Snacking now or later? Individual differences in following intentions or habits explained by time perspective.

Even when individuals are aware of long-term health effects of their diet, and form healthy intentions, they often engage in relatively unhealthy snacking habits. Some individuals fall back on unhealthy habits more easily than others. We aim to explore whether time perspective can explain why some individuals are more prone to rely on habits and others on intentions. Study 1 (N = 1503) provides a first exploration of the role of time perspective by exploring individual differences in perception of long-term and short-term consequences. In accordance with our hypotheses, Study 1 shows that habits are associated with short-term consequences and intentions with long-term consequences. Study 2 (N = 1497) shows that the effects of habits on snacking behaviour are strengthened by a present time perspective, whereas the effects of intentions on snacking behaviour are strengthened by a future time perspective. These findings imply that there is a fundamental difference in the guiding function of intentions and habits which might explain individual differences in following intentions versus habits. Individuals with a long-term perspective are more inclined to follow intentions and individuals with a short-term perspective are more inclined to follow habits.

Identification of cis-acting elements involved in 3'-end formation of Saccharomyces cerevisiae 18S rRNA.

In yeast, the 3' end of mature 18S rRNA is generated by endonucleolytic cleavage of the 20S precursor at site D. Available data indicate that the major cis-acting elements required for this processing step are located in relatively close proximity to the cleavage site. To identify these elements, we have studied the effect of mutations in the mature 18S and ITS1 sequences neighboring site D on pre-rRNA processing in vivo. Using clustered point mutations, we found that alterations in the sequence spanning site D from position -5 in 18S rRNA to +6 in ITS1 reduced the efficiency of processing at this site to different extents as demonstrated by the lower level of the mature 18S rRNA and the increase in 20S pre-rRNA in cells expressing only mutant rDNA units. More detailed analysis revealed an important role for the residue located 2 nt upstream from site D (position -2), whereas sequence changes at position -1, +1, and +2 relative to site D had no effect. The data further demonstrate that the proposed base pairing between the 3' end of 18S rRNA and the 5' end of ITS1 is not important for efficient and accurate processing at site D, nor for the formation of functional 40S ribosomal subunits. These results were confirmed by analyzing the accumulation of the D-A2 fragment derived from the mutant 20S pre-rRNA in cells that lack the Xrn1p exonuclease responsible for its degradation. The latter results also showed that the accuracy of cleavage was affected by altering the spacer sequence directly downstream of site D but not by mutations in the 18S rRNA sequence preceding this site.

All three functional domains of the large ribosomal subunit protein L25 are required for both early and late pre-rRNA processing steps in Saccharomyces cerevisiae.

Mutational analysis has shown that the integrity of the region in domain III of 25S rRNA that is involved in binding of ribosomal protein L25 is essential for the production of mature 25S rRNA in the yeast Saccharomyces cerevisiae. However, even structural alterations that do not noticeably affect recognition by L25, as measured by an in vitro assay, strongly reduced 25S rRNA formation by inhibiting the removal of ITS2 from the 27S(B) precursor. In order to analyze the role of L25 in yeast pre-rRNA processing further we studied the effect of genetic depletion of the protein or mutation of each of its three previously identified functional domains, involved in nuclear import (N-terminal), RNA binding (central) and 60S subunit assembly (C-terminal), respectively. Depletion of L25 or mutating its (pre-)rRNA-binding domain blocked conversion of the 27S(B) precursor to 5.8S/25S rRNA, confirming that assembly of L25 is essential for ITS2 processing. However, mutations in either the N- or the C-terminal domain of L25, which only marginally affect its ability to bind to (pre-)rRNA, also resulted in defective ITS2 processing. Furthermore, in all cases there was a notable reduction in the efficiency of processing at the early cleavage sites A0, A1 and A2. We conclude that the assembly of L25 is necessary but not sufficient for removal of ITS2, as well as for fully efficient cleavage at the early sites. Additional elements located in the N- as well as C-terminal domains of L25 are required for both aspects of pre-rRNA processing.

Nuclear and nucleolar localization of Saccharomyces cerevisiae ribosomal proteins S22 and S25.

Nuclear import usually relies on the presence of nuclear localization sequences (NLSs). NLSs are recognized by NLS receptors (importins), which target their substrates to the nuclear pore. We identified the NLSs of the yeast ribosomal proteins S22 and S25 and studied the former by mutational analysis. Furthermore, in S25 the nucleolar targeting information was found to overlap with its NLS. Comparison with previously published data on yeast ribosomal protein NLSs and computer analysis indicates the existence of a novel type of ribosomal protein-specific NLS that differs from the classical Chelsky and bipartite NLSs. The existence of such a ribosomal protein-specific NLS is in accordance with the recent identification of ribosomal protein-specific importins.

Mutational analysis of the C-terminal region of Saccharomyces cerevisiae ribosomal protein L25 in vitro and in vivo demonstrates the presence of two distinct functional elements.

A previous analysis of yeast ribosomal protein L25 implicated an evolutionarily conserved motif of seven amino acids near the C terminus (positions 120 to 126) in specific binding of the protein to domain III of 26 S rRNA. We analyzed the effect of various point mutations in this amino acid sequence on the capacity of the protein to interact in vitro with its binding site on the rRNA. Most of the mutations tested, including some conservative replacements, strongly reduced or abolished rRNA binding, further supporting a pivotal role for the motif in the specific interaction between L25 and 26 S rRNA. We have also determined the ability of the various mutant L25 species to complement in vivo for the absence of wild-type protein in cells that conditionally express the chromosomal L25 gene. Surprisingly, up to a fivefold reduction in the in vitro binding capacity of L25 is tolerated without affecting the ability of the mutant protein to support (virtually) wild-type rates of 60 S subunit formation and cell growth. Mutations that completely abolish recognition of 26 S rRNA, however, block the formation of 60 S particles, demonstrating that binding of L25 to this rRNA is an essential step in the assembly of the large ribosomal subunit. Using the same combination of approaches we identified an element, located between positions 133 and 139, that is indispensable for the ability of L25 to support a normal rate of 60 S subunit formation, but plays a relatively minor role in determining the rRNA-binding capacity of the protein. In particular, the presence of a hydrophobic amino acid at position 135 was found to be highly important. These results indicate that the element in question is crucial for a step in the assembly of the 60 S subunit subsequent to association of L25 with 26 S rRNA.

Characterization of the Saccharomyces cerevisiae nuclear gene CYB3 encoding a cytochrome b polypeptide of respiratory complex II.

Computer-assisted structural analysis of the predicted product of the previously described open reading frame (ORF) YKL4 located on the left arm of chromosome XI of Saccharomyces cerevisiae revealed a high degree of similarity (> 50%) to bovine cytochrome b560, the sdhC polypeptide of the Escherichia coli succinate dehydrogenase (SDH) complex and the protein specified by ORF137 located on the chloroplast DNA of Marchantia polymorpha. Disruption of the yeast gene severely impaired mitochondrial function, while Northern analysis showed it to be subject to catabolite repression. Deletion analysis of the CYB3 promoter identified a single HAP2/3/4-binding element that is necessary and sufficient for carbon source-dependent transcriptional regulation. These experiments also suggested the presence of additional, as yet unidentified, transcriptional control elements, both negative and positive. Taken together, these data lead us to conclude that the CYB3 gene encodes the yeast homolog of the bovine cytochrome b560 component of complex II of the mitochondrial electron transport chain.

The phylogenetically conserved doublet tertiary interaction in domain III of the large subunit rRNA is crucial for ribosomal protein binding.

Previous phylogenetic analysis of rRNA sequences for covariant base changes has identified approximately 20 potential tertiary interactions. One of these is present in domain III of the large subunit rRNA and consists of two adjacent Watson-Crick base pairs that, in Saccharomyces cerevisiae 26S rRNA, connect positions 1523 and 1524 to positions 1611 and 1612. This interaction would strongly affect the structure of an evolutionarily highly conserved region that acts as the binding site for the early-assembling ribosomal proteins L25 and EL23 of S. cerevisiae and Escherichia coli, respectively. To assess the functional importance of this tertiary interaction, we determined the ability of synthetically prepared S. cerevisiae ribosomal protein L25 to associate in vitro with synthetic 26S rRNA fragments containing sequence variations at positions 1523 and 1524 and/or positions 1611 and 1612. Mutations that prevent the formation of both base pairs abolished L25 binding completely, whereas the introduction of compensatory mutations fully restored protein binding. Disruption of only the U1524.A1611 pair reduced L25 binding to approximately 30% of the value shown by the wild-type 26S rRNA fragment, whereas disruption of the G1523.C1612 base pair resulted in almost complete loss of protein binding. These results strongly support the existence and functional importance of the proposed doublet tertiary interaction in domain III of the large subunit rRNA.

Molecular cloning and physical analysis of an 8.2 kb segment of chromosome XI of Saccharomyces cerevisiae reveals five tightly linked genes.

The nucleotide sequence of 6472 base pairs of an 8.2 kb segment of Saccharomyces cerevisiae chromosome XI has been determined. The sequence contains a cluster of four long open reading frames (ORF) designated YKL2, YKL3, YKL4 and TGL1 in the same orientation, flanked at the 5'-end by a divergent incomplete ORF (YKL1). Transcription and Southern analysis of the four complete ORFs showed that all are expressed and are present in single copy on the haploid genome. The average codon adaptation index of the coding regions is approximately 0.2, suggesting that these genes are lowly expressed. The upstream regions of all four genes as well as the YKL1 ORF contain putative promoter elements previously found to be characteristic of nuclear genes encoding mitochondrial proteins. Significant sequence similarities were found between the YKL3 protein and Escherichia coli ribosomal protein S2 as well as between the TGL1 protein and triglyceride lipases from rat salivary gland and human gastric tissue. The 3'-end of the 6472 bp nucleotide sequence overlaps with the upstream region of the previously identified CTK1 gene, encoding the largest subunit of CTD kinase (Lee, J.M. and Greenleaf, A.L., 1991, Gene Expression 2, 149-167), thereby increasing the number of genes on the 8.2 kb fragment to at least five. The transcripts of these genes represent approximately 83% of the DNA fragment, making it one of the most highly transcribed regions of the yeast chromosome analysed to date.

Identification and functional analysis of the nuclear localization signals of ribosomal protein L25 from Saccharomyces cerevisiae.

The regions of the large subunit ribosomal protein L25 from Saccharomyces cerevisiae responsible for nuclear localization of the protein were identified by constructing fusion genes encoding various segments of L25 linked to the amino terminus of beta-galactosidase. Indirect immunofluorescence of yeast cells expressing the fusions demonstrated that amino acid residues 1 to 17 as well as 18 to 41 of L25 promote import of the reporter protein into the nucleus. Both nuclear localization signal (NLS) sequences appear to consist of two distinct functional parts: one showed relatively weak nuclear targeting activity, whereas the other considerably enhances this activity but does not promote nuclear import by itself. Microinjection of in vitro prepared intact and N-terminally truncated L25 into Xenopus laevis oocytes demonstrated that the region containing the two NLS sequences is indeed required for efficient nuclear localization of the ribosomal protein. This conclusion was confirmed by complementation experiments using a yeast strain that conditionally expresses wild-type L25. The latter experiments also indicated that amino acid residues 1 to 41 of L25 are required for full functional activity of yeast 60 S ribosomal subunits. Yeast cells expressing forms of L25 that lack this region are viable, but show impaired growth and a highly abnormal cell morphology.

rRNA binding domain of yeast ribosomal protein L25. Identification of its borders and a key leucine residue.

We have delineated the region of yeast ribosomal protein L25 responsible for its specific binding to 26 S rRNA by a novel approach using in vitro synthesized, [35S]methionine-labeled fragments as well as point mutants of the L25 protein. The rRNA binding capacity of these mutant polypeptides was tested by incubation with an in vitro transcribed, biotinylated fragment of yeast 26 S rRNA that contains the complete L25 binding site. Protein-rRNA interaction was assayed by binding of the rRNA-r-protein complex to streptavidin-agarose followed either by analysis of the bound polypeptide by SDS/polyacrylamide gel electrophoresis or by precipitation with trichloroacetic acid. Our results show that the structural elements necessary and sufficient for specific interaction of L25 with 26 S rRNA are contained in the region bordered by amino acids 62 and 126. The remaining parts of the protein, in particular the C-terminal 16 residues, while not essential for binding, do enhance its affinity for 26 S rRNA. To test whether, as suggested by the results of the deletion experiments, the evolutionarily conserved sequence motif K120KAYVRL126 is involved in rRNA binding, we replaced the leucine residue at position 126 by either isoleucine or lysine. The first substitution did not affect binding. The second, however, completely abolished the specific rRNA binding capacity of the protein. Thus, Leu126, and possibly the whole conserved sequence motif, plays a key role in binding of L25 to 26 S rRNA.

In vivo and in vitro analysis of structure-function relationships in ribosomal protein L25 from Saccharomyces cerevisiae.

We have developed a combination of in vivo and in vitro methods which allows us to determine the effect of practically every structural change, deletions as well as point mutations, on various biological functions of a ribosomal protein (r-protein). We have used this approach to delineate the functional domains of r-protein L25 from Saccharomyces cerevisiae. By analysis of the intracellular distribution of fusion proteins carrying various portions of L25 linked to Escherichia coli beta-galactosidase we traced the nuclear localization signal(s) of L25 to the region encompassing the N-terminal 61 amino acids of the protein. On the other hand, using in vitro prepared fragments of L25 we located the domain responsible for its specific binding to 26S rRNA to the region between amino acids 61 and 135. In order to be able to analyze the effect of mutations in L25 on ribosome biogenesis and function in vivo we constructed a mutant yeast strain in which the chromosomal L25 gene is placed under control of the inducible yeast GAL promoter. Since this strain is unable to grow on glucose as a carbon source the L25 gene must be essential for cell viability. Growth on glucose can be restored by introduction of a wild-type L25 gene on a plasmid, demonstrating that under these conditions the cells are dependent upon an extrachromosomally supplied copy of the gene.

Part of respiratory nitrate reductase of Klebsiella aerogenes is intimately associated with the peptidoglycan.

Lysozyme digestion and sonication of sodium dodecyl sulfate (SDS)-purified Klebsiella aerogenes murein sacculi resulted in the quantitative release of both subunits of nitrate reductase, as well as a number of other cytoplasmic membrane polypeptides (5.2%, by weight, of the total membrane proteins). Similar results were obtained after lysozyme digestion of SDS-prepared peptidoglycan fragments, which excluded the phenomenon of simple trapping of the polypeptides by the surrounding peptidoglycan matrix. About 28% of membrane-bound nitrate reductase appears to be tightly associated with the peptidoglycan. Additional evidence for this association was demonstrated by positive immunogold labeling of SDS-murein sacculi and thin sections of plasmolyzed bacteria. Qualitative amino acid analysis of trypsin-treated sacculi, a tryptic product of holo-nitrate reductase, and amino- and carboxypeptidase digests of both nitrate reductase subunits indicated the possible existence of a terminal anchoring peptide containing the following amino acids: (Gly)n, Trp, Ser, Pro, Ile, Leu, Phe, Cys, Tyr, Asp, and Lys.

Detoxification of mercury, cadmium, and lead in Klebsiella aerogenes NCTC 418 growing in continuous culture.

Klebsiella aerogenes NCTC 418 growing in the presence of cadmium under glucose-, sulfate-, or phosphate-limited conditions in continuous culture exhibited sulfide formation and Pi accumulation as the only demonstrable detoxification mechanisms. In the presence of mercury under similar conditions only HgS formation could be confirmed, by an increased sensitivity to mercury under sulfate-limited conditions, among others. The fact that the cells were most sensitive to cadmium under conditions of phosphate limitation and most sensitive to mercury under conditions of sulfate limitation led to the hypothesis that these inorganic detoxification mechanisms generally depended on a kind of "facilitated precipitation". The process was coined thus because heavy metals were probably accumulated and precipitated near the cell perimeter due to the relatively high local concentrations of sulfide and phosphate there. Depending on the growth-limiting nutrient, mercury proved to be 25-fold (phosphate limitation), 75-fold (glycerol limitation), or 150-fold (sulfate limitation) more toxic than cadmium to this organism. In the presence of lead, PbS formation was suggested. Since no other detoxification mechanisms were detected, for example, rendering heavy metal ions innocuous as metallo-organic compounds, it was concluded that formation of heavy metal precipitates is crucially important to this organism. In addition, it was observed that several components of a defined mineral medium were able to reduce mercuric ions to elemental mercury. This abiotic mercury volatilization was studied in detail, and its general and environmental implications are discussed.

Inorganic phosphate accumulation and cadmium detoxification in Klebsiella aerogenes NCTC 418 growing in continuous culture.

Klebsiella aerogenes NCTC 418, growing in the presence of cadmium under glucose-, sulfate-, or phosphate-limited conditions in continuous culture, exhibits two different cadmium detoxifying mechanisms. In addition to sulfide formation, increased accumulation of Pi is demonstrated as a novel mechanism. Intracellular cadmium is always quantitatively counterbalanced by a concerted increase in both inorganic sulfide and Pi contents of the cells. This led to the conclusion that production of sulfide and accumulation of Pi are detoxification mechanisms present in K. aerogenes but that their relative importance is crucially dependent on the strain and the growth conditions employed.

Mass spectrometric analysis of fluorescent products originating from the molybdenum cofactor.

Mass spectra of 4 fluorescent HPLC fractions originating from the molybdenum cofactor in xanthine oxidase extracts have been obtained with the method of field desorption (FD). The most polar fraction contains compounds which show peaks in the M/Z = 110-230 and M/Z = 580-750 range. Two other fractions exhibit in the FD spectra peaks at M/Z = 1,113 and M/Z = 886, respectively. Both corresponding compounds contain at most 24 C atoms and lack S, Mo, Cl and Br, as judged from the isotopic pattern. The most apolar fluorescent compound, which could be isolated only from xanthine oxidase extracts prepared in the absence of phosphate, has been identified as a species with a molecular weight around 482.

Molybdenum cofactor from the cytoplasmic membrane of Proteus mirabilis.

Molybdenum cofactor was extracted from membranes of Proteus mirabilis by three methods: acidification, heat treatment and heat treatment in the presence of sodium-dodecylsulphate (SDS). Extracts prepared by the latter method contained the highest concentration of molybdenum cofactor. In these extracts molybdenum cofactor was present in a low molecular weight form. It could not penetrate an YM-2 membrane during ultrafiltration suggesting a molecular weight above 1000. During aerobic incubation of cofactor extracts from membranes at least four fluorescent species were formed as observed in a reversed-phase high performance liquid chromatography (HPLC) system. The species in the first peak was inhomogeneous while the species in the others seem to be homogeneous. In water, all fluorescent products had an excitation maximum at 380 nm and an emission maximum at 455 nm. Their absorption spectra showed maxima at around 270 nm and 400 nm. Fluorescent compounds present in the first peak could penetrate an YM-2 membrane during ultrafiltration, whereas the compounds in the other peaks hardly did. Using xanthine oxidase from milk as source of molybdenum cofactor apparently identical cofactor species were found. Cytoplasmic nor membrane extracts of the chlorate resistant mutant chl S 556 of P. mirabilis could complement nitrate reductase of Neurospora crassa nit-1 in the presence of 20 mM molybdate. However, fluorescent species with identical properties as found for the wild-type were formed during aerobic incubation of extracts from membranes of this mutant.

Adaptation to Cadmium by Klebsiella aerogenes Growing in Continuous Culture Proceeds Mainly via Formation of Cadmium Sulfide.

The adaptation of Klebsiella aerogenes to high levels of cadmium was studied in continuous culture under conditions of glucose limitation. When up to 6 x 10 M cadmium was added to a culture in steady state, growth ceased instantaneously but resumed within 5 h (dilution rate, 0.1 h). When again in steady state, these adapted cells exhibited a far greater tolerance to cadmium than did unadapted cells (not previously exposed to cadmium) when tested on solid media containing different concentrations of cadmium. This relative insensitivity of adapted cells to cadmium was subsequently lost in continuous culture within 5 days after omitting cadmium from the influent medium. Thus, the phenomenon was an inducible physiological process. Adapted cells contained substantial amounts of cadmium (up to 2.4% of the bacterial dry weight). The cadmium content of the cells was dependent on growth conditions and was found to be proportional to the inorganic sulfide content of the cells in all cases. This suggested that formation of CdS is probably the most important mechanism of detoxification in this organism. The presence of large numbers of electron-dense granules on the cell surface (absent in cultures without added cadmium) provided additional support for this conclusion.

Immunoferrin labeling of respiratory nitrate reductase in membrane vesicles of Bacillus licheniformis and Klebsiella aerogenes.

The indirect immunoferritin labeling method was used to localize the membrane-bound respiratory nitrate reductase in membrane vesicles and protoplasts or sphereplasts of Bacillus licheniformis and Klebsiella aerogenes, respectively. For a comparison of the labeling of the various vesicle preparations, which differed not only in size but also in the percentage of inside-out orientation, a quantification of the results was needed to circumvent the problem of non-specifically bound ferritin. From the results of sidedness of the nitrate reductase in the cytoplasmic membrane of the above-mentioned bacteria was determined as being cytoplasmic in B. licheniformis and as transmembranous in K. aerogenes.

Respiratory nitrate reductase: its localization in the cytoplasmic membrane of Klebsiella aerogenes and Bacillus licheniformis.

The sidedness of the respiratory nitrate reductase in the cytoplasmic membrane of Bacillus licheniformis and Klebsiella aerogenes was studied by indirect immunofluorescence and by lactoperoxidase-catalyzed iodination. It was shown that the two subunits (Mr 150000 and 57000, respectively) of nitrate reductase of B. licheniformis are localized on the cytoplasmic side of the membrane, whereas the K. aerogenes enzyme is a transmembrane protein. The different localization of nitrate reductase in the membranes of these organisms may be related to their different rôle in oxidative phosphorylation.