Departament de Ciències Fisiològiques II, Universitat de Barcelona, 08907 Hospitalet de Llobregat, Spain
1 To whom correspondence should be addressed at Departament de Ciències Fisiològiques II, Universitat de Barcelona, Feixa Llarga s/n, 08907 Hospitalet de Llobregat, Spain. Fax: 34-93-402 4268. E-mail: jllorens{at}ub.edu.
Received July 21, 2005; accepted September 1, 2005
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ABSTRACT |
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Key Words: iminodipropionitrile; allylnitrile; crotononitrile; hexadienenitrile; vestibular hair cells; inferior olive; motor behavior.
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INTRODUCTION |
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IDPN also causes olfactory deficits associated with degeneration of the olfactory mucosa (Genter et al., 1992, 1996
), hearing deficits associated with loss of the auditory hair cells and ganglion neurons (Crofton and Knight, 1991
; Crofton et al., 1994
), and visual deficits associated with clouding of the cornea and retinal detachment and degeneration (Barone et al., 1995
; Herr et al., 1995
; Selye, 1957
; Seoane et al., 1999
).
Further interest in nitrile neurotoxicity was raised by the finding that allylnitrile (3-butenenitrile), crotononitrile (2-butenenitrile), and 2-pentenenitrile also induce the ECC syndrome (Tanii et al., 1989a,b
). The association of motor disturbances with vestibular toxicity has been demonstrated for allylnitrile (Balbuena and Llorens, 2001
) and crotononitrile (Balbuena and Llorens, 2003
; Llorens et al., 1998
), whereas no axonopathy occurred after administration of crotononitrile (Llorens et al., 1998
) or allylnitrile (unpublished results). In the case of crotononitrile, only the cis- isomer induces both the ECC syndrome and vestibular hair cell loss, whereas trans-crotononitrile does not induce either of these effects (Balbuena and Llorens, 2003
). We thus concluded that vestibular toxicity fully accounts for the ECC syndrome, and we hypothesized that neuronal degeneration in the central nervous system (CNS) is not involved in its induction. However, several articles report on the deleterious central effects of both IDPN and allylnitrile as an alternative explanation to the vestibular hypothesis for the ECC syndrome. These include studies on apoptosis (Zang et al., 1999
), gene expression (Fritschi et al., 2003
), neurotransmitter systems (Tanii et al., 2000
, Wakata et al., 2000
), and free radicals (Nomoto, 2004
; Wakata et al., 2000
). Recent data from our laboratory have demonstrated that trans-crotononitrile, which spares sensory systems (Balbuena and Llorens, 2003
), does indeed cause a selective pattern of neuronal degeneration in the CNS in association with behavioral effects that differ from the ECC syndrome (Seoane et al., 2005
). There is also evidence suggesting that hexadienenitrile (2,4-hexadiene-1-nitrile) may have neurotoxic effects on the CNS (O'Donoghue, 2000
).
In the present study we compared the behavioral effects of IDPN, allylnitrile, cis-crotononitrile, trans-crotononitrile, and hexadienenitrile in the rat using test methods sensitive to the ECC syndrome or to the trans-crotononitrile syndrome. In addition, we assessed the CNS effects of these nitriles with the Fluoro-Jade B stain, which selectively labels degenerating neurons (Schmued and Hopkins, 2000a,b
). Finally, the effects of hexadienenitrile on the auditory and vestibular sensory epithelia were examined by scanning electron microscopy (SEM), as these had not been reported previously. Taken together with previous data (Balbuena and Llorens 2001
, 2003
; Llorens et al., 1993a
, 1993b
; Seoane et al., 1999
, 2005
), this study revealed two groups of neurotoxic nitriles: the vestibulotoxic nitriles, IDPN, allylnitrile, and cis-crotononitrile, which cause the ECC syndrome but no selective neuronal degeneration in the CNS, and the group including trans-crotononitrile and hexadienenitrile, which cause selective neurodegeneration in the CNS and motor deficits resulting from neuronal degeneration in the inferior olive complex.
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METHODS |
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Animals
The care and use of animals were in accordance with Law 5/1995 and Act 214/1997 of the Autonomous Community (Generalitat) of Catalonia, and approved by the Ethics Committee on Animal Experiment of the University of Barcelona. Fifty-eight 8- to 9-week-old male Long-Evans rats (CERJ, Le-Genest-Saint-Isle, France) were used. They were housed two to four per cage in standard Macrolon cages (280 x 520 x 145 mm) with wood shavings as bedding at 22° ± 2°C. At least 7 days were provided for acclimation before experimentation. The rats were maintained on a 12:12 L:D cycle (0700:1900 h) and given standard diet pellets (A04, U.A.R., France) ad libitum.
For histology, rats were anaesthetized with 400 mg kg1 chloral hydrate and transcardially perfused with 50 ml of heparinized saline followed by 400 ml of fixative solution.
Dosing and Experimental Design
One set of rats was used to compare the effects of the nitriles on behavior. Before testing and dosing, the animals in this set were trained for the vertical ladder task (see below). The rats were then assigned to one of five groups, and dosed i.p. for 3 consecutive days with control vehicle (3 rats received 1 ml kg1 day1 of corn oil and 4 rats received 2 ml kg1 day1 of olive oil,), 110 mg kg1 day1 of cis-crotononitrile (in corn oil, n = 10), 250 mg kg1 day1 of trans-crotononitrile (in corn oil, n = 7), 50 mg kg1 day1 of allylnitrile (in olive oil, n = 10), 300 mg kg1 day1 of hexadienenitrile (in olive oil, n = 7), or 400 mg kg1 day1 of IDPN (in 2 ml kg1 of saline, n = 7). The doses were selected on the basis of previous work (Balbuena and Llorens, 2001, 2003
; Llorens et al., 1993a
; Seoane et al., 1999
, 2005
) to elicit maximal neurotoxic effects with minimal mortality. A larger number of animals were assigned to the cis-crotononitrile and allylnitrile groups, because these treatments were considered more likely than the other treatments to cause death of some animals. The rats were weighed and examined for vestibular function by the tail-hang test (see Balbuena and Llorens, 2001
) at dosing days and at days 1, 5, 6, 8, 12, 15, 19, and 21 after dosing. A complete behavioral assessment was performed at days 0 (pre-test), 1, 6, and 20 after the third day of dosing (Balbuena and Llorens, 2001
, 2003
; Llorens et al., 1993a
; Seoane et al., 2005
). On each of these days, we assessed locomotor and rearing activities in the open field, vestibular function by a complete test battery, and holding time on a vertical ladder. Gait analysis was performed on day 19 (Seoane et al., 2005
). Three rats from the hexadienenitrile group were used for inner ear histology on day 40 after dosing (Llorens et al., 1993b
; Balbuena and Llorens, 2001
, 2003
).
Another set of rats was administered the same nitrile doses as above to assess for neuronal degeneration in the CNS at 2 days after administration of hexadienenitrile (n = 2) or at 7 days after administration of saline (n = 2), cis-crotononitrile (n = 3), trans-crotononitrile (n = 2), allylnitrile (n = 3), hexadienenitrile (n = 3), or IDPN (n = 2). Literature data are available for neurodegeneration-selective stains assessment of the effects of trans-crotononitrile (by Fluoro-Jade B staining, Seoane et al., 2005) and IDPN (by silver staining, Llorens et al., 1993a
).
Behavioral Analysis
Vestibular rating.
The disturbance of vestibular function was determined by a complete battery of behavioral tests or the tail-hang test alone. The test battery (Llorens et al., 1993b; including modifications by Llorens and Rodríguez-Farré, 1997
) has been successfully used to assess the loss of vestibular function caused by surgical (Llorens et al., 1993b
) and chemical (Llorens and Rodríguez-Farré, 1997
) bilabyrinthectomies, as well as by IDPN (Llorens et al., 1993b
), crotononitrile (Llorens et al., 1998
), allylnitrile (Balbuena and Llorens, 2001
), and cis-crotononitrile (Balbuena and Llorens, 2003
) toxicity. The battery includes observation of spontaneous motor behavior (Crofton and Knight, 1991
), the tail-hang reflex (Selye, 1957
; Hunt et al., 1987
), contact inhibition of the righting reflex (Shoham et al., 1989
; Ossenkopp et al., 1990
), and the air righting reflex (Ossenkopp et al., 1990
). Briefly, rats were placed for 1 min in a 50 x 50 cm glass cube, and the experimenter rated the animals from 0 to 4 for circling, retropulsion, and abnormal head movements. Circling was defined as stereotyped circling ambulation. Retropulsion consisted of backward displacement of the animal. Head bobbing consisted of intermittent extreme backward extension of the neck. The rats were afterwards rated 0 to 4 by the tail-hang reflex, contact inhibition of the righting reflex, and air righting reflex tests. When lifted by the tail, normal rats exhibit a "landing" response consisting of forelimb extension. Rats with impaired vestibular function bent ventrally, sometimes "crawling" up toward their tails, thus tending to occipital landing (see Fig. 4 in Selye, 1957
). For the contact inhibition of the righting reflex, rats were placed supine on a horizontal surface and a metal bar grid was lightly placed in contact with the soles of the animals' feet. Healthy rats quickly right themselves, whereas the vestibular-deficient rats lie on their backs with their feet up and "walk" with respect to the ventral surface (see Fig. 1 in Shoham et al., 1989
). For the air righting reflex, the animals were held supine and dropped from a height of 40 cm onto a foam cushion. Normal rats are successful in righting themselves in the air, whereas vestibular-deficient rats are not. A summary statistic was obtained by adding up the scores for all behavior patterns and expressing this sum as a percentage of the maximal score of 24.
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Gait topography analysis.
Stepping movements were evaluated as described by Parker and Clarke (1990). After marking the rat hind and fore feet with ink (red and black ink, respectively), the animal walks across chart paper in an elevated pathway, leaving a permanent record of its footprints. Rats displaying the ECC syndrome were unable to walk on the elevated pathway, so their footprints were recorded in the open field. Stride length and stride width were measured, as these parameters had been previously reported to be modified after trans-crotononitrile exposure (Seoane et al., 2005
).
Holding time on a vertical ladder.
A parallel bar grid made of plastic-covered wire (3 mm wide, spaced 1.8 cm) was used as a ladder. This ladder was vertically placed inside the acrylic tube of a hot plate test apparatus (Model-DS37, Ugo Basile, Comerio, Va, Italy), and covered with a board to prevent escape of the rat. The hot plate temperature was set at 56°C. The animals were trained to avoid the hot plate by holding onto the vertical ladder during a pre-fixed time interval until lifted by the experimenter. The rats were trained for 4 pre-test days at increasing time intervals, two trials per day, following the sequence 20, 40, 60, 90, 90, 90, 90, and 90 s. On the test days, rats were allowed to escape after 120 s, or when they had climbed the ladder for the third time after two shorter holding episodes. The mean holding time of these two episodes, or the maximal 120 s time was recorded for each animal.
Histology
To identify degenerating neurons in the CNS, the fixative solution consisted of 4% paraformaldehyde in 0.1 M phosphate buffer (pH 7.4). Brain and spinal cord tissues were removed from the perfusion-fixed animals and immersed in the same fixative at 4°C for 14 days. To examine all brain regions as well as the spinal cord, the whole brain and one slice sample from both the cervical and the lumbar regions of the spinal cord were cut in transverse sections (50 µm) using a Leica VT1000M vibrating blade microtome. Every third section was dried onto a microscopy slide for subsequent staining with Fluoro-Jade B (Schmued and Hopkins, 2000a, 2000b
), while the other two sections were cryoprotected and stored at 32°C for further analysis if required. In some experiments, the sections were co-stained with 4'-6-diamidino-2-phenylindole (DAPI), a stain with affinity for double-stranded DNA that labels cell nuclei; a second series of sections were stained with cresyl violet. Degenerating neurons were identified by comparison of Fluoro-Jade B stained sections with the appearance of the corresponding structures in the normal brain, according to the atlases by Paxinos et al. (1999a
, 1999b
). Observation of the DAPI and cresyl violet stains was used to improve or confirm the identification of the damaged structures.
To assess inner ear morphology in rats administered hexadienenitrile, we examined surface preparations of the vestibular and auditory sensory epithelia by SEM, as previously done with IDPN (Llorens et al., 1993b; Llorens and Rodríguez-Farré, 1997
; Seoane et al., 2001
), allylnitrile (Balbuena and Llorens, 2001
), and cis- and trans-crotononitrile (Balbuena and Llorens, 2003
). Briefly, the fixative solution consisted of 2.5% glutaraldehyde in 0.1 M cacodylate buffer (pH 7.2). After perfusion, the sensory epithelia in the temporal bones were dissected out in the same fixative and allowed an additional 1.5 h of fixation. The dissection procedure usually provides the complete set of vestibular receptors, the entire apical turn of the organ of Corti, and representative fragments of its middle and basal turns. The samples were then post-fixed for 1 h in 1% osmium tetroxide in cacodylate buffer and subsequently stored for 1272 h in 70% ethanol at 4°C. They were then dehydrated with increasing concentrations of ethanol up to 100%, dried in a critical-point dryer using liquid CO2, coated with 5 nm of gold, and stored in a vacuum chamber for 13 days. The epithelia were then observed in a LEICA 360 SEM at an accelerating voltage of 715 kV.
Statistics
Vertical ladder data were analyzed using the Kruskal-Wallis analysis of variance, with pair-wise comparisons analyzed with the Mann-Whitney U-test. Other data were tested with one-way analysis of variance (ANOVA) or repeated measures MANOVAWilks' criterionwith day as the within-subject factor. Orthogonal contrasts, followed by Duncan's test when applicable, were used for post-hoc analysis. The level was set at 0.05. The SPSS 12.0.1 for Windows program package was used.
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RESULTS |
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All the nitriles significantly decreased the body weight of the animals. The greatest effect was observed for IDPN, with a maximal loss of body weight at day 8 after the last dose, when a 21% loss with respect to pre-dosing values was recorded. Body weight increased thereafter, but it did not recover to control levels, and mean weight for the IDPN group was only 76% of control mean values at day 21. The maximal weight loss caused by the other nitriles was in the 1015% range and occurred by day 5 after the last dose. As with IDPN, no compensation occurred, and final (day 21) body weights were lower than control body weights in the trans-crotononitrile (90%), cis-crotononitrile (89%), hexadienenitrile (91%), and allylnitrile (87%) groups.
Animals treated with allylnitrile, cis-crotononitrile, or IDPN showed a clouding of the cornea, largely reversible, as previously described (Balbuena and Llorens, 2001, 2003
; Seoane et al., 1999
). In contrast, no changes in corneal transparency were observed in animals treated with hexadienenitrile or trans-crotononitrile.
Effects of the Nitriles on Behavior
Simple observation of the animals indicated that nitrile treatment resulted in the development of one of two clearly different syndromes of abnormal motor behavior. Rats treated with IDPN, allylnitrile, or cis-crotononitrile developed the ECC syndrome (Selye, 1957), characterized by hyperactivity, circling, and head bobbing. This was associated with increased ratings in the tail-hang test. Ratings of 23 were recorded on day 1 after the three IDPN doses, and as early as 1 day after the first dose of allylnitrile or cis-crotononitrile. A full ECC syndrome and tail-hang rating scores of 34 were observed in all of these animals on day 5 post-dosing. Rats treated with trans-crotononitrile or hexadienenitrile showed a syndrome of marked impairment of limb control with paresis and a gait disturbance characterized by faltering locomotion but with no hyperactivity, circling, or head bobbing. Tail-hang scores for these animals, like those for control animals, were 0 throughout the entire experimental period, although a rating of 1 was occasionally given.
Assessment of vestibular function with the full test battery (Fig. 1) demonstrated a marked and permanent loss in animals treated with IDPN, allylnitrile, or cis-crotononitrile, whereas animals treated with trans-crotononitrile or hexadienenitrile showed no loss of vestibular function.
In the open field animals, the groups of animals treated with any of the nitriles showed a decreased rearing activity at each time post exposure (Fig. 2A), significantly below levels noted in the control group. In contrast, the different nitriles had different effects on locomotor activity (Fig. 2B). At day 1 after treatment, significantly decreased locomotor activity was recorded for IDPN, trans-crotononitrile, and hexadienenitrile animals. The effect of trans-crotononitrile and hexadienenitrile was transient, and no differences from control animals were observed for these groups at later points in time. Rats treated with allylnitrile or cis-crotononitrile were markedly hyperactive on days 6 and 21, and IDPN rats were hyperactive on day 21.
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Effects of the Nitriles on the Central Nervous System
Control animals showed no Fluoro-Jade B labeling in any part of the CNS. Similarly, rats treated with IDPN showed no cell labeling with Fluoro-Jade B in any part of the CNS, although punctuate staining was consistently found in many glomeruli of the olfactory bulbs (Fig. 5A, Table 1). Because no bulbar neurons were labeled, this label must correspond to degeneration of the incoming terminals of the olfactory primary neurons, which is in agreement with the known ability of IDPN to damage the olfactory sensory epithelium and the silver staining observed in the olfactory glomeruli in association with this damage (Genter et al., 1992; Llorens et al., 1993a
). Like IDPN rats, cis-crotononitrile rats showed no neuronal degeneration, but labeling of the primary terminals was found in a few glomeruli in the olfactory bulbs of only 2 of 3 rats examined. Punctuate staining in a few olfactory glomeruli was also the only finding in brain sections of allylnitrile animals stained with Fluoro-Jade B, while no labeling was evident in any other brain region (Fig. 5B, Table 1).
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Hexadienenitrile exposure resulted in labeling of neurons by the Fluoro-Jade B stain in several brain regions (Fig. 6, Table 1). An extensive neuronal degeneration, identical to that recorded for the trans-crotononitrile animals, occurred in the inferior olive (Fig. 6A) and the piriform cortex (Fig. 6B). All of the hexadienenitrile animals showed a lesion significantly larger than that of the trans-crotononitrile animals in the lateral entorhinal cortex, and this lesion extended to the parasubiculum through a band deep across the medial entorhinal cortex area while sparing the superficial layers of this last area (Fig. 6C). Hexadienenitrile also caused a consistent labeling of neurons in the prelimbic and possibly the anterior cingulate areas of the prefrontal cortex (Fig. 6D), and in a more sparse way in the M2 area of the frontal cortex (Fig. 6E). A few neurons were also labeled in the dorsal transition zone. Only the two animals examined at 2 days after dosing showed labeling of a very few neurons in parietal and temporal regions of the cortex, and also of nerve terminals in the olfactory glomeruli. One of these animals also showed a marked labeling of the anterodorsal thalamic nucleus, as well as two focal areas of neuronal degeneration in the cerebellum. These cerebellar lesions were unilateral and involved both the Purkinje and granular cells (Fig. 6F).
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DISCUSSION |
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The permanent behavioral syndrome induced by IDPN in rodents, also known as the "ECC syndrome" (Selye, 1957), is easily recognized by the naked eye. While the same syndrome is also caused by allylnitrile and cis-crotononitrile (Balbuena and Llorens 2001
, 2003
; Tanii et al., 1989a
,b
), recent data indicate that trans-crotononitrile induces a very different syndrome of motor dysfunction in the rat (Balbuena and Llorens 2003
; Seoane et al., 2005
). In the present series of experiments we have observed that hexadienenitrile also induces this second syndrome. The neurotoxic nitriles can thus be divided into two groups according to their overt behavioral effects. This conclusion was also supported by the quantitative data from the present study, in which the same test methods were used to characterize the behavioral effects of these five nitriles.
On the one hand, IDPN, allylnitrile, and cis-crotononitrile induced high scores in the vestibular test battery and hyperactivity in the open field, but did not significantly decrease stride length. The fact that IDPN animals showed reduced activity before the permanent hyperactivity became apparent was in good agreement with previous data (Llorens et al., 1993b; Llorens and Rodríguez-Farré, 1997
) and may result from a combination of causes, including the slower progression of the vestibular toxicity of IDPN in comparison with cis-crotononitrile and allylnitrile (Balbuena and Llorens, 2001
), the coexistence of other toxic actions, such as the neurofilamentous axonopathy, and a larger degree of body weight loss. The lack of effect of these nitriles on stride length was a remarkable finding, because most aspects of motor control are profoundly affected in the ECC syndrome.
On the other hand, trans-crotononitrile and hexadienenitrile did not modify the vestibular rating scores and did not increase locomotor activity in the open field, but they did cause a marked decrease in stride length. As previously reported for trans-crotononitrile (Seoane et al., 2005), both this nitrile and hexadienenitrile significantly reduced animals' ability to hold onto a vertical grid, although this test was unsuitable for hyperactive animals treated with the other nitriles. The behavior of the hexadienenitrile and trans-crotononitrile animals on the ladder suggested that they were impaired in their ability to maintain the isometric muscle contraction required by the task. Common effects of all of the nitriles under study were the reduction in rearing activity and the increase in hindlimb stride width. These similarities probably result from the fact that both syndromes include impaired balance through loss of either vestibular or olivo-cerebellar function (see below). It is also of interest that IDPN, allylnitrile, and cis-crotononitrile caused corneal opacity, whereas trans-crotononitrile and hexadienenitrile did not, which further supports the simple hypothesis that two different mechanisms of toxicity are involved in causing the two behavioral syndromes. The isomeric specificity of the two crotononitrile isomers noticeably illustrates that strict structural requirements critically determine the neurotoxic effect of the nitriles.
The Fluoro-Jade B study did not reveal degenerating neurons in the CNS of rats at 7 days after treatment with IDPN, allylnitrile, or cis-crotononitrile, a time at which the ECC was fully developed. The Fluoro-Jade fluorochromes selectively and sensitively label neurons at a late stage in degeneration, with quite a long time window for labeling (Poirier et al., 2000; Schmued and Hopkins, 2000a
, 2000b
); for instance, they are able to reveal degenerating inferior olive neurons from 1 to at least 12 days after exposure to trans-crotononitrile (Seoane et al., 2005
). We thus conclude that no central neuron degeneration was associated with the ECC syndrome. The present Fluoro-Jade B data for IDPN are in good agreement with our previous silver stain data (Llorens et al., 1993a
), indicating that the incoming primary olfactory terminals are the only prominent "central" target for IDPN-induced neuronal degeneration, with no evidence for other major central targets that could account for the syndrome. Nevertheless, Fluoro-Jade B is not a reliable marker for terminal degeneration: it failed to reveal in the cerebellum the climbing fibers from the degenerating inferior olive neurons in trans-crotononitrile and hexadienenitrile animals (see also Seoane et al., 2005
). Thus, the greater sensitivity of silver stains in revealing degenerating axons may explain why no degenerating axons were observed in brain areas of IDPN animals, where sparse axonal degeneration had been found in the silver stain study (Llorens et al., 1993b
). In the olfactory bulbs, the extent of labeling following allylnitrile and cis-crotononitrile was small compared to that following IDPN, which is in agreement with the indirect data suggesting that the olfactory damage caused by the former is smaller than that caused by the latter (Balbuena and Llorens 2001
, 2003
). As discussed above (see Introduction), axonopathy is not associated with the ECC syndrome either. It thus becomes apparent that the peripheral vestibular toxicity of IDPN, allylnitrile, and cis-crotononitrile fully accounts for the syndrome.
In contrast to the ECC-inducing nitriles, trans-crotononitrile and hexadienenitrile caused selective neuronal degeneration in the CNS. The pattern of neuronal degeneration coincided for both nitriles in its main targets (inferior olive and piriform cortex) and showed a greater involvement of secondary targets (lateral entorhinal cortex/parasubiculum, frontal cortex, prefrontal cortex) in hexadienenitrile-treated rats as compared to trans-crotononitrile-treated rats. Whereas the lack of auditory and vestibular effects has already been reported for trans-crotononitrile (Balbuena and Llorens, 2003), a similar lack of auditory and vestibular toxicity has been determined here for hexadienenitrile. In previous studies, we determined that the motor deficits caused by trans-crotononitrile resemble but are not identical to those induced by 3-acetylpyridine, owing to the fact that both chemicals target the inferior olive but show differences in the extent to which different subnuclei of the olive are affected (Seoane et al., 2005
). Hexadienenitrile effects were identical to those of trans-crotononitrile in both stride length, a parameter less severely altered by 3-acetylpyridine, and vertical holding time, a parameter not altered by 3-acetylpyridine (Seoane et al., 2005
). Although the functional consequences of some of the toxic effects of trans-crotononitrile and hexadienenitrile, such as the degeneration of the piriform cortex or of the entorhinal/parasubicular region, remain to be studied, current knowledge about the function of the different brain regions makes it possible to give a satisfactory explanation of their motor effects. The inferior olive is the exclusive source of the climbing fibers to the cerebellum, and its degeneration results in major loss of cerebellar function. As discussed in detail elsewhere (Seoane et al., 2005
), the motor effects of trans-crotononitrile are likely to be due mainlyperhaps onlyto the extensive degeneration it causes in the inferior olive complex. In the case of hexadienenitrile, a number of targets were affected to a larger extent than in the case of trans-crotononitrile. However, many of these regions are known to be involved in functions other than the motor function, such as olfaction or memory in the case of the entorhinal cortex. The neurons degenerating in the frontal cortex need to be considered here: these could have a motor function, but they were scarce in number. Taken together with the fact that the motor effects of hexadienenitrile could not be distinguished from those of trans-crotononitrile, this suggests that the motor syndrome caused by hexadienenitrile was also likely to be mainly due to the degeneration of the inferior olive.
Some of the hexadienenitrile animals exhibited terminal degeneration in the olfactory glomeruli indicative of primary olfactory neuron degeneration. Thus, olfactory toxicity could be a property of nitriles that are toxic to either the audiovestibular system or the inferior olive. Available evidence suggests that the olfactory toxicity of IDPN may involve particular metabolic pathways not necessarily identical to those putatively involved in its vestibular toxicity (Genter et al., 1994). Another observation worth discussing is the focal lesion found in one of the 5 hexadienenitrile animals. The focal nature of the lesion would suggest that it was not related to the treatment. However, identical focal lesions had been recorded in the cerebellum in 2 of 3 rats dosed with three daily doses of 60 mg kg1 of allylnitrile from a preliminary study (unpublished data); one of these animals also displayed focal lesions in the striatum. This suggests that these lesions could be related to nitrile treatment. One mechanism causing these lesions could be vascular damage; hemorrhagic spots have been observed in the brains of allylnitrile-treated mice (Tanii et al., 1989b
).
In conclusion, the present and previous data indicate that neurotoxic nitriles induce one of two syndromes of abnormal motor behavior: (1) the ECC syndrome caused by IDPN, allylnitrile, and cis-crotononitrile, and resulting from degeneration of the vestibular sensory hair cells with no CNS toxicity role, and (2) the syndrome of faltering movements, caused by trans-crotononitrile and hexadienenitrile, and resulting from degeneration of the inferior olive neurons. In addition, nitriles in either group may eventually cause other neurotoxic effects common to both, such as olfactory mucosa degeneration or neurovascular damage, which are, except for the olfactory toxicity of IDPN, still poorly characterized.
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NOTES |
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ACKNOWLEDGMENTS |
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REFERENCES |
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Balbuena, E., and Llorens, J. (2003). Comparison of cis- and trans-crotononitrile effects in the rat reveals specificity in the neurotoxic properties of nitrile isomers. Toxicol. Appl. Pharmacol. 187, 89100.[CrossRef][ISI][Medline]
Barone, S., Jr., Herr, D. W., and Crofton, K. M. (1995). Effects of 3,3'-iminodipropionitrile on the peripheral structures of the rat visual system. Neurotoxicology 16, 451468.[ISI][Medline]
Cadet, J. L. (1989). The iminodipropionitrile (IDPN)-induced dyskinetic syndrome: Behavioral and biochemical pharmacology. Neurosci. Biobehav. Rev. 13, 3945.[CrossRef][ISI][Medline]
Chou, S. M., and Hartmann, H. A. (1964). Axonal lesions and waltzing syndrome after IDPN administration in rats. With a concept"Axostasis." Acta Neuropathol. 3, 428450.[CrossRef]
Clark, A. W., Griffin, J. W., and Price, D. L. (1980). The axonal pathology in chronic IDPN intoxication. J. Neuropathol. Exp. Neurol. 39, 4255.[ISI][Medline]
Crofton, K. M., and Knight, T. (1991). Auditory deficits and motor dysfunction following iminodipropionitrile administration in the rat. Neurotoxicol. Teratol. 13, 575581.[CrossRef][ISI][Medline]
Crofton, K. M., Janssen, R., Prazma, J., Pulver, S., and Barone, S., Jr. (1994). The ototoxicity of 3,3'-iminodipropionitrile: Functional and morphological evidence of cochlear damage. Hear. Res. 80, 129140.[CrossRef][ISI][Medline]
Delay, J., Pichot, P., Thuillier, J., and Marquiset, J. P. (1952). Action de l'amino-dipropionitrile sur le comportement moteur de la souris blanche. C. R. Soc. Biol. 146, 533534.[ISI]
DeVito, S. C. (1996). Designing safer nitriles, In: Designing Safer Chemicals (S. C. DeVito, and R. L. Garrett, Eds.), pp. 194223. American Chemical Society, Washingto, DC.
Fritschi, J. A., Lauterburg, T., and Burgunder, J. M. (2003). Expression of neurotransmitter genes in motor regions of the dyskinetic rat after iminodipropionitrile. Neurosci. Lett. 347, 4548.[CrossRef][ISI][Medline]
Genter, M. B., Llorens, J., O'Callaghan, J. P., Peele, D. B., Morgan, K. T., and Crofton, K. M. (1992). Olfactory toxicity of ß,ß'-iminodipropionitrile (IDPN) in the rat. J. Pharmacol. Exp. Ther. 263, 14321439.[Abstract]
Genter, M. B., Deamer, N. J., Cao, Y., and Levi, P. E. (1994). Effects of P450 inhibition and induction on the olfactory toxicity of beta,beta'-iminodipropionitrile (IDPN) in the rat. J. Biochem. Toxicol. 9, 3139.[ISI][Medline]
Genter, M. B., Owens, D. M., Carlone, H. B., and Crofton, K. M. (1996). Characterization of olfactory deficits in the rat following administration of 2,6-dichlorobenzonitrile (dichlobenil), 3,3'-iminodipropionitrile, or methimazole. Fundam. Appl. Toxicol. 29, 7177.[CrossRef][ISI][Medline]
Herr, D. W., King, D., Barone, S., Jr., and Crofton, K. M. (1995). Alterations in flash evoked potentials (FEPs) in rats produced by 3,3'-iminodipropionitrile (IDPN). Neurotoxicol. Teratol. 17, 645656.[CrossRef][ISI][Medline]
Hunt, M. A., Miller, S. W., Nielson, H. C., and Horn, K. M. (1987). Intratympanic injections of sodium arsanilate (atoxil) solution results in postural changes consistent with changes described for labyrinthectomized rats. Behav. Neurosci. 101, 427428.[CrossRef][ISI][Medline]
Llorens, J., Aguiló, A., and Rodríguez-Farré, E. (1998). Behavioral disturbances and vestibular pathology following crotonitrile exposure in rats. J. Periph. Nerv. Sys. 3, 189196.[ISI][Medline]
Llorens, J., Crofton, K. M., and O'Callaghan, J. P. (1993a). Administration of 3,3'-iminodipropionitrile to the rat results in region-dependent damage to the central nervous system at levels above the brain stem. J. Pharmacol. Exp. Ther. 265, 14921498.[Abstract]
Llorens, J., Demêmes, D., and Sans, A. (1993b). The behavioral syndrome caused by 3,3'-iminodipropionitrile and related nitriles in the rat is associated with degeneration of the vestibular sensory hair cells. Toxicol. Appl. Pharmacol. 123, 199210.[CrossRef][ISI][Medline]
Llorens, J., and Rodríguez-Farré, E. (1997). Comparison of behavioral, vestibular, and axonal effects of subchronic IDPN in the rat. Neurotoxicol. Teratol. 19, 117127.[CrossRef][ISI][Medline]
Nomoto, N. (2004). Inhibitory effect of free radical scavenger, MCI-186, in the increase of hydroxyl radical induced by iminodipropionitrile in rats. J. Neurol. Sci. 219, 4144.[CrossRef][ISI][Medline]
O'Donoghue, J. L. (2000). 2,4-Hexadiene-1-nitrile. In Experimental and Clinical Neurotoxicology (P. S. Spencer, H. H. Schaumburg, and A. C. Ludolph, Eds.), 2nd edition, p. 632. Oxford University Press, New York.
Ossenkopp, K.-P., Prkacin, A., and Hargreaves, E. L. (1990). Sodium arsanilate-induced vestibular dysfunction in rats: Effects on open-field behavior and spontaneous activity in the automated digiscan monitoring system. Pharmacol. Biochem. Behav. 36, 875881.[CrossRef][ISI][Medline]
Parker, A. J., and Clarke, K. A. (1990). Gait topography in rat locomotion. Physiol. Behav. 48, 4147.[CrossRef][ISI][Medline]
Paxinos, G., Kus, L., Ashwell, K. W. S., and Watson, C. (1999a). Chemoarchitectonic Atlas of the Rat Forebrain. Academic Press, San Diego, CA.
Paxinos, G., Carrive, P., Wang, H., and Wang, P.-Y. (1999b). Chemoarchitectonic Atlas of the Rat Brainstem. Academic Press, San Diego, CA.
Poirier, J. L., Capek, R., and De Koninck, Y. (2000). Differential progression of dark neuron and Fluoro-Jade labelling in the rat hippocampus following pilocarpine-induced status epilepticus. Neuroscience 97, 5968.[CrossRef][ISI][Medline]
Schmued, L. C., and Hopkins, K. J. (2000a). Fluoro-Jade B: A high affinity fluorescent marker for the localization of neuronal degeneration. Brain Res. 874, 123130.[CrossRef][ISI][Medline]
Schmued, L. C., and Hopkins, K. J. (2000b). Fluoro-Jade: Novel fluorochromes for detecting toxicant-induced neuronal degeneration. Toxicol. Pathol. 28, 9199.[ISI][Medline]
Selye, H. (1957). Lathyrism. Rev. Canad. Biol. 16, 182.[Medline]
Seoane, A., Apps, R., Balbuena, E., Herrero, L., and Llorens, J. (2005). Differential effects of trans-crotononitrile and 3-acetylpyridine on inferior olive integrity and behavioural performance in the rat. Eur. J. Neurosci. 22, 880894.[CrossRef][ISI][Medline]
Seoane, A., Dememes, D., and Llorens, J. (2001). Relationship between insult intensity and mode of hair cell loss in the vestibular system of rats exposed to 3,3'-iminodipropionitrile. J. Comp. Neurol. 439, 385399.[CrossRef][ISI][Medline]
Seoane, A., Espejo, M., Pallàs, M., Rodríguez-Farré, E., Ambrosio, S., and Llorens, J. (1999). Degeneration and gliosis in rat retina and central nervous system following 3,3'-iminodipropionitrile exposure. Brain Res. 833, 258271.[CrossRef][ISI][Medline]
Shoham, S., Chen, Y.-C., Devietti, T. L., and Teitelbaum. (1989). Deafferentation of the vestibular organ: Effects on atropine-resistant EEG in rats. Psychobiology 17, 307314.[ISI]
Slagel, D. E., and Hartmann, H. A. (1965). The distribution of neuroaxonal lesions in mice injected with iminodipropionitrile with special reference to the vestibular system. J. Neuropathol. Exp. Neurol. 24, 599620.[ISI][Medline]
Tanii, H., Zang, X.-P., Saito, N., and Saijoh, K. (2000). Involvement of GABA neurons in allylnitrile-induced dyskinesia. Brain Res. 887, 454459.[CrossRef][ISI][Medline]
Tanii, H., Hayashi, M., and Hashimoto, K. (1989a). Nitrile-induced behavioral abnormalities in mice. Neurotoxicology 10, 157166.[ISI][Medline]
Tanii, H., Kurosaka, Y., Hayashi, M., and Hashimoto, K. (1989b). Allylnitrile: A compound which induces long-term dyskinesia in mice following a single administration. Exp. Neurol. 103, 6467.[CrossRef][ISI][Medline]
Wakata, N., Araki, Y., Sugimoto, H., Iguchi, H., and Kinoshita, M. (2000). IDPN-induced monoamine and hydroxyl radical changes in the rat brain. Neurochem. Res. 25, 401404.[CrossRef][ISI][Medline]
Zang, X. P., Tanii, H., Kobayashi, K., Higashi, T., Oka, R., Koshino, Y., and Saijoh, K. (1999). Behavioral abnormalities and apoptotic changes in neurons in mice brain following a single administration of allylnitrile. Arch. Toxicol. 73, 2232.[CrossRef][ISI][Medline]
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