The Plasmid-Encoded Signal Peptidase SipP Can Functionally Replace the Major Signal Peptidases SipS and SipT ofBacillus subtilis (original) (raw)
Related papers
Journal of Bacteriology, 2002
Most bacteria contain one type I signal peptidase (SPase) for cleavage of signal peptides from secreted proteins. The developmental complex bacterium Streptomyces lividans has the ability to produce and secrete a significant amount of proteins and has four different type I signal peptidases genes (sipW, sipX, sipY, and sipZ) unusually clustered in its chromosome. Functional analysis of the four SPases was carried out by phenotypical and molecular characterization of the different individual sip mutants. None of the sip genes seemed to be essential for bacterial growth. Analysis of total extracellular proteins indicated that SipY is likely to be the major S. lividans SPase, since the sipY mutant strain is highly deficient in overall protein secretion and extracellular protease production, showing a delayed sporulation phenotype when cultured in solid medium.
Molecular Microbiology, 1995
Various strains of Bacillus subtilis (natto) contain small cryptic plasmids that replicate via the rolling circle mechanism. Like plasmids from other Gram-positive bacteria, these plasmids are composed of several distinct structural modules. A new structural module was identified on the B. subtilis plasmids pTA1015 and pTA1040. It is composed of two genes: one specifies an unidentified protein with a putative signal peptide; the other (sipP) specifies a functional type I signal peptidase (SPase). Th e homologous, but non-identical, sipP genes of the two plasmids are the first identified plasmid-specific SPase-encoding genes. With respect t o structure and activity, the corresponding enzymes (denoted SipP) ar e highly similar to the chromosomally encoded SPase, SipS, of B. subtilis and several newly identified SPases of other bacilli. Our findings suggest that plasmid-encoded SPases have evolved because under certai n conditions SPase can be a limiting factor for protein secretion in B. subtilis.
Membrane Topology of the Streptomyces lividans Type I Signal Peptidases
Journal of Bacteriology, 2001
Most bacterial membranes contain one or two type I signal peptidases (SPases) for the removal of signal peptides from export proteins. For Streptomyces lividans, four different type I SPases (denoted SipW, SipX, SipY, and SipZ) were previously described. In this communication, we report the experimental determination of the membrane topology of these SPases. A protease protection assay of SPase tendamistat fusions confirmed the presence of the N-as well as the C-terminal transmembrane anchor for SipY. SipX and SipZ have a predicted topology similar to that of SipY. These three S. lividans SPases are currently the only known prokaryotictype type I SPases of gram-positive bacteria with a C-terminal transmembrane anchor, thereby establishing a new subclass of type I SPases. In contrast,
PROTEOMICS, 2006
The developmentally complex bacterium Streptomyces lividans has the ability to produce and secrete a significant amount of protein and possesses four different type I signal peptidase genes (sipW, sipX, sipY and sipZ) that are unusually clustered in its chromosome. 2-DE and subsequent MS of extracellular proteins showed that proteins with typical export signals for type I and type II signal peptidases are the main components of the S. lividans secretome. Secretion of extracellular proteins is severely reduced in a strain deficient in the major type I signal peptidase (SipY). This deficiency was efficiently compensated by complementation with any of the other three signal peptidases as deduced from a comparison of the corresponding 2-D PAGE patterns with that of the wild-type strain.
Journal of Biotechnology, 1998
Bacillus subtilis is one of the best known Gram-positive bacteria at both the genetic and physiological level. The entire sequence of its chromosome is known and efficient tools for the genetic modification of this bacterium are available. Moreover, B. subtilis and related Bacillus species are widely used in biotechnology, in particular for the production of secreted enzymes. Although bacilli can secrete large amounts of several native enzymes, the use of these bacteria for the production of heterologous enzymes has frequently resulted in low yields. Here we describe the identification of several components of the Bacillus protein secretion machinery. These components can now be engineered for optimal protein secretion. Special emphasis is given on type I signal peptidases, which remove signal peptides from secretory precursor proteins. Five genes specifying such enzymes (sip, for signal peptidase) are present on the B. subtilis chromosome. Although none of the sip genes is essential by itself, a specific combination of mutations in these genes is lethal. The expression pattern of some of the sip genes coincides with that of many secretory proteins, which seems to reflect an adaptation to high demands on the secretion machinery. Although the various B. subtilis type I signal peptidases have at least partially overlapping substrate specificities, clear differences in substrate preferences are also evident. These observations have implications for the engineering of the processing apparatus for improved secretion of native and heterologous proteins by Bacillus.
MGG Molecular & General Genetics, 1991
The effects of 25-fold overproduction of Escheriehia coli signal peptidase I (SPase I) on the processing kinetics of various (hybrid) secretory proteins, comprising fusions between signal sequence functions selected from the Bacillus subtilis chromosome and the mature part of TEM-/Mactamase, were studied in E. coli. One precursor (pre[A2d]-/Mactamase) showed an enhanced processing rate, and consequently, a highly improved release of the mature enzyme into the periplasm. A minor fraction of a second hybrid precursor (pre[Al 3i]-/Mactamase), which was not processed under standard conditions of SPase I synthesis, was shown to be processed under conditions of SPase I overproduction. However, this did not result in efficient release of the mature/%lactamase into the periplasm. In contrast, the processing rates of wild-type pre-/Mactamase and pre(A2)-/%lactamase, already high under standard conditions, were not detectably altered by SPase I overproduction. These results demonstrate that the availability of SPase I can be a limiting factor in protein export in E. coli, in particular with respect to (hybrid) precursor proteins showing low (SPase I) processing efficiencies.
The underlying mechanisms of type II protein secretion
Biochimica et Biophysica Acta (BBA) - Molecular Cell Research, 2004
The cell envelope of Gram-negative bacteria is composed of two membranes, which are separated by the peptidoglycan-containing periplasm. Whereas the envelope forms an essential barrier against harmful substances, it is nevertheless a compartment of intense traffic for large proteins such as enzymes and toxins. Numerous studies dealing with the molecular mechanism of protein secretion have revealed that Gram-negative bacteria evolved different strategies to achieve this process. Among them, the type II secretion mechanism is part of a twostep process. Exoproteins following this pathway are synthesized as signal peptide-containing precursors. After cleavage of the signal peptide, the mature exoproteins are released into the periplasm, where they fold. The type II machinery, also known as the secreton, is responsible for the translocation of the periplasmic intermediates across the OM. The type II system is broadly conserved in Gram-negative bacteria and involves a set of 12-16 different proteins named GspC-M, GspAB, GspN, GspO, and GspS. The type II secretion system is highly reminiscent of the type IV piliation assembly system. Based on findings about the subcellular localisation of the Gsp components, protein-protein interactions between Gsps and their multimerisation status, structural data and electron microscopy observation, it could be proposed a working model that strikingly runs both systems in parallel.
Biotechnology and Bioengineering, 2005
The removal of the signal peptide from a precursor protein is a crucial step of protein secretion. In order to improve Bacillus megaterium as protein production and secretion host, the influence of homologous type I signal peptidase SipM overproduction on recombinant Leuconostoc mesenteroides dextransucrase DsrS synthesis and export was investigated. The dsrS gene was integrated as a single copy into the chromosomal bgaM locus encoding b-galactosidase. Desired clones were identified by blue-white selection. In this strain, the expression of sipM from a multicopy plasmid using its own promoter increased the amount of secreted DsrS 3.7-fold. This increase in protein secretion by SipM overproduction was next transferred to a high level DsrS production strain using a multicopy plasmid encoding sipM with its natural promoter and dsrS under control of a strong xyloseinducible promoter. No further increase in DsrS export were observed when this vector was carrying two sipM copies. Similarly, bicistronic sipM and dsrS high level expression did not enhance DsrS secretion, indicating the natural limitation of the approach. Interestingly, SipMenhanced DsrS secretion also resulted in an overall increase of DsrS production. ß