Age-related cone abnormalities in zebrafish with genetic lesions in sonic hedgehog.

PURPOSE: Sonic hedgehog (Shh) signaling is essential for photoreceptor differentiation and retinal cell survival in embryonic zebrafish. The study was conducted to determine whether adult heterozygous carriers of mutant alleles for the shh gene display retinal abnormalities. METHODS: Retinal cryosections from young, middle-aged, and senescent wild-type and sonic-you(+/-) (syu(+/-)) zebrafish were probed with retinal cell type-specific markers. Contralateral retinal flatmounts from these fish, and from adult albino zebrafish subjected to light-induced photoreceptor damage followed by regeneration, were hybridized with blue cone opsin cRNA for quantitative analysis of the blue cone pattern. Retinal expression of shh mRNA was measured by quantitative RT-PCR. RESULTS: Regions of cone loss and abnormal cone morphology were observed in the oldest syu(+/-) zebrafish, although no other retinal cell type was affected. This phenotype was age-related and genotype-specific. Cone distribution in the oldest syu(+/-) zebrafish was predominantly random, as assessed by measuring the short-range pattern, whereas that of wild-type fish and the younger syu(+/-) zebrafish was statistically regular. A measure of long-range pattern revealed atypical cone aggregation in the oldest syu(+/-) zebrafish. The light-treated albino zebrafish displayed random cone patterns immediately after light toxicity, but showed cone aggregation on regeneration. Retinas from the syu(+/-) fish showed reduced expression of shh mRNA compared with those of wild-type siblings. CONCLUSIONS: The syu(+/-) zebrafish presents a model for the study of hereditary age-related cone abnormalities. The syu(+/-) retinas most likely experience progressive cone photoreceptor loss, accompanied by cone regeneration. Shh signaling may be required to maintain cone viability throughout life.

Habituation of the head-shake response induces changes in brain matrix metalloproteinases-3 (MMP-3) and -9.

Habituation is defined as a decrease in responsiveness to a repeatedly presented stimulus. The head-shake response (HSR) demonstrates several fundamental properties of habituation including sensitivity to the frequency and intensity of stimulation, and spontaneous recovery. This response shows behavioral plasticity; however the neural plasticity presumed to underlie this behavioral phenomenon has only recently been investigated. The present study initially compared male and female rats and noted equivalent habituation and spontaneous recovery. A second experiment utilized female rats to test the hypothesis that habituation induces changes in neural plasticity. At inter-session intervals (ISIs) of 5 min, 2, 6, and 24 h following HSR habituation independent groups of rats received a second habituation experience, then tissue samples were immediately collected from hippocampal, prefrontal and piriform cortices, and cerebellum. Western blots indicated significant elevations in the expression of matrix metalloproteinase-3 (MMP-3) in hippocampal, prefrontal and piriform cortices at a delay interval of 2 h, and in the prefrontal cortex at 24 h in habituated rats. Increases in active and pro MMP-9 activity were measured by zymography in the hippocampus of habituated rats over yoked controls. Decreases in active MMP-9 activity were seen in the prefrontal cortex, and in pro MMP-9 in the piriform cortex, of habituated as compared with yoked control rats. No changes in MMP-3 or MMP-9 were observed in the cerebellum, and no changes in MMP-2 were seen in any of the four structures examined. These results suggest that habituation of the HSR produced elevations in MMP-3 expression in three of the four structures presently examined, accompanied by increased MMP-9 activity in the hippocampus and decreases in the prefrontal cortex. However, cues present in the test environment appear to have provoked elevations in MMP-3 and -9 independent of those accompanying habituation.

Role of mitogen-activated protein kinases during recovery from head-shake response habituation in rats.

Habituation is defined as a decrease in responsiveness to a repeatedly presented stimulus. The head-shake response (HSR) consists of a rapid twisting of the head about the front-to-rear axis elicited by a stream of air to the ear. This response demonstrates several fundamental properties of habituation including sensitivity to the frequency and intensity of stimulation, and spontaneous recovery. Despite an abundance of behavioral data on the HSR, relatively little is known about its physiological mechanism(s). To address this issue, changes in mitogen-activated protein kinases (MAPK) were assessed 5 min and 2, 6, and 24 h following the habituation of the HSR. Three cascades of MAPK activity were measured in the cerebellum and hippocampal, prefrontal, and piriform cortices, including extracellular-response kinase (ERK), p-38 kinase (p-38), and stress-activated protein kinase (SAPK). Significant activation of p-38 and SAPK was observed in all four brain structures, accompanied by modest changes in ERK activity. Recovery of the HSR was characterized by decreasing MAPK activation with control levels re-established 24 h after habituation. The present results suggest that MAPK activation mediates recovery from habituation; however, these findings may also support alternative interpretations such that MAPK activation reflects the encoding of spatial cues associated with the testing environment and/or are due to stress induced by the habituation protocol.

Influence of hippocampectomy on habituation, exploratory behavior, and spatial memory in rats.

Two frequently cited functions of the hippocampus are mediation of spatial memories and habituation. The present investigation employed head-shake response (HSR) as the habituated behavior in intact and bilaterally hippocampectomized rats. This HSR appears to be minimally influenced by spatial cues. These rats were further tested on two behavioral paradigms that make use of spatial cues, namely open field object exploration, and the Morris water maze. The results indicate that hippocampectomized rats revealed habituation of the HSR, but not to objects within the open field. In agreement with previous reports, hippocampectomized rats were severely impaired both in acquiring and recalling the location of the submerged platform in the Morris water maze task. In a separate experiment independent groups of rats were trained on one of these three paradigms, and tissues were collected from hippocampal, prefrontal, and piriform cortices for the measurement of matrix metalloproteinases (MMPs) as markers of neural plasticity. There were significant MMP-9 elevations in the prefrontal and piriform cortices of rats tested using the object exploration task, in the prefrontal and hippocampal cortices of rats that solved the Morris water maze task, but minimal MMP changes in any tissues taken from HSR habituated rats. These results question the hypothesis that habituation is solely mediated by the hippocampus in favor of a process that utilizes different brain structures and degrees of neural plasticity dependent upon task requirements.