Degradation and replenishment of the labile protein fraction in non-growing cells of the asporogenic mutant ofBacillus megaterium

Kinetics of degradation of labelled proteins was followed in two asporogenic mutants ofBacillus megaterium during incubation in a sporulation medium. Both the mutant producing exocellular protease (KM 1prn ⁺) and the mutant not producing the enzyme (KM 12prn) were found to contain a labile protein fraction, whose proportion decreases with prolonged time of labelling and whose half-life is about 1 h. Most proteins were relatively stable and were degraded at a rate of 1 %/h and 2 %/h in strains KM 1 and KM 12, respectively (half life 70–80 h and 35–40 h in strains KM 1 and KM 12, respectively). The intracellular proteolytic activity of the KM 12 mutant remains practically the same during incubation in the sporulation medium or slowly increases. The labile protein fraction practically disappears from the cells after a 3.5-h incubation. When such a culture is then subjected to a shift-up and transferred again to the sporulation medium, the rate of protein turnover temporarily increases. The temporary increase of the turnover rate is caused by a partial replenishment of the labile protein fraction rather than by an accelerated degradation of the relatively stable fraction. The intracellular proteolytic activity does not increase under these conditions. The wild sporogenic strain ofB. megaterium also contains the labile protein fraction. Its half protein life is 1 h or less. However, the second protein fraction is degraded much more rapidly than in the asporogenic mutants and its half life is 6–7 h.     

Effects of Mutational Loss of Specific Intracellular Proteases on the Sporulation of Bacillus subtilis

Two protease-deficient mutants of Bacillus subtilis 168 (Trp(-)) were isolated and compared with the parental strain with respect to production of intracellular proteases and sporulation. A mutant lacking the metal-requiring "neutral" protease intracellularly sporulated as well as the parental strain. A second mutant, deficient in an as yet uncharacterized intracellular protease, failed to sporulate normally. It is proposed that this new protease is also involved in intracellular protein turnover.     

Construction and properties of an intracellular serine protease mutant of Bacillus subtilis.

An intracellular serine protease (ISP-1) mutant of Bacillus subtilis was created by introducing a frameshift into the coding region of the cloned gene. Intracellular protease activity in the mutant was very low, yet sporulation in both nutrient broth and minimal medium was normal. The rate of bulk protein turnover in the mutant was slightly slower than that in the wild-type strain. These results suggest that the gene for ISP-1 is not essential and that ISP-1 is not the major enzyme involved in protein turnover during sporulation.     

Protease and peptidase activities in growing and sporulating cells and dormant spores of Bacillus megaterium.

Peptidase and protease activities on many different substrates have been determined in several stages of growth of Bacillus megaterium. Extracts of log-phase cells, sporulating cells, and dormant spores of B. megaterium each hydrolyzed 16 different di- and tripeptides. The specific peptidase activity was highest in dormant spores, and the activity in sporulating cells and log-phase cells was about 1.2-fold and 2- to 3-fold lower, respectively. This peptidase acticity was wholly intracellular since extracellular peptidase activity was not detected throughout growth and sporulation. In contrast, intracellular protease activity on a variety of common protein substrates was highest in sporulating cells, and much extracellular activity was also present at this time. The specific activity of intracellular protease in sporulating cells was about 50- and 30-fold higher than that in log-phase cells and dormant spores, respectively. However, the two unique dormant spores proteins known to be the major species degraded during spore germination were degraded most rapidly by extracts of dormant spores, and slightly slower by extracts from log-phase or sporulating cells. The specific activities for degradation of peptides and proteins are compared to values for intracellular protein turnover during various stages of growth.     

Turnover of mitochondrial steroidogenic acute regulatory (StAR) protein by Lon protease: the unexpected effect of proteasome inhibitors

Steroidogenic acute regulatory protein (StAR) is a vital mitochondrial protein promoting transfer of cholesterol into steroid making mitochondria in specialized cells of the adrenal cortex and gonads. Our previous work has demonstrated that StAR is rapidly degraded upon import into the mitochondrial matrix. To identify the protease(s) responsible for this rapid turnover, murine StAR was expressed in wild-type Escherichia coli or in mutant strains lacking one of the four ATP-dependent proteolytic systems, three of which are conserved in mammalian mitochondria-ClpP, FtsH, and Lon. StAR was rapidly degraded in wild-type bacteria and stabilized only in lon (-)mutants; in such cells, StAR turnover was fully restored upon coexpression of human mitochondrial Lon. In mammalian cells, the rate of StAR turnover was proportional to the cell content of Lon protease after expression of a Lon-targeted small interfering RNA, or overexpression of the protein. In vitro assays using purified proteins showed that Lon-mediated degradation of StAR was ATP-dependent and blocked by the proteasome inhibitors MG132 (IC(50) = 20 microm) and clasto-lactacystin beta-lactone (cLbetaL, IC(50) = 3 microm); by contrast, epoxomicin, representing a different class of proteasome inhibitors, had no effect. Such inhibition is consistent with results in cultured rat ovarian granulosa cells demonstrating that degradation of StAR in the mitochondrial matrix is blocked by MG132 and cLbetaL but not by epoxomicin. Both inhibitors also blocked Lon-mediated cleavage of the model substrate fluorescein isothiocyanate-casein. Taken together, our former studies and the present results suggest that Lon is the primary ATP-dependent protease responsible for StAR turnover in mitochondria of steroidogenic cells.     

Protein synthesis and breakdown in the mother-cell and forespore compartments during spore morphogenesis in Bacillus megaterium

Recently developed techniques for isolating forespores from bacilli at all stages of spore morphogenesis have been exploited to investigate the contribution of each of the two compartments of the sporulating cell to the overall pattern of protein synthesis and degradation during sporulation in Bacillus megaterium. These studies have shown: (1) that protein synthesis continues in both compartments throughout spore morphogenesis; (2) that the degradation of proteins made at all times during vegetative growth and sporulation is confined to the mother-cell compartment; (3) that proteins synthesized in the mother-cell compartment during sporulation are subsequently degraded more rapidly than proteins synthesized during vegetative growth. This rate of degradation increases the later the proteins are synthesized in the sporulation sequence. Mature spores were disrupted, and the percentage of the total protein in soluble and particulate fractions was determined. Pulse-labelling experiments were performed to investigate the extent to which the proteins of these two fractions are newly synthesized during sporulation. These data were used to calculate the extent of capture of vegetative cell protein at the time of formation of the forespore septum. The value obtained is consistent with evidence from electron micrographs and supports a model for the origin of spore protein in which there is no protein turnover in the developing forespore.     

Conditional Mutants of Meiosis in Yeast

Three temperature-sensitive mutants, spo1-1, spo2-1, and spo3-1, were characterized with respect to their behavior in sporulation medium at a restrictive temperature. The time of expression of the functions defective in the mutants was determined by temperature-shift experiments during the sporulation process. In addition, each mutant was examined for the following: (i) its ability to undergo the nuclear divisions of meiosis; (ii) deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein synthesis; (iii) protein turnover; and (iv) colony-forming ability after exposure to sporulation medium. Mutant spo1-1 is defective in a function which confers a temperature-sensitive period which extends over 32% of the sporulation cycle. The temperature-sensitive period of mutant spo2-1 occupies 34% of the cycle, whereas the temperature-sensitive period of mutant spo3-1 extends over 2% of the sporulation cycle. Cytological evidence indicates that all three mutants initiate but do not complete the meiotic nuclear divisions. The DNA content of sporulation cultures of mutants spo1-1 and spo3-1 did not increase to the wild-type level; DNA synthesis in spo2-1 was normal. All three strains exhibit a loss of colony-forming ability during incubation in sporulation medium at the restrictive temperature. RNA and protein synthesis and protein turnover occur in the mutants.     

The Fission Yeast Synaptobrevin Ortholog Syb1 Plays an Important Role in Forespore Membrane Formation and Spore Maturation

Synaptobrevin, also called vesicle-associated membrane protein (VAMP), is a component of the plasma membrane N-methylmaleimide-sensitive factor attachment protein receptor (SNARE) complex, which plays a key role in intracellular membrane fusion. Previous studies have revealed that, similar to synaptobrevin in other organisms, the fission yeast synaptobrevin ortholog Syb1 associates with post-Golgi secretory vesicles and is essential for cytokinesis and cell elongation. Here, we report that Syb1 has a role in sporulation. After nitrogen starvation, green fluorescent protein (GFP)-Syb1 is found in intracellular dots. As meiosis proceeds, GFP-Syb1 accumulates around the nucleus and then localizes at the forespore membrane (FSM). We isolated a syb-S1 mutant, which exhibits a defect in sporulation. In syb1-S1 mutants, the FSM begins to form but fails to develop a normal morphology. Electron microscopy shows that an abnormal spore wall is often formed in syb1-S1 mutant spores. Although most syb1-S1 mutant spores are germinated, they are less tolerant to ethanol than wild-type spores. The syb1-S1 allele carries a missense mutation, resulting in replacement of a conserved cysteine residue adjacent to the transmembrane domain, which reduces the stability and abundance of the Syb1 protein. Taken together, these results indicate that Syb1 plays an important role in both FSM assembly and spore wall formation.     

Expression and degradation of the cystic fibrosis transmembrane conductance regulator in Saccharomyces cerevisiae

Many cystic fibrosis disease-associated mutations cause a defect in the biosynthetic processing and trafficking of the cystic fibrosis transmembrane conductance regulator (CFTR) protein. Yeast mutants, defective at various steps of the secretory pathway, have been used to dissect the mechanisms of biosynthetic processing and intracellular transport of several proteins. To exploit these yeast mutants, we have employed an expression system in which the CFTR gene is driven by the promoter of a structurally related yeast ABC protein, Pdr5p. Pulse-chase experiments revealed a turnover rate similar to that of nascent CFTR in mammalian cells. Immunofluorescence microscopy showed that most CFTR colocalized with the endoplasmic reticulum (ER) marker protein Kar2p and not with a vacuolar marker. Degradation was not influenced by the vacuolar protease mutants Pep4p and Prb1p but was sensitive to the proteasome inhibitor lactacystin beta-lactone. Blocking ER-to-Golgi transit with the sec18-1 mutant had little influence on turnover indicating that it occurred primarily in the ER compartment. Degradation was slowed in cells deficient in the ER degradation protein Der3p as well as the ubiquitin-conjugating enzymes Ubc6p and Ubc7p. Finally a mutation (sec61-2) in the translocon protein Sec61p that prevents retrotranslocation across the ER membrane also blocked degradation. These results indicate that whereas approximately 75% of nascent wild-type CFTR is degraded at the ER of mammalian cells virtually all of the protein meets this fate on heterologous expression in Saccharomyces cerevisiae.     

The A-factor-binding protein of Streptomyces griseus negatively controls streptomycin production and sporulation.

A-factor, 2-(6'-methylheptanoyl)-3R-hydroxymethyl-4-butanolide, is an autoregulator essential for streptomycin production and sporulation in Streptomyces griseus. S. griseus 2247 that requires no A-factor for streptomycin production or sporulation was found to have a defect in the A-factor-binding protein. This observation implied that the A-factor-binding protein in the absence of A-factor repressed the expression of both phenotypes in the wild-type strain. Screening among mutagenized S. griseus colonies for strains producing streptomycin and sporulating in the absence of A-factor yielded three mutants that were also deficient in the A-factor-binding protein. Reversal of the defect in the A-factor-binding protein of these mutants led to the simultaneous loss of streptomycin production and sporulation. These data suggested that the A-factor-binding protein played a role in repressing both streptomycin production and sporulation and that the binding of A-factor to the protein released its repression. Mutants deficient in the A-factor-binding protein began to produce streptomycin and sporulate at an earlier stage of growth than did the wild-type strain. These mutants produced approximately 10 times more streptomycin than did the parental strain. These findings are consistent with the idea that the intracellular concentration of A-factor determines the timing of derepression of the gene(s) whose expression is repressed by the A-factor-binding protein.     

Biochemical and physiological properties of an extracellular protease produced by Bacillus megaterium

A protease, excreted by a sporogeneous strain of B. megaterium, growing exponentially in a minimum glucose ammonium medium, was isolated. It is a neutral endopeptidase, stabilized by Ca⁺⁺, inhibited by o-phenanthroline, but not by di-isopropylfluorophosphate. The specificity, studied on insulin B-chain, glucagon, cytochrome c, and dipeptides substrates, indicated the need for a dipeptide backbone with both substituted amino and carboxyl groups. A requirement was observed for a nonpolar lateral chain in the amino acid whose amino group was involved in the peptide bond (Leu, Phe, Ala, He, Val). Rates of hydrolysis varied also with the amino acid whose carboxyl group was involved (e.g., His > Ser > Ala > Gly). In complex medium, supplemented with Yeast Extract, the biosynthesis of the protease was repressed during growth, but the same enzyme was excreted during sporulation. The repression was apparently of the same nature as that controlling sporulation during and after growth (e.g., repression by a mixture of amino acids or high concentration of glucose). An asporogeneous mutant showed a normal product ion of protease under all conditions, and a low intracellular protease turnover after growth. A mutant unable to produce protease showed a normal sporulation and a high protein turnover. This protease, here termed megapeptidase, seems to be a typical growth enzyme, not related to either the sporulation process or to the protein turnover after growth.     

The yeast plasma membrane protein Alr1 controls Mg2+ homeostasis and is subject to Mg2+-dependent control of its synthesis and degradation

The Saccharomyces cerevisiae ALR1 (YOL130w) gene product Alr1p is the first known candidate for a Mg(2+) transport system in eukaryotic cells and is distantly related to the bacterial CorA Mg(2+) transporter family. Here we provide the first experimental evidence for the location of Alr1p in the yeast plasma membrane and for the tight control of its expression and turnover by Mg(2+). Using well characterized npi1 and end3 mutants deficient in the endocytic pathway, we demonstrate that Alr1 protein turnover is dependent on ubiquitination and endocytosis. Furthermore, cells lacking the vacuolar protease Pep4p accumulated Alr1p in the vacuole. Mutants lacking Alr1p (Deltaalr1) showed a 60% reduction of total intracellular Mg(2+) compared with the wild type and failed to grow in standard media. When starved of Mg(2+), mutant and wild-type cells had similar low levels of intracellular Mg(2+); but upon addition of Mg(2+), wild-type cells replenished the intracellular Mg(2+) pool within a few hours, whereas Deltaalr1 mutant cells did not. Expression of the bacterial Mg(2+) transporter CorA in the yeast Deltaalr1 mutant partially restored growth in standard media. The results are discussed in terms of Alr1p being a plasma membrane transporter with high selectivity for Mg(2+).     

Impact of staphylococcal protease expression on the outcome of infectious arthritis

The exoproteases of Staphylococcus aureus have been proposed as virulence factors during S. aureus infections. To investigate this, we used the wild-type S. aureus strain 8325-4 and its mutants devoid of aureolysin, serine protease, and cysteine protease, respectively, in a well-established model of septic arthritis in mice. The inactivation of the exoprotease genes did not affect the frequency or the severity of joint disease. We conclude that in the model of haematogenously spread staphylococcal arthritis, the bacterial proteases studied do not act as virulence factors.     

Intracellular proteases during sporulation and enterotoxin formation byClostridium perfringens type A

Intracellular proteolytic activity was detected in cell-free extracts ofClostridium perfringens NCTC 10239 and NCTC 8798. The kinetics of protease, enterotoxin, and spore formation as well as growth of the wild type at elevated temperature and the use of sporulation mutants indicated that most protease activity was related to sporulation. Intracellular protease activity was inhibited by a mixture of tetrasodium ethylenediaminetetraacetic acid and phenylmethylsulfonyl fluoride; this indicated the presence of an alkaline serine protease and a neutral metallo-protease. Stage 0 sporulation mutants produced only metallo-sensitive proteases; this indicated that only the serine protease was sporulation-specific.     

Extracellular proteases modify cell wall turnover in Bacillus subtilis.

The rate of turnover of peptidoglycan in exponentially growing cultures of Bacillus subtilis was observed to be sensitive to extracellular protease. In protease-deficient mutants the rates of cell wall turnover were greater than that of wild-type strain 168, whereas hyperprotease-producing strains exhibited decreased rates of peptidoglycan turnover. The rate of peptidogylcan turnover in a protease-deficient strain was decreased when the mutant was grown in the presence of a hyperprotease-producing strain. The addition of phenylmethylsulfonyl fluoride, a serine protease inhibitor, to cultures of hyperprotease-producing strains increased their rates of cell wall turnover. Isolated cell walls of all protease mutants contained autolysin levels equal to or greater than that of wild-type strain 168. The presence of filaments, or cells with incomplete septa, was observed in hyperprotease-producing strains or when a protease-deficient strain was grown in the presence of subtilisin. The results suggest that the turnover of cell walls in B. subtilis may be regulated by extracellular proteases.     

Limb-girdle muscular dystrophy (LGMD-1C) mutants of caveolin-3 undergo ubiquitination and proteasomal degradation. Treatment with proteasomal inhibitors blocks the dominant negative effect of LGMD-1C mutanta and rescues wild-type caveolin-3

Caveolin-3 is the principal structural protein of caveolae in striated muscle. Autosomal dominant limb-girdle muscular dystrophy (LGMD-1C) in humans is due to mutations (DeltaTFT and Pro --> Leu) within the CAV3 gene. We have shown that LGMD-1C mutations lead to formation of unstable aggregates of caveolin-3 that are retained intracellularly and are rapidly degraded. The mechanism by which LGMD-1C mutants of caveolin-3 are degraded remains unknown. Here, we show that LGMD-1C mutants of caveolin-3 undergo ubiquitination-proteasomal degradation. Treatment with proteasomal inhibitors (MG-132, MG-115, lactacystin, or proteasome inhibitor I), but not lysosomal inhibitors, prevented degradation of LGMD-1C caveolin-3 mutants. In the presence of MG-132, LGMD-1C caveolin-3 mutants accumulated within the endoplasmic reticulum and did not reach the plasma membrane. LGMD-1C mutants of caveolin-3 behave in a dominant negative fashion, causing intracellular retention and degradation of wild-type caveolin-3. Interestingly, in cells co-expressing wild-type and mutant forms of caveolin-3, MG-132 treatment rescued wild-type caveolin-3; wild-type caveolin-3 was not degraded and reached the plasma membrane. These results may have clinical implications for treatment of patients with LGMD-1C.     

Functional dissection of a cell-division inhibitor, SulA, of Escherichia coli and its negative regulation by Lon

SulA is induced in Escherichia coli by the SOS response and inhibits cell division through interaction with FtsZ. To determine which region of SulA is essential for the inhibition of cell division, we constructed a series of N-terminal and C-terminal deletions of SulA and a series of alanine substitution mutants. Arginine at position 62, leucine at 67, tryptophan at 77 and lysine at 87, in the central region of SulA, were all essential for the inhibitory activity. Residues 3–27 and the C-terminal 21 residues were dispensable for the activity. The mutant protein lacking N-terminal residues 3–47 was inactive, as was that lacking the C-terminal 34 residues. C-terminal deletions of 8 and 21 residues increased the growth-inhibiting activity in lon ⁺ cells, but not in lon ^? cells. The wild-type and mutant SulA proteins were isolated in a form fused to E. coli maltose-binding protein, and tested in vitro for sensitivity to Lon protease. Lon degraded wild-type SulA and a deletion mutant lacking the N-terminal 93 amino acids, but did not degrade the derivative lacking 21 residues at the C-terminus. Futhermore, the wild-type SulA and the N-terminal deletion mutant formed a stable complex with Lon, while the C-terminal deletion did not. MBP fused to the C-terminal 20 residues of SulA formed a stable complex with, but was not degraded by Lon. When LacZ protein was fused at its C-terminus to 8 or 20 amino acid residues from the C-terminal region of SulA the protein was stable in lon ⁺ cells. These results indicate that the C-terminal 20 residues of SulA permit recognition by, and complex formation with, Lon, and are necessary, but not sufficient, for degradation by Lon.