Variation among 41 Genotypes of Tomato (Lycopersicon esculentumMill.) for Crossability toL. peruvianum(L.) Mill.

Even with the aid of tissue culture, crosses betweenLycopersiconesculentum(E) andL. peruvianum(P) typically yield few progeny.To determine whether some E genotypes produce more progeny perfruit that others when crossed with P, 41 E genotypes were crossedwith pollen bulked from five P accessions. This first experiment(expt 1) was replicated over 2 years. In a second experiment(expt 2), differences among three genotypes each of E and P,and among individual plants within E genotypes were investigated.The E genotypes for expt 2 were chosen for relatively high andlow crossability based on results of expt 1. The P genotypesfor expt 2 were from different accessions than those used inexpt 1. For both experiments, the 15 largest ovules from eachripe fruit were cultured aseptically for 1 month. Out of 1228fruit, 753 hybrids were obtained. For expt 1, significant genotypeby year interactions were observed. Within each year, therewere significant differences among E genotypes for crossability.In expt 2, significant effects were found for E genotypes, butnot for interactions between E and P genotypes, P genotypes,nor plants within E genotypes. Moreover, general crossabilityfor E genotypes using bulked pollen (expt 1) was indicativeof general crossability with three P accessions not presentin the bulk (expt 2). Thus, selecting E genotypes of high crossabilityto P is the key to obtaining progeny for gene introgression.Rare production of ExP seed which was large and had brown seedcoats typical of E seed indicated strong selection pressureto maintain separate species, but gene exchange in nature maybe possible albeit at a low rate over long periods of time. Interspecific hybridization; Lycopersicon esculentum; Lycopersicon peruvianum; ovule culture; speciation     

Functional aspects of the capsid structure of Mengo virus

The three-dimensional structure of the Mengo virus capsid has been determined at a resolution of 3.0 A. This achievement is discussed in an historical context, and the general features of picornavirus capsid design are presented. The dynamic functional aspects of the Mengo virus capsid--namely its ability to interact with specific receptors on host cells, to dissociate and release the viral genomic RNA into the cellular cytoplasm, to assemble with progeny RNA molecules and form new virions, and to alter its external surface in order to evade neutralization by circulating antibodies--are discussed. Comparisons with other picornaviruses whose capsid structures have also been elucidated (poliovirus serotype 1 and 3, human rhinovirus types 14 and 1A, and foot-and-mouth disease virus type O) illustrate both the similarities and the distinctive features of capsid design found within this family of mammalian viruses.     

The structure and maturation of intermediates in bacteriophage T7 DNA replication

Concatemeric DNA from T7-infected cells consists of phage genomes in a linear head-to-tail arrangement. Adjacent genomes within a concatemer overlap for the length of the terminal repetition. Fast-sedimenting T7 DNA contains single-stranded regions at roughly unit-lentth intervals but these interruptions are heterogeneously distributed and do not occur at the genetic termini. Mutations in either bacteriophage genes 9, 18, or 19 (required for DNA maturation and packaging) lead to the synthesis and persistence of DNA with fewer interruptions than normal.