Pubertal maturation and sex effects on the default-mode network connectivity implicated in mood dysregulation

This study examines the effects of puberty and sex on the intrinsic functional connectivity (iFC) of brain networks, with a focus on the default-mode network (DMN). Consistently implicated in depressive disorders, the DMN’s function may interact with puberty and sex in the development of these disorders, whose onsets peak in adolescence, and which show strong sex disproportionality (females > males). The main question concerns how the DMN evolves with puberty as a function of sex. These effects are expected to involve within- and between-network iFC, particularly, the salience and the central-executive networks, consistent with the Triple-Network Model. Resting-state scans of an adolescent community sample (n = 304, male/female: 157/147; mean/std age: 14.6/0.41 years), from the IMAGEN database, were analyzed using the AFNI software suite and a data reduction strategy for the effects of puberty and sex. Three midline regions (medial prefrontal, pregenual anterior cingulate, and posterior cingulate), within the DMN and consistently implicated in mood disorders, were selected as seeds. Within- and between-network clusters of the DMN iFC changed with pubertal maturation differently in boys and girls (puberty-X-sex). Specifically, pubertal maturation predicted weaker iFC in girls and stronger iFC in boys. Finally, iFC was stronger in boys than girls independently of puberty. Brain–behavior associations indicated that lower connectivity of the anterior cingulate seed predicted higher internalizing symptoms at 2-year follow-up. In conclusion, weaker iFC of the anterior DMN may signal disconnections among circuits supporting mood regulation, conferring risk for internalizing disorders

Borréliose de Lyme : rôle de l’interface cutanée et du microbiome dans la physiopathologie de la maladie

Lyme disease is the most common vector-borne disease in the Northern Hemisphere. Skin is a key organ in the disease, since it is the key interface where host cells, pathogen, skin microbiota and vector interact early during pathogen transmission. We developed a late lyme borreliosis model on mice. This model allowed us to develop a specific detection method of Borreliella proteins in the mouse skin by SRM-MS that might be used to develop a human diagnosis of disseminated Lyme disease. In a second part, we analysed the relationship between skin microbiota, resident skin cells (keratinocytes and fibroblasts), in the presence or absence of Borreliella. The secretome of three commensals bacteria, S. epidermidis, P. acnes and C. striatum was shown to have a synergistic activity with Borreliella in pro-inflammatory gene expressions by keratinocytes and fibroblasts. P. acnes and C. striatum secretomes were also able to inhibit partially the inflammatory response of keratinocytes that might help the transmission/dissemination of the pathogen.La maladie de Lyme est la maladie à transmission vectorielle la plus répandue de l’hémisphère Nord. La peau est un organe clef dans cette maladie, car c’est à cet endroit qu’interagissent les cellules de l’hôte, le pathogène, le microbiote cutané et le vecteur. Nous avons développé un modèle murin d’infection disséminée de borréliose de Lyme, qui nous a permis de développer une méthode spécifique de détection de protéines de Borreliella dans le tissu cutané murin par SRM-MS, pouvant aboutir à une méthode de diagnostic chez l’homme. Dans un deuxième temps, nous nous sommes intéressés aux relations entre le microbiote cutané, les cellules résidentes de la peau, kératinocytes et fibroblastes, avec Borreliella. Les sécrétomes de trois bactéries commensales, S. epidermidis, P. acnes et C. striatum possèdent un effet synergique sur l’expression de gènes inflammatoires par les kératinocytes et les fibroblastes. Les sécrétomes de P. acnes et de C. striatum se sont également montrés capables d’inhiber une partie de la réponse inflammatoire des kératinocytes, pouvant aider le pathogène lors de la transmission/dissémination précoce

Lyme Borreliosis : role of the skin interface and the microbiome in the physiopathology of the disease

La maladie de Lyme est la maladie à transmission vectorielle la plus répandue de l’hémisphère Nord. La peau est un organe clef dans cette maladie, car c’est à cet endroit qu’interagissent les cellules de l’hôte, le pathogène, le microbiote cutané et le vecteur. Nous avons développé un modèle murin d’infection disséminée de borréliose de Lyme, qui nous a permis de développer une méthode spécifique de détection de protéines de Borreliella dans le tissu cutané murin par SRM-MS, pouvant aboutir à une méthode de diagnostic chez l’homme. Dans un deuxième temps, nous nous sommes intéressés aux relations entre le microbiote cutané, les cellules résidentes de la peau, kératinocytes et fibroblastes, avec Borreliella. Les sécrétomes de trois bactéries commensales, S. epidermidis, P. acnes et C. striatum possèdent un effet synergique sur l’expression de gènes inflammatoires par les kératinocytes et les fibroblastes. Les sécrétomes de P. acnes et de C. striatum se sont également montrés capables d’inhiber une partie de la réponse inflammatoire des kératinocytes, pouvant aider le pathogène lors de la transmission/dissémination précoce.Lyme disease is the most common vector-borne disease in the Northern Hemisphere. Skin is a key organ in the disease, since it is the key interface where host cells, pathogen, skin microbiota and vector interact early during pathogen transmission. We developed a late lyme borreliosis model on mice. This model allowed us to develop a specific detection method of Borreliella proteins in the mouse skin by SRM-MS that might be used to develop a human diagnosis of disseminated Lyme disease. In a second part, we analysed the relationship between skin microbiota, resident skin cells (keratinocytes and fibroblasts), in the presence or absence of Borreliella. The secretome of three commensals bacteria, S. epidermidis, P. acnes and C. striatum was shown to have a synergistic activity with Borreliella in pro-inflammatory gene expressions by keratinocytes and fibroblasts. P. acnes and C. striatum secretomes were also able to inhibit partially the inflammatory response of keratinocytes that might help the transmission/dissemination of the pathogen

Lyme Borreliosis : role of the skin interface and the microbiome in the physiopathology of the disease

La maladie de Lyme est la maladie à transmission vectorielle la plus répandue de l’hémisphère Nord. La peau est un organe clef dans cette maladie, car c’est à cet endroit qu’interagissent les cellules de l’hôte, le pathogène, le microbiote cutané et le vecteur. Nous avons développé un modèle murin d’infection disséminée de borréliose de Lyme, qui nous a permis de développer une méthode spécifique de détection de protéines de Borreliella dans le tissu cutané murin par SRM-MS, pouvant aboutir à une méthode de diagnostic chez l’homme. Dans un deuxième temps, nous nous sommes intéressés aux relations entre le microbiote cutané, les cellules résidentes de la peau, kératinocytes et fibroblastes, avec Borreliella. Les sécrétomes de trois bactéries commensales, S. epidermidis, P. acnes et C. striatum possèdent un effet synergique sur l’expression de gènes inflammatoires par les kératinocytes et les fibroblastes. Les sécrétomes de P. acnes et de C. striatum se sont également montrés capables d’inhiber une partie de la réponse inflammatoire des kératinocytes, pouvant aider le pathogène lors de la transmission/dissémination précoce.Lyme disease is the most common vector-borne disease in the Northern Hemisphere. Skin is a key organ in the disease, since it is the key interface where host cells, pathogen, skin microbiota and vector interact early during pathogen transmission. We developed a late lyme borreliosis model on mice. This model allowed us to develop a specific detection method of Borreliella proteins in the mouse skin by SRM-MS that might be used to develop a human diagnosis of disseminated Lyme disease. In a second part, we analysed the relationship between skin microbiota, resident skin cells (keratinocytes and fibroblasts), in the presence or absence of Borreliella. The secretome of three commensals bacteria, S. epidermidis, P. acnes and C. striatum was shown to have a synergistic activity with Borreliella in pro-inflammatory gene expressions by keratinocytes and fibroblasts. P. acnes and C. striatum secretomes were also able to inhibit partially the inflammatory response of keratinocytes that might help the transmission/dissemination of the pathogen

Détection rapide des mutations gyrA chez les entérobactéries par pyroséquençage multiplex

REIMS-BU Santé (514542104) / SudocSudocFranceF

Prélèvements à visée bactériologique des liquides de dialyse péritonéale. Comment limiter le nombre de péritonites à culture négative ?

Peritonitis is a major and serious complication in terms of morbi-mortality for patients treated with peritoneal dialysis. Their microbiological diagnosis is challenging for both the detection of the etiological agents and in interpreting positive cultures. Many microorganisms can cause this infection; usual micro-organisms such as coagulase-negative staphylococci or Enterobacteriaceae, but also ‘atypical’ bacteria, which culture or detection, is more tedious can be found. To identify the responsible bacteria, molecular biology and culture techniques can be set up. Molecular biology (particularly the sequencing of the universal 16s rDNA gene) makes it possible to identify atypical agents, but antimicrobial susceptibility testing cannot be performed following these technics. The culture of peritoneal dialysis fluids remains the ‘gold-standard’ for the diagnosis of these infections. Nevertheless this must be optimized to enhance its sensitivity. The etiological diagnosis of peritonitis in patients treated with peritoneal dialysis may be difficult, but modern microbiology combined with a bacterioclinical discussion allow the identification of the microorganism responsible for the infection in the great majority of the cases.Les péritonites sont une complication majeure et grave en termes de morbi-mortalité chez les patients traités par dialyse péritonéale. Leur diagnostic microbiologique est compliqué tant au point vu de la détection des agents étiologiques des péritonites que de l’interprétation des cultures positives. De nombreux micro-organismes peuvent être à l’origine de cette infection ; germes « classiques » comme les staphylocoques à coagulase négative ou les entérobactéries, mais également des bactéries « atypiques », de culture ou de détection plus fastidieuse. Pour mettre en évidence les bactéries responsables, des techniques de biologie moléculaire et de culture peuvent être mises en place. La biologie moléculaire (particulièrement la recherche universelle (ADNr 16s)) permet d’identifier d’éventuels germes atypiques, mais ne permet pas la réalisation d’un antibiogramme. La culture des liquides de dialyse péritonéale reste donc le « gold-standard » pour le diagnostic de ces infections. Celle-ci doit être néanmoins optimisée pour abaisser son seuil de sensibilité. Le diagnostic étiologique des péritonites chez les patients traités par dialyse péritonéale peut être difficile, mais la microbiologie moderne combinée à une discussion bactério-clinique permet l’identification du germe responsable de l’infection dans la très grande majorité des cas. Abstract Peritonitis is a major and serious complication in terms of morbi-mortality for patients treated with peritoneal dialysis. Their microbiological diagnosis is challenging for both the detection of the etiological agents and in interpreting positive cultures.Many microorganisms can cause this infection; usual micro-organisms such as coagulase-negative staphylococci or Enterobacteriaceae, but also ‘atypical’ bacteria, which culture or detection, is more tedious can be found.To identify the responsible bacteria, molecular biology and culture techniques can be set up. Molecular biology (particularly the sequencing of the universal 16s rDNA gene) makes it possible to identify atypical agents, but antimicrobial susceptibility testing cannot be performed following these technics.The culture of peritoneal dialysis fluids remains the ‘gold-standard’ for the diagnosis of these infections. Nevertheless this must be optimized to enhance its sensitivity.The etiological diagnosis of peritonitis in patients treated with peritoneal dialysis may be difficult, but modern microbiology combined with a bacterioclinical discussion allow the identification of the microorganism responsible for the infection in the great majority of the cases

Comparative Activity of Ciprofloxacin, Levofloxacin and Moxifloxacin against Klebsiella pneumoniae, Pseudomonas aeruginosa and Stenotrophomonas maltophilia Assessed by Minimum Inhibitory Concentrations and Time-Kill Studies.

The aim of this study was to compare the in vitro susceptibility of Klebsiella pneumoniae, Pseudomonas aeruginosa and Stenotrophomonas maltophilia to three fluoroquinolones. The minimum inhibitory concentrations (MICs) to ciprofloxacin, levofloxacin and moxifloxacin were examined by E-test® for a total of 40 K. pneumoniae strains, 40 S. maltophilia strains and 40 P. aeruginosa strains. Then, the bactericidal activity of these fluoroquinolones was investigated on five strains of each bacterial species by means of time-kill curves. For K. pneumoniae and P. aeruginosa, the distance of the measured MIC from the clinical break-point is a good indicator of the bactericidal activity for ciprofloxacin and levofloxacin as obtained in our experiments. The lower the MIC, the better the bactericidal activity in term of CFU Log decreases. If MIC of ciprofloxacin and levofloxacin against the considered bacteria are far from clinical breakpoint, these two antibiotics are equivalent. According to our MIC50 and modal MIC, the breakpoints of both ciprofloxacin and levofloxacin seem to be somewhat high and data suggest reducing them. On S. maltophilia, none of the tested antibiotics showed a satisfactory activity

Skin Interface, a Key Player for Borrelia Multiplication and Persistence in Lyme Borreliosis

International audienceThe skin plays a key role in vector-borne diseases because it is the site where the arthropod coinoculates pathogens and its saliva. Lyme borreliosis, particularly well investigated in this context, is a multisystemic infectious disease caused by Borrelia burgdorferi sensu lato and transmitted by the hard tick Ixodes. Numerous in vitro studies were conducted to better understand the role of specific skin cells and tick saliva in host defense, vector feeding, and pathogen transmission. The skin was also evidenced in various animal models as the site of bacterial multiplication and persistence. We present the achievements in this field as well as the gaps that impede comprehensive knowledge of the disease pathophysiology and the development of efficient diagnostic tools and vaccines in humans. Copyright © 2020 Elsevier Ltd. All rights reserved