Temperature- and sex-related effects of serine protease alleles on larval development in the Glanville fritillary butterfly.

The body reserves of adult Lepidoptera are accumulated during larval development. In the Glanville fritillary butterfly, larger body size increases female fecundity, but in males fast larval development and early eclosion, rather than large body size, increase mating success and hence fitness. Larval growth rate is highly heritable, but genetic variation associated with larval development is largely unknown. By comparing the Glanville fritillary population living in the Åland Islands in northern Europe with a population in Nantaizi in China, within the source of the post-glacial range expansion, we identified candidate genes with reduced variation in Åland, potentially affected by selection under cooler climatic conditions than in Nantaizi. We conducted an association study of larval growth traits by genotyping the extremes of phenotypic trait distributions for 23 SNPs in 10 genes. Three genes in clip-domain serine protease family were associated with larval growth rate, development time and pupal weight. Additive effects of two SNPs in the prophenoloxidase-activating proteinase-3 (ProPO3) gene, related to melanization, showed elevated growth rate in high temperature but reduced growth rate in moderate temperature. The allelic effects of the vitellin-degrading protease precursor gene on development time were opposite in the two sexes, one genotype being associated with long development time and heavy larvae in females but short development time in males. Sexually antagonistic selection is here evident in spite of sexual size dimorphism.

Fitness differences associated with Pgi SNP genotypes in the Glanville fritillary butterfly (Melitaea cinxia).

Allozyme variation at the phosphoglucose isomerase (PGI) locus in the Glanville fritillary butterfly (Melitaea cinxia) is associated with variation in flight metabolic rate, dispersal rate, fecundity and local population growth rate. To map allozyme to DNA variation and to survey putative functional variation in genomic DNA, we cloned the coding sequence of Pgi and identified nonsynonymous variable sites that determine the most common allozyme alleles. We show that these single-nucleotide polymorphisms (SNPs) exhibit significant excess of heterozygotes in field-collected population samples as well as in laboratory crosses. This is in contrast to previous results for the same species in which other allozymes and SNPs were in Hardy-Weinberg equilibrium or exhibited an excess of homozygotes. Our results suggest that viability selection favours Pgi heterozygotes. Although this is consistent with direct overdominance at Pgi, we cannot exclude the possibility that heterozygote advantage is caused by the presence of one or more deleterious alleles at linked loci.

Dynamic exchanges of RNA interactions leading to catalytic core formation in the U12-dependent spliceosome.

Important general insights into the mechanism of pre-mRNA splicing have emerged from studies of the U12-dependent spliceosome. Here, photochemical cross-linking analyses during U12-dependent spliceosome assembly have surprisingly revealed that an upstream 5' exon region is required for establishing two essential catalytic core interactions, U12/U6atac helix Ib and U6atac/5' splice site contacts, but not for U5/5' exon interactions or partial unwinding of U4atac/U6atac. A novel intermediate, representing an alternative pathway for catalytic core formation, is a ternary snRNA complex containing U4atac/U6atac stem II and U12/U6atac helix Ia that forms even without U6atac replacing U11 at the 5' splice site. A powerful oligonucleotide displacement method suggests that the blocked complexes analyzed to deduce the interdependence of these multiple RNA exchanges are authentic intermediates in U12-dependent spliceosome assembly.

Initial recognition of U12-dependent introns requires both U11/5' splice-site and U12/branchpoint interactions.

We have investigated the formation of prespliceosomal complex A in HeLa nuclear extracts on a splicing substrate containing an AT-AC (U12-type) intron from the P120 gene. Using an RNase H protection assay and specific blocking oligonucleotides, we find that recognition of the 5' splice-site (5'ss) and branchpoint sequence (BPS) elements by U11 and U12 snRNPs, respectively, displays strong cooperativity, requiring both sites in the pre-mRNA substrate for efficient complex formation. Deletion analysis indicates that beside the 5'ss and BPS, no additional elements in the pre-mRNA are necessary for A-complex formation, although 5' exon sequences provide stimulation. Cross-linking studies with pre-mRNAs containing the 5'ss or BPS alone indicate that recognition of the BPS by the U12 snRNP is stimulated at least 20- to 30-fold by the binding of the U11 snRNP to the 5'ss in the same pre-mRNA molecule, whereas recognition of the 5'ss by U11 is stimulated approximately fivefold by the U12/BPS interaction. These results argue that intron recognition in the U12-dependent splicing pathway is carried out by a single U11/U12 di-snRNP complex, suggesting greater rigidity in the intron recognition process than in the major spliceosome.