Studies of the Listeria monocytogenes Cellobiose Transport Components and Their Impact on Virulence Gene Repression

BACKGROUND

Many bacteria transport cellobiose via a phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS). In Listeria monocytogenes, two pairs of soluble PTS components (EIIACel1/EIIBCel1 and EIIACel2/EIIBCel2) and the permease EIICCel1 were suggested to contribute to cellobiose uptake. Interestingly, utilization of several carbohydrates, including cellobiose, strongly represses virulence gene expression by inhibiting PrfA, the virulence gene activator.

RESULTS

The LevR-like transcription regulator CelR activates expression of the cellobiose-induced PTS operons celB1-celC1-celA1, celB2-celA2, and the EIIC-encoding monocistronic celC2. Phosphorylation by P∼His-HPr at His550 activates CelR, whereas phosphorylation by P∼EIIBCel1 or P∼EIIBCel2 at His823 inhibits it. Replacement of His823 with Ala or deletion of both celA or celB genes caused constitutive CelR regulon expression. Mutants lacking EIICCel1, CelR or both EIIACel exhibitedslow cellobiose consumption. Deletion of celC1 or celR prevented virulence gene repression by the disaccharide, but not by glucose and fructose. Surprisingly, deletion of both celA genes caused virulence gene repression even during growth on non-repressing carbohydrates. No cellobiose-related phenotype was found for the celC2 mutant.

CONCLUSION

The two EIIA/BCel pairs are similarly efficient as phosphoryl donors in EIICCel1-catalyzed cellobiose transport and CelR regulation. The permanent virulence gene repression in the celA double mutant further supports a role of PTSCel components in PrfA regulation.

Transport and Catabolism of Pentitols by Listeria monocytogenes

Transposon insertion into Listeria monocytogenes lmo2665, which encodes an EIIC of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS), was found to prevent D-arabitol utilization. We confirm this result with a deletion mutant and show that Lmo2665 is also required for D-xylitol utilization. We therefore called this protein EIICAxl. Both pentitols are probably catabolized via the pentose phosphate pathway (PPP) because lmo2665 belongs to an operon, which encodes the three PTSAxl components, two sugar-P dehydrogenases, and most PPP enzymes. The two dehydrogenases oxidize the pentitol-phosphates produced during PTS-catalyzed transport to the PPP intermediate xylulose-5-P. L. monocytogenes contains another PTS, which exhibits significant sequence identity to PTSAxl. Its genes are also part of an operon encoding PPP enzymes. Deletion of the EIIC-encoding gene (lmo0508) affected neither D-arabitol nor D-xylitol utilization, although D-arabitol induces the expression of this operon. Both operons are controlled by MtlR/LicR-type transcription activators (Lmo2668 and Lmo0501, respectively). Phosphorylation of Lmo0501 by the soluble PTSAxl components probably explains why D-arabitol also induces the second pentitol operon. Listerial virulence genes are submitted to strong repression by PTS sugars, such as glucose. However, D-arabitol inhibited virulence gene expression only at high concentrations, probably owing to its less efficient utilization compared to glucose.

Transport and Catabolism of Carbohydrates by

We identified the genes encoding the proteins for the transport of glucose and maltose in <i>Neisseria meningitidis</i> strain 2C4-3. A mutant deleted for <i>NMV_1892</i><i>(glcP)</i> no longer grew on glucose and deletion of <i>NMV_0424</i><i>(malY)</i> prevented the utilization of maltose. We also purified and characterized glucokinase and α-phosphoglucomutase, which catalyze early catabolic steps of the two carbohydrates. <i>N. meningitidis</i> catabolizes the two carbohydrates either via the Entner-Doudoroff (ED) pathway or the pentose phosphate pathway, thereby forming glyceraldehyde-3-P and either pyruvate or fructose-6-P, respectively. We purified and characterized several key enzymes of the two pathways. The genes required for the transformation of glucose into gluconate-6-P and its further catabolism via the ED pathway are organized in two adjacent operons. <i>N. meningitidis</i> also contains genes encoding proteins which exhibit similarity to the gluconate transporter <i>(NMV_2230)</i> and gluconate kinase <i>(NMV_2231)</i> of Enterobacteriaceae and Firmicutes. However, gluconate might not be the real substrate of <i>NMV_2230</i> because <i>N. meningitidi</i>s was not able to grow on gluconate as the sole carbon source. Surprisingly, deletion of <i>NMV_2230</i> stimulated growth in minimal medium in the presence and absence of glucose and drastically slowed the clearance of <i>N. meningitidis</i> cells from transgenic mice after intraperitoneal challenge.

The phosphocarrier protein HPr of Neisseria meningitidis interacts with the transcription regulator CrgA and its deletion affects capsule production, cell adhesion, and virulence

The bacterial phosphotransferase system (PTS) transports and phosphorylates sugars, but also carries out numerous regulatory functions. The β-proteobacterium Neisseria meningitidis possesses an incomplete PTS unable to transport carbon sources because it lacks a membrane component. Nevertheless, the residual phosphorylation cascade is functional and the meningococcal PTS was therefore expected to carry out regulatory roles. Interestingly, a ΔptsH mutant (lacks the PTS protein HPr) exhibited reduced virulence in mice and after intraperitoneal challenge it was rapidly cleared from the bloodstream of BALB/c mice. The rapid clearance correlates with lower capsular polysaccharide production by the ΔptsH mutant, which is probably also responsible for its increased adhesion to Hec-1-B epithelial cells. In addition, compared to the wild-type strain more apoptotic cells were detected when Hec-1-B cells were infected with the ΔptsH strain. Coimmunoprecipitation revealed an interaction of HPr and P-Ser-HPr with the LysR type transcription regulator CrgA, which among others controls its own expression. Moreover, ptsH deletion caused increased expression of a ΦcrgA-lacZ fusion. Finally, the presence of HPr or phospho-HPr's during electrophoretic mobility shift assays enhanced the affinity of CrgA for its target sites preceding crgA and pilE, but HPr did not promote CrgA binding to the sia and pilC1 promoter regions.

PTS-Mediated Regulation of the Transcription Activator MtlR from Different Species: Surprising Differences despite Strong Sequence Conservation

The hexitol D-mannitol is transported by many bacteria via a phosphoenolpyruvate (PEP):carbohydrate phosphotransferase system (PTS). In most Firmicutes, the transcription activator MtlR controls the expression of the genes encoding the D-mannitol-specific PTS components and D-mannitol-1-P dehydrogenase. MtlR contains an N-terminal helix-turn-helix motif followed by an Mga-like domain, two PTS regulation domains (PRDs), an EIIB(Gat)- and an EIIA(Mtl)-like domain. The four regulatory domains are the target of phosphorylation by PTS components. Despite strong sequence conservation, the mechanisms controlling the activity of MtlR from Lactobacillus casei, Bacillus subtilis and Geobacillus stearothermophilus are quite different. Owing to the presence of a tyrosine in place of the second conserved histidine (His) in PRD2, L. casei MtlR is not phosphorylated by Enzyme I (EI) and HPr. When the corresponding His in PRD2 of MtlR from B. subtilis and G. stearothermophilus was replaced with alanine, the transcription regulator was no longer phosphorylated and remained inactive. Surprisingly, L. casei MtlR functions without phosphorylation in PRD2 because in a ptsI (EI) mutant MtlR is constitutively active. EI inactivation prevents not only phosphorylation of HPr, but also of the PTS(Mtl) components, which inactivate MtlR by phosphorylating its EIIB(Gat)- or EIIA(Mtl)-like domain. This explains the constitutive phenotype of the ptsI mutant. The absence of EIIB(Mtl)-mediated phosphorylation leads to induction of the L. caseimtl operon. This mechanism resembles mtlARFD induction in G. stearothermophilus, but differs from EIIA(Mtl)-mediated induction in B. subtilis. In contrast to B. subtilis MtlR, L. casei MtlR activation does not require sequestration to the membrane via the unphosphorylated EIIB(Mtl) domain.

Transcription regulators controlled by interaction with enzyme IIB components of the phosphoenolpyruvate: sugar phosphotransferase system

Numerous bacteria possess transcription activators and antiterminators composed of regulatory domains phosphorylated by components of the phosphoenolpyruvate:sugar phosphotransferase system (PTS). These domains, called PTS regulation domains (PRDs), usually contain two conserved histidines as potential phosphorylation sites. While antiterminators possess two PRDs with four phosphorylation sites, transcription activators contain two PRDs plus two regulatory domains resembling PTS components (EIIA and EIIB). The activity of these transcription regulators is controlled by up to five phosphorylations catalyzed by PTS proteins. Phosphorylation by the general PTS components EI and HPr is usually essential for the activity of PRD-containing transcription regulators, whereas phosphorylation by the sugar-specific components EIIA or EIIB lowers their activity. For a specific regulator, for example the Bacillus subtilis mtl operon activator MtlR, the functional phosphorylation sites can be different in other bacteria and consequently the detailed mode of regulation varies. Some of these transcription regulators are also controlled by an interaction with a sugar-specific EIIB PTS component. The EIIBs are frequently fused to the membrane-spanning EIIC and EIIB-mediated membrane sequestration is sometimes crucial for the control of a transcription regulator. This is also true for the Escherichia coli repressor Mlc, which does not contain a PRD but nevertheless interacts with the EIIB domain of the glucose-specific PTS. In addition, some PRD-containing transcription activators interact with a distinct EIIB protein located in the cytoplasm. The phosphorylation state of the EIIB components, which changes in response to the presence or absence of the corresponding carbon source, affects their interaction with transcription regulators. This article is part of a Special Issue entitled: Inhibitors of Protein Kinases (2012).

Membrane sequestration by the EIIB domain of the mannitol permease MtlA activates the Bacillus subtilis mtl operon regulator MtlR

In most firmicutes expression of the mannitol operon is regulated by MtlR. This transcription activator is controlled via phosphorylation of its regulatory domains by components of the phosphoenolpyruvate : carbohydrate phosphotransferase system (PTS). We found that activation of Bacillus subtilis MtlR also requires an interaction with the EIIB(Mtl) domain of the mannitol permease MtlA (EIICB(Mtl) ). The constitutive expression of the mtlAFD operon in an mtlF mutant was prevented when entire mtlA or only its 3' part (EIIB(Mtl) ) were deleted. Yeast two-hybrid experiments revealed a direct interaction of the EIIB(Mtl) domain with the two C-terminal domains of MtlR. Complementation of the Δ3'-mtlA ΔmtlF or ΔmtlAFD mutants with mtlA restored constitutive MtlR activity, whereas complementation with only 3'-mtlA had no effect. Moreover, synthesis of EIIB(Mtl) in strains producing constitutively active MtlR caused MtlR inactivation. Interestingly, EIIB(Mtl) fused to the trans-membrane protein YwqC restored constitutive MtlR activity in the above mutants. Replacing the phosphorylatable Cys with Asp in MtlA or soluble EIIB(Mtl) lowered MtlR activation, indicating that MtlR does not interact with phosphorylatyed EIIB(Mtl) . Induction of the B. subtilis mtl operon therefore follows a novel regulation mechanism where the transcription activator needs to be sequestered to the membrane by unphosphorylated EIICB(Mtl) in order to be functional.

Mutational analysis of glucose transport regulation and glucose-mediated virulence gene repression in Listeria monocytogenes

Listeria monocytogenes transports glucose/mannose via non-PTS permeases and phosphoenolpyruvate:carbohydrate phosphotransferase systems (PTS). Two mannose class PTS are encoded by the constitutively expressed mpoABCD and the inducible manLMN operons. The man operon encodes the main glucose transporter because manL or manM deletion significantly slows glucose utilization, whereas mpoA deletion has no effect. The PTS(Mpo) mainly functions as a constitutively synthesized glucose sensor controlling man operon expression by phosphorylating and interacting with ManR, a LevR-like transcription activator. EIIB(Mpo) plays a dual role in ManR regulation: P~EIIB(Mpo) prevailing in the absence of glucose phosphorylates and thereby inhibits ManR activity, whereas unphosphorylated EIIB(Mpo) prevailing during glucose uptake is needed to render ManR active. In contrast to mpoA, deletion of mpoB therefore strongly inhibits man operon expression and glucose consumption. A ΔptsI (EI) mutant consumes glucose at an even slower rate probably via GlcU-like non-PTS transporters. Interestingly, deletion of ptsI, manL, manM or mpoB causes elevated PrfA-mediated virulence gene expression. The PTS(Man) is the major player in glucose-mediated PrfA inhibition because the ΔmpoA mutant showed normal PrfA activity. The four mutants showing PrfA derepression contain no or only little unphosphorylated EIIAB(Man) (ManL), which probably plays a central role in glucose-mediated PrfA regulation.

Control of Bacillus subtilis mtl operon expression by complex phosphorylation-dependent regulation of the transcriptional activator MtlR

Many bacteria transport mannitol via the mtlAF-encoded phosphoenolpyruvate (PEP):carbohydrate phosphotransferase system (PTS). In most firmicutes the transcriptional activator MtlR controls expression of the mtl operon. MtlR possesses an N-terminal DNA binding domain, two PTS regulation domains (PRDs), an EIIB(Gat)- and EIIA(Mtl)-like domain. These four regulatory domains contain one or two potential PTS phosphorylation sites. Replacement of His-342 or His-399 in PRD2 with Ala prevented the phosphorylation of Bacillus subtilis MtlR by PEP, EI and HPr. These mutations as well as EI inactivation caused a loss of MtlR function in vivo. In contrast, phosphomimetic replacement of His-342 with Asp rendered MtlR constitutively active. The absence of phosphorylation in PRD2 serves as catabolite repression mechanism. When EIIA(Mtl) and the soluble EIIB(Mtl) domain of the EIICB(Mtl) permease were included in the phosphorylation mixture, His-599 in the EIIA-like domain of MtlR also became phosphorylated. Replacement of His-599 with Asp rendered MtlR inactive, while His599Ala replacement caused slightly constitutive, glucose-repressible MtlR activity. Doubly mutated His342Ala/His599Ala MtlR was still phosphorylated by EI, HPr and EIIA(Mtl) at Cys-419 in the EIIB(Gat)-like domain. Cys419Ala replacement and deletion of EIIA(Mtl) caused strong constitutive glucose-repressible MtlR activity. This is the first report that Cys phosphorylation controls PRD-containing transcriptional activators.

Genome evolution in yeasts

Identifying the mechanisms of eukaryotic genome evolution by comparative genomics is often complicated by the multiplicity of events that have taken place throughout the history of individual lineages, leaving only distorted and superimposed traces in the genome of each living organism. The hemiascomycete yeasts, with their compact genomes, similar lifestyle and distinct sexual and physiological properties, provide a unique opportunity to explore such mechanisms. We present here the complete, assembled genome sequences of four yeast species, selected to represent a broad evolutionary range within a single eukaryotic phylum, that after analysis proved to be molecularly as diverse as the entire phylum of chordates. A total of approximately 24,200 novel genes were identified, the translation products of which were classified together with Saccharomyces cerevisiae proteins into about 4,700 families, forming the basis for interspecific comparisons. Analysis of chromosome maps and genome redundancies reveal that the different yeast lineages have evolved through a marked interplay between several distinct molecular mechanisms, including tandem gene repeat formation, segmental duplication, a massive genome duplication and extensive gene loss.

Hyperthermostabilization of Bacillus licheniformis alpha-amylase and modulation of its stability over a 50 degrees C temperature range

Bacillus licheniformis alpha-amylase (BLA) is a highly thermostable starch-degrading enzyme that has been extensively studied in both academic and industrial laboratories. For over a decade, we have investigated BLA thermal properties and identified amino acid substitutions that significantly increase or decrease the thermostability. This paper describes the cumulative effect of some of the most beneficial point mutations identified in BLA. Remarkably, the Q264S-N265Y double mutation led to a rather limited gain in stability but significantly improved the amylolytic function. The most hyperthermostable variants combined seven amino acid substitutions and inactivated over 100 times more slowly and at temperatures up to 23 degrees C higher than the wild-type enzyme. In addition, two highly destabilizing mutations were introduced in the metal binding site and resulted in a decrease of 25 degrees C in the half-inactivation temperature of the double mutant enzyme compared with wild-type. These mutational effects were analysed by protein modelling based on the recently determined crystal structure of a hyperthermostable BLA variant. Our engineering work on BLA shows that the thermostability of an already naturally highly thermostable enzyme can be substantially improved and modulated over a temperature range of 50 degrees C through a few point mutations.

Cloning of SEC61 homologues from Schizosaccharomyces pombe and Yarrowia lipolytica reveals the extent of functional conservation within this core component of the ER translocation machinery

The Sec61 protein is required for protein translocation across the ER membrane in both yeast and mammals and is found in close association with polypeptides during their membrane transit. In Saccharomyces cerevisiae Sec61p is essential for viability and the extent of sequence similarity between the yeast and mammalian proteins (55% sequence identity) suggests that the role of Sec61p in the translocation mechanism is likely to be conserved. In order to further our understanding of the structure and function of Sec61p we have cloned homologues from both Schizosaccharomyces pombe and Yarrowia lipolytica. The S. pombe gene comprises six exons encoding a 479 residue protein which we have immunolocalised to the endoplasmic reticulum. Sequence comparisons reveal that S. pombe Sec61p is 58.6% identical to that of S. cerevisiae. The deduced amino acid sequence of the Y. lipolytica protein shares 68.8% sequence identity with S. cerevisiae Sec61p. Gene disruption studies have shown that the SEC61 is required for viability in both S. pombe and Y. lipolytica demonstrating that the essential nature of this protein is not unique to S. cerevisiae. Moreover, heterologous complementation studies indicate that the Y. lipolytica SEC61 gene can complement a null mutation in S. cerevisiae. Sequence comparisons between the various eukaryotic Sec61p homologues reveal a number of highly conserved domains, including several transmembrane sequences and the majority of cytosolic loops. These comparisons will provide an important framework for the detailed analysis of interactions between Sec61p and other components of the translocation machinery and between Sec61p and translocating polypeptide chains.

Cloning the Yarrowia lipolytica homologue of the Saccharomyces cerevisiae SEC62 gene

Yarrowia lipolytica SEC62 cDNA was cloned by functional complementation of a thermo-sensitive sec62 Saccharomyces cerevisiae mutant strain. The Y. lipolytica SEC62 promoter region was amplified by the inverse polymerase chain reaction (PCR). The cDNA codes for a 396 amino-acid protein with two potential trans-membrane domains. Y. lipolytica Sec62p behaves as an integral membrane protein as shown by Western blotting. Y. lipolytica SEC62 cDNA is able to complement a S. cerevisiae sec62 null mutant strain confirming functional conservation, although only 53.6% amino-acid similarity is observed between Y. lipolytica and S. cerevisiae Sec62.

Hyperthermostable mutants of Bacillus licheniformis alpha-amylase: multiple amino acid replacements and molecular modelling

We have identified previously two critical positions for the thermostability of the highly thermostable alpha-amylase from Bacillus licheniformis. We have now introduced all 19 possible amino acid residues to these two positions, His133 and Ala209. The most favourable substitutions were to Ile and Val, respectively, which both increased the half-life of the enzyme at 80 degrees C by a factor of approximately 3. At both positions a stabilizing effect of hydrophobic residues was observed, although only in the case of position 133 could a clear correlation be drawn between the hydrophobicity of the inserted amino acid and the gain in protein stability. The construction of double mutants showed a cumulative effect of the most favourable and/or deleterious substitutions. Computer modelling was used to generate a 3-D structure of the wild-type protein and to model substitutions at position 209, which lies in the conserved (alpha/beta)8 barrel domain of alpha-amylase; Ala209 would be located at the beginning of the third helix of the barrel, in the bottom of a small cavity facing the fourth helix. The model suggests that replacement by, for example, a valine could fill this cavity and therefore increase intra- and interhelical compactness and hydrophobic interactions.

Hyperthermostable variants of a highly thermostable alpha-amylase

Genetic screening at temperatures between 70-80 degrees C far exceeds the range of growth of most bacteria, and is not applicable to isolate easily thermostable protein variants. We describe a temperature shift protocol and an in vivo screening method which allowed us to identify a hyperthermostable variant of the thermostable alpha-amylase from Bacillus licheniformis. Our strategy was to select, after hydroxylamine mutagenesis, an intragenic suppressor mutation which overcomes a mutation leading to a thermolabile enzyme. Sequence analysis of the mutated gene revealed only one change in the amino acid sequence, substituting a valine for alanine at position 209. This single amino acid replacement increased the half-life of the protein at 90 degrees C by a factor of two to three relative to the wild-type enzyme. When this substitution was combined with another stabilizing substitution (H133Y) we described previously, the stabilizing effects were additive. The half-life of the new protein was about 12 hours at 90 degrees C, corresponding to a nine to ten-fold increase over the wild-type enzyme and the industrial Bacillus licheniformis alpha-amylase Termamyl. These mutations are located in a predicted folding domain of the protein which appears crucial in determining thermal stability.

Use of amber suppressors to investigate the thermostability of Bacillus licheniformis alpha-amylase. Amino acid replacements at 6 histidine residues reveal a critical position at His-133

A set of 12 Escherichia coli suppressor tRNAs, inserting different amino acids in response to an amber codon, has been used to create rapidly numerous protein variants of a thermostable amylase; by site-directed mutagenesis, amber mutations were first introduced into Bacillus licheniformis alpha-amylase gene at position His35, His133, His247, His293, His406, or His450; genes carrying one or two amber mutations were then expressed in the different suppressor strains, generating over 100 amylase variants with predicted amino acid changes that could be tested for thermostability. Within the detection limits of the assays, amino acid replacements at five histidine positions had no significant effect. In contrast, suppressed variants substituted at residue His133 clearly exhibited modified thermostability and could be either less stable or more stable than the wild-type amylase, depending on the amino acid inserted at this position; comparison of the variants indicates that the hydrophobicity of the substituting residue is an important but not a determinant factor of stabilization. The effect of the most stabilizing and destabilizing amino acid substitutions, His133 to Tyr and to Pro, respectively, were confirmed by introducing the corresponding missense mutations into the gene sequence. The advantages and limits of informational suppression in protein stability studies are discussed as well as structural features involved in the thermostability of B. licheniformis alpha-amylase.