Dysregulated placental expression of kynurenine pathway enzymes is associated with inflammation and depression in pregnancy.

BACKGROUND: Perinatal depression (including antenatal-, postnatal-, and depression that spans both timepoints) is a prevalent disorder with high morbidity that affects both mother and child. Even though the full biological blueprints of perinatal depression remain incomplete, multiple studies indicate that, at least for antenatal depression, the disorder has an inflammatory component likely linked to a dysregulation of the enzymatic kynurenine pathway. The production of neuroactive metabolites in this pathway, including quinolinic acid (QUIN), is upregulated in the placenta due to the multiple immunological roles of the metabolites during pregnancy. Since neuroactive metabolites produced by the pathway also may affect mood by directly affecting glutamate neurotransmission, we sought to investigate whether the placental expression of kynurenine pathway enzymes controlling QUIN production was associated with both peripheral inflammation and depressive symptoms during pregnancy. METHODS: 68 placentas obtained at birth were analyzed using qPCR to determine the expression of kynurenine pathway enzymes. Cytokines and metabolites were quantified in plasma using high-sensitivity electroluminescence and ultra-performance liquid chromatography, respectively. Maternal depressive symptoms were assessed using the Edinburgh Postnatal Depression Scale (EPDS) throughout pregnancy and the post-partum. Associations between these factors were assessed using robust linear regression with ranked enzymes. RESULTS: Low placental quinolinate phosphoribosyl transferase (QPRT), the enzyme responsible for degrading QUIN, was associated with higher IL-6 and higher QUIN/kynurenic acid ratios at the 3rd trimester. Moreover, women with severe depressive symptoms in the 3rd trimester had significantly lower placental expression of both QPRT and 2-amino-3-carboxymuconate-6-semialdehyde decarboxylase (ACMSD); impaired activity of these two enzymes leads to QUIN accumulation. CONCLUSION: Overall, our data support that a compromised placental environment, featuring low expression of critical kynurenine pathway enzymes is associated with increased levels of plasma cytokines and the dysregulated kynurenine metabolite pattern observed in depressed women during pregnancy.

Integrative transcriptome- and DNA methylation analysis of brain tissue from the temporal pole in suicide decedents and their controls.

Suicide rates have increased steadily world-wide over the past two decades, constituting a serious public health crisis that creates a significant burden to affected families and the society as a whole. Suicidal behavior involves a multi-factorial etiology, including psychological, social and biological factors. Since the molecular neural mechanisms of suicide remain vastly uncharacterized, we examined transcriptional- and methylation profiles of postmortem brain tissue from subjects who died from suicide as well as their neurotypical healthy controls. We analyzed temporal pole tissue from 61 subjects, largely free from antidepressant and antipsychotic medication, using RNA-sequencing and DNA-methylation profiling using an array that targets over 850,000 CpG sites. Expression of NPAS4, a key regulator of inflammation and neuroprotection, was significantly downregulated in the suicide decedent group. Moreover, we identified a total of 40 differentially methylated regions in the suicide decedent group, mapping to seven genes with inflammatory function. There was a significant association between NPAS4 DNA methylation and NPAS4 expression in the control group that was absent in the suicide decedent group, confirming its dysregulation. NPAS4 expression was significantly associated with the expression of multiple inflammatory factors in the brain tissue. Overall, gene sets and pathways closely linked to inflammation were significantly upregulated, while specific pathways linked to neuronal development were suppressed in the suicide decedent group. Excitotoxicity as well as suppressed oligodendrocyte function were also implicated in the suicide decedents. In summary, we have identified central nervous system inflammatory mechanisms that may be active during suicidal behavior, along with oligodendrocyte dysfunction and altered glutamate neurotransmission. In these processes, NPAS4 might be a master regulator, warranting further studies to validate its role as a potential biomarker or therapeutic target in suicidality.

Upregulation of α-synuclein following immune activation: Possible trigger of Parkinson's disease.

Alpha-synuclein (α-syn) has been suggested to have many functions including, vesicle transport in neurons, transcriptional regulator, modulator of immune cell maturation and response, and a role as an antimicrobial peptide. This protein forms insoluble aggregates, called Lewy bodies, in several neurodegenerative diseases, termed synucleinopathies, including Parkinson's disease (PD), Multiple System Atrophy, and Lewy Body Dementia, and aggregates are also commonly found in Alzheimer's disease. Moreover, multiplications and point mutations in the gene cause rare autosomal dominant forms of parkinsonism, which resemble sporadic PD. It has been suggested that the accumulation of α-syn in the monomeric state followed by aggregation of the protein and seeding of further pathogenic α-syn aggregates are key steps in the pathogenesis of synucleinopathies. The triggers of α-syn aggregation in neurodegeneration are unknown, but inflammation caused by bacterial and viral pathogens or exposure to environmental toxins have been implicated. The purpose of this review is to present emerging evidence that α-syn may play a role in the immune response to pathogens. We present recent findings suggesting that upregulation of α-syn levels is a normal response to infections. We propose that under certain conditions (e.g., dysregulated inflammatory responses due to genetic predisposition and aging), monomeric α-syn will form oligomers that are taken up by nerve endings and undergo axonal transport to the central nervous system, where they can aggregate into pathogenic fibrils. Under unfavorable conditions, we suggest that this process can trigger neurodegenerative disease. Therefore, a deeper understanding of the roles of α-syn in the immune system could provide crucial insights into the origins of synucleinopathies.

Maternal Herpesviridae infection during pregnancy alters midbrain dopaminergic signatures in adult offspring.

BACKGROUND: Motor symptoms of Parkinson's disease (PD) are apparent after a high proportion of dopamine neurons in the substantia nigra have degenerated. The vast majority of PD cases are sporadic, and the underlying pathobiological causes are poorly understood. Adults exhibit great variability in the numbers of nigral dopamine neurons, suggesting that factors during embryonic or early life regulate the development and physiology of dopaminergic neurons. Furthermore, exposure to infections and inflammation in utero has been shown to affect fetal brain development in models of schizophrenia and autism. Here, we utilize a mouse maternal infection model to examine how maternal herpesvirus infection impacts dopaminergic neuron-related gene and protein expression in the adult offspring. METHODS: Pregnant mice were injected with murine cytomegalovirus (MCMV), murine gamma herpes virus-68 (MHV68) or phosphate buffered saline (PBS) at embryonic day 8.5. Offspring were sacrificed at eight weeks of age and midbrains were processed for whole genome RNA sequencing, DNA methylation analysis, targeted protein expression and high-performance liquid chromatography for quantification of dopamine and its metabolites. RESULTS: The midbrain of adult offspring from MHV68 infected dams had significantly decreased expression of genes linked to dopamine neurons (Th, Lmx1b, and Foxa1) and increased Lrrk2, a gene involved in familial PD and PD risk that associates with neuroinflammation. Deconvolution analysis revealed that the proportion of dopamine neuron genes in the midbrain was reduced. There was an overall increase in DNA methylation in the midbrain of animals from MHV68-infected dams and pathway analyses indicated mitochondrial dysfunction, with reductions in genes associated with ATP synthesis, mitochondrial respiratory chain, and mitochondrial translation in the offspring of dams infected with MHV68. TIGAR (a negative regulator of mitophagy) and SDHA (mitochondrial complex II subunit) protein levels were increased, and the levels of 3,4-dihydroxyphenylacetic acid (DOPAC) in the striatum were increased in these offspring compared to offspring from uninfected control dams. No such changes were observed in the offspring of dams infected with MCMV. CONCLUSION: Our data suggest that maternal infection with Herpesviridae, specifically MHV68, can trigger changes in the development of the midbrain that impact dopamine neuron physiology in adulthood. Our work is of importance for the understanding of neuronal susceptibility underlying neurodegenerative disease, with particular relevance for PD.

Effect of different Aggregatibacter actinomycetemcomitans strains on dual-species biofilms formed with Porphyromonas gingivalis or Dialister pneumosintes.

There are five evolutionarily divergent clades of Aggregatibacter actinomycetemcomitans, with possible differences in phenotype and virulence potential among strains. This study examined the formation of biofilm by each of 11 distinct strains of A. actinomycetemcomitans, alone or after coculture with two species of oral bacteria (Porphyromonas gingivalis ATCC33277 or Dialister pneumosintes ATCC33048). Confocal laser scanning microscopy (CLSM) and electron microscopy were used to characterize the dual-species biofilms of interest. A reduction in dual-species A. actinomycetemcomitans-P. gingivalis biofilms was observed for A. actinomycetemcomitans RHAA1, suggesting an antagonistic relationship. The amounts of dual-species A. actinomycetemcomitans-D. pneumosintes biofilms were either increased or decreased in some - but not all - strains, indicative of strain-specific phenotypes. The CLSM analyses confirmed the existence of an antagonistic relationship between A. actinomycetemcomitans D7S-1 and P. gingivalis ATCC33277, and a synergistic relationship between A. actinomycetemcomitans D7S-1 and D. pneumosintes ATCC33048. The electron microscopy analyses revealed distinct morphological features of A. actinomycetemcomitans D7S-1 and D. pneumosintes ATCC33048 dual-species biofilms. The results indicate that the relationship between A. actinomycetemcomitans and oral bacteria may vary among strains, which could lead to distinct strain-specific patterns of niche sharing in subgingival microbiota.

Quantifying Salmonella population dynamics in water and biofilms.

Members of the bacterial genus Salmonella are recognized worldwide as major zoonotic pathogens often found to persist in non-enteric environments including heterogeneous aquatic biofilms. In this study, Salmonella isolates that had been detected repeatedly over time in aquatic biofilms at different sites in Spring Lake, San Marcos, Texas, were identified as serovars Give, Thompson, Newport and -:z10:z39. Pathogenicity results from feeding studies with the nematode Caenorhabditis elegans as host confirmed that these strains were pathogenic, with Salmonella-fed C. elegans dying faster (mean survival time between 3 and 4 days) than controls, i.e., Escherichia coli-fed C. elegans (mean survival time of 9.5 days). Cells of these isolates inoculated into water at a density of up to 10(6) ml(-1) water declined numerically by 3 orders of magnitude within 2 days, reaching the detection limit of our quantitative polymerase chain reaction (qPCR)-based quantification technique (i.e., 10(3) cells ml(-1)). Similar patterns were obtained for cells in heterogeneous aquatic biofilms developed on tiles and originally free of Salmonella that were kept in the inoculated water. Cell numbers increased during the first days to more than 10(7) cells cm(-2), and then declined over time. Ten-fold higher cell numbers of Salmonella inoculated into water or into biofilm resulted in similar patterns of population dynamics, though cells in biofilms remained detectable with numbers around 10(4) cells cm(-2) after 4 weeks. Independent of detectability by qPCR, samples of all treatments harbored viable salmonellae that resembled the inoculated isolates after 4 weeks of incubation. These results demonstrate that pathogenic salmonellae were isolated from heterogeneous aquatic biofilms and that they could persist and stay viable in such biofilms in high numbers for some time.

Cytokines and tryptophan metabolites can predict depressive symptoms in pregnancy.

Depression during and after pregnancy affects up to 20% of pregnant women, but the biological underpinnings remain incompletely understood. As pregnancy progresses, the immune system changes to facilitate fetal development, leading to distinct fluctuations in the production of pro-inflammatory factors and neuroactive tryptophan metabolites throughout the peripartum period. Therefore, it is possible that depression in pregnancy could constitute a specific type of inflammation-induced depression. Both inflammatory factors and kynurenine metabolites impact neuroinflammation and glutamatergic neurotransmission and can therefore affect mood and behavior. To determine whether cytokines and kynurenine metabolites can predict the development of depression in pregnancy, we analyzed blood samples and clinical symptoms in 114 women during each trimester and the postpartum. We analyzed plasma IL-1ß, IL-2, -6, -8, -10, TNF, kynurenine, tryptophan, serotonin, kynurenic- quinolinic- and picolinic acids and used mixed-effects models to assess the association between biomarkers and depression severity. IL-1ß and IL-6 levels associated positively with severity of depressive symptoms across pregnancy and the postpartum, and that the odds of experiencing significant depressive symptoms increased by >30% per median absolute deviation for both IL-1ß and IL-6 (both P = 0.01). A combination of cytokines and kynurenine metabolites in the 2nd trimester had a >99% probability of accurately predicting 3rd trimester depression, with an ROC AUC > 0.8. Altogether, our work shows that cytokines and tryptophan metabolites can predict depression during pregnancy and could be useful as clinical markers of risk. Moreover, inflammation and kynurenine pathway enzymes should be considered possible therapeutic targets in peripartum depression.

Associations between estrogen and progesterone, the kynurenine pathway, and inflammation in the post-partum.

BACKGROUND: Depression during and after pregnancy is common, affecting at least 15% of women. Features of depression in pregnancy range from mild symptoms of disrupted mood and interest to severe depression and suicidal behavior. Previous studies suggest hormone- and immune dysregulations might contribute to post-partum depression, but consistent evidence is lacking. METHODS: A total of 163 women were included in the study in the post-partum. Peri-partum depression (PPD) was diagnosed using SCID interviews and depressive symptoms were quantified using the Edinburgh Perinatal Depression Rating Scale (EPDS), retrospectively long-term, as well as acutely. Plasma estrogen, progesterone, pro- and anti-inflammatory cytokines and kynurenine metabolites were measured in the post-partum. RESULTS: Higher estrogen and progesterone in the post-partum were linked to more severe depressive symptoms over pregnancy. In the post-partum, estrogen was positively correlated with the pro-inflammatory cytokine IL-6 and negatively correlated with kynurenine and picolinic acid. Conversely, progesterone was negatively correlated with IL-1ß and several metabolites in the kynurenine pathway, including quinolinic acid. LIMITATIONS: Associative study design, did not attempt to assess causality. Did not adjust hormone levels for medication effects. CONCLUSIONS: Our study suggests that higher sex hormones in the post-partum are linked to depression severity over pregnancy. Estrogen was coupled with a pro-inflammatory profile and neurotoxic kynurenine metabolites, whereas progesterone was linked to an anti-inflammatory profile in the post-partum.

Characterization of enteropathogenic and Shiga toxin-producing Escherichia coli in cattle and deer in a shared agroecosystem.

Shiga toxin-producing Escherichia coli (STEC) is an important foodborne pathogen. Cattle are suggested to be an important reservoir for STEC; however, these pathogens have also been isolated from other livestock and wildlife. In this study we sought to investigate transmission of STEC, enterohemorrhagic E. coli (EHEC) and enteropathogenic E. coli (EPEC) between cattle and white-tailed deer in a shared agroecosystem. Cattle feces were collected from 100 animals in a Michigan dairy farm in July 2012, while 163 deer fecal samples were collected during two sampling periods (March and June). The locations of deer fecal pellets were recorded via geographic information system mapping and microsatellite multi-locus genotyping was used to link the fecal samples to individual deer at both time points. Following subculture to sorbitol MacConkey agar and STEC CHROMagar, the pathogens were characterized by serotyping, stx profiling, and PCR-based fingerprinting; multilocus sequence typing (MLST) was performed on a subset. STEC and EHEC were cultured from 12 to 16% of cattle, respectively, and EPEC was found in 36%. Deer were significantly less likely to have a pathogen in March vs. June where the frequency of STEC, EHEC, and EPEC was 1, 6, and 22%, respectively. PCR fingerprinting and MLST clustered the cattle- and deer-derived strains together in a phylogenetic tree. Two STEC strains recovered from both animal species shared MLST and fingerprinting profiles, thereby providing evidence of interspecies transmission and highlighting the importance of wildlife species in pathogen shedding dynamics and persistence in the environment and cattle herds.

Diversity of Salmonella in biofilms and water in a headwater ecosystem.

The diversity of Salmonella was analysed in biofilm and water samples from the spring and slough arms of Spring Lake, the headwaters of the San Marcos River, Texas, during the drought of 2011, with only one potential run-off event at the beginning of the study. Salmonellae were detected in semiselective enrichment cultures by end-point PCR during the entire sampling period of (11 sampling events during 2 months). From the spring arm site, 73% of the biofilms and 41% of the water samples were positive for salmonellae, while only 9% of the biofilms and 23% of the water samples were positive from the slough arm site. Salmonellae could be isolated from all positive samples, with higher diversity in biofilms compared with water samples and more strains obtained from the spring arm than from the slough arm. Differences between sites were generally caused by less frequently detected isolates, while the majority of isolates that were present in both biofilms and water from both sites was represented by three strains only. Quantification attempts by quantitative PCR directly in samples without prior enrichment did not result in a reliable detection of salmonellae, suggesting that numbers in all samples were below the detection limit.

Salmonellae in fish feces analyzed by in situ hybridization and quantitative polymerase chain reaction.

The potential of fish to transfer salmonellae from heterogeneous aquatic biofilms into feces was assessed in controlled aquarium studies with Suckermouth Catfish Hypostomus plecostomus and with biofilms inoculated with salmonellae. Neither the presence of catfish nor inoculation with salmonellae had detectable effects on the abundance of the microbial community. Densities of the microbial community were about 10(5) cells/mL in the water during a 1-week period, whereas densities of the microbial community increased 10-fold (10(6) to 10(7) cells/mg) in catfish feces during the same period. Salmonellae were detected by both quantitative polymerase chain reaction (qPCR) and situ hybridization in water samples immediately after inoculation, in numbers of about 10(4) cells/mL, representing up to 20% of the cells of the microbial community. Numbers decreased by three orders of magnitude within the first 3 d of the study, which represented only 0.01% of the community, and became undetectable after day 5. In catfish feces, numbers of Salmonella initially increased to up to 6% of the cells of the community but then declined. These results suggest that Salmonella are not biomagnified during gut passage, and thus, fish only provide a means for the translocation of this pathogen.

Quantification of Frankia in soils using SYBR Green based qPCR.

A SYBR Green based qPCR method was developed for the quantification of clusters 1 and 3 of the actinomycete Frankia in soils. Primer nifHr158 was designed to be used as reverse primer in combination with forward primer nifHf1 specifically amplifying a 191-bp fragment of the nifH gene of these Frankia. The primer combination was tested for specificity on selected pure cultures, and by comparative sequence analyses of randomly selected clones of a clone library generated with these primers from soil DNA extracts. After adjustments of DNA extraction conditions, and the determination of extraction efficiencies used for sample normalization, copy numbers of nifH genes representing Frankia of clusters 1 and 3 were quantified in different mineral soils, resulting in cell density estimates for these Frankia of up to 10(6) cells [g soil {dry weight}](-1) depending on the soil. Despite indications that the nifH gene is not a perfect target for the quantification of Frankia, the qPCR method described here provides a new tool for the quantification and thus a more complete examination of the ecology of Frankia in soils.

Temporal analyses of the distribution and diversity of Salmonella in natural biofilms.

The diversity and distribution of salmonellae in freshwater biofilms were analyzed at a fine scale (i.e. in 20 locations from a 324 cm(2) area) for two sites in San Marcos, TX. A concrete storm water overflow channel (City Park) was sampled 4 times and a concrete surface in the spring-fed headwaters of the San Marcos River (Spring Lake) 5 times between April and September 2009, and each biofilm sample analyzed by a combination of traditional enrichment methods and molecular techniques. PCR detection of the invA gene, that encodes a protein of a type III secretion system present in salmonellae, after semi-selective enrichment of salmonellae was achieved in biofilms from all 20 locations at the City Park site, with locations generally being positive 2-3 times out of 4 sampling times for a total of 59% positive samples. InvA gene fragment detection in biofilms was less frequent for the 5 sampling times and 20 locations from the Spring Lake site (18% of all samples), with 1 sampling time being entirely negative and 8 locations remaining negative throughout the study. Rep-PCR fingerprinting of 491 Salmonella isolates obtained from both sites resulted in 30 distinct profiles, with 26 and 7 profiles retrieved from City Park and Spring Lake samples, respectively, and thus with 3 profiles present at both sites, and multiple strains frequently obtained from single locations at both sites. The composition of Salmonella strains in the area analyzed changed in time with large differences between early (April, June) and late sampling times (September) within and among sites, except for one strain (S12) that was present at almost all sampling times at both sites, though often at different locations within the area analyzed. These results demonstrate the presence of salmonellae in natural biofilms and a significant micro-heterogeneity with differences in diversity and persistence of salmonellae.

[Effects of plant functional groups removal on the soil carbon, nitrogen pools in a Leymus chinensis community of typical steppe in Inner Mongolia].

A field plant functional groups (PFGs) removal experiment was conducted in 2005-2007 to study the effects of plant diversity in a Leymus chinensis community of typical steppe in Inner Mongolia on the topsoil (0-10 cm) carbon (C) and nitrogen (N) pools. In the three successive years, the topsoil total C and N contents had a slight change (< 15%). They changed little in 2005, but were significantly higher in 2006 than in 2007 (P < 0.05). The topsoil NH4(+)-N content had a greater inter-annual change, being 80% higher in 2006 than in 2007, while the NO3(-)-N content had less significant change (P > 0.05). There was a positive linear relationship (P < 0.05) between the number of removed PFGs and the content of soil NO3(-)-N, which meant that the decrease of plant diversity increased soil NO3(-)-N content, and consequently, led to a possible soil nitrogen loss through leaching.