Abstract
Impairments in mood and cognitive function are the key brain abnormalities observed in Gulf war illness (GWI), a chronic multisymptom health problem afflicting ∼25% of veterans who served in the Persian Gulf War-1. Although the precise cause of GWI is still unknown, combined exposure to a nerve gas prophylaxis drug pyridostigmine bromide (PB) and pesticides DEET and permethrin during the war has been proposed as one of the foremost causes of GWI. We investigated the effect of 4 weeks of exposure to Gulf war illness-related (GWIR) chemicals in the absence or presence of mild stress on mood and cognitive function, dentate gyrus neurogenesis, and neurons, microglia, and astrocytes in the hippocampus. Combined exposure to low doses of GWIR chemicals PB, DEET, and permethrin induced depressive- and anxiety-like behavior and spatial learning and memory dysfunction. Application of mild stress in the period of exposure to chemicals exacerbated the extent of mood and cognitive dysfunction. Furthermore, these behavioral impairments were associated with reduced hippocampal volume and multiple cellular alterations such as chronic reductions in neural stem cell activity and neurogenesis, partial loss of principal neurons, and mild inflammation comprising sporadic occurrence of activated microglia and significant hypertrophy of astrocytes. The results show the first evidence of an association between mood and cognitive dysfunction and hippocampal pathology epitomized by decreased neurogenesis, partial loss of principal neurons, and mild inflammation in a model of GWI. Hence, treatment strategies that are efficacious for enhancing neurogenesis and suppressing inflammation may be helpful for alleviation of mood and cognitive dysfunction observed in GWI.
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INTRODUCTION
Nearly 25% of 700 000 veterans who served in the Persian Gulf War-1 (PGW-1) are diagnosed with Gulf war illness (GWI) (Golomb, 2008; Binns et al, 2008). GWI is a chronic multisymptom health problem that is poorly understood because the underlying pathologies causing different symptoms are unclear. Among the health problems, illnesses affecting the brain and musculoskeletal system appear to be more prevalent (Amato et al, 1997; Haley et al, 2000a, 2000b; Steele, 2000). Brain dysfunction is typified mainly by depression, anxiety, and learning and memory impairments (Haley et al, 2000a, 2000b; Odegard et al, 2012).
Although the precise etiology of GWI is unknown, several suspected causes have been proposed. Among these, the hypothesis that GWI is linked to a combination of exposures encountered by service personnel during the PGW-1 has received much attention. First, veterans who were stationed in the battlefield areas were believed to have consumed pyridostigmine bromide (PB) pills daily during the war (Binns et al, 2008). PB was employed as a prophylactic treatment (ie, as a reversible acetylcholinesterase (AChE) inhibitor) to protect against the possible attack with irreversible AChE inhibitors such as organophosphate nerve gas agents (Binns et al, 2008). Second, preparations for the PGW-1 comprised measures to offset infectious diseases transmitted by insects and ticks in the region. The measures included the use of pesticides for the area protection and the use of insect repellants on the skin and the uniform. The pesticides included the insecticide permethrin (PM) and the insect repellant N,N-diethyl-m-toluamide (DEET) (Haley and Kurt, 1997). Permethrin, a synthetic pyrethroid, is a widely used insecticide (Vijverberg and van den Bercken, 1990). Permethrin intoxication results as a consequence of the sustained opening of voltage-gated sodium channels leading to repetitive discharges after a single stimulus (Narahashi, 1985). The chemical DEET is the most commonly used insect repellant (Veltri et al, 1994). Although the precise target of DEET is unknown, extensive and repeated topical application of DEET leads to human poisoning including death (Chaney et al, 2000).
Thus, in view of the exposure of service personnel to both GWI-related (GWIR) chemicals (PB, PM, and DEET) and war-related stress, it is hypothesized that the neurological symptoms displayed by a significant number of PGW-1 veterans are because of synergistic interaction of PB with pesticides PM and DEET and/or stress (Binns et al, 2008; Friedman et al, 1996; Hyams et al, 1996; Everson et al, 1999; Steele et al, 2012; Abdullah et al, 2011; Torres-Altoro et al, 2011). This chemical exposure hypothesis is also supported by the report of the Research advisory committee (RAC) on GWI that the overall prevalence of GWI is greater in veterans who used higher amounts of pesticides than veterans who had limited exposure to pesticides during the PGW-1 (Binns et al, 2008). In this study, using a rat model, we investigated whether exposure to GWIR chemicals for 4 weeks would be sufficient to cause anxiety- and depressive-like behavior and/or cognitive dysfunction. Because changes such as reduced neurogenesis, neurodegeneration, or inflammation in the hippocampus may underlie impairments in mood and cognitive function (Bilbo et al, 2012; Deng et al, 2010; Eisch and Petrik, 2012), we also examined whether exposure to GWRI chemicals is associated with declined neurogenesis, loss of principal neurons, activation of microglia, and hypertrophy of astrocytes in the hippocampus.
MATERIALS AND METHODS
Animals
Three-month-old Sprague-Dawley rats obtained from Harlan (Indianapolis, IN) were randomly assigned to one of the four major groups (n=6/group/time point, total, 48): (1) vehicle (VEH) group receiving vehicle and handling daily for 4 weeks; (2) chemicals (CHEM) group receiving PM, DEET, and PB, and handling daily for 4 weeks; (3) chemicals plus stress (CHEM+STRESS) group receiving PM, DEET, PB, and 5 min of restraint stress daily for 4 weeks; and (4) naive control group.
Application of Chemicals and Stress
The chemical PB (1.3 mg/kg) was administered through oral gavage (500 μl in sterile water). Solutions of DEET (200 μl containing 40 mg/kg in 70% alcohol) and PM (200 μl, 0.13 mg/kg in 70% alcohol) were applied sequentially to fur-clipped skin areas located on the back of neck and the upper thoracic region. A rat restrainer was used for the induction of 5 min of restraint stress, as described in our previous study (Parihar et al, 2011). The doses of PB, PM, and DEET were chosen based on a previous study (Abdel-Rahman et al, 2002).
Behavioral Analyses
During the third month after the exposure, animals in all groups (n=6/group) were tested for mood and cognitive function using a variety of behavioral analyses in the following sequence: elevated plus maze test (EPMT, for assessing anxiety-like behavior), novel object recognition test (NORT, for examining object recognition memory), water maze test (WMT, for investigating spatial learning and memory), and forced swim test (FST, for assessing depressive-like behavior).
Analyses of Anxiety- and Depressive-Like Behavior
Animals were examined with EPMT and FST, as described in our recent reports (Parihar et al, 2011; Hattiangady and Shetty, 2012) and the Supplementary File. Numbers of open arm entries and times spent in open arms were considered as indices of anxiety-like behavior, and the amount of time spent in floating in FST was used as an index of depressive-like behavior.
Measurement of Recognition Memory Function
Recognition memory was measured using NORT, as described elsewhere (Broadbent et al, 2009; Parihar et al, 2011) and the Supplementary File.
Assessment of Spatial Learning and Memory Function
Spatial learning and memory function was measured through a WMT, as detailed in our recent reports (Parihar et al, 2011; Hattiangady and Shetty, 2012) and the Supplementary File.
Analyses of Hippocampal Neurogenesis
For analyses at an early time point, subgroups of animals from every group (n=6/group) received intraperitoneal injections of 5′-bromodeoxyuridine (BrdU; 50 mg/kg, once every 6 h for 18 h) immediately after the exposure regimen. Animals were perfused 6 h after the last BrdU injection and brain tissues processed for BrdU immunohistochemistry, BrdU and doublecortin (DCX) dual immunofluorescence and confocal microscopy, and DCX immunohistochemistry. For analyses of neurogenesis at an extended time point, animals that underwent behavioral tests were used. A week after the completion of behavioral tests (ie, in the fourth month after the exposure), animals received intraperitoneal injections of BrdU (100 mg/kg; once daily for 12 days). Animals were perfused a month after the last BrdU injection and brain tissues were processed for BrdU immunohistochemistry, BrdU and neuron-specific nuclear antigen (NeuN) dual immunofluorescence and confocal microscopy, and DCX immunohistochemistry (n=4–6 animals/group), as detailed in our previous reports (Hattiangady and Shetty, 2010; Parihar et al, 2011).
Measurement of Numbers of Newly Born Cells and Neurons
The numbers of newly born (BrdU+) cells and newly born (DCX+) neurons in the subgranular zone–granule cell layer (SGZ-GCL) of the dentate gyrus (DG) were measured from 30-μm-thick serial sections (every 15th) through the entire hippocampus via an optical fractionator method using StereoInvestigator, as detailed in the Supplementary File.
Quantification of Neuronal Differentiation of Newly Born Cells and Net Neurogenesis
We quantified the percentages of BrdU+ newly born cells in the SGZ-GCL expressing: (1) DCX in tissues collected 6 h after the last of four BrdU injections; and (2) NeuN in tissues collected 1 month after the last of 12 daily BrdU injections, using methods described in our earlier report (Hattiangady and Shetty, 2010). We measured net neurogenesis using data such as total numbers of BrdU+ cells and percentages of newly born cells that differentiate into DCX+ or NeuN+ neurons.
Analyses of NSCs in the Hippocampus
Serial sections (every 15th) through the entire hippocampus from tissues harvested for long-term neurogenesis analyses were processed for visualization of Sox-2 (a marker of neural stem cell (NSCs) and a subpopulation of astrocytes; Hattiangady and Shetty, 2008). The number of Sox-2+ cells in the SGZ was quantified (n=4 animals/group) as described in our earlier report (Hattiangady and Shetty, 2008) and the Supplementary File. Next, we performed dual immunofluorescence for Sox-2 and S-100β and quantified fractions of Sox-2+ cells expressing S-100β (mature astrocytes) and Sox-2+ cells lacking S-100β (putative NSCs) using a confocal microscope. We estimated the numbers of putative NSCs in the SGZ using data such as total numbers of Sox-2+ cells and percentages of Sox-2+ cells that lacked S-100β. To ascertain the proliferative behavior of NSCs, we performed dual immunofluorescence for Sox-2 and Ki-67 (an endogenous marker of proliferating cells) and quantified fractions of Sox-2+ cells expressing Ki-67. We appraised the numbers of putative NSCs in the SGZ exhibiting proliferation through data such as total numbers of Sox-2+ cells and percentages of Sox-2+ cells that express Ki-67.
Analyses of Hippocampal Neurodegeneration, Volume, and Inflammation
Serial sections (every 15th) through the entire hippocampus from tissues harvested for long-term neurogenesis analyses above were processed for NeuN immunostaining (Shetty et al, 2009). Next, the numbers of NeuN+ neurons in different cell layers of the hippocampus were stereologically measured (n=5/group; Shetty et al, 2009 and Supplementary File). Volumes of DG, CA1 and CA3 subfields, and the entire hippocampus (including fimbria) were measured through tracing of hippocampal regions and the entire hippocampus (including fimbria) in serial sections (n=5 animals/group) using Neurolucida (Microbrightfield). Additional sets of serial sections (every 20th) were processed for visualization of all astrocytes (GFAP immunohistochemistry), reactive astrocytes (nestin and vimentin immunohistochemistry), and activated microglia (ED-1 immunohistochemistry) using methods described elsewhere (Abdel-Rahman et al, 2004b; Hattiangady et al, 2004). The numbers of ED-1+ cells were quantified per section, whereas GFAP+ structures in different regions of the hippocampus were quantified through area fraction analysis using the software program ImageJ, as described in our earlier report (Shetty et al, 2004) and Supplementary Data File.
Characterization of the Effects of GWIR Chemicals on NSC Proliferation In Vitro
Hippocampi of postnatal day −1 rat pups were dissected, triturated, and processed as single-cell suspension (Hattiangady and Shetty, 2012). One hundred live cells suspended in 0.5 ml of NSC proliferation medium were plated per culture well in a 24-well plate in the presence of individual or combinations of GWIR chemicals (each at a concentration of 100 μM; n=16 culture wells/group). Cells were allowed to proliferate for 7 days. The numbers of neurospheres/100 live cells plated in different treated groups were measured to ascertain the extent of NSC proliferation.
Data Analyses
Values (mean±SEM) from different groups were compared using one-way ANOVA followed by Newman–Keuls multiple comparison post-tests. For learning analyses in WM tests, additional tests such as one-way and two-way repeated measures ANOVA (RM-ANOVA) with Bonferroni multiple comparisons post hoc tests were employed. Because VEH-treated rats did not differ from naive controls for any of the parameters measured, the experimental groups were compared with the VEH-treated group in all analyses.
RESULTS
Exposure to GWIR Chemicals Did Not Alter Body Weights or General Behavior of Animals
Exposure to CHEM or CHEM+STRESS did not cause major health defects in animals. This was evidenced by comparable increases in body weights between VEH-treated animals and animals treated with CHEM or CHEM+STRESS in the exposure period as well as 2 months after the exposure (p>0.05, F=0.96, two-way ANOVA; Supplementary Figure S1 and Supplementary Data File). Moreover, animals did not display discoloration of the fur or any other signs of significant pain and discomfort (such as porphyrin around eyes/nose, poor grooming, decreased mobility, or head tucked hunched posture).
Exposure to GWIR Chemicals Induced Depressive- and Anxiety-Like Behavior
Animals treated with CHEM or CHEM+STRESS exhibited increased levels of depressive- and anxiety-like behavior in FST and EPMT in comparison with VEH-treated animals (Figure 1). This was revealed through greater amount of time spent in immobility (or floating) in FST (p<0.0001, F=20.7; Figure 1a2), and fewer entries into open arms (p<0.0001, F=28.1; Figure 1b1) and reduced dwell time in open arms in EPMT (p<0.0001, F=22.9; Figure 1b2). Furthermore, animals treated with CHEM+STRESS exhibited greater immobility time and fewer open arm entries than animals treated with CHEM alone (p<0.05–0.01, Figure 1a2 and b1).
Exposure to GWIR Chemicals Resulted in Spatial Learning and Memory Dysfunction
Analyses of swim speeds revealed no statistical differences among the three groups. However, animals exposed to CHEM+STRESS exhibited 17% reduced swim speed than VEH-treated rats (Figure 1a]). Therefore, all learning data were analyzed using both swim path lengths and latency values. Both parameters revealed comparable findings and hence only swim path length data are illustrated (Figure 2a2). One-way RM-ANOVA on swim path lengths to reach the hidden platform over the learning sessions revealed that animals belonging to all three groups have the ability for spatial learning (p<0.0001; F-values: VEH=39.9, CHEM=7.5, and CHEM+STRESS=11.1; Figure 2a2). However, two-way RM-ANOVA revealed that exposure to GWIR chemicals had significant effect on learning curves (p<0.01, F=8.5). The post hoc tests revealed that swim path lengths were significantly longer in CHEM and CHEM+STRESS groups than the VEH group in the third learning session (p<0.05–0.01; Figure 2a2). Furthermore, analyses of swim path efficiency (the ratio of the shortest possible swim path length to actual swim path length) using two-way RM-ANOVA demonstrated that exposure to GWIR chemicals affected learning (p<0.0001, F=23.03). Animals exposed to CHEM or CHEM+STRESS displayed swim path efficiencies in the last five sessions of learning that were inferior to VEH-treated rats (p<0.05–0.0001; Figure 2a3). We also measured activity in the thigmotactic zone (TZ), an annular area measuring 18 cm width along the periphery of the pool. Activity in the TZ refers to an animal's propensity to move along the edge of its environment, and swimming for prolonged periods in the TZ during the course of WMT is attributed to anxiety or fear (Treit and Fundytus, 1998; Herrero et al, 2006). However, animals exposed to CHEM or CHEM+STRESS did not display increased anxiety in the WMT, which was evidenced through comparable swim path lengths in the TZ between rats belonging to these two groups and the VEH group (Figure 2a4, two-way RM-ANOVA, p>0.05, F=1.7). In addition, comparable average latency values to reach the platform in the visible platform test revealed similar visual sensory function in the three groups of rats (mean±SEM in seconds: VEH, 7.5±2.4; CHEM, 5.9±0.9; and CHEM+STRESS, 7.8±1.6, p>0.05, F=0.35). Thus, learning deficits seen in animals exposed to CHEM or CHEM+STRESS are not related to increased anxiety, motor disability, or visual sensory dysfunction. Data pertaining to activity in the TZ further implied that animals in these groups were able to focus on the learning task but their overall ability for learning was inferior to VEH-treated rats.
Rats treated with VEH spent greater amount of the probe test time in the platform quadrant (PQ, a quadrant of the pool where platform was placed during learning sessions) in comparison with all other quadrants. This was evidenced through ANOVA analyses of swim path lengths and dwell times in different quadrants (p<0.0001, F=12.6; Figure 2b2 and c1). In contrast, rats exposed to CHEM or CHEM+STRESS did not display greater affinity for the PQ vis-à-vis the other three quadrants (p>0.05, F=0.9–2.9, Figure 2b3). Memory retrieval dysfunction in rats exposed to CHEM or CHEM+STRESS was also apparent from shorter swim path lengths in the PQ than rats in the VEH group (p<0.05–0.01, Figure 2d1). Rats exposed to CHEM+STRESS also exhibited reduced dwell time in the PQ than VEH- or CHEM-treated rats (p<0.05, Figure 2d2). Furthermore, rats exposed to CHEM or CHEM+STRESS displayed longer swim path lengths for first entry to target area (TA, an area denoting the actual position of the platform, p<0.01, Figure 3e1). Rats exposed to CHEM+STRESS in addition showed longer swim path length values for their first entry to platform area (PA, an annular area denoting the position of the platform as well as the immediate surrounding region) and PQ than rats treated with VEH (p<0.05, Figure 2e2 and e3).
As rats exposed to CHEM+STRESS exhibited greater level of depressive- and anxiety-like behavior in FST and EPMT than other groups, we examined whether greatly impaired memory function in these rats are linked to increased despair through a principal component analysis (PCA). This analysis showed that memory dysfunction contributed to 40%, depression to 35%, and anxiety to 24% of the variance in principal component 1. Thus, analyses of principal components and thigmotactic activity in WMT together suggested that memory dysfunction, depression, and anxiety are comorbidities in this prototype of GWI. The results of PCA are detailed in the Supplementary Data File.
Exposure to GWIR Chemicals Did Not Impair Recognition Memory Function
Rats exposed to CHEM+STRESS spent greatly reduced time in object exploration, in comparison with both VEH- and CHEM-treated rats (p<0.0001, F=18.1; Supplementary Figure S2a1). Hence, an average time spent with the novel object by these rats was much less than that observed for VEH- or CHEM-treated rats (p<0.001, F=12.4; Supplementary Figure S2a2). However, the percentage of the total object exploration time spent with the novel object (object discrimination index) was comparable across the three groups (p>0.05, F=0.9; Supplementary Figure S2a3).
Exposure to GWIR Chemicals Resulted in Reduced Hippocampal Neurogenesis
In comparison with VEH-treated animals, animals exposed to CHEM or CHEM+STRESS displayed reduced production of new cells per day (p<0.0001, F=70.1; Figure 3a1 to d), no changes in neuronal differentiation of newly born cells (p>0.05, F=3.3; Figure 3e1 and f), diminished net neurogenesis (p<0.0001, F=98.4; Figure 3g), and reduced levels of ongoing neurogenesis (based on numbers of DCX+ immature neurons, p<0.0001, F=115.8; Figure 3h1 to k). Furthermore, in comparison with animals treated with CHEM alone, animals treated with CHEM+STRESS exhibited reduced levels of new cell production, net neurogenesis, and ongoing neurogenesis (p<0.001, Figure 3d, g, and k).
GWIR Chemical-Induced Reduced Neurogenesis Persisted for Prolonged Periods
Characterization of neurogenesis in the fourth month after the exposure regimen revealed a trend similar to that observed in the immediate postexposure period. Animals exposed to CHEM or CHEM+STRESS exhibited reduced production of new cells per day (p<0.001, F=19.8; Figure 4a1 to c2 and e1), no changes in neuronal fate-choice decision of newly born cells (p>0.05, F=3.9; Figure 4d1 to d3 and e2), diminished net neurogenesis (p<0.001, F=21.3; Figure 3e3), and reduced levels of ongoing neurogenesis (based on numbers of DCX+ immature neurons, p<0.0001, F=28.3; Figure 4f1 to i).
Moreover, animals treated with CHEM+STRESS exhibited reduced levels of net neurogenesis and ongoing neurogenesis than animals exposed to CHEM alone (p<0.05, Figure 4e3 and i).
Exposure to GWIR Chemicals Did Not Kill SGZ-NSCs But Inhibited Their Proliferation
Immunohistochemistry for Sox-2 suggested normal distribution (density) of Sox-2+ cells in the SGZ of all groups (Figure 5a1 to a3). Dual immunofluorescence analyses for Sox-2 and S-100β demonstrated comparable distribution of Sox-2+ cells expressing S-100β (Sox-2+ mature astrocytes) and Sox-2+ cells lacking S-100β (Sox-2+ putative NSCs) in all groups (Figure 5b1 to b3). Furthermore, total numbers of Sox-2+ cells and Sox-2+ putative NSCs in the SGZ were comparable across the three groups (p>0.05, F=1.8–4.2; Figure 5c1 and c2). However, analyses of the percentage of Sox-2+ cells that express Ki-67 (a marker of dividing cells, Figure 5d1 to e3) in the SGZ revealed fewer NSCs undergoing proliferation in animals exposed to CHEM or CHEM+STRESS in comparison with their counterparts in VEH-treated animals (p<0.05, F=5.97, Figure 5f1; p<0.0001, F=142.1; Figure 5f2). The overall detrimental effect on proliferation was, however, similar between animals treated with CHEM or CHEM+STRESS.
Exposure to GWIR Chemicals Induced Hippocampal Neuron Loss
Examination of NeuN-immunostained tissue sections revealed normal hippocampal cytoarchitecture in all groups (Figure 6a1 to c4). However, stereological quantification demonstrated partial loss of neurons in several cell layers (GCL and DH of the DG, and CA1 cell layer) of animals exposed to CHEM or CHEM+STRESS (p<0.05–0.001, F=5.2–15.5; Figure 6d1 to d3). However, the overall loss was similar between animals treated with CHEM or CHEM+STRESS except for the CA3 cell layer where only animals exposed to CHEM+STRESS showed loss of neurons (p<0.01, Figure 6d4). Furthermore, exposure to GWIR chemicals decreased volumes of the DG (significant for CHEM+STRESS group, p<0.05, F=4.4; Figure 6e1) and the CA3 subfield (significant for both CHEM and CHEM+STRESS groups, p<0.05, F=5.3; Figure 6e3) but not the CA1 subfield (p>0.05, F=2.9; Figure 6e2). However, the overall hippocampal volume including fimbria was significantly decreased in both CHEM and CHEM+STRESS groups (p<0.01, F=6.6; Figure 6e4).
Exposure to GWIR Chemicals Resulted in Mild Hippocampal Inflammation
Analyses of sections using ED-1 antibody demonstrated the presence of activated microglia in the hippocampus of animals treated with CHEM or CHEM+STRESS (Figure 7b1 to c4). Interestingly, these microglia were frequently observed in the hippocampal fissure (Figure 7b2 and c1) and fimbria (Figure 7b1). However, some isolated microglia could also be seen in the CA1 stratus radiatum (Figure 7c4). The overall density of activated microglia was greater in animals exposed to CHEM+STRESS than animals exposed to CHEM alone (p<0.05, Figure 7d). Analyses using nestin and vimentin antibodies did not reveal the presence of reactive astrocytes in animals exposed to GWIR chemicals. However, GFAP immunostaining demonstrated astrocytes exhibiting hypertrophy in animals treated with CHEM (Figure 7f1 to f3) or CHEM+STRESS (Figure 7g1 to g3) in comparison with VEH-treated animals (Figure 7e1 to e3). Area fraction analyses of GFAP+ structures revealed that animals exposed to CHEM or CHEM+STRESS exhibited hypertrophy of GFAP+ structures in all regions of the hippocampus in comparison with the VEH group (p<0.01–0.0001, F=12.6–43.8; Figure 7h1 to h4, p<0.01–0.001). However, area fractions of GFAP+ structures were comparable between CHEM and CHEM+STRESS groups.
Exposure of NSCs to DEET and/or PM Inhibited NSC Proliferation In Vitro
In control cultures, ∼7% of plated cells proliferated and formed clear larger neurospheres. Interestingly, the presence of 100 μM PB did not interfere with NSC proliferation, as both number and size of neurospheres were comparable between control and PB-treated cultures (Supplementary Figure S3a1, a2, and b). However, the presence of 100 μM DEET or PM considerably decreased the proliferation of NSCs (Supplementary Figure S3a3 and a4). This was evidenced by 76–78% reduction in the numbers of neurospheres generated per 100 cells plated (Supplementary Figure S3b) and reduced size of neurospheres (Supplementary Figure S3a3 and a4). Furthermore, a combination of PB, DEET, and PM decreased neurosphere formation by 92% (Supplementary Figure S3a5 and b).
DISCUSSION
This study provides novel evidence that combined exposure to low doses of GWIR chemicals for 4 weeks is sufficient for inducing chronic hippocampal dysfunction typified by increased depressive- and anxiety-like behavior, and spatial learning and memory impairments in a rat model. These findings are akin to depression, anxiety, and cognitive dysfunction reported in veterans with GWI (Haley et al, 1997; David et al, 2002; Li et al, 2011; Odegard et al, 2012). At the structural level, these impairments were associated with persistent reductions in dentate neurogenesis, partial loss of principal neurons, mild neuroinflammation, and reduced hippocampal volume. Moreover, addition of mild stress in the period of exposure to GWIR chemicals exacerbated mood, cognitive, and neurogenesis impairments, although application of mild stress alone has been shown to be associated with beneficial effects on cognitive and mood function (Parihar et al, 2011). In vitro analyses further showed that PM and DEET (but not PB) exposure can greatly inhibit the proliferation of NSCs. Interestingly, cognitive dysfunction observed in this rat model contrasts with a recent study in C57BL/6 mouse model where exposure to similar doses of chemicals and stress did not impair cognitive function but enhanced anxiety when examined 20 days after the exposure (Abdullah et al, 2012). The discrepancy between the two studies likely reflects differences in animal species and timing of behavioral analyses.
Links Between Mood and Cognitive Dysfunction and Impaired Hippocampal Neurogenesis
Although multiple factors can interfere with mood and cognitive function, changes in the quantity of adult hippocampal neurogenesis are widely believed to influence both mood and spatial learning and memory function (Deng et al, 2010; Eisch and Petrik, 2012). Indeed, we found substantial decreases in hippocampal neurogenesis at both early and extended periods after the exposure to GWIR chemicals. In addition, reduced neurogenesis was associated with decreased volume of the hippocampus. Considering these, a question emerges of whether persistently reduced hippocampal neurogenesis is one of the underlying causes of mood and memory dysfunction in GWI. This proposition is supported by multiple observations in previous studies. First, there are credible evidences in favor of the hypothesis that mood function depends on the extent of hippocampal neurogenesis (Snyder et al, 2011; Eisch and Petrik, 2012; Kheirbek et al, 2012), which includes findings that humans with depression exhibit smaller hippocampal volume likely because of persistently reduced neurogenesis (Small et al, 2011; Fotuhi et al, 2012), antidepressants upregulate hippocampal neurogenesis with a lag time comparable with the delay between antidepressant treatment and positive clinical outcome on mood function (Malberg et al, 2000), and ablation of hippocampal neurogenesis impairs antidepressant efficacy (Santarelli et al, 2003). Although a few rodent studies have contradicted the above association (Meshi et al, 2006; David et al, 2009), there is considerable support in favor of the neurogenic hypothesis of depression, which includes a recent non-human primate study showing that hippocampal neurogenesis is necessary for the therapeutic action of antidepressants (Perera et al, 2011; Eisch and Petrik, 2012). Second, although a negative correlation was seen in a few earlier studies (Bizon et al, 2004), most studies support an important role for hippocampal neurogenesis in spatial memory function. This includes observations that animals housed in enriched environment, undergoing physical exercise, treated for corticosterone reductions, or exposed to predictable chronic mild stress displayed enhanced neurogenesis and improved spatial memory function (Kempermann et al, 2002; van Praag et al, 2005; Montaron et al, 2006; Parihar et al, 2011), and aged rats with unimpaired spatial memory ability displayed greater extent of neurogenesis than rats with impaired spatial memory (Drapeau et al, 2003). Moreover, recent studies that utilized selective neurogenesis ablation techniques strongly support a role for hippocampal neurogenesis in spatial memory function (Dupret et al, 2007, 2008; Wang et al, 2012). Interestingly, animals exposed to GWIR chemicals did not display impaired recognition memory function in NORT, which may be because of a partial involvement of the hippocampus in this task (Broadbent et al, 2009).
Thus, reduced hippocampal neurogenesis likely contributes to mood and cognitive dysfunction observed in GWI. Although the basic in vivo imaging correlates of human hippocampal neurogenesis (such as quantification of cerebral blood flow in the SGZ) is feasible (Manganas et al, 2007; Pereira et al, 2007), greater advances in imaging techniques will be required to correlate the loss of neurogenesis with altered mood or cognitive function in veterans with GWI. However, several previous studies have shown the presence of hippocampal dysfunction as well as increased incidence of depression, anxiety, and memory dysfunction in GW veterans (David et al, 2002; Black et al, 2004; Menon et al, 2004; Li et al, 2011; Odegard et al, 2012). MRI studies have also shown smaller hippocampus in a subset of GW veterans exhibiting posttraumatic stress disorder but not in GW veterans affected with depression alone (Vythilingam et al, 2005; Apfel et al, 2011).
Other Factors Contributing to GWIR Chemical-Mediated Hippocampal Dysfunction
Quantification of NeuN+ neurons revealed 19–31% loss of neurons in different subfields of the hippocampus, with no differences in the extent of neuron loss between animals exposed to CHEM or CHEM+STRESS. Additional analyses suggested mild inflammation typified by the occurrence of activated microglia in white matter regions and hypertrophy of astrocytes in all subfields. Although previous studies have suggested some neuron loss in the hippocampus with exposure to CHEM+STRESS (Abdel-Rahman et al, 2002, 2004a), occurrences of neuron loss, activated microglia, and hypertrophied astrocytes in animals exposed to CHEM alone are additional novel findings in this study. Neurodegeneration is likely because of both direct and indirect effects of chemicals. For instance, PM can mediate direct neurodegeneration by causing prolonged activation of voltage-gated sodium channels and hyperexcitability in neurons (Ray and Fry, 2006). On the other hand, DEET is a weak AChE inhibitor but can enhance the activity of other AChE inhibitors such as PB (Corbel et al, 2009). Previous studies in this GWI model have indeed seen both decreased AChE activity and disruption of the blood brain barrier in multiple brain regions (Abdel-Rahman et al, 2002, 2004a). Because both partial neurodegeneration and inflammation can interfere with hippocampal function and neurogenesis (Krishnadas and Cavanagh, 2012; Kohman and Rhodes, 2013), it is plausible that these two factors have also contributed to mood and cognitive dysfunction and impaired neurogenesis observed in animals exposed to GWIR chemicals. Additional factors may also be involved. For example, a recent lipidomics study reported that regulation of acetylcholine regulator and signaling pathways undergo alterations with exposure to GWIR chemicals (Abdullah et al, 2012).
Causes of Reduced Hippocampal Neurogenesis in Animals Exposed to GWIR Chemicals
Our analyses revealed that similar numbers of putative NSCs persist, and comparable fractions of newly born cells differentiate into mature neurons between VEH-treated animals and animals treated with GWIR chemicals. This suggested that exposure to low doses of GWIR chemicals did not kill NSCs or alter the neuronal fate-choice decision of new cells generated by NSCs. However, fewer NSCs were undergoing proliferation in animals exposed to GWIR chemicals. These results imply that reduced proliferation of NSCs is the underlying cause of declined neurogenesis in animals exposed to GWIR chemicals. Reduced proliferation of NSCs in the exposure period can result from direct effects of chemicals, as our in vitro assays showed that DEET and PM can greatly inhibit NSC proliferation at μM concentrations. On the other hand, reduced proliferation of NSCs observed in the fifth month after the exposure is likely because of changes in NSC microenvironment following exposure to chemicals. Apart from the mild inflammation noted above, this may also involve increased oxidative stress observed in previous studies with exposure to GWIR chemicals (Li et al, 2001; Abu-Qare et al, 2001). Thus, inflammation and oxidative stress mediated by GWIR chemicals are the likely causes of NSC dysfunction in GWI.
CONCLUSIONS
We show the first evidence of an association between mood and cognitive dysfunction and hippocampal pathology typified by decreased neurogenesis, partial loss of principal neurons, and mild inflammation in a rat model of GWI. Hence, application of novel treatment strategies that are efficacious for enhancing neurogenesis as well as suppressing inflammation may be helpful for improving mood and cognitive function in veterans with GWI.
FUNDING AND DISCLOSURE
The authors declare no conflict of interest.
References
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Acknowledgements
This study was supported primarily by a grant for ‘Gulf War Illness Research’ from the Department of Veterans Affairs (Merit Review Award to AKS) and partly by a grant from the Texas A&M Health Science Center (Emerging Technology Funds to AKS).
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VKP, BH, and AKS contributed equally to this work. VKP performed chemical and stress exposures to animals, behavioral experiments, immunohistochemistry, stereological cell counts, collection, analyses, and interpretation of data and prepared an initial rough draft of the manuscript text. BH gave input to behavioral experiments, performed immunohistochemistry, stereological cell counts, confocal microscopy, and contributed to collection, analyses, and interpretation of behavioral data and assembly of figures. BS performed chemical and stress exposures to animals, tissue processing, histology, immunohistochemistry, and contributed to behavioral experiments and collection of data. AKS conceived the study, conceptualized the experimental design, analyzed, interpreted and assembled data, prepared all figures and wrote the manuscript. All authors gave input to the manuscript text and approved the final version of the manuscript.
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Parihar, V., Hattiangady, B., Shuai, B. et al. Mood and Memory Deficits in a Model of Gulf War Illness Are Linked with Reduced Neurogenesis, Partial Neuron Loss, and Mild Inflammation in the Hippocampus. Neuropsychopharmacol 38, 2348–2362 (2013). https://doi.org/10.1038/npp.2013.158
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DOI: https://doi.org/10.1038/npp.2013.158
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