magnification images were taken with a 40× or 100×
objective lens (oil immersion) for morphometric measures of
labeled structures. The morphometric analysis was carried out
with ImageJ (version 1.42; Rasband W.S., ImageJ, Bethesda,
Maryland, USA, U.S. National Institutes of Health; 1997–2011.
http://imagej.nih.gov/ij/). In the behavioral experiments, we esti-
mated the number of c-Fos-immunolabeled neurons in the IC
using a similar quantitative analysis as previously described by
Castellano et al. (2013). High magnification micrographs (×40)
of the ipsilateral and contralateral IC were taken with a Leica
microscope (model # DMRB) coupled to a motorized x–y–z
motor stage, and connected to a PC with Stereo Investigator
software (MicroBrightField, VT, USA). The stereological anal-
ysis was accomplished with the aid of the optical fractionator
method (Gundersen et al., 1988). We selected one section con-
taining the left and right IC in each one of the 12 animals used
in the behavioral experiments. To guarantee the homogeneity
and the reproducibility of the area of interest, the contour of
the IC was drawn at low magnification (2x), using transpar-
ent templates taken from the atlas of the rat brain (Paxinos and
Watson, 2009) at 0.2 mm anterior from the interaural plane.
The templates were placed on the screen of the computer and
served to select the same area of interest in all histological sec-
tions. After that, the Stereo Investigator system automatically
estimated the size of the counting grid (optical dissector) and
the number of zones to be sampled. The neurons were counted
according to the optical dissector counting rules as they first
came into focus from 3 μm below the upper surface of the sec-
tion and did not touch the right inferior and superior edges of
the dissector. Quantification was carried out in a single-blind
assessment by two different investigators and only neurons that
displayed a clearly staining above the background were consid-
ered as a count. For the immunofluorescence and colocalization
experiments, the sections were examined with a conventional
brightfield microscope equipped with epifluorescence. In selected
slides, the sections were analyzed with a Leica TCS SP2 confo-
cal laser scanning microscope (Leica Microsystems, Mannheim,

Germany) coupled to a Leica DM IRE2 inverted microscope
and equipped with argon and helium neon lasers with excita-
tion wavelengths of 458, 476, 488, 543, 568, and 633 nm. The
fluorochromes FITC, Cy3, DiI, and Cy5 were detected sequen-
tially, stack by stack, with the acousto-optical tunable filter system
and triple dichroic mirror TD488/543/633. The background was
controlled, and the photomultiplier voltage (800 V) was selected
for maximal sensitivity in the linear range. The objectives used
were oil immersion ×40 and ×63/numerical aperture 1.30, pro-
viding a resolution of ×150 nm in the xy plane and ×300 nm
along the z-axis (pinhole 1 Airy unit), as well as several elec-
tronic zoom factors up to ×1.58. To determine the codistribu-
tion of the immunolabeled terminals, series of 25–50 confocal
images were obtained to generate a maximal-intensity z projec-
tion of stacks and an orthogonal projection (= xy, xz, yz planes,
for z stacks series). Colocalization of the fluorochromes within
positive terminals was verified in the orthogonal view. All pho-
tomicrographs shown in the figures were processed with minor
modifications in brightness, contrast and to remove the tissue
free background using Adobe Photoshop® CS3 Extended (Version
10.0) and assembled in Canvas 7.0 software. Statistical analy-
ses were performed using the SPSS software, version 18.0 (SPSS
Inc., Chicago, IL, USA). All mean values were expressed ± the
standard error of the mean. Comparisons between groups were
made by analysis of variance (mixed ANOVA split-plot), with
pairwise comparisons Sheffe (between-subjects analysis) and
Bonferroni post-hoc test (intra-subject analysis). To compare dif-
ferences between two means, we used Student’s t-test taking into
account the Levene’s test for equality of variances. The differences
between groups were regarded as statistically significant when
p ≤ 0.05.

RESULTS
HRP INJECTIONS INTO THE BASAL AND APICAL COILS OF THE
COCHLEA
To determine whether cochlear nerve terminals innervate CRNs
in a tonotopic specific manner, we injected HRP into the basal
and apical regions of the cochlea. In parasagittal sections of
the cochlear nucleus complex, we observed HRP labeling as an
intense black reaction product in which a densely bundle of axons
were identified (Figure 2). These HRP labeled axons followed
the characteristic V-shaped branching pattern of the primary
cochlear afferents (Figures 2A,B). To define the injection site, we
followed the criteria established by Merchán et al. (1988) and
examined the areas of the cochlear nucleus complex in which the
HRP-labeled fibers decussated and terminated. In cases with HRP
injections in the basal coil of the cochlea, the cochlear nerve fibers
bifurcate dorsally and give rise terminals into dorsal parts of the
cochlear nucleus complex (Figure 2A). We examined the course
of HRP-labeled axons within the cochlear root nucleus, and found
that they give off collaterals of various diameters (ranged from
0.4 to 1.6 μm) and numerous endings that terminated on CRNs
somata, but not exclusively (Figures 2A1,A2). To verify that HRP-
labeled fibers terminate on the cell body of CRNs, we immunos-
tained brainstem sections for CaBP. The cochlear nerve collaterals
were orientated perpendicular to the parent fibers, and extended
approximately 70 μm in length to innervate the cell body of CRNs

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immunostained for CaBP (Figures 2A3,A4). In cases with HRP
injections in the apical coil of the cochlea, the cochlear nerve
fibers divided more ventrally and form axonal terminals into
ventral parts of the cochlear nucleus complex (Figure 2B). In
the cochlear root nucleus of these cases, we observed numerous
HRP-labeled fibers that span away from the CRNs cell body and
followed the course of CRNs dendrites (Figure 2B1). Although
we also observed that HRP-labeled fibers give off terminals on
cell bodies of CRNs (Figure 2B2), a greater number of these ter-
minals appear to establish contact on primary and distal CRNs

FIGURE 2 | Injections of HRP in the basal and apical regions of the

spiral ganglion generate respectively labeled auditory nerve endings

on the cell body and dendrites of cochlear root neurons (CRNs). (A)

Parasagittal section of the cochlear nucleus complex shows labeled primary
auditory afferents after injection of HRP in the basal coil of the cochlea.
Notice that auditory nerve fibers divide dorsally and terminate in the dorsal
part of the anteroventral cochlear nucleus (AVCN) and posteroventral
cochlear nucleus (PVCN). (A1,A2) Higher magnification of the cochlear root
nucleus corresponding to the frames in (A). Note HRP-labeled endings
outlining the unlabeled neuronal somata of CRNs (asterisks). (A3,A4) High
magnification micrographs of the cochlear root nucleus show HRP-labeled
collaterals of primary auditory fibers (arrowheads) that terminate on the cell
body of CRNs immunolabeled for CaBP. (B) Parasagittal section of the
cochlear nucleus complex shows labeled primary auditory afferents after
injection of HRP in the apical coil of the cochlea. Notice that auditory nerve
fibers bifurcate ventrally and terminate in the ventral part of the AVCN and
PVCN. (B1) High magnification of the cochlear root nucleus corresponding
to the frame in (B) shows HRP-labeled endings (arrowheads) outlining the
unlabeled dendrite of a CRN. (B2) High magnification micrograph shows
HRP-labeled auditory nerve endings (arrows) outlining the cell body of a
CRN. (B3,B4) High magnification of the cochlear root nucleus shows details
of HRP-labeled endings (arrowheads) outlining perpendicular (B3) and
parallel (B4) unlabeled dendrites of CRNs after HRP injection in the apical
coil of the cochlea. DCN, dorsal cochlear nucleus. Scale bars = 1 mm in A

and B; 25 μm in A1–A4, B1–B4.

dendrites (Figures 2B3,B4). This set of data suggests that auditory
nerve inputs could be distributed preferentially on the cell body
and dendrites of CRNs depending, respectively, on their basal or
apical cochlear origin.

COCHLEAR NERVE ENDINGS ON CRNs COLABEL WITH VGLUT1
Our HRP injections in the apical regions of the spiral ganglion
gave evidence that primary auditory afferents might innervate
dendrites of CRNs. To fully confirm this result, we retrogradely
labeled CRNs by injecting D-FICT in the TB and inserted DiI
crystals into the cochlear nerve root (Figure 3). The D-FICT
injection sites in the TB were equal as those reported in our
previous studies (Gómez-Nieto et al., 2008b; Gómez-Nieto and
Rubio, 2009). Our D-FICT injections filled axons of approxi-
mately 3 μm in diameter that coursed through the contralateral
TB (Figure 3A, see also Figure 4A below). We followed the direc-
tions of these labeled axons and found that they emerged from
retrogradely labeled cell bodies of CRNs (Figure 3A). The DiI

FIGURE 3 | Auditory nerve projections to cochlear root neurons (CRNs)

dendrites. (A) Epi-fluorescence micrograph of a coronal section shows a
representative case with an insertion of DiI crystals into the cochlear root
(asterisk) and retrogradely labeled CRNs (arrows) after D-FITC injection into
the trapezoid body (TB). Notice thick CRNs axons (arrowheads) labeled with
D-FITC coursing through the TB. (B1–B3) Confocal micrographs show
auditory nerve terminals on dendrites of CRNs. DiI-labeled auditory nerve
fibers which send collaterals (arrows) into the region of CRNs are shown in
(B1) (in red). CRNs retrogradely labeled with D-FITC are shown in (B2) (in
green). The image (B3) is the merge of the two maximum z-series
projection shown in (B1,B2). (C) Detail of the boxed area in (B3) show a
dendrite of a CRN decorated with auditory terminals. The orthogonal view
in (C) confirms that auditory nerve terminals are in close apposition with
the dendrite (arrowhead). Scale bars = 200 μm in A; 75 μm in B1–B3;
25 μm in C.

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Gómez-Nieto et al. New insights into the ASR circuit

crystals inserted into the cochlear nerve root led to diffusion
along auditory nerve fibers (Figure 3A). In the cochlear root
nucleus, we observed thin DiI-labeled collaterals branching per-
pendicularly from the main auditory nerve fibers (Figure 3B1).
The DiI-labeled collaterals gave rise to small endings that ter-
minated on dendrites of CRNs (Figures 3B1–B3). The orthog-
onal view of confocal z-stack confirmed that those cochlear
nerve endings were in close apposition to dendrites of CRNs
(Figure 3C).

The excitatory synaptic marker VGLUT1 has been associated
with the mediation of glutamate transport at cochlear nerve fibers
in other areas of the cochlear nucleus complex (Zhou et al.,
2007; Gómez-Nieto and Rubio, 2009). As expected from our pre-
vious report (Gómez-Nieto et al., 2008b), we found a strong
immunoreactivity for VGLUT1 in the cochlear root nucleus
(Supplemental Figure 1). VGLUT1-labeled endings equally dis-
tributed throughout dorsal and ventral portions of the cochlear
root nucleus (Supplemental Figure 1). They were quite numer-
ous and fully decorated cell bodies as well as primary and dis-
tal dendrites of CRNs (Supplemental Figure 1). To determine
whether these VGLUT1 immunopositive endings colabel with ter-
minals of the auditory nerve, we used a triple-labeling method
consisting of double tract-tracing with D-FITC for CRNs and
DiI for cochlear nerve endings, combined with immunofluo-
rescence for VGLUT1. As described in the above experiments,
D-FITC injection in the TB retrogradely labeled the cell body
and dendrites of CRNs (Figures 4A,B). The inserted DiI crys-
tals into the cochlear nerve root diffused through cochlear nerve
fibers and collaterals, allowing us to label cochlear nerve termi-
nals (Figure 4C). We also found many VGLUT1-immunopositive
endings that were outlining cell bodies and dendrites (Figure 4D).
Our confocal analyses identified cochlear nerve terminals as
VGLUT1-immunopositive endings that were closely apposed
to CRNs (Figure 4E). The orthogonal view of cochlear nerve
endings confirmed the colocalization DiI-labeled endings with
VGLUT1 immunolabeling (Figure 4F).

ELECTROPHYSIOLOGICAL RESPONSES OF PnC NEURONS TO CONTRA-,
IPSI-, AND BILATERAL ACOUSTIC STIMULATIONS
To determine whether acoustically driven PnC neurons are
involved in binaural summation processing, pure tones (fre-
quency range from 0.5 to 35 kHz) and noise bursts of 75 ms
duration were presented contra-, ipsi-, and bilateral to the
recording site at four different intensities (60, 70, 80, and
90 dB SPL). A total of 169 and 49 multi-units recordings were
obtained using pure tones and noise bursts, respectively. PnC
neuronal activity exhibited an onset response with very short
first spike latencies (Figure 5). For example, in Figure 5A noise
bursts of 90 dB SPL evoked the PnC neuronal activity with
a mean spike latency of 4.39 ± 0.12 ms. The major firing
rate was observed within the first 25 ms after stimuli presen-
tation (Figure 5A). Using this integration window, we exam-
ined the mean spike latency and firing rate of PnC neurons
depending on acoustic stimuli (noise bursts and pure tones)
and on the side of stimuli presentation (Figures 5B,C). We
found that the mean spike latency was shorter with pure tone
(3.94 ± 0.39 ms) than with noise burst stimulations (4.83 ±

FIGURE 4 | Auditory nerve endings onto cochlear root neurons

(CRNs) colabel with VGLUT1. (A) Epi-fluorescence micrograph of a
coronal section shows retrogradely labeled CRNs after D-FITC injection
into the trapezoid body (TB) and the insertion site of DiI crystals into
the cochlear root (asterisk). Notice thick CRNs axons (arrowheads)
labeled with D-FITC coursing through the TB. (B) Confocal image of
retrogradely labeled CRNs with D-FITC (position denoted by an arrow
in A). (C) Confocal image of DiI-labeled endings which arise from
auditory nerve collaterals (arrows). (D) Confocal image shows
VGLUT1-immunolabeled endings. (E) Confocal image shows VGLUT1
colabeled with auditory nerve terminals on CRNs. This image is the
merge of the three maximum z-series projection shown in (B–D). (F)

Detail of the boxed area in E shows VGLUT1-auditory nerve terminals
(arrowheads) on dendrites of CRNs. Colocalization of VGLUT1 puncta
and DiI is confirmed by the orthogonal view. Scale bars = 500 μm in
A; 40 μm in B–E; 20 μm in F.

0.58 ms), showing significant differences when they were pre-
sented monaurally (both contra- and ipsilateral to the record-
ing site). However, no significant difference was found between
pure tone and noise burst stimulations after binaural presen-
tations (Figure 5B). There was also no significant difference in
spike latencies when comparing binaural with monaural presen-
tation of pure tones or noise bursts. Regarding the PnC neuronal
activity, we found that the mean firing rate (spikes/ms) was sig-
nificantly greater with binaural than with monaural presentations
(Figure 5C). Thus, we consistently observed that either pure tones

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FIGURE 5 | Electrophysiological responses of PnC neurons to

contra-, ipsi-, and bilateral acoustic stimulations. (A) PST
histogram shows the PnC neuronal activity (spikes/ms) evoked by
noise bursts of 90 dB SPL and 75 ms duration (black line) delivered
contralaterally to the recording site. Notice that the mean first spike
latency is very short (4.39 ± 0.12 ms). The shadow area displays
the integration window (first 25 ms after stimuli presentation) used to
calculate the firing rate. (B) Histogram shows mean spike latencies
of PnC neurons after contra-, ipsi-, and bilateral acoustic stimulations
with noise bursts and pure tones. Notice that the spike latencies
are shorter following pure tone than noise burst stimulations, with
significant differences when stimuli were presented monaurally (both
contra- and ipsilateral to the recording site). No significant difference
(ns) was found after binaural presentations. Bars represent mean
values and SEM, ∗ [contralateral presentation, F(1,216)= 4.399,
p = 0.037; ipsilateral presentation, F(1,216) = 8.137, p = 0.005]. (C)

Histogram shows the mean firing rate (spikes/ms) of PnC neurons
within the first 25 ms after contra-, ipsi-, and bilateral acoustic

stimulations with noise bursts and pure tones. Binaural presentations
showed significantly higher firing rates than monaural [∗,
F(2,216) = 14.852, p = 0.000]. Significant differences were found
between noise bursts and pure tones following binaural presentations
[∗, F(2, 216) = 4.037, p = 0.019], whereas no significant differences (ns)
were found in monaural presentations. Bars represent mean values
and SEM. (D) Firing rate-intensity function of PnC neurons in
response to pure tones following contra-, ipsi-, and bilateral stimulus
presentations. Binaural presentations showed significant differences
with monaural presentations (both contra- and ipsilateral to the
recording site) for tones of 60, 70, 80, and 90 dB SPL. Data points
represent the means with SEM, [∗, F(6,216) = 3.014, p = 0.015]. (E) Low
magnification micrograph shows a representative case of a recording
site labeled with BDA. (F) Micrograph shows CRNs retrogradely
labeled with BDA (arrowheads) after the injection site shown in (E).
Notice thick BDA-labeled axons of CRNs in the trapezoid body (TB,
arrows). CRNs, cochlear root neurons; PnC, caudal pontine reticular
nucleus. Scale bars = 1 mm in E; 200 μm in F.

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or noise bursts evoked higher responses when they were pre-
sented binaurally than when delivered monaurally. Significant
differences were also found between pure tone and noise burst
stimulations following binaural presentations, whereas monau-
ral presentations showed no significant differences (Figure 5C).
We further studied the neuronal activity of PnC neurons by
presenting contra-, ipsi-, and bilateral pure tones at many inten-
sities (Figure 5D). With contralateral presentations of the tones,
we observed a greater increase in firing rates with increas-
ing stimulus intensity. In contrast, this effect of the intensity
was not observed with ipsilateral presentations of the tones
(Figure 5D). For all the intensities tested, the firing rate was
significantly greater with binaural than with monaural presen-
tations (Figure 5D). In all the experiments, the bilateral evoked
responses in PnC were almost equal to the sum of the contralat-
eral and ipsilateral evoked responses, suggesting the existence of
a binaural summation process (Figures 5C,D). To identify the
origin of short-latency acoustic inputs to the acoustically driven
area of PnC, we injected BDA at the end of each experiment.
The BDA injections were small (∼0.3 mm), round in shape,
and restricted to ventrocaudal regions of the PnC (Figure 5E,
see also Supplemental Figures 2, 3). In all cases, we found
BDA-labeled axons in the TB that emerged from retrogradely
labeled CRNs (Figure 5F). The number of BDA-labeled neu-
rons located on the contralateral cochlear root nucleus (75.6%)
was considerably higher than on the ipsilateral nucleus (24.4%).
This result indicates that CRNs provide short latency acous-
tic inputs to PnC with a clear contralateral preference. Because
BDA is an effective bidirectional pathway tracer (Rajakumar
et al., 1993), we also observed retrogradely labeled neurons and
anterogradely labeled terminals in the PnC contralateral to the
recording/injection site (Supplemental Figures 2, 3). The labeled
fibers from PnC neurons of the right side crossed the midline
and enter into the opposite (left) reticular formation giving off
BDA-labeled terminals onto retrogradely labeled PnC neurons
(Supplemental Figures 2, 3). This result supports the idea that
reciprocal connections might exist between the left and right
PnC. In cases with slightly larger injections, we also found very
few neurons retrogradely labeled by BDA in the DCN and VCN
(Supplemental Figure 4). However, the number of retrogradely
labeled neurons in the DCN and VCN was considerably less
than those labeled in the cochlear root nucleus (see table in
Supplemental Figure 4).

BDA INJECTIONS IN THE DORSAL AND VENTRAL COCHLEAR NUCLEUS
The results described above indicated that acoustically driven
PnC neurons receive bilateral, but mainly contralateral, inputs
from CRNs. However, the presence of very few retrogradely
labeled neurons in other areas of the cochlear nucleus complex
led us to investigate whether these regions innervate PnC neu-
rons. This was done by injecting BDA into the left DCN and
VCN. All injections sites of BDA in the DCN and VCN were
restricted to the corresponding nucleus and did not spread to
adjacent areas of the cochlear nucleus complex (Figures 6A, 7A).
BDA injections in the DCN were small (0.5–0.7 mm in diam-
eter) and round in shape (Figure 6A). To check the efficiency
of BDA injections in the DCN, we analyzed the distribution of

anterograde labeling in nuclei that are well known to receive DCN
inputs (Cant and Gaston, 1982; Malmierca et al., 2002; Cant and
Benson, 2003). Our material showed BDA-labeled fibers and ter-
minals in the contralateral DCN (Figure 6B), the ipsilateral (data
not shown) and contralateral VCN (Figure 6C), the contralateral
IC (Figure 6D), and the contralateral medial geniculate body
(Figure 6E). We also observed thin and thick labeled fibers of
approximately 0.7 and 2.8 μm in diameter, respectively, in the
pontine reticular formation (Figures 6F,G). We examined both
type of BDA-labeled fibers and found that they do not innervate
giant PnC neurons (Figure 6G). Due to the bidirectional nature
of the transport of the BDA, the cochlear nerve terminals that
innervate DCN neurons uptake the tracer and filled retrogradely
cochlear nerve fibers (Supplemental Figure 5). We followed these
retrogradely labeled fibers and found that they innervate CRNs
somata in a similar pattern than that observed in our HRP
injections in the basal coil of the cochlea (for comparisons see
Figures 2A1–A4 and Supplemental Figure 5). In cases with BDA
injection in the VCN, we obtained small (0.3–0.8 mm in diam-
eter) and slightly elongated injection sites (e.g., in Figure 7A).
These injections generated anterograde labeling in nuclei that
are known to be targeted by VCN projecting neurons (Cant and
Gaston, 1982; Friauf and Ostwald, 1988; Doucet and Ryugo, 1997,
2003; Cant and Benson, 2003). Thus, we observed a thin band
of axons and swellings in the ipsilateral lateral superior olive
(Figure 7A2) as well as BDA-labeled terminals in the contralat-
eral medial nucleus of the TB (Figure 7B), the contralateral DCN
(Figure 7C), and the contralateral anteroventral cochlear nucleus
(Figure 7D2). In the reticular pontine formation, we found BDA-
labeled fibers that passed in close proximity to giant PnC neu-
rons, but without giving off any terminal fields (Figure 7D1).
In sum, these track-tracing experiments suggest that other areas
of the cochlear nucleus complex are not likely to innervate PnC
neurons.

THE ACOUSTIC STARTLE REFLEX IN RATS WITH MONAURAL
SOUND-DEPRIVATION
Our electrophysiological and morphological studies indicated the
existence of a binaural summation process in the neuronal activ-
ity of PnC neurons that receive acoustic inputs from CRNs. To
determine whether these results are consistent with the binaural
summation of the behavioral response, we investigated the ASR
in rats prior to and following monaural earplugging. By plugging
the sound reaching from one ear, the acoustic inputs to the CRNs
in the right was reduced, and hence affected the bilateral afferent
processing within the ASR pathway. Changes of the ASR ampli-
tude for each intensity of the stimulus (noise bursts of 95, 105, and
115 dB SPL) are shown in Figure 8A and Supplemental Figure 6.
In general, an increase of the acoustic stimulus intensity resulted
in a proportional increase of the ASR amplitude. As compared to
controls animals, we observed that the ASR amplitude was sig-
nificantly lower in monaural earplugged rats [F(1,12)= 6.32; p =
0.04]. A similar reduction was found when compared the exper-
imental group prior to and following monaural earplugging,
showing significant differences in the tested range of stimulus
intensity [F(5,6) = 8.45; p = 0.008]. On the contrary, there were
no significant differences in ASR amplitude between control and

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FIGURE 6 | BDA injections in the dorsal cochlear nucleus (DCN) do not

generate labeled terminals on giant neurons of the caudal pontine

reticular nucleus (PnC). (A) Micrograph of a Nissl-stained coronal section
shows a BDA injection site (IS) in the DCN. (B–E) Micrographs of the
contralateral DCN (B), the contralateral ventral cochlear nucleus (VCN; C), the
contralateral inferior colliculus (IC; D) and the contralateral medial geniculate
body (MG; E) show anterograde labeling after the BDA injection shown in (A).
(B1–E1) Higher magnification corresponding to the frames in (B–E)

respectively, shows details of BDA-labeled terminals in those nuclei. (F)

Nissl-stained section of the contralateral PnC shows axons labeled with BDA
crossing the pontine reticular formation (see higher magnification in F1). The
F1 inset (position denoted by an arrowhead) shows the absence of labeled
terminals on a giant PnC neuron. (G) High magnification micrographs show
representative examples of thick and thin BDA-labeled axons (denoted by
arrows and arrowheads, respectively) crossing the caudal pontine reticular
formation. Notice that DCN projecting axons do not give off endings onto
Nissl-stained PnC neurons. Scale bars = 500 μm in A and B; 50 μm in B1,
C1, D1, E1, and G; 1 mm in C–F; 200 μm in F1; 25 μm in the F1 inset.

pre-earplugged animals (Figure 8A). We also found no signifi-
cant differences in ASR latency between normal hearing (control
and pre-earplugged animals) and monaural earplugged condi-
tions at all stimulus intensities tested (Supplemental Figure 6).
As a histological control, c-Fos immunoreactivity in the IC was
assessed to check the efficiency of the monaural earplugging
(Figures 8B–E). In the contralateral plugged side, the number of
c-Fos immunolabeled neurons was significantly less in earplugged
rats than in controls (p < 00.5), whereas a similar number of neu-
rons were observed in the ipsilateral side (Figure 8B). When the

ipsi- and contralateral sides to the earplugging were compared,
the contralateral side showed a comparative largest decrease in
c-Fos immunolabeling (Figures 8C–E). This indicates that the
earplug attenuated the sound from reaching the right ear, and
hence, reduced the neuronal activity of the contralateral auditory
pathway including the left IC (Figures 8C–E). In sum, we showed
that the ASR amplitude was higher when the acoustic startling
stimulus was processed binaurally than when it was processed
monaurally, indicating that there is a strong summation for ASR.
Comparing the electrophysiological and behavioral experiments,

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Gómez-Nieto et al. New insights into the ASR circuit

FIGURE 7 | BDA injections in the ventral cochlear nucleus (VCN) do not

generate labeled terminals on giant neurons of the caudal pontine

reticular nucleus (PnC). (A) Micrograph of a Nissl-stained coronal section
shows a case with BDA injections in the VCN. (A1) A higher magnification
(corresponding to the white frame in A) shows a labeled VCN projection
neuron (arrow) in the proximity of the BDA injection sites (IS). (A2)

Nissl-stained section of the ipsilateral lateral superior olive (LSO),
corresponding to the black frame in (A), shows the characteristic projection
pattern of VCN neurons. The inset in (A2) (position denoted with an
arrowhead) illustrates a higher magnification of BDA-labeled terminals in the
LSO. (B,C) Micrographs of the contralateral medial nucleus of the trapezoid
body (MNTB; B) and the contralateral dorsal cochlear nucleus (DCN; C) show
anterograde labeling after the BDA injections shown in (A). (B1–C1) Higher

magnification of BDA-labeled terminals corresponding to the frame in (B,C),
respectively. The inset in (C1) (position denoted with an arrowhead)
illustrates a higher magnification of BDA-labeled terminals on a Nissl-stained
DCN neuron. (D) Micrograph of a Nissl-stained section containing the
contralateral PnC and the anteroventral cochlear nucleus (AVCN). (D1) High
magnification (corresponding to the black frame in D) shows the absence of
labeled terminals on PnC neurons (asterisk). Note that labeled fibers (arrow)
do not give off terminals. (D2) High magnification (corresponding to the white
frame in D) shows anterograde labeling in the contralateral AVCN. The inset in
(D2) (position denoted with an arrowhead) illustrates details of BDA-labeled
terminals on Nissl-stained AVCN neurons. SOC, superior olivary complex.
Scale bars = 1 mm in A, C, and D; 50 μm in A1, C1, D1, and D2; 200 μm in
A2; 10 μm in A2 inset; 500 μm in B; 25 μm in B1 and insets of C1 and D2.

we found that the reduction of PnC neurons’ responses after
monaural acoustic stimulation is consistent with the reduction
in the ASR amplitude following the monaural sound-deprivation
(for comparisons see Figures 5D, 8A).

DISCUSSION
In this study, we showed key morphofunctional aspects of the
ASR primary neuronal circuit. In the first central relay station,
we found that dendrites and cell bodies of CRNs receive selec-
tive inputs from specific regions of the cochlea. We also verified
that these cochlear nerve inputs are immunopositive for VGLUT1
as occurs in other areas of the cochlear nucleus complex (Zhou
et al., 2007; Gómez-Nieto and Rubio, 2009). In the second cen-
tral relay station, we demonstrated that the short-latency acoustic
inputs to PnC neurons are provided mainly, if not exclusively, by
CRNs. Our electrophysiological results indicated that there is a
strong binaural summation in the neuronal activity of PnC neu-
rons which can be linked to the bilateral projections from the
cochlear root nucleus to the PnC (López et al., 1999; Nodal and
López, 2003). Finally and accordingly with our electrophysiologi-
cal findings, we showed that the overall response of the behavioral

paradigm is higher when the acoustic startling stimulus is pro-
cessed binaurally than when processed monaurally. Our study
clearly supports that the functional connections of the cochlear
root nucleus with PnC constitutes the neuronal bases underlying
the rapid short-latency and binaural summation of the ASR.

TONOTOPIC-SPECIFIC DISTRIBUTION THROUGH THE CELL BODY AND
DENDRITES OF CRNs
Alerting and escape behaviors have high dependence on the fre-
quency of sounds, which are of great importance in the life of
rodents. For example, rats emit ultrasounds in the frequency
range between 18 and 30 kHz in response to a threatening stim-
ulus (predator exposure), and hence, serve as alarm calls to
specifically warn other individuals (Cuomo and Cagiano, 1987;
Blanchard et al., 1991). CRNs provide acoustic information to
a wide variety of non-auditory nuclei involved in the startle
reflex, orientation of head and ears toward a novel sound, vocal-
ization, emotional information, and escape (López et al., 1999;
Nodal and López, 2003; Horta-Júnior et al., 2008). Since these
sensory events and escape behaviors are initially mediated by
CRNs (Lee et al., 1996; López et al., 1999), it is likely that

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Gómez-Nieto et al. New insights into the ASR circuit

FIGURE 8 | The acoustic startle reflex (ASR) in rats with monaural

sound-deprivation. (A) Amplitude-intensity function of the ASR in
response to noise bursts shows differences between the control (n = 6)
and the experimental group (n = 6), before and following monaural
earplugging. Notice that ASR amplitude was significantly higher in control
and pre-earplugging rats than earplugged animals at all intensities tested
(95, 105, and 115 dB SPL). Data is expressed in mean values and error bars
represent standard deviation (SEM), ∗p < 0.05 [control vs. monaural
earplugged animals, F(1,12) = 6.32; p = 0.04; experimental group,
pre-earplugging vs. monaural earplugging, F(5, 6) = 8.45, p = 0.008]. The
source of variability is the number of animals and trials. (B) Histogram
shows the number of c-Fos immunopositive neurons per mm2 in the
inferior colliculus (IC) of control and monaural earplugged animals. Notice
that the contralateral plugged side (left IC) contains significantly less
neurons than the left IC of control animals. However, the right IC of control
and monaural earplugged animals showed no significant differences (ns).
Bars represent mean values and SEM, ∗p < 0.05. The variability observed
in the stereological study comes from sampling one section containing the
left and right IC in each one of the 12 animals used in the behavioral
experiments. C, Low magnification micrograph shows c-Fos
immunoreactivity in the IC of a monaural earplugged animal. (D,E) High
magnification micrographs corresponding to the frames in (C) show c-Fos
immunolabeling in the contralateral (D, left IC) and ipsilateral plugged side
(E, right IC). Note the number of c-Fos immunolabeled neurons is
considerable less in the contralateral than the ipsilateral plugged side. Scale
bars = 1 mm in C; 50 μm in D and E.

CRNs receive selective inputs from specific regions of the cochlea.
Our HRP injections in apical and basal coils of the cochlea
indicated that the cell body and dendrites of CRNs are prefer-
entially innervated by different portions of the cochlea. Fibers
from basal, high frequency parts of the cochlea, terminated pref-
erentially on the cell body whereas those from more apical, low
frequency parts of the cochlea, mainly terminated on dendrites.

These qualitative observations are in agreement with Osen et al.
(1991) studies, which showed that the base of the cochlea is
the source of most primary inputs to CRNs somata. Our study
further demonstrated that dendrites of CRNs, which are quite
extensive, are highly innervated by cochlear nerve inputs. The
technical challenge of labeling dendrites of CRNs while ana-
lyzing the primary afferents might explain why this result was
not shown in our previous reports (Merchán et al., 1988; Osen
et al., 1991; López et al., 1993). In the present study, the exper-
imental approach designed by Gómez-Nieto and Rubio (2009)
combining two neuronal tracers, D-FICT in the TB and DiI in
the cochlear nerve root, allowed us to confirm that CRNs den-
drites also receive cochlear nerve inputs. The frequency-specific
distribution described in our study provides an explanation for
the frequency tuning curves observed in extracellular recordings
of CRNs (Sinex et al., 2001; Gómez-Nieto et al., 2013). Thus,
our results showed that CRNs somata and primary dendrites
receive massive high-frequency inputs that might be responsi-
ble for the high characteristic frequency of CRNs (∼30 kHz).
Since the basal regions of the cochlea have also the shortest
latencies, these might provide a specialization to minimize the
response latency in CRNs (Sinex et al., 2001). Furthermore, it
is interesting to point out that CRNs responded to a frequency
range from 1.5 to 40 kHz that is nearly the entire audiogram of
the rat (Kelly and Masterton, 1977; Sinex et al., 2001), which
is in line with our observations showing high and mostly low
frequency inputs on CRNs dendrites. Our data together with
the fact that the synaptic strength becomes larger as one moves
along the dendrite (Spruston, 2000; London and Segev, 2001)
suggest that CRNs, which are high frequency specialized neu-
rons, might also integrate a wide range of frequencies in their
dendrites.

RAPID GLUTAMATERGIC TRANSMISSION IN THE COCHLEAR ROOT
NUCLEUS
The ASR behavioral paradigm is defined by its rapid and short
latency reflex actions (Szabo, 1964; Hoffman and Ison, 1980). For
that, CRNs have specific morphological, physiological and neuro-
chemical properties that provide them the capacity of mediating
fast and secure neurotransmission of short-latency auditory cues
(López et al., 1993, 1999; Sinex et al., 2001). An important out-
come of our study was to demonstrate that cochlear nerve inputs
on CRNs colabeled with VGLUT1. This result together with the
fact that VGLUT1 terminals massively covered CRNs on the z
axis (Gómez-Nieto et al., 2008b; see also our results) indicates
that auditory nerve terminals on CRNs are far more numerous
than reported in previous studies (Merchán et al., 1988). Since
cochlear nerve fibers use glutamate as neurotransmitter (Hackney
et al., 1996; Rubio and Juiz, 2004; Rubio, 2006), VGLUT1 might
contribute to the synaptic efficacy by regulation of vesicle cycling
and filling (Wilson et al., 2005). Furthermore, the relatively low
affinity for their substrate allows the VGLUT1 to transport large
amounts of glutamate more rapidly (Bergles and Edwards, 2008).
Thus, our results showed that CRNs somata and dendrites are
fully covered by VGLUT1-cochlear nerve terminals which pro-
vide a great speed on synaptic signaling in the first component
of the ASR circuit. This VGLUT1-cochlear nerve colabeling has

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Gómez-Nieto et al. New insights into the ASR circuit

been also found on bushy cells of the VCN (Gómez-Nieto and
Rubio, 2009), a neuronal type that encodes features of the acous-
tic waveform and conveys precise temporal information to upper
auditory structures (Friauf and Ostwald, 1988; Cant and Benson,
2003). VGLUT1 terminals on CRNs (ASR pathway) and bushy
cells (auditory pathway) exhibit an altered morphology in mice
with targeted deletion of the gene coding for the auxiliary subunit
α2δ3 of voltage-gated calcium channels (Pirone et al., 2014). Both
neuronal types express the α2δ3 subunit and its lack lead to neu-
ronal deficits in the auditory and the ASR pathway, including the
inability to discriminate temporal dimensions of sounds (Pirone
et al., 2014). Thus, CRNs might provide fast acoustic informa-
tion with accurate temporal precision to the ASR pathway just as
bushy cells do for the ascending auditory pathway. This idea is in
line with our findings that support the CRNs-PnC projection as
the neuronal pathway underlying the binaural summation of the
ASR (discussed below).

ORIGIN OF SHORT-LATENCY ACOUSTIC INPUTS TO PnC NEURONS
A conclusive demonstration that one nucleus is not innervated
by another is difficult to accomplish in any region of the cen-
tral nervous system. This became more difficult if that nucleus,
as occurs in PnC, receives a large number of inputs and con-
tains numerous crossing fibers. Bearing this argument in mind,
our study provided evidence that supports the CRNs as the solely
source of short-latency acoustic inputs to giant PnC neurons. Our
electrophysiological experiments with subsequent neuronal trac-
ing showed retrogradely labeled CRNs after recording acoustically
driven PnC neurons. This result is consistent with our previ-
ous reports that demonstrated the projections from the cochlear
root nucleus to PnC neurons (López et al., 1999; Nodal and
López, 2003). In addition, our BDA injections in PnC also gen-
erated very few retrogradely labeled neurons in the DCN and
VCN, which in principle suggests that other areas of cochlear
nucleus complex might provide short-latency acoustic inputs to
PnC as proposed by other studies (Davis et al., 1982; Kandler
and Herbert, 1991; Lingenhöhl and Friauf, 1994; Meloni and
Davis, 1998). Lingenhöhl and Friauf (1994) reported retrogradely
labeled somata in DCN and VCN after injecting a pure retrograde
trace (FluoroGold) in PnC. By contrast, our restricted BDA injec-
tions into the DCN and VCN were unable to demonstrate the
connection of these two areas with giant PnC neurons. Although
we filled a great number of DCN and VCN projecting neurons,
as shown by the labeled terminal fields in many nuclei known to
receive innervations from the DCN and VCN (reviewed in Cant
and Benson, 2003), we did not find any terminal fields on PnC
neurons. A possible explanation for these contradictory results
is that DCN and VCN neurons were retrogradely labeled after
tracer injections in PnC as a consequence of the tracer uptake
by fibers of passage rather than by terminals on PnC neurons.
This idea seems to be consistent with previous studies report-
ing that DCN and VCN projections to PnC were very weak, and
not as dense as those from the cochlear root nucleus (Friauf and
Ostwald, 1988; Kandler and Herbert, 1991; Meloni and Davis,
1998). In accordance with this morphological data, behavioral
studies showed that chemical lesions of CRNs drastically reduced
the startle response at all intensities (Lee et al., 1996), whereas

electrolytic lesions of the DCN did not (Davis et al., 1982; Meloni
and Davis, 1998). Meloni and Davis (1998) found that elec-
trolytic lesions of the DCN lead to a significant reduction in ASR
amplitude at 110 and 115 dB SPL startle-eliciting intensities and
normal responses on all other intensities. Interestingly, one find-
ing of our BDA injections in DCN was that some auditory nerve
terminals on CRNs and DCN neurons arise from the same par-
ent auditory nerve fiber. According to this, electrolytic lesions
of the DCN might damage auditory nerve terminals on CRNs,
and might reduce the ASR amplitude at high intensities. It is
well established that auditory nerve fibers that reach the dorsal
part of the cochlear nucleus complex originated from the basal
coils (high-frequency) of the cochlea (Saint Marie et al., 1999).
Thus, our BDA injections in the dorsal part of the DCN gener-
ated retrograde labeled terminals on the cell body of CRNs in a
similar pattern than that observed in our HRP injections in the
basal coil of the cochlea. This result verifies the tonotopic-specific
distribution through the cell body and dendrites of CRNs and
suggests that both CRNs and DCN neurons receive similar acous-
tic information. DCN projects to the IC (Beyerl, 1978; Oliver and
Shneiderman, 1991; Oliver et al., 1999; Cant and Benson, 2003),
which is known to participate in the modulation of the ASR
(Leitner and Cohen, 1985; Fendt et al., 2001; Yeomans et al., 2006;
Gómez-Nieto et al., 2008a, 2013). It is, therefore, likely that DCN
might provide acoustic information to ASR modulation pathways
rather than being necessary for the initiation and elicitation of
the ASR.

NEURONAL BASES UNDERLYING BINAURAL SUMMATION OF THE
ACOUSTIC STARTLE REFLEX
Our electrophysiological data showed that PnC neurons, which
are innervated by CRNs, responded with very short spike latencies
to noise bursts. The fact that sounds that contain every frequency
activate PnC neurons is consistent with our hypothesis that fre-
quency integration occurs in CRNs dendrites, and implies that
CRNs provide precise and rapid acoustic information to PnC
neurons. Our previous studies reported that CRNs have thick
myelinated axons and contain calcium binding proteins that con-
fer to the cochlear root nucleus the necessary specializations for
sending fast electric signals to PnC (López et al., 1993, 1999).
Accordingly, more recent studies have demonstrated that proteins
such as the potassium channel subunit Kv1.1 and the transcrip-
tion factor Math5-lacZ are highly expressed in CRNs (Oertel
et al., 2008; Saul et al., 2008). These proteins have been found
to participate in fast neurotransmission, temporal synchrony, and
processing of binaural information (Saul et al., 2008; Allen and
Ison, 2012). Consistently with the molecular specializations of
CRNs, an important conclusion that we draw from our elec-
trophysiological experiments is that the CRNs-PnC projections
determine the binaural summation of the ASR. This phenomenon
of binaural summation provides that the startling stimulus pre-
sented to both ears is perceived as more intense than if it were
presented in monaural mode. Therefore, there is strong binau-
ral summation for startle, with a preference for acoustic stimuli
delivered near the midline to activate both ears simultaneously
(reviewed in Yeomans et al., 2002). Accordingly, we showed that
the binaural evoked responses of PnC neurons were almost the

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Gómez-Nieto et al. New insights into the ASR circuit

sum of those evoked monaurally. The fact that the bilateral CRNs-
PnC projections have a clear contralateral predominance (López
et al., 1999; Nodal and López, 2003) might explain our result
showing higher PnC neurons’ responses evoked with contralateral
than ipsilateral acoustic stimulations. Our electrophysiological
analysis also revealed that PnC neurons’ responses increased as
the contralateral stimulus intensity increases, a result which is in
line with our behavioral data and the contralateral predominance
of the CRNs-PnC pathway. Wagner et al. (2000) suggested that
the superior olivary complex, which is involved in binaural pro-
cessing, is necessary for the full expression of the ASR. However,
the possibility that neuronal circuits beyond the cochlear nucleus
complex contribute to the binaural summation of the ASR seems
very limited. The ASR mediated via the superior olivary com-
plex involves too many synapses to accomplish the short latency
of the ASR, and this led us to restrict the binaural summation
to the CRNs-PnC pathway. In accordance with two reports in
rats (Lingenhöhl and Friauf, 1994) and cats (Walberg, 1974), our
study suggests the existence of reciprocal connections between
the left and right PnC, which need to be accounted for the final
evoked response of PnC neurons. Further research is required
to learn more about these crossed reticulo-reticular connec-
tions and their possible functional role in the ASR. It is also
relevant to note that our electrophysiological results were con-
sistent with our behavioral experiments showing that the ASR
amplitude was higher when the acoustic startling stimulus was
processed binaurally than when it was processed monaurally. We
came to this conclusion comparing the behavioral response of
the control animals with that of monaural earplugged animals.
Therefore, it was essential in this experimental design to ver-
ify the effectiveness of the earplugging. Since c-Fos protein has
been widely used as a marker of early neuronal activation (Sagar
et al., 1988; Dragunow and Faull, 1989; Murphy and Feldon,
2001), we quantified the c-Fos immunolabeling in the IC. The
IC was selected for c-Fos quantification because it is an oblig-
atory relay center for most ascending auditory tracts (Beyerl,
1978; Oliver and Shneiderman, 1991) and plays an important
role in the prepulse inhibition of the ASR (Leitner and Cohen,
1985; Fendt et al., 2001; Li and Yue, 2002; Yeomans et al., 2006;
Gómez-Nieto et al., 2008a, 2013). Our results showed that the
number of c-Fos immunolabeled neurons in the contralateral
IC was drastically reduced by the earplugging. This reduction
was not found in the ipsilateral side to the earplugging because
the IC receives auditory inputs from the contralateral cochlear
nucleus (Beyerl, 1978; Oliver and Shneiderman, 1991). Since
monaural conductive hearing loss reduces auditory nerve activity
and affects sound processing along the central auditory pathway
(Potash and Kelly, 1980), the reduction of c-Fos immunoreac-
tivity in the IC indicates that bilateral afferent processing within
the ASR pathway was affected by the earplugging. As expected by
Davis and Wagner (1969) report, we found that the ASR ampli-
tude increased with increasing stimulus intensity in control and
pre-earplugged animals. In contrast, earplugged animals showed
much less ASR amplitude, suggesting that the binaural ASR path-
way is required to elicit a full startling response. Our study
suggests the CRNs-PnC pathway as an anatomical and physiolog-
ical specialization that determines the binaural summation of the

ASR. Since CRNs also projects to non-auditory nuclei involved
in other startling reflex modalities (López et al., 1999; Horta-
Júnior et al., 2008), it is reasonable to propose that the CRNs
projections might also participate in cross-modal summation of
the ASR (Yeomans et al., 2002). In conclusion, our study con-
solidates the CRNs as the “early warning system” responsible for
the execution and propagation of bilateral acoustic startling sig-
nals at very short latencies, and that is what defines the ASR in
itself.

ACKNOWLEDGMENTS
We thank Sonia Hernández and David Sánchez for excellent tech-
nical assistance in the quantitative analyses of c-Fos immunore-
activity. This research was supported by grants from the Spanish
Ministry of Science and Innovation (MICINN, #BFU2010-
17754) to Dr. Dolores E. López; the São Paulo State Research
Foundation (FAPESP, #2008/02771-6) to Dr. José de Anchieta
C. Horta-Júnior; and the 1R01DC013048-01 to Dr. María E.
Rubio.

SUPPLEMENTARY MATERIAL
The Supplementary Material for this article can be found
online at: http://www.frontiersin.org/journal/10.3389/fnins.
2014.00216/abstract
Supplemental Figure 1 | Distribution of VGLUT1-immunolabeled endings

in the cochlear root nucleus. (A) Epi-fluorescence micrograph of a coronal

section shows VGLUT1-immunolabeled endings (Cy3 fluorochrome) in the

cochlear root nucleus. (B–E) Epi-fluorescence micrographs of the boxed

areas in (A) show distribution of VGLUT1-immunolabeled endings from

dorsal to ventral regions of the cochlear root nucleus. Note that numerous

VGLUT1-immunolabeled endings decorate unlabeled cell bodies (arrows)

and dendrites (arrowheads) of cochlear root neurons (CRNs). TB, trapezoid

body. Scale bars = 200 μm in A; 25 μm in B–E.

Supplemental Figure 2 | BDA injections in the caudal pontine reticular

nucleus (PnC) generate anterograde and retrograde labeling in the

contralateral PnC. (A) Low magnification micrograph of a coronal section

of the brainstem shows a representative case with BDA injection sites (IS)

in the right PnC. The tracer was injected after recording of acoustically

driven PnC neurons. Notice numerous BDA-labeled axons (arrowheads)

crossing the midline toward the contralateral PnC. Also, thick axons of

cochlear root neurons (position denoted with an arrow) were retrogradely

labeled with BDA in the trapezoid body (TB). (B) Higher magnification

corresponding to the frame in (A) shows details of BDA-labeled terminals

onto retrogradely labeled giant PnC neurons (arrows). Scale bars = 1 mm

in A; 200 μm in B.

Supplemental Figure 3 | Reciprocal connections between the left and right

caudal pontine reticular nuclei (PnC). (A) Micrograph of a Nissl-stained

coronal section shows a BDA injection site (IS) in the right PnC. The tracer

was injected after recording of acoustically driven PnC neurons.

Arrowheads indicate crossed reticulo-reticular projections labeled with

BDA. Also, thick axons of cochlear root neurons (position denoted with an

arrow) were retrogradely labeled with BDA in the trapezoid body (TB).

(B,C) Higher magnification corresponding to the frames in (A) shows

details of BDA-labeled terminals (arrowheads) onto Nissl-stained giant

PnC neurons. Notice a PnC neuron retrogradely labeled by BDA (asterisk

in C). Scale bars = 1 mm in A; 25 μm in B and C.

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Supplemental Figure 4 | Retrograde labeling in the coclear nucleus

complex after BDA injections in the acoustically driven area of the caudal

pontine reticular nucleus (PnC). (A) High magnification micrograph shows

a coronal section of the contralateral dorsal cochlear nucleus (DCN) in

which a BDA-retrogradely labeled neuron (arrow) was found after the

injection site shown in Supplemental Figure 2A. (B) High magnification

micrograph shows a BDA-retrogradely labeled neuron (arrow) in the

contralateral ventral cochlear nucleus (VCN). (C) Quantitative distribution

of retrogradely labeled neurons in the cochlear nucleus complex after BDA

injections in the acoustically driven area of PnC. The table shows the

retrograde labeling obtained in the seven cases used in the

electrophysiological experiments. Notice that the number of retrogradely

labeled neurons in the DCN and VCN is considerably less than those

labeled in the cochlear root nucleus. Scale bar = 200 μm in A and B.

Supplemental Figure 5 | BDA injections in the dorsal cochlear nucleus

(DCN) generate retrogradely labeled terminals on the cell body of cochlear

root neurons (CRNs). (A) Nissl-stained coronal section of the cochlear root

nucleus shows retrogradely labeled fibers after the BDA injections shown

in Figure 6A. (B) Higher magnification corresponding to the frame in A

shows details of BDA-labeled terminals (arrowheads) on CRNs somata.

Notice that the morphology and distribution of these BDA-labeled

terminals resemble those of the cochlear nerve after HRP injections in the

basal coil of the cochlea (see Figures 2A1–A4). VCN, ventral cochlear

nucleus. Scale bars = 400 μm in A; 50 μm in B.

Supplemental Figure 6 | ASR amplitude, ASR latency and weight in rats

prior to and following monaural earplugging. (A) Histograms show the

ASR amplitude in response to noise burst of 95, 105, and 115 dB SPL in

rats before and following 4 days of monaural earplugging. Notice that ASR

amplitude was significantly higher in normal hearing than following

monaural earplugging at all intensities tested (95, 105, and 115 dB SPL).

Data is expressed in mean values and error bars represent standard

deviation (SEM), ∗p < 0.05 [experimental group, pre-earplugging vs.

monaural earplugging, F(5,6)= 8.45, p = 0.008]. (B) Data-set tables display

the ASR amplitude (mean values of Vmax within the testing session), ASR

latency (mean values of Tmax within the testing session) and weight of

each animal in normal hearing conditions (pre-earplugging) and following

monaural earplugging. There were no significant differences in the ASR

latency between the normal hearing and earplugged conditions for all

stimulus intensities tested. Notice the animals maintained their weight

steady throughout the behavioral experiment.

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