Expression of functional beta-galactosidase containing the coxsackievirus 3C protease as an internal fusion

Alpha complementation of beta-galactosidase (beta gal) is intracistronic and requires interaction between the alpha donor region (residues 3-41) and alpha acceptor fragment (produced by M15). We have constructed two plasmids which direct the synthesis of hybrid beta gal: coxsackievirus proteins in Escherichia coli. One plasmid, pBD1045, encodes an enzymatically active 3C protease of coxsackievirus B3 fused between the amino-terminal 79 amino acids of beta gal (containing the alpha donor region) and amino acids 80 to 1023 (alpha acceptor region). A second plasmid, pBD1043 encodes an inactive 3C protease and results in a fusion of 260 coxsackievirus amino acids between residues 79 and 80 of the beta gal monomer. Both hybrid proteins expressed by these constructs have beta-galactosidase activity regardless of whether the viral protease (183 amino acids) is autocatalytically cleaved out of the chimeric protein (pBD1045) or remains as part of a fusion protein (pBD1043). The implications of these results for structural flexibility of the complemented beta-galactosidase enzyme are discussed.     

Elevated paraquat resistance can be used as a bioassay for longevity in a genetically based long-lived strain of Drosophila.

A long-lived (L) strain of Drosophila melanogaster, derived from a normal-lived (R) strain by artificial selection, has a significantly different adult longevity. Previous work has shown that 1) the two strains age in the same manner, 2) the major genes responsible for much of the L strain's extended longevity are located on the 3rd chromosome, and 3) the extended longevity phenotype is significantly modulated by the larval environment. In this report, we investigate the resistance of the L and R strains to the lethal effects of dietary paraquat. We show that, within the limitations of our described chromosomal and environmental manipulations, the extended longevity phenotype always accompanies the phenotype of elevated paraquat resistance. In addition, reversed selection applied to the L strain results in the simultaneous decrease of both life span and paraquat resistance. Thus, the presence or absence of the latter phenotype may be used as a bioassay for the presence or absence of the extended longevity phenotype, without any necessary implication of causality. Use of this bioassay should greatly speed up the genetic analysis of this system by allowing us to identify long-lived animals at a young age. Finally, we show that the age-related loss of elevated paraquat resistance in both strains precedes all the other age-related functional decrements which we have previously noted in this system.     

Intracellular chloride in submucosal gland cells

The chloride ion concentration within isolated tracheal submucosal gland cells was studied micro-spectrofluorometrically using a fluorescent dye, 6-methoxy-N-(3-sulfopropyl) quinolinium (SPQ), that is quenched by Cl-. Cells from normal weanling swine and from a cystic fibrosis (CF) patient were used. Ion substitution experiments showed that cell fluorescence increased in both cell types when bath Cl- was replaced with the impermeant anion glucuronate. Following a Donnan-type ion substitution that kept the product of the bath K+ and Cl- concentrations constant, reducing bath chloride had little effect on fluorescence for normal cells, but caused a marked increase for CF cells. Thus, K+ and Cl- ions have approximately the same Nernst potential in control submucosal gland cells; in contrast, cells from a CF patient concentrated Cli, resulting in a Cl- Nernst potential that was more positive than the K+ Nernst potential. This finding is consistent with the hypothesis that CF submucosal gland cells have a decreased Cl- permeability.