Mold inhalation causes innate immune activation, neural, cognitive and emotional dysfunction.

Individuals living or working in moldy buildings complain of a variety of health problems including pain, fatigue, increased anxiety, depression, and cognitive deficits. The ability of mold to cause such symptoms is controversial since no published research has examined the effects of controlled mold exposure on brain function or proposed a plausible mechanism of action. Patient symptoms following mold exposure are indistinguishable from those caused by innate immune activation following bacterial or viral exposure. We tested the hypothesis that repeated, quantified doses of both toxic and nontoxic mold stimuli would cause innate immune activation with concomitant neural effects and cognitive, emotional, and behavioral symptoms. We intranasally administered either 1) intact, toxic Stachybotrys spores; 2) extracted, nontoxic Stachybotrys spores; or 3) saline vehicle to mice. As predicted, intact spores increased interleukin-1ß immunoreactivity in the hippocampus. Both spore types decreased neurogenesis and caused striking contextual memory deficits in young mice, while decreasing pain thresholds and enhancing auditory-cued memory in older mice. Nontoxic spores also increased anxiety-like behavior. Levels of hippocampal immune activation correlated with decreased neurogenesis, contextual memory deficits, and/or enhanced auditory-cued fear memory. Innate-immune activation may explain how both toxic mold and nontoxic mold skeletal elements caused cognitive and emotional dysfunction.

Differential effects of exposure to toxic or nontoxic mold spores on brain inflammation and Morris water maze performance.

People who live or work in moldy buildings often complain of "brain fog" that interferes with cognitive performance. Until recently, there was no published research on the effects of controlled exposure to mold stimuli on cognitive function or an obvious mechanism of action, fueling controversy over these claims. The constellation of health problems reported by mold-exposed individuals (respiratory issues, fatigue, pain, anxiety, depression, and cognitive deficits) correspond to those caused by innate immune activation following exposure to bacterial or viral stimuli. To determine if mold-induced innate immune activation might cause cognitive issues, we quantified the effects of both toxic and nontoxic mold on brain immune activation and spatial memory in the Morris water maze. We intranasally administered either 1) intact, toxic Stachybotrys chartarum spores; 2) ethanol-extracted, nontoxic Stachybotrys chartarum spores; or 3) control saline vehicle to mice. Inhalation of nontoxic spores caused significant deficits in the test of long-term memory of platform location, while not affecting short-term memory. Inhalation of toxic spores increased motivation to reach the platform. Interestingly, in both groups of mold-exposed males, numbers of interleukin-1ß-immunoreactive cells in many areas of the hippocampus significantly correlated with latency to find the platform, path length, and swimming speed during training, but not during testing for long-term memory. These data add to our prior evidence that mold inhalation can interfere with cognitive processing in different ways depending on the task, and that brain inflammation is significantly correlated with changes in behavior.

Neurotoxic effects of DSP-4 on the central noradrenergic system in male zebra finches.

When administered systemically, the noradrenergic neurotoxin N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine (DSP-4) appears to target the noradrenergic innervation originating in the locus coeruleus causing long-term decrements in noradrenergic function. In songbirds, DSP-4-treatment decreased female-directed singing by males and copulation solicitation responses of females to male songs. However, DSP-4 treatment in songbirds did not lower measures of NE function in the brain to the same extent as it does in mammals. The current study had two goals: determining if two DSP-4 treatments 10 days apart would cause significant decrements in noradrenergic function in male zebra finches and determining if, as in other species, the noradrenergic innervation of midbrain and cortical areas would be profoundly affected while hypothalamic areas were spared. Dopamine-beta-hydroxylase immunoreactivity (DBH-ir) was quantified in thirteen brain regions (five vocal control nuclei, one auditory nucleus, two hypothalamic nuclei, and five additional areas that demonstrated high DBH labeling in controls). Within 20 days, DSP-4 treatment profoundly reduced the number of DBH-ir cells in both the locus coeruleus and ventral subcoeruleus. Unlike a previous study, DBH labeling delineated four out of five vocal control nuclei and an auditory nucleus. As expected, DSP-4 treatment significantly decreased DBH labeling in all areas examined in the mesencephalon and telencephalon without significantly affecting DBH-ir in hypothalamic areas. This double treatment regime appears to be much more effective in decreasing noradrenergic function in songbirds than the single treatment typically used.

Dopaminergic modulation of reproductive behavior and activity in male zebra finches.

We previously demonstrated that hormone treatments which stimulate female-directed singing increased levels and turnover of dopamine (DA) in brain areas controlling the motor patterning of song. To help determine how DA affects singing, we quantified the effects of treating adult male finches with the D1/D2 receptor antagonist cis-flupenthixol. Adult males were given subcutaneous silastic implants of androgen, in case drug treatment interfered with androgen secretion. One week later, they were tested with females. Males were divided into three groups matched for levels of courtship singing. Males were then subcutaneously implanted with osmotic minipumps containing either saline, a low, or a high dose of cis-flupenthixol. Each male was tested with a different female 5 and 10 days after implantation to determine how this D1/D2 receptor antagonist affected behavior. Both drug doses affected female-directed singing 5 days after initiation of treatment. High-dose males sang to females significantly less often than males in the other two groups. Low-dose males showed fewer high-intensity courtship displays in which males dance towards females as they sing. These effects on courtship singing were not seen at day 10, though other behavioral effects were seen at this time. Male beak wipes, rocks, following females and female withdrawals from males were also affected by drug treatment. General activity in the home cage was decreased by day 11. These data demonstrate that singing and several other female-directed behaviors are sensitive to perturbations in DA receptor function.

Hormonal modulation of singing: hormonal modulation of the songbird brain and singing behavior.

During the past three decades research on the hormonal control of singing has fundamentally altered our basic concepts about how hormones modulate brain function and activate behavior. Exciting discoveries first documented in songbird brains have since been documented in a wide variety of vertebrate species, including humans. Circulating hormones organize sexual dimorphisms in brain structure during development, activate changes in brain structure during adulthood, and modulate the addition of new neurons in the adult brain. The brain has proved to be the primary source of estrogens in general circulation in adult male finches. Studies of the hormonal modulation of singing are complicated by multiple sites of hormone production, multiple sites of hormone action, hormone metabolism by different tissues, the involvement of a variety of hormones, and the effects of social context. This chapter provides a brief review of these topics, as well as a brief overview of techniques used to study endocrine mechanisms controlling behavior.

Learning from bird brains: how the study of songbird brains revolutionized neuroscience.

During the past 30 years, songbirds have become a popular model for neuroscience research. The author reviews three fundamental discoveries that have revolutionized the field and changed the way we understand the structure and function of the brain.

Brief alteration in dopaminergic function during development causes deficits in adult reproductive behavior.

Our previous research revealed dramatic increases in dopaminergic function in vocal control and auditory nuclei in male zebra finches during the period of song learning. Such increases were not seen in the hypothalamic areas examined. In the current study, we manipulated dopamine receptor function during this period to determine how this might affect later singing behavior. Males were implanted with osmotic minipumps providing 0, 0.5, or 5 microg/g/day of the mixed D1/D2 dopamine receptor antagonist cis-flupenthixol from day 45 until day 57. At approximately 86 days of age, males were given subcutaneous silastic implants containing a maintenance dose of androgen, in case antagonist treatment interfered with adult androgen secretion. One week later, they began a series of three weekly tests to determine if this early treatment affected courtship singing. Males treated with the low dose of cis-flupenthixol showed profound decrements in courtship singing and copulatory behavior. Unlike saline-treated controls, low-dose males sang to females infrequently. High-intensity courtship displays in which males dance towards females while singing were most affected. Despite their decreased courtship singing, low-dose males were interested in females. They approached females as frequently as males in the other two groups, but antagonist-treated males were less likely to follow females if they moved. Low-dose males also attempted to mount females significantly less often than high-dose males. High-dose males groomed significantly less frequently than males in the other two groups. Thus, brief early treatment with cis-flupenthixol had profound and long-lasting effects on female-directed singing and on copulatory behavior, despite androgen treatment.

Vasotocin treatment inhibits courtship in male zebra finches; concomitant androgen treatment inhibits this effect.

Zebra finches evolved in arid areas of Australia. Their reproduction is stimulated by water availability, which is unpredictable. Cheng (Poult. Sci. Rev. 5 (1993) 37) hypothesized that the primary mechanism controlling reproduction in species relying on unpredictable cues should be inhibitory. The onset of stimulatory environmental conditions terminates the inhibition, allowing rapid initiation of reproduction. As the primary hormone regulating water balance in birds, arginine vasotocin (AVT) appears a likely candidate to modulate reproduction in finches. Drought conditions cause sustained AVT release, which in other species inhibits androgen production. To determine whether increased AVT inhibits reproductive behavior, intact males were tested with females and divided into three groups matched for courtship behavior. Osmotic minipumps containing (a) saline, (b) 264 ng AVT, or (c) 1320 ng AVT in saline were implanted subcutaneously and males tested 48 h later. AVT-treated males socialized with females, but the high dose significantly reduced singing and courtship displays. To determine whether AVT acted by depressing androgen secretion, additional males were given subcutaneous androgen implants and divided into two groups matched for courtship behavior. Males were then implanted with minipumps containing (a) saline or (b) the high AVT dose. Males treated with AVT plus androgen showed no deficits in courtship behavior. These data suggest that AVT secretion during periods of drought may inhibit reproduction by inhibiting androgen production. Inhibition of reproductive behavior by AVT may be a more general phenomenon. Large quantities of AVT or, in mammals the closely-related peptide vasopressin (VP), are released when animals are stressed, and high levels of AVT/VP may inhibit reproductive behavior. The extremely short half-life of these peptides means that once proximal factors become more favorable, the gonads should rapidly be released from the peptides' inhibitory actions.