Perinatal hypoxia-ischemia induces apoptotic and excitotoxic death of periventricular white matter oligodendrocyte progenitors.

Hypoxia-ischemia (HI) is a leading cause of white matter damage, a major contributor to cerebral palsy in premature infants. Preferential white matter damage is believed to result from vulnerability of the immature oligodendrocyte (the pro-OL) to factors elevated during ischemic damage, such as oxygen free radicals and glutamate. In order to determine whether pro-OLs undergo apoptotic death after HI, we analyzed periventricular white matter OLs in P7 rats 4, 12 and 24 h after HI to analyze the time course and mode of cell death. DNA fragmentation was seen at 12 and 24 h of recovery after HI, representing a 17-fold increase over control. In addition, caspase-3 activation was found in NG2+ pro-OLs at 12 h. Electron-microscopic analysis of cell death in the white matter revealed a transition from early necrotic deaths to hybrid cell deaths to classical apoptosis between 4 and 24 h of recovery from HI. The delayed time course of apoptosis in pro-OLs supports the feasibility of interventions to improve clinical outcomes for newborns surviving birth asphyxia.

Characterization of a class II pilin expression locus from Neisseria meningitidis: evidence for increased diversity among pilin genes in pathogenic Neisseria species.

Strains of Neisseria meningitidis elaborate one of two classes of pili. Meningococcal class I pili have many features in common with pili produced by N. gonorrhoeae, including the ability to bind monoclonal antibody SM1 and a common gene and protein structure consisting of conserved, semivariable, and hypervariable regions. Class II pili are SM1 nonreactive and display smaller subunit molecular weights than do gonococcal or meningococcal class I pili. In this study, we have determined the N-terminal amino acid sequence for class II pilin and isolated the expression locus encoding class II pilin from N. meningitidis FAM18. Meningococcal class II pilin displays features typical of type IV pili and shares extensive amino acid identity with the N-terminal conserved regions of other neisserial pilin proteins. However, the deduced class II pilin sequence displays several unique features compared with previously reported meningococcal class I and gonococcal pilin sequences. Class II pilin lacks several conserved peptide regions found within the semivariable and hypervariable regions of other neisserial pilins and displays a large deletion in a hypervariable region of the protein believed to be exposed on the pilus face in gonococcal pili. DNA sequence comparisons within all three regions of the coding sequence also suggest that the meningococcal class II pilin gene is the most dissimilar of the three types of neisserial pilE loci. Additionally, the class II locus fails to display flanking-sequence homology to class I and gonococcal genes and lacks a downstream Sma/Cla repeat sequence, a feature present in all other neisserial pilin genes examined to date. These data indicate meningococcal class II pili represent a structurally distinct class of pili and suggest that relationships among pilin genes in pathogenic Neisseria do not necessarily follow species boundaries.