Three phylogenetic groups have driven the recent population expansion of Cryptococcus neoformans.

Cryptococcus neoformans (C. neoformans var. grubii) is an environmentally acquired pathogen causing 181,000 HIV-associated deaths each year. We sequenced 699 isolates, primarily C. neoformans from HIV-infected patients, from 5 countries in Asia and Africa. The phylogeny of C. neoformans reveals a recent exponential population expansion, consistent with the increase in the number of susceptible hosts. In our study population, this expansion has been driven by three sub-clades of the C. neoformans VNIa lineage; VNIa-4, VNIa-5 and VNIa-93. These three sub-clades account for 91% of clinical isolates sequenced in our study. Combining the genome data with clinical information, we find that the VNIa-93 sub-clade, the most common sub-clade in Uganda and Malawi, was associated with better outcomes than VNIa-4 and VNIa-5, which predominate in Southeast Asia. This study lays the foundation for further work investigating the dominance of VNIa-4, VNIa-5 and VNIa-93 and the association between lineage and clinical phenotype.

Characterization of revertant muscle fibers in Duchenne muscular dystrophy, using exon-specific monoclonal antibodies against dystrophin.

Most Duchenne muscular dystrophy (DMD) patients have genetic deletions or point mutations in the dystrophin gene that alter the reading frame of dystrophin mRNA. This causes early termination of translation, and no dystrophin (or, less commonly, a truncated N-terminal dystrophin fragment) is produced. In many DMD patients, however, a small proportion of muscle fibers show strong dystrophin staining, and these "revertant fibers" are thought to arise by a mechanism that restores the reading frame. Exon-specific monoclonal antibodies (mAbs) have now been used to determine, for the first time, which exons are removed, in order to correct the reading frame in individual muscle fibers. Thus, 15 revertant fibers in a DMD patient with a frameshift deletion of exon 45 were shown to correct the frameshift by the additional deletion of exon 44 (or perhaps exon 46 in some fibers) from the dystrophin mRNA, but not by larger deletions. This result was consistent with reverse transcription (RT)-PCR and sequencing of a minor dystrophin mRNA with an exon 43/46 junction in this biopsy. In a DMD patient with a frameshift deletion of exons 42 and 43, however, larger deletions than the minimum necessary were used to correct the frameshift. In this patient, who produces a half-size N-terminal dystrophin fragment in all fibers, we were able to show that the revertant dystrophin replaces the truncated dystrophin in revertant-fiber sarcolemma. The results are consistent with somatic mutations in revertant-fiber nuclei, which result in removal of additional exons from dystrophin mRNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural relationships between hepatitis B surface antigen in human plasma and dimers from recombinant vaccine: a monoclonal antibody study.

Ten monoclonal antibodies were obtained from mice immunized with a yeast recombinant hepatitis B vaccine. They were selected at an early stage for their ability to bind to native surface antigen particles (HBsAg) in human plasma. All antibodies recognized conformational epitopes which were destroyed completely or almost completely by reduction of disulphide bridges. They were divided into five epitope groups by their competition for binding to recombinant S protein, though epitopes within each group are not identical. Recombinant S protein migrated on SDS-PAGE in the absence of reducing agents as a mixture of monomers and dimers/oligomers. Sucrose gradient analysis suggests that all these forms are co-aggregated into HBsAg-like particles. On Western blots, all ten antibodies either bound only to dimers/oligomers or strongly preferred them over monomers. The results suggest that, of the antibodies produced in response to recombinant vaccine in mice, most of those which bind strongly to 'native' HBsAg particles in human plasma recognize surface structures created by interaction between two subunits.

Structural rearrangements in active and inactive forms of hydrogenase from Thiocapsa roseopersicina.

The electrophoretic behavior of Thiocapsa roseopersicina hydrogenase on sodium dodecyl sulfate gels demonstrates that the protein exists in two active forms, A1 and A2, which may be interconverted. Each of these forms has a characteristic electrophoretic mobility and differs in its sensitivity to O2. Form A1 is O2-labile and converts to A2 under O2. Form A2 is less sensitive to O2 and may be converted into A1 under H2 atmosphere. Both active forms are present in aerobically isolated samples. Because the proteins are still active on 15% sodium dodecyl sulfate gels, they are not completely denatured, and the apparent molecular masses do not necessarily represent the true molecular masses of the enzymes. A1 has an Rf = 0.19, corresponding to an apparent molecular mass of 90 kDa, and A2 has an Rf = 0.35, corresponding to an apparent molecular mass of 49 kDa. A sedimentation equilibrium centrifugation study of the active enzyme shows that the holoenzyme has a molecular mass of 98 kDa. Form A2 may be separated into two subunits of molecular mass of 64 kDa and 34 kDa, respectively. Thus, form A2 represents the holoenzyme with a true molecular mass of 98 kDa. Amino acid compositions and N-terminal amino acid sequences of the A2 protein and these subunits are consistent with a heterodimeric holoenzyme. The relationship between the conformational changes detected in this study and a three-state scheme proposed on the basis of EPR spectroscopic studies of the metal-containing cofactors present in the enzyme is also discussed.