The microbiome regulates amygdala-dependent fear recall.

The amygdala is a key brain region that is critically involved in the processing and expression of anxiety and fear-related signals. In parallel, a growing number of preclinical and human studies have implicated the microbiome-gut-brain in regulating anxiety and stress-related responses. However, the role of the microbiome in fear-related behaviours is unclear. To this end we investigated the importance of the host microbiome on amygdala-dependent behavioural readouts using the cued fear conditioning paradigm. We also assessed changes in neuronal transcription and post-transcriptional regulation in the amygdala of naive and stimulated germ-free (GF) mice, using a genome-wide transcriptome profiling approach. Our results reveal that GF mice display reduced freezing during the cued memory retention test. Moreover, we demonstrate that under baseline conditions, GF mice display altered transcriptional profile with a marked increase in immediate-early genes (for example, Fos, Egr2, Fosb, Arc) as well as genes implicated in neural activity, synaptic transmission and nervous system development. We also found a predicted interaction between mRNA and specific microRNAs that are differentially regulated in GF mice. Interestingly, colonized GF mice (ex-GF) were behaviourally comparable to conventionally raised (CON) mice. Together, our data demonstrates a unique transcriptional response in GF animals, likely because of already elevated levels of immediate-early gene expression and the potentially underlying neuronal hyperactivity that in turn primes the amygdala for a different transcriptional response. Thus, we demonstrate for what is to our knowledge the first time that the presence of the host microbiome is crucial for the appropriate behavioural response during amygdala-dependent memory retention.

Gutsy Moves: The Amygdala as a Critical Node in Microbiota to Brain Signaling.

The amygdala is a key brain area regulating responses to stress and emotional stimuli, so improving our understanding of how it is regulated could offer novel strategies for treating disturbances in emotion regulation. As we review here, a growing body of evidence indicates that the gut microbiota may contribute to a range of amygdala-dependent brain functions from pain sensitivity to social behavior, emotion regulation, and therefore, psychiatric health. In addition, it appears that the microbiota is necessary for normal development of the amygdala at both the structural and functional levels. While further investigations are needed to elucidate the exact mechanisms of microbiota-to-amygdala communication, ultimately, this work raises the intriguing possibility that the gut microbiota may become a viable treatment target in disorders associated with amygdala dysregulation, including visceral pain, post-traumatic stress disorder, and beyond. Also see the video abstract here: https://youtu.be/O5gvxVJjX18.

Microbes & neurodevelopment--Absence of microbiota during early life increases activity-related transcriptional pathways in the amygdala.

The mammalian amygdala is a key emotional brain region for eliciting social behaviour, critically involved in anxiety and fear-related behaviours, and hence a focus of research on neurodevelopmental and stress-related disorders such as autism and anxiety. Recently, increasing evidence implicates host-microbe interactions in the aetiology of these conditions. Germ-free (GF) mice, devoid of any microbiota throughout organismal maturation, are a well-established tool to study the effects of absence of the microbiota on host physiology. A growing body of independently replicated findings confirm that GF animals demonstrate altered anxiety-related behaviour and impaired social behaviour. However, the underlying mechanisms of this interaction and the nature of the pathways involved are only insufficiently understood. To further elucidate the molecular underpinnings of microbe-brain interaction, we therefore exploited unbiased genome-wide transcriptional profiling to determine gene expression in the amygdala of GF and GF mice that have been colonised after weaning. Using RNA-sequencing and a comprehensive downstream analysis pipeline we studied the amygdala transcriptome and found significant differences at the levels of differential gene expression, exon usage and RNA-editing. Most surprisingly, we noticed upregulation of several immediate early response genes such as Fos, Fosb, Egr2 or Nr4a1 in association with increased CREB signalling in GF mice. In addition, we found differential expression and recoding of several genes implicated in brain physiology processes such as neurotransmission, neuronal plasticity, metabolism and morphology. In conclusion, our data suggest altered baseline neuronal activity in the amygdala of germ-free animals, which is established during early life and may have implications for understanding development and treatment of neurodevelopmental disorders.

In vivo characterization of chronic traumatic encephalopathy using [F-18]FDDNP PET brain imaging.

Chronic traumatic encephalopathy (CTE) is an acquired primary tauopathy with a variety of cognitive, behavioral, and motor symptoms linked to cumulative brain damage sustained from single, episodic, or repetitive traumatic brain injury (TBI). No definitive clinical diagnosis for this condition exists. In this work, we used [F-18]FDDNP PET to detect brain patterns of neuropathology distribution in retired professional American football players with suspected CTE (n = 14) and compared results with those of cognitively intact controls (n = 28) and patients with Alzheimer's dementia (AD) (n = 24), a disease that has been cognitively associated with CTE. [F-18]FDDNP PET imaging results in the retired players suggested the presence of neuropathological patterns consistent with models of concussion wherein brainstem white matter tracts undergo early axonal damage and cumulative axonal injuries along subcortical, limbic, and cortical brain circuitries supporting mood, emotions, and behavior. This deposition pattern is distinctively different from the progressive pattern of neuropathology [paired helical filament (PHF)-tau and amyloid-ß] in AD, which typically begins in the medial temporal lobe progressing along the cortical default mode network, with no or minimal involvement of subcortical structures. This particular [F-18]FDDNP PET imaging pattern in cases of suspected CTE also is primarily consistent with PHF-tau distribution observed at autopsy in subjects with a history of mild TBI and autopsy-confirmed diagnosis of CTE.

[Lemierre's syndrome: septic thrombophlebitis of the internal jugular vein secondary to acute amygdalitis]. / Síndrome de Lemierre: tromboflebitis séptica de la yugular interna secundaria a amigdalitis aguda.

Lemierre's syndrome is an uncommon clinical entity. It consists of an acute oropharyngeal infection, with secondary septic thrombophlebitis of the internal jugular vein frequently complicated with multiple metastatic infections. It is generally caused by anaerobic Gram-negative organisms. Although it is rarely reported in the antibiotic era, this disease must be taken into account because it is a potentially life-threatening infection requiring a specific and early treatment. We report a case of Lemierre's syndrome managed in our hospital.

Síndrome de Lemierre: Tromboflebitis séptica de la yugular interna secundaria a amigdalitis aguda / Lemierre's syndrome: septic jugularis interna thrombophlebitis secondary to acute amigdalitis

El síndrome de Lemierre es un cuadro poco frecuente en la actualidad. Consiste en una tromboflebitis séptica de la vena yugular interna, con frecuentes metástasis sépticas, secundaria a una infección faríngea u odontógena producida generalmente por gérmenes Gram-negativos anaerobios. Aunque su incidencia es escasa en la era antibiótica, debe ser conocido por tratarse de una complicación grave que requiere la instauración de un tratamiento específico precoz. Presentamos un caso de Síndrome de Lemierre ocurrido en nuestro hospital (AU)

Lemierre's syndrome is an uncommon clinical entity. It consists of an acute oropharyngeal infection, with secondary septic thrombophlebitis of the internal jugular vein frequently complicated with multiple metastatic infections. It is generally caused by anaerobic Gram-negative organisms. Although it is rarely reported in the antibiotic era, this disease must be taken into account because it is a potentially life-threatening infection requiring a specific and early treatment. We report a case of Lemierre's syndrome managed in our hospital (AU)

Brain structures selectively targeted by canine distemper virus in a mouse model infection.

Paramyxoviruses such as measles virus or canine distemper virus are etiological agents for acute and chronic encephalitis (measles inclusion body encephalitis, subacute sclerosing panencephalitis and chronic distemper encephalitis or old dog encephalitis). The mechanisms by which viral injury leads to neurological diseases have not yet been fully elucidated. We have developed an experimental model in mice in order to analyze the spatial and temporal distribution of canine distemper virus in the central nervous system. Cerebral target structures for viral replication were examined for the presence of viral material (proteins and mRNA) during the two stages of the biphasic disease. During the acute stage of infection all target areas could be identified by day 6 with a similar anatomical distribution in all the animals examined, which were either intracranially or intracerebroventricularly infected. Viral mRNA and proteins were selectively localized in certain brain structures such as the thalamus, hypothalamus, substantia nigra (pars compacta), locus ceruleus and raphe nuclei (dorsalis and centralis), and limbic system (hippocampus, septum, entorhinal and cingulate cortex, amygdala). The virus was apparently unable to replicate in cerebellum, striatum, a large part of cortex, or endothelial cells. During the subacute disease, viral material was no longer detectable except in a few structures such as hypothalamus up to 4-6 weeks after inoculation. After this time, all target structures were devoid of any labeling in spite of the occurrence of pathology (obesity, paralysis) during this viral quiescent phase. These results suggest that after the initial viral exposure, expression of viral genes in defined structures might disrupt central homeostasis and finally may lead to neurological or neuroendocrine diseases, even in the absence of the hallmarks of the virus.

[Evaluation of a fast test for direct research on streptococcal group A from pharyngeal samples]. / Evaluation d'un test rapide pour la recherche directe du streptocoque du groupe A dans les prélèvements pharyngés.

Importance of streptococcal pharyngitis rapid diagnosis is increasing. 645 patients with pharyngoamygdalitis were tested. The correlation between bacteriologic culture and rapid test is 86%, the sensibility of the test is 68%, its specificity is 92%, while the predictive positive and negative values are 75% and 90%. These results show the interest of the rapid test for the diagnosis of streptococcal pharyngitis.

Herpes simplex virus DNA in the brain of psychotic patients.

Herpes simplex virus (HSV) DNA was found by spot blot hybridization in the right nc. amygdalae of 3 out 10 patients who underwent curative stereotactic surgery for severe mental retardation with aggressive behavior and/or paranoic schizophrenia. Of these, 6 were also tested for the presence of CMV DNA sequences with negative results. Biopsy specimens from nc. amygdalae of another 7 psychotic patients were cultured in vitro but no virus was isolated.