The preprotoxin gene of the 1.9 kb M1 dsRNA genome from type I killer yeast has been sequenced em... more The preprotoxin gene of the 1.9 kb M1 dsRNA genome from type I killer yeast has been sequenced employing a partial-length cDNA derived from an in vivo transcript. A single open reading frame, commencing with AUG at M1 dsRNA bases 14-16, terminates with UAG at 963-965 and codes for a 316 amino acid protein, believed to be identical to the 34 kd preprotoxin species, M1-P1, synthesized by in vitro translation of denatured M1 dsRNA. N-terminal sequencing of M1-P1 confirms this prediction. Secreted toxin is shown to consist of two dissimilar, disulfide-bonded subunits, alpha and beta, of apparent size 9.5 and 9.0 kd, respectively, whose N-terminal sequences are also found in the predicted preprotoxin sequence. Its proposed domains consist of delta, a 44 amino acid N-terminal segment, followed by alpha and beta, which are separated by gamma, a large central glycosylated segment. Processing sites, domain functions, and the potential role of gamma in immunity are discussed.
Virus-like particles containing either L or M double-stranded ribonucleic acid (dsRNA) were isola... more Virus-like particles containing either L or M double-stranded ribonucleic acid (dsRNA) were isolated from a killer toxin-producing strains of Saccharomyces cerevisiae (K+ R+). At least 95% of M- and 87% of L-dsRNA were recovered in virus-like particle-containing fractions. The major capsid polypeptides (ScV-P1) of both L and M virus-like particles were shown to be identical, and 95% of the cellular ScV-P1 was found in the virus-like particle-containing fractions. Since L-dsRNA encodes ScV-P1, provision of this protein for encapsidation of M-dsRNA defines at least one functional relationship between these dsRNA genomes and associates the L-dsRNA with the killer character. If encapsidation of M-dsRNA is essential for its replication or expression, then L-dsRNA plays an essential role in maintenance or expression of the killer phenotype. The relationship between the L- and M-dsRNA genomes would be analogous to that between a helper and a defective virus. The presence of only minor quan...
In this review we focus on the molecular biology of the most intensively investigated killer syst... more In this review we focus on the molecular biology of the most intensively investigated killer system, the M1-dsRNA-determined K1 killer system of S. cerevisiae. We hope to demonstrate the relevance of this system to many of the vital issues in yeast and general eucaryotic molecular biology. It should be emphasized that cytoplasmic dsRNA species have been shown to determine the killer phenotype only in Saccharomyces sp. and Ustilago sp. strains. Only in one other species, Kluyveromyces lactis, has cytoplasmic inheritance of the phenotype and the nature of its determinant (one of two linear dsDNA species) been clearly demonstrated. Brief summaries of recent information on the K. lactis and Ustilago maydis systems are included because of their comparative value and intrinsic interest.
The activity, stability and spectroscopic properties of yeast K+ -activated aldehyde dehydrogenas... more The activity, stability and spectroscopic properties of yeast K+ -activated aldehyde dehydrogenase were measured at various times after removal from, and after returning to a solution containing K+. Enzyme activity is rapidly lost on removal of most of the K+ and rapidly regained if K+ is replaced immediately. These activity changes are slower than likely rates of K+ dissociation and association. These rapid changes in concentration result in altered enzyme stability with enzyme in K+ the more stable. U.v. difference spectra are produced whenever enzyme in an activating environment (K+ or Tl+) is compared with enzyme in a non-activating environment (Tris+ or Li+). These spectral changes occur within 10s. The saturation characteristics with K+ are hyperbolic for all three phenomena of activation, stabilization and spectral change, with estimated apparent dissociation constants (Ks) for K+ of 7.5 mM, 5.5 mM and 6 mM respectively. Continued incubation of enzyme in the absence of K+ res...
Data from steady-state kinetic analysis of yeast K+-activated aldehyde dehydrogenase are consiste... more Data from steady-state kinetic analysis of yeast K+-activated aldehyde dehydrogenase are consistent with a ternary complex mechanism. Evidence from alternative substrate analysis and product-inhibition studies supports an ordered sequence of substrate binding in which NAD+ is the leading substrate. A preincubation requirement for NAD+ for maximum activity is also consistent with the importance of a binary enzyme-NAD+ complex. Dissociation constant for enzyme-NAD+ complex determined kinetically is in reasonable agreement with that determined by direct binding. The order of substrate addition proposed here differs from that proposed for a yeast aldehyde dehydrogenase previously reported. Different methods of purification produced an enzyme that showed similar kinetic characteristics to those reported here.
Univalent cation activators of aldehyde dehydrogenase have dual effects, both interpreted as cati... more Univalent cation activators of aldehyde dehydrogenase have dual effects, both interpreted as cation-induced or -stabilized conformation changes. These two processes are differentiated by the time scales of their associated changes in activity. Using Tl+ as an activator, under certain conditions, the slower change in activity saturates at a Tl+ concentration which is only 0.1 Ks for the faster change. This, together with evidence for cation-induced rather than cation-stabilized conformation changes, is used to propose separate binding sites for cations responsible for the two activation processes. Equilibrium dialysis indicates 4 binding sites per active site for Rb+ or 6 sites for Tl+. At least one of the additional sites for Tl+ is an inhibitory site which has been differentiated from the activator sites on the basis of steady-state and pre-steady-state kinetic data.
The preprotoxin gene of the 1.9 kb M1 dsRNA genome from type I killer yeast has been sequenced em... more The preprotoxin gene of the 1.9 kb M1 dsRNA genome from type I killer yeast has been sequenced employing a partial-length cDNA derived from an in vivo transcript. A single open reading frame, commencing with AUG at M1 dsRNA bases 14-16, terminates with UAG at 963-965 and codes for a 316 amino acid protein, believed to be identical to the 34 kd preprotoxin species, M1-P1, synthesized by in vitro translation of denatured M1 dsRNA. N-terminal sequencing of M1-P1 confirms this prediction. Secreted toxin is shown to consist of two dissimilar, disulfide-bonded subunits, alpha and beta, of apparent size 9.5 and 9.0 kd, respectively, whose N-terminal sequences are also found in the predicted preprotoxin sequence. Its proposed domains consist of delta, a 44 amino acid N-terminal segment, followed by alpha and beta, which are separated by gamma, a large central glycosylated segment. Processing sites, domain functions, and the potential role of gamma in immunity are discussed.
Virus-like particles containing either L or M double-stranded ribonucleic acid (dsRNA) were isola... more Virus-like particles containing either L or M double-stranded ribonucleic acid (dsRNA) were isolated from a killer toxin-producing strains of Saccharomyces cerevisiae (K+ R+). At least 95% of M- and 87% of L-dsRNA were recovered in virus-like particle-containing fractions. The major capsid polypeptides (ScV-P1) of both L and M virus-like particles were shown to be identical, and 95% of the cellular ScV-P1 was found in the virus-like particle-containing fractions. Since L-dsRNA encodes ScV-P1, provision of this protein for encapsidation of M-dsRNA defines at least one functional relationship between these dsRNA genomes and associates the L-dsRNA with the killer character. If encapsidation of M-dsRNA is essential for its replication or expression, then L-dsRNA plays an essential role in maintenance or expression of the killer phenotype. The relationship between the L- and M-dsRNA genomes would be analogous to that between a helper and a defective virus. The presence of only minor quan...
In this review we focus on the molecular biology of the most intensively investigated killer syst... more In this review we focus on the molecular biology of the most intensively investigated killer system, the M1-dsRNA-determined K1 killer system of S. cerevisiae. We hope to demonstrate the relevance of this system to many of the vital issues in yeast and general eucaryotic molecular biology. It should be emphasized that cytoplasmic dsRNA species have been shown to determine the killer phenotype only in Saccharomyces sp. and Ustilago sp. strains. Only in one other species, Kluyveromyces lactis, has cytoplasmic inheritance of the phenotype and the nature of its determinant (one of two linear dsDNA species) been clearly demonstrated. Brief summaries of recent information on the K. lactis and Ustilago maydis systems are included because of their comparative value and intrinsic interest.
The activity, stability and spectroscopic properties of yeast K+ -activated aldehyde dehydrogenas... more The activity, stability and spectroscopic properties of yeast K+ -activated aldehyde dehydrogenase were measured at various times after removal from, and after returning to a solution containing K+. Enzyme activity is rapidly lost on removal of most of the K+ and rapidly regained if K+ is replaced immediately. These activity changes are slower than likely rates of K+ dissociation and association. These rapid changes in concentration result in altered enzyme stability with enzyme in K+ the more stable. U.v. difference spectra are produced whenever enzyme in an activating environment (K+ or Tl+) is compared with enzyme in a non-activating environment (Tris+ or Li+). These spectral changes occur within 10s. The saturation characteristics with K+ are hyperbolic for all three phenomena of activation, stabilization and spectral change, with estimated apparent dissociation constants (Ks) for K+ of 7.5 mM, 5.5 mM and 6 mM respectively. Continued incubation of enzyme in the absence of K+ res...
Data from steady-state kinetic analysis of yeast K+-activated aldehyde dehydrogenase are consiste... more Data from steady-state kinetic analysis of yeast K+-activated aldehyde dehydrogenase are consistent with a ternary complex mechanism. Evidence from alternative substrate analysis and product-inhibition studies supports an ordered sequence of substrate binding in which NAD+ is the leading substrate. A preincubation requirement for NAD+ for maximum activity is also consistent with the importance of a binary enzyme-NAD+ complex. Dissociation constant for enzyme-NAD+ complex determined kinetically is in reasonable agreement with that determined by direct binding. The order of substrate addition proposed here differs from that proposed for a yeast aldehyde dehydrogenase previously reported. Different methods of purification produced an enzyme that showed similar kinetic characteristics to those reported here.
Univalent cation activators of aldehyde dehydrogenase have dual effects, both interpreted as cati... more Univalent cation activators of aldehyde dehydrogenase have dual effects, both interpreted as cation-induced or -stabilized conformation changes. These two processes are differentiated by the time scales of their associated changes in activity. Using Tl+ as an activator, under certain conditions, the slower change in activity saturates at a Tl+ concentration which is only 0.1 Ks for the faster change. This, together with evidence for cation-induced rather than cation-stabilized conformation changes, is used to propose separate binding sites for cations responsible for the two activation processes. Equilibrium dialysis indicates 4 binding sites per active site for Rb+ or 6 sites for Tl+. At least one of the additional sites for Tl+ is an inhibitory site which has been differentiated from the activator sites on the basis of steady-state and pre-steady-state kinetic data.
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