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.     

Increased ATP-dependent proteolytic activity in lon-deficient Escherichia coli strains lacking the DnaK protein.

Extracts made from Escherichia coli null dnaK strains contained elevated levels of ATP-dependent proteolytic activity compared with levels in extracts made from dnaK+ strains. This ATP-dependent proteolytic activity was not due to Lon, Clp, or Alp-associated protease. Comparison of the levels of ATP-dependent proteolytic activity present in lon rpoH dnaK mutants and in lon rpoH dnaK+ mutants showed that the level of ATP-dependent proteolytic activity was elevated in the lon rpoH dnaK mutant strain. These findings suggest that DnaK negatively regulates a new ATP-dependent proteolytic activity, independently of sigma 32. Other results indicate that an ATP-dependent proteolytic activity was increased in a lon alp strain after heat shock. It is not yet known whether the same protease is associated with the increased ATP-dependent proteolytic activity in the dnaK mutants and in the heat-shocked lon alph strain.     

A yeast mutant temperature-sensitive for mitochondrial assembly is deficient in a mitochondrial protease activity that cleaves imported precursor polypeptides.

We have previously described two yeast mutants which, at elevated temperature, stop growing and accumulate precursors to several imported mitochondrial proteins. We now show that one of these mutants (mas 1) is deficient in a matrix-located protease activity which cleaves the pre-sequences from mitochondrial precursor proteins. Isolated mas 1 mitochondria catalyze oxidative phosphorylation, exhibit respiratory control and import mitochondrial precursor polypeptides, but are defective in removing transient pre-sequences from imported precursors. The phenotype of the mas 1 mutant suggests that the matrix-located processing protease is essential for growth and for mitochondrial assembly.     

Isolation of protease-proficient, recombinase-deficient recA mutants of Escherichia coli K-12

We isolated recA mutants with altered protease activity and then examined recombinase activity to determine whether the protease and recombinase functions of the RecA protein of Escherichia coli are separable. We found five mutants that had moderately strong constitutive RecA protease activity but no recombinase activity above the delta recA strain background, the first clear-cut examples of mutants of this class, designated Prtc Rec-. We also isolated 65 mutants that were protease-defective toward the LexA repressor and found that all of them were also recombinase deficient. Four of these mutants retained both partial recombinase activity and partial inducible protease activity. The recombinase-defective mutants were much more sensitive than the recA+ strain to crystal violet, kanamycin, and chloramphenicol, indicating altered membrane permeability. The recA (Prtc Rec-) mutants had a subtle alteration in protease specificity, all being defective in spontaneous induction of phages lambda imm434 and 21. They differed from Prtc Rec+ mutants of comparable or even weaker constitutive protease strength, all of which showed dramatic spontaneous induction of these prophages. However, treating a Prtc Rec- mutant with mitomycin C resulted in significant prophage induction. Thus, the RecA proteins of the Prtc Rec- mutants have constitutive protease activity toward the LexA repressor, but have only DNA damage-activable protease activity toward phage repressors. UV-induced mutagenesis from his to his+ was studied for one Prtc Rec- mutant, and induced mutation frequencies as high as those for the recA+ strain were found despite the absence of recombinase activity.     

Plaque color method for rapid isolation of novel recA mutants of Escherichia coli K-12: new classes of protease-constitutive recA mutants

As a prerequisite to mutational analysis of functional sites on the RecA protein of Escherichia coli, a method was developed for rapid isolation of recA mutants with altered RecA protease function. The method involves plating mutagenized lambda recA+ cI ind on strains deleted for recA and containing, as indicators of RecA protease activity, Mu d(Ap lac) fusions in RecA-inducible genes. The lambda recA phages were recognized by their altered plaque colors, and the RecA protease activity of the lambda recA mutant lysogens was measured by expression of beta-galactosidase from dinD::lac. One class of recA mutants had constitutive protease activity and was designated Prtc; in these cells the RecA protein was always in the protease form without the usual need for DNA damage to activate it. Some Prtc mutants were recombinase negative and were designated Prtc Rec-. Another class of 65 recA mutants isolated as being protease defective were all also recombinase defective. Unlike the original temperature-dependent Prtc Rec+ mutant (recA441), the new Prtc Rec+ mutants showed constitutive protease activity at any growth temperature, with some having considerably greater activity than the recA441 strain. Study of these strong Prtc Rec+ mutants revealed a new SOS phenomenon, increased permeability to drugs. Use of this new SOS phenomenon as an index of protease strength clearly distinguished 5 Prtc mutants as the strongest among 150. These five strongest Prtc mutants showed the greatest increase in spontaneous mutation frequency and were not inhibited by cytidine plus guanosine, which inhibited the constitutive protease activity of the recA441 strain and of all the other new Prtc mutants. Strong Prtc Rec+ mutants were more UV resistant than recA+ strains and showed indications of having RecA proteins whose specific activity of recombinase function was higher than that of wild-type RecA. A Prt+ Rec- mutant with an anomalous response to effectors is described.     

Deletion of the SNP1 trypsin protease from Stagonospora nodorum reveals another major protease expressed during infection

The wheat fungal pathogen Stagonospora nodorum produces an extracellular trypsin-like protease, SNP1, during early stages of hyphal growth on the surface of host leaves and during penetration. Variation of SNP1 mRNA levels and enzyme activity during infection, were correlated with levels of aggressiveness of three wild-type isolates. SNP1 was deleted in two wild-type isolates using a gene replacement strategy. SNP1-deleted mutants completely lacked trypsin activity in vitro and on inoculated wheat leaves, but were not reduced in pathogenicity. SNP1-deleted mutants still have 50% of the total alkaline protease activity of wild-type. This residual activity comes from a previously undetected alkaline protease with subtilisin-like substrate and inhibitor specificities, which is produced in vitro and on host leaves. We hypothesize that this subtilisin protease may act in concert with SNP1 and may compensate for the loss of trypsin protease activity in the SNP1-deletion mutants.     

Differential regulation of G protein alpha subunit trafficking by mono- and polyubiquitination

Previously we used mass spectrometry to show that the yeast G protein alpha subunit Gpa1 is ubiquitinated at Lys-165, located within a subdomain not present in other G alpha proteins (Marotti, L. A., Jr., Newitt, R., Wang, Y., Aebersold, R., and Dohlman, H. G. (2002) Biochemistry 41, 5067-5074). Here we describe the functional role of Gpa1 ubiquitination. We find that Gpa1 expression is elevated in mutants deficient in either proteasomal or vacuolar protease function. Vacuolar protease pep4 mutants accumulate monoubiquitinated Gpa1, and much of the protein is localized within the vacuolar compartment. In contrast, proteasome-defective rpt6/cim3 mutants accumulate polyubiquitinated Gpa1, and in this case the protein exhibits cytoplasmic localization. Cells that lack Ubp12 ubiquitin-processing protease activity accumulate both mono- and polyubiquitinated forms of Gpa1. In this case, Gpa1 accumulates in both the cytoplasm and vacuole. Finally, a Gpa1 mutant that lacks the ubiquitinated subdomain remains unmodified and is predominantly localized at the plasma membrane. These data reveal a strong relationship between the extent of ubiquitination and trafficking of the G protein alpha subunit to its site of degradation.     

Isolation and characterization of protease overproducing mutants of Trichoderma harzianum

Several Trichoderma strains have been reported to be effective in controlling plant diseases, and the action of fungal hydrolytic enzymes is considered as the main mechanism involved in the antagonistic process. Strain Trichoderma harzianum T334 is a potential biocontrol agent against plant pathogenic fungi with the ability to produce low levels of proteases constitutively. To improve its fungal antagonistic capacity, mutagenetic program was undertaken for the construction of protease overproducing derivates. The mutant strains were obtained by means of UV-irradiation and were selected for p-fluorophenyl-alanine resistance or altered colony morphology. It was revealed by means of specific chromogenic protease substrates that both trypsin-like and chymotrypsin-like protease secretion was elevated in most of the mutant strains. The profiles of isoenzymes were different between the mutants and the wild-type strain, when examined by gel filtration chromatography. Certain mutants proved to be better antagonists against plant pathogens in in vitro antagonism experiments. This study suggests the possibility of using mutants with improved constitutive extracellular protease secretion against plant pathogenic fungi.     

Isolation and characterization of Bacillus megaterium mutants containing decreased levels of spore protease.

A proteolytic activity present in spores of Bacillus megaterium has previously been implicated in the initiation of hydrolysis of the A, B, and C proteins which are degraded during spore germination. Four mutants of B. megaterium containing 20 to 30% of the normal level of spore proteolytic activity have been isolated. Partial purification of the protease from wild-type spores by a reviewed procedure resulted in the resolution of spore protease activity on the A, B, and C proteins into two peaks--a major one (protease II) and a minor one (protease I). The protease mutants tested lacked active protease II. All of the mutants exhibited a decreased rate of degradation of the A, B, and C proteins during spore germination at 30 degrees C, but degradation of the proteins did occur. Degradation of the A, B, and C proteins during germination of the mutant spores was decreased neither by blockade of ATP production nor by germination at 44 degrees C. Initiation of spore germination was normal in all four mutants, and all four mutants went through outgrowth, grew, and sporulated normally in rich medium. Similarly, outgrowth of spores of two of the four mutants was normal in minimal medium at 30 degrees C. In the two mutants studied, the kinetics of loss of spore heat resistance and spore UV light resistance during germination were identical to those of wild-type spores. This indicates that the A, B, and C proteins alone are not sufficient to account for the heat or UV light resistance of the dormant spore.     

Potato virus Y NIa protease activity is not sufficient for elicitation of Ry-mediated disease resistance in potato

Ry confers extreme resistance (ER) to all strains of potato virus Y (PVY). In previous work, we have shown that the protease domain of the nuclear inclusion a protease (NIaPro) from PVY is the elicitor of the Ry-mediated resistance and that integrity of the protease active site is required for the elicitation of the resistance response. Two possibilities arise from these results: first, the structure of the active protease has elicitor activity; second, NIa-mediated proteolysis is required to elicit the resistance response. To resolve these possibilities, the NIaPro from PVY was randomly mutagenised and the clones obtained were screened for elicitation of cell death as an indicator of resistance and proteolytic activity. We did not find any mutants that had retained the ability to elicit cell death but had lost protease activity, as measured by processing of the NIa cleavage site in the viral genome. This was consistent with the idea that protease activity is necessary for elicitor activity. However, protease activity was not sufficient because we found three elicitor-defective mutants in which there was a high level of protease activity in this assay.     

Transposon mutagenesis of Pseudomonas aeruginosa exoprotease genes.

Transposon Tn5 was used to generate protease-deficient insertion mutants of Pseudomonas aeruginosa. The presence of Tn5 in the chromosome of P. aeruginosa was demonstrated by transduction and DNA-DNA hybridization. The altered protease production and kanamycin resistance were cotransduced into a wild-type P. aeruginosa strain. A radiolabeled probe of Tn5 DNA hybridized to specific BamHI fragments isolated from the insertion mutants. Two independently isolated Tn5 insertion mutants had reduced protease production, partially impaired elastase activity, and no immunologically reactive alkaline protease.     

Analysis of two Aspergillus nidulans genes encoding extracellular proteases

Characterization of prtADelta mutants, generated by gene disruption, showed that the prtA gene is responsible for the majority of extracellular protease activity secreted by Aspergillus nidulans at both neutral and acid pH. The prtA delta mutation was used to map the prtA gene to chromosome V. Though aspartic protease activity has never been reported in A. nidulans and the prtADelta mutants appear to lack detectable acid protease activity, a gene (prtB) encoding a putative aspartic protease was isolated from this species. Comparison of the deduced amino acid sequence of PrtB to the sequence of other aspergillopepsins suggests that the putative prtB gene product contains an eight-amino-acid deletion prior to the second active site Asp residue of the protease. RT-PCR experiments showed that the prtB gene is expressed, albeit at a low level.     

FtsH11 protease plays a critical role in Arabidopsis thermotolerance

Plants, as sessile organisms, employ multiple mechanisms to adapt to the seasonal and daily temperature fluctuations associated with their habitats. Here, we provide genetic and physiological evidence that the FtsH11 protease of Arabidopsis contributes to the overall tolerance of the plant to elevated temperatures. To identify the various mechanisms of thermotolerance in plants, we isolated a series of Arabidopsis thaliana thermo-sensitive mutants (atts) that fail to acquire thermotolerance after pre-conditioning at 38 degrees C. Two allelic mutants, atts244 and atts405, were found to be both highly susceptible to moderately elevated temperatures and defective in acquired thermotolerance. The growth and development of the mutant plants at all stages examined were arrested after exposure to temperatures above 30 degrees C, which are permissive conditions for wild-type plants. The affected gene in atts244 was identified through map-based cloning and encodes a chloroplast targeted FtsH protease, FtsH11. The Arabidopsis genome contains 12 predicted FtsH protease genes, with all previously characterized FtsH genes playing roles in the alleviation of light stress through the degradation of unassembled thylakoid membrane proteins and photodamaged photosystem II D1 protein. Photosynthetic capability, as measured by chlorophyll content (chl a/b ratios) and PSII quantum yield, is greatly reduced in the leaves of FtsH11 mutants when exposed to the moderately high temperature of 30 degrees C. Under high light conditions, however, FtsH11 mutants and wild-type plants showed no significant difference in photosynthesis capacity. Our results support a direct role for the A. thaliana FtsH11-encoded protease in thermotolerance, a function previously reported for bacterial and yeast FtsH proteases but not for those from plants.     

Protease-deficient mutants of Pseudomonas aeruginosa: pleiotropic changes in activity of other extracellular enzymes.

Mutants of Pseudomonas aeruginosa strain PAKS-I which are defective in the formation of extracellular protease activity have been characterized. The mutants produced between approximately 1 and 25% of the protease activity of the wild type and no strains completely lacking extracellular protease were found, even after repeated mutagen treatment. Most mutants also had changed activities of extracellular staphylolytic enzyme, lipase and lecithinase. Four of 13 mutants were unable to release alkaline phosphatase and staphylolytic enzyme into the medium in contrast to the wild type. Serotype, phage type and biochemical reactions were essentially unchanged. The results indicate that some of the mutations affected the cell envelope structure of function leading to decreased ability to release extracellular proteins, and that other mutations possibly affected a common regulatory mechanism for extracellular enzymes.     

Isolation of mutants ofClostridium acetobutylicum ATCC 824 deficient in protease activity

In this study we report the isolation of mutants ofClostridium acetobutylicum ATCC 824 that are deficient in protease activity. The mutants were formed by use of Tn916 transposon mutagenesis, and this study further indicates this technique as a viable method for studying the genetics ofC. acetobutylicum. The reduced protease phenotype can be distinguished on milk agar plates and was confirmed by enzyme activity measurements with the fluorescent protease substrate FITC-casein. The protease-deficient strains are capable of normal spore formation and solvent production.     

Isolation and characterization of mutants of a marine Vibrio strain that are defective in production of extracellular proteins

A marine Vibrio strain, Vibrio sp. strain 60, produces several extracellular proteins, including protease, amylase, DNase, and hemagglutinin. Mutants of Vibrio sp. strain 60 (epr mutants) pleiotropically defective in production of these extracellular proteins were isolated. They fell into two classes, A and B. In class A, no protease activity was detected in the cells either, whereas in class B, considerable protease activity was detected in the cells. Gel electrophoretic analysis revealed that the protease detected in class B mutant cells was similar to the protease excreted by the parent strain. In addition, the protease in class B mutant cells was found to be localized in the periplasmic space. These results suggest that the passage of the protease through the outer membrane is blocked in class B mutants. Comparison of membrane protein profiles by polyacrylamide gel electrophoresis revealed that all the epr mutants contained an increased amount of a 94,000-Mr protein that may be an outer membrane protein. Four epr mutations were mapped in two different regions of the Vibrio chromosome by transduction; two class A mutations and one class B mutation were located close to each other, whereas another class B mutation was located in a different region of the chromosome.