White matter injury and autistic-like behavior predominantly affecting male rat offspring exposed to group B streptococcal maternal inflammation.

The impact of the group B streptococcus (GBS)-induced maternal inflammation on offspring's brain has not yet been investigated despite GBS being one of the most frequent bacteria colonizing or infecting pregnant women. According to our hypothesis GBS-induced maternal immune activation plays a role in offspring perinatal brain damage and subsequent neurodisabilities such as autism. Using a new preclinical rat model of maternal inflammation triggered by inactivated GBS, we demonstrated placental, neuropathological and behavioral impacts on offspring. GBS-exposed placentas presented cystic lesions and polymorphonuclear infiltration located within the decidual/maternal side of the placenta, contrasting with macrophagic infiltration and necrotic areas located in the labyrinth/fetal compartment of the placenta after lipopolysaccharide-induced maternal inflammation. Brain damage featured lateral ventricles widening, predominately in the male, reduction of periventricular external capsules thickness, oligodendrocyte loss, and disorganization of frontoparietal subcortical tissue with no glial proliferation. Autistic hallmarks were found in offspring exposed to GBS, namely deficits in motor behavior, social and communicative impairments, i.e. profound defects in the integration and response to both acoustic and chemical signals that are predominant modes of communication in rats. Surprisingly, only male offspring were affected by these combined autistic-like traits. Our results show for the first time that materno-fetal inflammatory response to GBS plays a role in the induction of placental and cerebral insults, remarkably recapitulating cardinal features of human autism such as gender dichotomy and neurobehavioral traits. Unlike other models of prenatal inflammatory brain damage (induced by viral/toll-like receptor 3 (TLR3) or Gram-negative/TLR4), maternal inflammation resulting from GBS/TLR2 interactions induced a distinctive pattern of chorioamnionitis and cerebral injuries. These results also provide important evidence that beyond genetic influences, modifiable environmental factors play a role in both the occurrence of autism and its gender imbalance.

Regulation of stress response in Oenococcus oeni as a function of environmental changes and growth phase.

Oenococcus oeni is a lactic acid bacterium which is able to grow in wine and perform malolactic fermentation. To survive and grow in such a harsh environment as wine, O. oeni uses several mechanisms of resistance including stress protein synthesis. The molecular characterisation of three stress genes hsp18, clpX, trxA encoding for a small heat shock protein, an ATPase regulation component of ClpP protease and a thioredoxin, respectively, allow us to suggest the existence in O. oeni of multiple regulation mechanisms as is the case in Bacillus subtilis. One common feature of these genes is that they are expressed under the control of housekeeping promoters. The expression of these genes as a function of growth is significantly different. Surprisingly, the clpX gene, which is induced by heat shock, was highly expressed in the early phase of growth. In addition to stress protein synthesis, adaptation to the acid pH of wine requires efficient cellular systems to extrude protons. Using inhibitors specific for different types of ATPases, we demonstrated the existence of H+-ATPase and P-type ATPase.

Acid sensitivity of neomycin-resistant mutants of Oenococcus oeni: a relationship between reduction of ATPase activity and lack of malolactic activity.

Mutants of Oenococcus oeni were isolated as spontaneous neomycin-resistant mutants. Three of these mutants harbored a significantly reduced ATPase activity that represented 50% of that of the wild-type strain. Their growth rates were also impaired at pH 5.3 (46-86% of the wild-type level). However, the profiles of sugar consumption appeared identical to those of the parental strain. At pH 3.2, all the mutant strains failed to grow and a drastic decrease in viability was observed after an acid shock. Surprisingly, all the isolated mutants were devoid of malolactic activity. These results suggest that the ATPase and malolactic activities of O. oeni are linked to each other and play a crucial role in the mechanism of resistance to an acid stress.

Rescue of polyomavirus DNA after co-transfection of recombinant plasmids with viral DNA fragments.

Plasmid DNA bearing a single copy of the mouse polyomavirus (Py) genome (template A) was transfected into murine cells together with another DNA (template B) carrying intact the viral sequence interrupted in template A. Rescue of unit-length Py DNA including markers from both templates was observed as long as the viral DNA in B overlapped that split in A by one kbp or more. Such rescue was not detectably enhanced by linearizing either or both template(s), and occurred in the absence of template replication. These findings are suggestive of an intermolecular recombination process taking place soon after transfection and starting with homologous pairing between A and B. Such pairing would facilitate removal of vector DNA from one template (A), followed by closure of the resulting break or gap through recombination with the other template (B). Since B may consist of a PCR-synthesized DNA fragment, these observations could conceivably serve as the basis for a method of generating mutant viral genomes.