Yeast mutants without phosphofructokinase activity can still perform glycolysis and alcoholic fermentation

Summary Mutants of Saccharomyces cerevisiae without detectable phosphofructokinase activity were isolated. They were partly recessive and belonged to two genes called PFK1 and PFK2. Mutants with a defect in only one of the two genes could not grow when they were transferred from a medium with a nonfermentable carbon source to a medium with glucose and antimycin A, an inhibitor of respiration. However, the same mutants could grow when antimycin A was added to such mutants after they had been adapted to the utilization of glucose. Double mutants with defects in both genes could not grow at all on glucose as the sole carbon source. Mutants with a single defect in gene PFK1 or PFK2 could form ethanol on a glucose medium. However, in contrast to wild-type cells, there was a lag period of about 2 h before ethanol could be formed after transfer from a medium with only nonfermentable carbon sources to a glucose medium. Wild-type cells under the same conditions started to produce ethanol immediately. Mutants with defects in both PFK genes could not form ethanol at all. Mutants without phosphoglucose isomerase or triosephosphate isomerase did not form ethanol either. Double mutants without phosphofructokinase and phosphoglucose isomerase accumulated large amounts of glucose-6-phosphate on a glucose medium. This suggested that the direct oxidation of glucose-6-phosphate could not provide a bypass around the phosphofructokinase reaction. On the other hand, the triosephosphate isomerase reaction was required for ethanol production. Experiments with uniformly labeled glucose and glucose labeled in positions 3 and 4 were used to determine the contribution of the different carbon atoms of glucose to the fermentative production of CO₂. With only fermentation operating, only carbon atoms 3 and 4 should contribute to CO₂ production. However, wild-type cells produced significant amounts of radioactivity from other carbon atoms and pfk mutants generated CO₂ almost equally well from all six carbon atoms of glucose. This suggested that phosphofructokinase is a dispensable enzyme in yeast glycolysis catalyzing only part of the glycolytic flux.     

Expression of viral early functions in rat 3Y1 cells infected with human papovavirus BK.

A plaque morphology mutant (pm-522) of BK virus (BKV) with a small deletion at map unit 0.72 can readily transform rat 3Y1 cells, but wild-type BKV (wt-501) cannot. We examined the expression of the viral early functions in BKV (wt-501 or pm-522)-infected 3Y1 cells within a 2-week period after infection, before foci of transformed cells became detectable, to know how the difference between the two BKVs occurs. After a high-multiplicity infection, comparable amounts of free viral DNA (forms I and II) were found by Southern blotting analyses to persist in the nuclei of the cells infected with wt and pm BKVs. Whereas the proportion of T antigen-positive cells, as revealed by the indirect immunofluorescence method with complement, remained at a level of 60% in pm BKV infection, the level of T antigen-positive cells in wt BKV infection decreased from the initial 45% to 1% on day 9. The results obtained by the immunoprecipitation analyses of radiolabeled proteins from the infected cells were consistent with the immunofluorescence data. Viral early mRNA was detectable on day 2 and increased on day 9 in pm BKV infection, but in wt BKV infection, the low level of early mRNA detected on day 2 disappeared on day 9. Cell DNA synthesis and cell growth were enhanced more in pm BKV infection than in wt BKV infection. The low level of viral DNA synthesis that occurred in the infected rat cells was more prominent in pm BKV infection than in wt BKV infection. These data indicate that the expression of viral early functions continued much longer in pm BKV-infected rat cells than in wt BKV-infected rat cells, where the expression was probably repressed soon after infection. Continued T antigen production directed by the unintegrated viral genomes appears to be required for efficient transformation of rat cells by BKV.     

Epitopes on foot-and-mouth disease virus outer capsid protein VP1 involved in neutralization and cell attachment.

Foot-and-mouth disease virus structural protein VP1 elicits neutralizing and protective antibody and is probably the viral attachment protein which interacts with cellular receptor sites on cultured cells. To study the relationships between epitopes on the molecule related to neutralization and cell attachment, we tested monoclonal antibodies prepared against type A12 virus, isolated A12 VP1, and a CNBr-generated A12 VP1 fragment for neutralization and effect on viral absorption. The antibodies selected for analysis neutralized viral infectivity with varying efficiencies. One group of antibodies caused a high degree of viral aggregation and inhibited the adsorption of virus to cells by 50 to 70%. A second group of antibodies caused little or no viral aggregation but inhibited the adsorption of virus to cells by 80 to 90%. One antibody, which is specific for the intact virion, caused little viral aggregation and had no effect on the binding of virus to specific cellular receptor sites. Thus, at least three antigenic areas on the surface of foot-and-mouth disease virus which were involved in neutralization were demonstrated. One of the antigenic sites appears to have been responsible for interaction with the cellular receptor sites on the surface of susceptible cells.     

Genetic basis of the neurovirulence of pseudorabies virus.

Lomniczi et al. (J. Virol. 49:970-979, 1984) have shown previously that two attenuated vaccine strains of pseudorabies virus have a similar deletion in the short unique (US) region of the genome. The region which is deleted normally codes for several translationally competent mRNAs. As expected, these mRNAs are not formed in the cells infected with the vaccine strains. The function specified by these mRNAs is thus not necessary for growth in cell culture. Using intracerebral inoculation of 1-day-old chicks as a test system, we have attempted to determine whether a gene within the region that is missing from the attenuated strains specifies functions that are required for the expression of virulence. An analysis of recombinants between the Bartha vaccine strain and a virulent pseudorabies virus strain (having or lacking a thymidine kinase gene [TK+ or TK-]) revealed the following. None of the recombinant plaque isolates that were either TK- or which had a deletion in the US was virulent. Not all recombinant plaque isolates which were both TK+ and had an intact US were virulent. These results indicate that both thymidine kinase activity and an intact US were necessary but not sufficient for the expression of virulence. Marker rescue experiments involving cotransfection of the Bartha strain DNA and a restriction fragment spanning the region of the genome that was missing from the Bartha strain resulted in the isolation of virions to which an intact US had been restored. These virions were not virulent but had an improved ability to replicate in the brains of chicks compared with that of the parental nonrescued Bartha strain. Our results show that genes in the US region, which are missing from the Bartha strain, were necessary for virulence but that this strain was also defective in other genes required for the expression of virulence. Thus, the virulence of pseudorabies virus, as measured by intracerebral inoculation into chicks, appears to be controlled multigenically.     

Nucleotide sequence of v-fps in the PRCII strain of avian sarcoma virus.

PRCII is an avian retrovirus whose oncogene (v-fps) induces fibrosarcomas in birds. The viral gene v-fps arose by transduction of an undetermined portion of a cellular gene known as c-fps. PRCII is weakly oncogenic when compared with Fujinami sarcoma virus, another transforming virus containing v-fps. As a first step in the elucidation of the molecular basis for the decreased virulence of PRCII, we have determined the entire nucleotide sequence of v-fps in the PRCII genome. The v-fps domain in PRCII encodes a polypeptide with a molecular weight of ca. 60,500 fused to a portion of the polyprotein encoded by the viral structural gene gag. The hybrid gag-fps polyprotein of PRCII would have a molecular weight of ca. 98,100, in accord with results of previous studies of the protein encoded by the PRCII genome. The leftward junctions between fps and gag in Fujinami sarcoma virus and PRCII are located at the same position in fps, but at different positions in gag. A sequence of 1,020 nucleotides, bounded by direct repeats of 6 nucleotides, is present in v-fps of Fujinami sarcoma virus but absent from PRCII. Our data should permit further explorations of the relationship between structure and function in the transforming protein encoded by v-fps.     

Decay and synthesis of ribosomal proteins during Dictyostelium discoideum development

Summary Ribosome turnover is a prominent process during cell differentiation in Dictyostelium discoideum. At the end of 24 h of development on filters, the cells contain only 30% of the ribosome content of vegetatively growing cells. We determined the relative rates of synthesis and decay of each of the ribosomal proteins during this period. Approximately 80% of the total vegetative cell ribosomal proteins were degraded during the course of fruiting body construction. Ribosomal RNA and protein degradation apparently occurred coordinately during development. Although all ribosomal proteins decayed during development, some were more stable and a few less stable than the average. In addition, all the ribosomal proteins were synthesized during this period. Most ribosomal proteins were synthesized at the same rate as other cellular proteins, although a number were made at lower or higher rates. It was estimated that about 35% of the ribosomes in developed cells represented those, that were made during cell differentiation. Differential decay and/or synthesis of ribosomal proteins could account for the observed difference in protein content of ribosomes from growing amoebae and late development cells and spores.Paper No. 4 in the series, Studies on Ribosomal Proteins in Dictyostelium discoideum. Paper No. 3 is Ramagopal and Ennis (1982)     

Induction of macrolide-lincosamide-streptogramin B resistance requires ribosomes able to bind inducer

Summary Plasmids were constructed containing the regulatory regions and N-terminal portions of ermC and of ermD, fused in phase with the coding sequence of the Escherichia coli lacZ gene. ermC and ermD are erythromycin (Em) inducible macrolide-lincosamide-streptogramin B resistance elements derived from Staphylococcus aureus and Bacillus licheniformis, respectively. The fusion plasmids were introduced into B. subtilis and used to study ermC and ermD regulation. In both cases, -galactosidase synthesis could be induced by low levels of Em. Induction was prevented by introduction of ole-2, a chromosomal mutation which decreases ribosomal affinity for Em. Induction also did not occur in the presence of intact copies of ermC, suggesting that prior or concomitant methylation of 23S rRNA, a treatment known to decrease ribosomal affinity for Em, was capable of interfering with ermC and ermD induction. These experiments are consistent with the translational attenuation model of ermC regulation, and together with other evidence, suggest that ermD is regulated by a similar mechanism.     

Coexistence of cytoplasmic and nuclear genes for male sterility in Petunia

Summary Cytoplasmic male sterility (cms) and nuclear male sterility (nms) in Petunia were described respectively as possible autonomous and integrated states of the same genetic element by Frankel (1971). In the present study we describe genetic analysis of the interaction between the cms, the nuclear gene for male sterility (e) and the fertility restorer allele (Rf). The main findings in this study are: (1) The nuclear sterility allele can coexist in one or two dosages with the cytoplasmic male sterility elements (ste) in somatic cells or female gametes; (2) the presence of the fertility restorer allele Rf is not required for the coexistence of ste and e and (3) Rf does not interact epistatically with e, e.g., the expression of e is independent of Rf—the genotypes (S) RfRfee and (S) Rfrfee are male sterile.Contribution from the Agricultural Research Organization. The Volcani Center, Bet Dagan, Israel. 1983 series No. 846 E     

Overlapping of the coding regions for alpha and gamma components of penicillin-binding protein 1 b in Escherichia coli

Summary The mode of biosynthesis of penicillin-binding protein(PBP)-1 b in Escherichia coli was investigated by use of the plasmid carrying the ponB(PBP-1 b) gene region. Analyses of the products synthesized in minicells and in vitro showed that PBP-1 b was synthesized as two molecular species corresponding to the and components of PBP-1 b. The coding regions for the and components were located within the ca. 3.7 kb MluI-HincII fragment and transcribed in the direction from the HincII to the MluI site. The capacity for producing the component was abolished by a deletion extending to the MluI site ca. 0.7 kb inward from the HincII end of the ca. 3.7 kb fragment; the remaining 3.0 kb region with the MluI site at both ends directed the production of the component alone. The production of the component was enough to correct all the known defects caused by a ponB mutation. In addition to these results, the analyses for cross-reacting materials produced in correspondence to the various deletions indicated that the coding regions for the and components overlapped and that the N-terminal portion was responsible for the difference between the two components. The distal region about 0.7 kb long inward from the MluI end of the MluI-HincII fragment was dispensable for producing the functional PBP-1 b, although the PBP-1 b produced was curtailed. By a larger distal deletion reaching almost to the middle of the MluI-HincII fragment, the polypeptide produced for PBP-1 b lost the ability to bind penicillin and still retained a low but significant activity for glycan synthesis. We suggest, therefore, that the polypeptide portion required for transglycosylase activity resides on the N-terminal half of PBP-1 b, followed by the middle portion necessary for penicillin-binding and the C-terminal part dispensable for the function of PBP-1 b.     

Evolutionary relationship of the Bacillus licheniformis macrolide-lincosamide-streptogramin B resistance elements

Summary Naturally occurring erythromycin (Em) resistance was found in 11 of the 18 Bacillus licheniformis isolates tested but was absent from a wide variety of other Bacillus strains. The Em resistance elements confer inducible macrolide-lincosamide-streptogramin B (MLS) resistance and are related to ermD an MLS resistance element previously cloned from the chromosome of B. licheniformis 749. The MLS sensitive B. licheniformis strains and the other sensitive Bacillus strains tested, lack sequences with detectable homology to ermD. The sensitive B. licheniformis strains do exhibit homology to sequences which flank ermD in B. licheniformis 749. The relative sizes of the homologous DNA fragments suggest that the sensitive strains are lacking a 3.6 kb segment which contains ermD. It is shown that ermD is homologous to chromosomal DNA from Streptomyces erythreus ATCC 11635, an Em producing organism. These observations suggest to us that MLS resistance may have arisen in the Streptomyces and spread to B. licheniformis another gram positive bacterium found in soil. It is further proposed that ermD is or was located on a transposon-like element and has spread and evolved further to yeild a variety of related Staphylococcal and Streptococcal MLS determinants.