Rechien Bader

Inducer exclusion in Escherichia coli by non‐PTS substrates: the role of the PEP to pyruvate ratio in determining the phosphorylation state of enzyme IIAGlc

The main mechanism causing catabolite repression in Escherichia coli is the dephosphorylation of enzyme IIAGlc, one of the enzymes of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS). The PTS is involved in the uptake of a large number of carbohydrates that are phosphorylated during transport, phosphoenolpyruvate (PEP) being the phosphoryl donor. Dephosphorylation of enzyme IIAGlc causes inhibition of uptake of a number of non‐PTS carbon sources, a process called inducer exclusion. In this paper, we show that dephosphorylation of enzyme IIAGlc is not only caused by the transport of PTS carbohydrates, as has always been thought, and that an additional mechanism causing dephosphorylation exists. Direct monitoring of the phosphorylation state of enzyme IIAGlc also showed that many carbohydrates that are not transported by the PTS caused dephosphorylation during growth. In the case of glucose 6‐phosphate, it was shown that transport and the first metabolic step are not involved in the dephosphorylation of enzyme IIAGlc, but that later steps in the glycolysis are essential. Evidence is provided that the [PEP]–[pyruvate] ratio, the driving force for the phosphorylation of the PTS proteins, determines the phosphorylation state of enzyme IIAGlc. The implications of these new findings for our view on catabolite repression and inducer exclusion are discussed.

Accessible DNA and Relative Depletion of H3K9me2 at Maize Loci Undergoing RNA-Directed DNA Methylation

Only a small fraction of the maize genome undergoes RNA-directed DNA methylation and, for several characteristics, the chromatin in these areas resembles euchromatin more than heterochromatin. RNA-directed DNA methylation (RdDM) in plants is a well-characterized example of RNA interference-related transcriptional gene silencing. To determine the relationships between RdDM and heterochromatin in the repeat-rich maize (Zea mays) genome, we performed whole-genome analyses of several heterochromatic features: dimethylation of lysine 9 and lysine 27 (H3K9me2 and H3K27me2), chromatin accessibility, DNA methylation, and small RNAs; we also analyzed two mutants that affect these processes, mediator of paramutation1 and zea methyltransferase2. The data revealed that the majority of the genome exists in a heterochromatic state defined by inaccessible chromatin that is marked by H3K9me2 and H3K27me2 but that lacks RdDM. The minority of the genome marked by RdDM was predominantly near genes, and its overall chromatin structure appeared more similar to euchromatin than to heterochromatin. These and other data indicate that the densely staining chromatin defined as heterochromatin differs fundamentally from RdDM-targeted chromatin. We propose that small interfering RNAs perform a specialized role in repressing transposons in accessible chromatin environments and that the bulk of heterochromatin is incompatible with small RNA production.

BglF, the sensor of the E. coli bgl system, uses the same site to phosphorylate both a sugar and a regulatory protein.

The Escherichia coli BglF protein is a sugar permease that is a member of the phosphoenolpyruvate‐dependent phosphotransferase system (PTS). It catalyses transport and phosphorylation of β‐glucosides. In addition to its ability to phosphorylate its sugar substrate, BglF has the unusual ability to phosphorylate and dephosphorylate the transcriptional regulator BglG according to β‐glucoside availability. By controlling the phosphorylation state of BglG, BglF controls the dimeric state of BglG and thus its ability to bind RNA and antiterminate transcription of the bgl operon. BglF has two phosphorylation sites. The first site accepts a phosphoryl group from the PTS protein HPr; the phosphoryl group is then transferred to the second phosphorylation site, which can deliver it to the sugar. We provide both in vitro and in vivo evidence that the same phosphorylation site on BglF, the second one, is in charge not only of sugar phosphorylation but also of BglG phosphorylation. Possible mechanisms that ensure correct phosphoryl delivery to the right entity, sugar or protein, depending on environmental conditions, are discussed.

Expression of the Xylulose 5-Phosphate Phosphoketolase Gene, xpkA, from Lactobacillus pentosus MD363 Is Induced by Sugars That Are Fermented via the Phosphoketolase Pathway and Is Repressed by Glucose Mediated by CcpA and the Mannose Phosphoenolpyruvate Phosphotransferase System

ABSTRACT Purification of xylulose 5-phosphate phosphoketolase (XpkA), the central enzyme of the phosphoketolase pathway (PKP) in lactic acid bacteria, and cloning and sequence analysis of the encoding gene, xpkA, from Lactobacillus pentosus MD363 are described. xpkA encodes a 788-amino-acid protein with a calculated mass of 88,705 Da. Expression of xpkA in Escherichia coli led to an increase in XpkA activity, while an xpkA knockout mutant of L. pentosus lost XpkA activity and was not able to grow on energy sources that are fermented via the PKP, indicating that xpkA encodes an enzyme with phosphoketolase activity. A database search revealed that there are high levels of similarity between XpkA and a phosphoketolase from Bifidobacterium lactis and between XpkA and a (putative) protein present in a number of evolutionarily distantly related organisms (up to 54% identical residues). Expression of xpkA in L. pentosus was induced by sugars that are fermented via the PKP and was repressed by glucose mediated by carbon catabolite protein A (CcpA) and by the mannose phosphoenolpyruvate phosphotransferase system. Most of the residues involved in correct binding of the cofactor thiamine pyrophosphate (TPP) that are conserved in transketolase, pyruvate decarboxylase, and pyruvate oxidase were also conserved at a similar position in XpkA, implying that there is a similar TPP-binding fold in XpkA.

Inducer exclusion by glucose 6-phosphate in Escherichia coli.

The main mechanism causing catabolite repression by glucose and other carbon sources transported by the phosphotransferase system (PTS) in Escherichia coli involves dephosphorylation of enzyme IIAGlc as a result of transport and phosphorylation of PTS carbohydrates. Dephosphorylation of enzyme IIAGlc leads to ‘inducer exclusion’: inhibition of transport of a number of non‐PTS carbon sources (e.g. lactose, glycerol), and reduced adenylate cyclase activity. In this paper, we show that the non‐PTS carbon source glucose 6‐phosphate can also cause inducer exclusion. Glucose 6‐phosphate was shown to cause inhibition of transport of lactose and the non‐metabolizable lactose analogue methyl‐β‐D‐thiogalactoside (TMG). Inhibition was absent in mutants that lacked enzyme IIAGlc or were insensitive to inducer exclusion because enzyme IIAGlc could not bind to the lactose carrier. Furthermore, we showed that glucose 6‐phosphate caused dephosphorylation of enzyme IIAGlc. In a mutant insensitive to enzyme IIAGlc‐mediated inducer exclusion, catabolite repression by glucose 6‐phosphate in lactose‐induced cells was much weaker than that in the wild‐type strain, showing that inducer exclusion is the most important mechanism contributing to catabolite repression in lactose‐induced cells. We discuss an expanded model of enzyme IIAGlc‐mediated catabolite repression which embodies repression by non‐ PTS carbon sources.

Autoregulation of lactose uptake through the LacYpermease by enzyme IIAGlc of the PTS in Escherichia coli K‐12

Bacterial growth on one or more carbon sources requires careful control of the uptake and metabolism of these carbon sources. In Escherichia coli, the phosphorylation state of enzyme IIAGlc of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) is involved in this control in two ways. The unphosphorylated form of IIAGlc causes ‘inducer exclusion’, the inhibition of uptake of a number of non‐PTS carbon sources, including lactose uptake by the lactose permease. The phosphorylated form of enzyme IIAGlc probably activates adenylate cyclase. In cells growing on lactose, enzyme IIAGlc was approximately 50% dephosphorylated, suggesting that lactose could inhibit its own uptake. This inhibition could be demonstrated by comparing lactose uptake rates in the wild‐type strain and in a mutant in which the lactose carrier was insensitive to inducer exclusion. In this deregulated mutant strain, lactose was consumed much faster, and large amounts of glucose were excreted. It was shown that enzyme IIAGlc was dephosphorylated more strongly and that the cAMP level was lower in the mutant, most probably causing the observed decrease in lac expression level. When the lac expression level in the mutant strain was increased to that of the parent strain by adding exogenous cAMP, growth on lactose was slower, suggesting that enzyme IIAGlc‐mediated inhibition of lactose uptake and downregulation of the lac expression level protected the cells against excessive lactose influx. An even stronger increase in the lac expression level in a mutant lacking enzyme IIAGlc caused complete growth arrest. We conclude that the autoregulatory mechanism that controls lactose uptake is an important mechanism for the cells in adjusting the uptake rate to their metabolic capacity.

Specific tandem repeats are sufficient for paramutation-induced trans-generational silencing.

Paramutation is a well-studied epigenetic phenomenon in which trans communication between two different alleles leads to meiotically heritable transcriptional silencing of one of the alleles. Paramutation at the b1 locus involves RNA-mediated transcriptional silencing and requires specific tandem repeats that generate siRNAs. This study addressed three important questions: 1) are the tandem repeats sufficient for paramutation, 2) do they need to be in an allelic position to mediate paramutation, and 3) is there an association between the ability to mediate paramutation and repeat DNA methylation levels? Paramutation was achieved using multiple transgenes containing the b1 tandem repeats, including events with tandem repeats of only one half of the repeat unit (413 bp), demonstrating that these sequences are sufficient for paramutation and an allelic position is not required for the repeats to communicate. Furthermore, the transgenic tandem repeats increased the expression of a reporter gene in maize, demonstrating the repeats contain transcriptional regulatory sequences. Transgene-mediated paramutation required the mediator of paramutation1 gene, which is necessary for endogenous paramutation, suggesting endogenous and transgene-mediated paramutation both require an RNA-mediated transcriptional silencing pathway. While all tested repeat transgenes produced small interfering RNAs (siRNAs), not all transgenes induced paramutation suggesting that, as with endogenous alleles, siRNA production is not sufficient for paramutation. The repeat transgene-induced silencing was less efficiently transmitted than silencing induced by the repeats of endogenous b1 alleles, which is always 100% efficient. The variability in the strength of the repeat transgene-induced silencing enabled testing whether the extent of DNA methylation within the repeats correlated with differences in efficiency of paramutation. Transgene-induced paramutation does not require extensive DNA methylation within the transgene. However, increased DNA methylation within the endogenous b1 repeats after transgene-induced paramutation was associated with stronger silencing of the endogenous allele.

Limits to inducer exclusion: inhibition of the bacterial phosphotransferase system by glycerol kinase

The uptake of methyl α‐D‐glucopyranoside by the phosphoenolpyruvate‐dependent phosphotransferase system of Salmonella typhimurium could be inhibited by prior incubation of the cells with glycerol. Inhibition was only observed for glycerol preincubation times longer than 45 s and required the preinduction of both the glucose and the glycerol‐catabolizing systems. Larger extents of inhibition by glycerol correlated with higher intracellular levels of glycerol kinase when the glp regulon had been induced to different extents. Preincubation with lactate did not inhibit methyl α‐D‐glucopyranoside uptake significantly, although both lactate and glycerol were oxidized by the cells. The cellular free‐energy state of the cells (intracellular [ATP]/[ADP] ratio) was virtually identical for lactate and glycerol preincubation, suggesting that the inhibition of phosphotransferase‐mediated uptake was not a metabolic effect. In vitro, phosphotransferase activity was inhibited to a maximal extent of 32% upon titrating cell‐free extracts with high concentrations of commercial glycerol kinase. The results show that uptake systems that have hitherto been regarded merely as targets of the phosphotransferase system component IIAGlc also have the capacity themselves to retroinhibit the phosphotransferase system flux, presumably by sequestration of the available IIAGlc, provided that these systems are induced to appropriate levels.

Generating Transgenic Plants with Single-copy Insertions Using BIBAC-GW Binary Vector

When generating transgenic plants, generally the objective is to have stable expression of a transgene. This requires a single, intact integration of the transgene, as multi-copy integrations are often subjected to gene silencing. The Gateway-compatible binary vector based on bacterial artificial chromosomes (pBIBAC-GW), like other pBIBAC derivatives, allows the insertion of single-copy transgenes with high efficiency. As an improvement to the original pBIBAC, a Gateway cassette has been cloned into pBIBAC-GW, so that the sequences of interest can now be easily incorporated into the vector transfer DNA (T-DNA) by Gateway cloning. Commonly, the transformation with pBIBAC-GW results in an efficiency of 0.2-0.5%, whereby half of the transgenics carry an intact single-copy integration of the T-DNA. The pBIBAC-GW vectors are available with resistance to Glufosinate-ammonium or DsRed fluorescence in seed coats for selection in plants, and with resistance to kanamycin as a selection in bacteria. Here, a series of protocols is presented that guide the reader through the process of generating transgenic plants using pBIBAC-GW: starting from recombining the sequences of interest into the pBIBAC-GW vector of choice, to plant transformation with Agrobacterium, selection of the transgenics, and testing the plants for intactness and copy number of the inserts using DNA blotting. Attention is given to designing a DNA blotting strategy to recognize single- and multi-copy integrations at single and multiple loci.