The polycistronic mRNA of the Zymomonas mobilis glf-zwf-edd-glk operon is subject to complex transcript processing

Control of glycolytic flux in Zymomonas mobilis by glucose 6-phosphate dehydrogenase activity

Glycolytic genes in Zymomonas mobilis are highly expressed and constitute half of the cytoplasmic protein. The first four genes (glf, zwf, edd, glk) in this pathway form an operon encoding a glucose permease, glucose 6-phosphate dehydrogenase (G6-P dehydrogenase), 6-phosphogluconate dehydratase, and glucokinase, respectively. Each gene was overexpressed from a tac promoter to investigate the control of glycolysis during the early stages of batch fermentation when flux (qCO(2)) is highest. Almost half of flux control appears to reside with G6-P dehydrogenase (C(J) (G6-P dehydrogenase) = 0.4). Although Z. mobilis exhibits one of the highest rates of glycolysis known, recombinants with elevated G6-P dehydrogenase had a 10% to 13% higher glycolytic flux than the native organism. A small increase in flux was also observed for recombinants expressing glf. Results obtained did not allow a critical evaluation of glucokinase and this enzyme may also represent an important control point. 6-Phosphogluconate dehydratase appears to be saturating at native levels. With constructs containing the full operon, growth rate and flux were both reduced, complicating interpretations. However, results obtained were also consistent with G6-P dehydrogenase as a primary site of control. Flux was 17% higher in operon constructs which exhibited a 17% increase in G6-P dehydrogenase specific activity, relative to the average of other operon constructs which contain a frameshift mutation in zwf. It is unlikely that all flux control residues solely in G6-P dehydrogenase (calculated C(J) (G6-P dehydrogenase) = 1.0) although these results further support the importance of this enzyme. As reported in previous studies, changes in flux were not accompanied by changes in growth rate providing further evidence that ATP production does not limit biosynthesis in rich complex medium.

Transcriptomic and metabolomic profiling of Zymomonas mobilis during aerobic and anaerobic fermentations

BACKGROUND

Zymomonas mobilis ZM4 (ZM4) produces near theoretical yields of ethanol with high specific productivity and recombinant strains are able to ferment both C-5 and C-6 sugars. Z. mobilis performs best under anaerobic conditions, but is an aerotolerant organism. However, the genetic and physiological basis of ZM4's response to various stresses is understood poorly.

RESULTS

In this study, transcriptomic and metabolomic profiles for ZM4 aerobic and anaerobic fermentations were elucidated by microarray analysis and by high-performance liquid chromatography (HPLC), gas chromatography (GC) and gas chromatography-mass spectrometry (GC-MS) analyses. In the absence of oxygen, ZM4 consumed glucose more rapidly, had a higher growth rate, and ethanol was the major end-product. Greater amounts of other end-products such as acetate, lactate, and acetoin were detected under aerobic conditions and at 26 h there was only 1.7% of the amount of ethanol present aerobically as there was anaerobically. In the early exponential growth phase, significant differences in gene expression were not observed between aerobic and anaerobic conditions via microarray analysis. HPLC and GC analyses revealed minor differences in extracellular metabolite profiles at the corresponding early exponential phase time point. Differences in extracellular metabolite profiles between conditions became greater as the fermentations progressed. GC-MS analysis of stationary phase intracellular metabolites indicated that ZM4 contained lower levels of amino acids such as alanine, valine and lysine, and other metabolites like lactate, ribitol, and 4-hydroxybutanoate under anaerobic conditions relative to aerobic conditions. Stationary phase microarray analysis revealed that 166 genes were significantly differentially expressed by more than two-fold. Transcripts for Entner-Doudoroff (ED) pathway genes (glk, zwf, pgl, pgk, and eno) and gene pdc, encoding a key enzyme leading to ethanol production, were at least 30-fold more abundant under anaerobic conditions in the stationary phase based on quantitative-PCR results. We also identified differentially expressed ZM4 genes predicted by The Institute for Genomic Research (TIGR) that were not predicted in the primary annotation.

CONCLUSION

High oxygen concentrations present during Z. mobilis fermentations negatively influence fermentation performance. The maximum specific growth rates were not dramatically different between aerobic and anaerobic conditions, yet oxygen did affect the physiology of the cells leading to the buildup of metabolic byproducts that ultimately led to greater differences in transcriptomic profiles in stationary phase.

Lactococcal plasmid pNP40 encodes a novel, temperature-sensitive restriction-modification system

A novel restriction-modification system, designated LlaJI, was identified on pNP40, a naturally occurring 65-kb plasmid from Lactococcus lactis. The system comprises four adjacent similarly oriented genes that are predicted to encode two m(5)C methylases and two restriction endonucleases. The LlaJI system, when cloned into a low-copy-number vector, was shown to confer resistance against representatives of the three most common lactococcal phage species. This phage resistance phenotype was found to be strongly temperature dependent, being most effective at 19 degrees C. A functional analysis confirmed that the predicted methylase-encoding genes, llaJIM1 and llaJIM2, were both required to mediate complete methylation, while the assumed restriction enzymes, specified by llaJIR1 and llaJIR2, were both necessary for the complete restriction phenotype. A Northern blot analysis revealed that the four LlaJI genes are part of a 6-kb operon and that the relative abundance of the LlaJI-specific mRNA in the cells does not appear to contribute to the observed temperature-sensitive profile. This was substantiated by use of a LlaJI promoter-lacZ fusion, which further revealed that the LlaJI operon appears to be subject to transcriptional regulation by an as yet unidentified element(s) encoded by pNP40.

Messenger RNA stability and its role in control of gene expression in bacteria and phages

The stability of mRNA in prokaryotes depends on multiple factors and it has not yet been possible to describe the process of mRNA degradation in terms of a unique pathway. However, important advances have been made in the past 10 years with the characterization of the cis-acting RNA elements and the trans-acting cellular proteins that control mRNA decay. The trans-acting proteins are mainly four nucleases, two endo- (RNase E and RNase III) and two exonucleases (PNPase and RNase II), and poly(A) polymerase. RNase E and PNPase are found in a multienzyme complex called the degradosome. In addition to the host nucleases, phage T4 encodes a specific endonuclease called RegB. The cis-acting elements that protect mRNA from degradation are stable stem-loops at the 5' end of the transcript and terminators or REP sequences at their 3' end. The rate-limiting step in mRNA decay is usually an initial endonucleolytic cleavage that often occurs at the 5' extremity. This initial step is followed by directional 3' to 5' degradation by the two exonucleases. Several examples, reviewed here, indicate that mRNA degradation is an important step at which gene expression can be controlled. This regulation can be either global, as in the case of growth rate-dependent control, or specific, in response to changes in the environmental conditions.

Transcriptional analysis of levU operon encoding saccharolytic enzymes and two apparent genes involved in amino acid biosynthesis in Zymomonas mobilis

Extracellular levansucrase (LevU) and sucrase (InvB) are two of the three saccharolytic enzymes involved in the sucrose metabolism of Zymomonas mobilis. The levU and invB genes were clustered with a 155bp interval on the chromosome. Both genes were transcribed constitutively at the basal level and the transcription of both genes was induced significantly when sucrose was added to the medium. These genes were transcribed as a bicistronic mRNA and the expression was modulated by a single promoter, which is located upstream of the levU gene. The transcriptional initiation site was mapped to -64bp from the translation start site of levU gene. These results indicated that two genes are most likely to constitute an operon. The glk operon, which encodes four glycolytic enzymes, was located close to the levU operon on the chromosome. Two apparent ORFs (ORF3 and 4) were found at the intervening sequence located between the glk and levU operons. These ORFs were transcribed divergently and showed high homology at the amino acid level with the bacterial global regulatory protein (Lrp) and aspartate racemase.

An operon encoding three glycolytic enzymes in Lactobacillus delbrueckii subsp. bulgaricus: glyceraldehyde-3-phosphate dehydrogenase, phosphoglycerate kinase and triosephosphate isomerase

The structural genes gap, pgk and tpi encoding three glycolytic enzymes, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), 3-phosphoglycerate kinase (PGK) and triosephosphate isomerase (TPI), respectively, have been cloned and sequenced from Lactobacillus delbrueckii subsp. bulgaricus (L. bulgaricus). The genes were isolated after screening genomic sublibraries with specific gap and pgk probes obtained by PCR amplification of chromosomal DNA with degenerate primers corresponding to amino acid sequences highly conserved in GAPDHs and PGKs. Nucleotide sequencing revealed that the three genes were organized in the order gap-pgk-tpi. The translation start codons of the three genes were identified by alignment of the N-terminal sequences. These genes predicted polypeptide chains of 338, 403 and 252 amino acids for GAPDH, PGK and TPI, respectively, and they were separated by 96 bp between gap and pgk, and by only 18 bp between pgk and tpi. The codon usage in gap, pgk, tpi and three other glycolytic genes from L. bulgaricus differed, noticeably from that in other chromosomal genes. The site of transcriptional initiation was located by primer extension, and a probable promoter was identified for the gap-pgk-tpi operon. Northern hybridization of total RNA with specific probes showed two transcripts, an mRNA of 1.4 kb corresponding to the gap gene, and a less abundant mRNA of 3.4 kb corresponding to the gap-pgk-tpi cluster. The absence of a visible terminator in the 3'-end of the shorter transcript and the location of this 3'-end inside the pgk gene indicated that this shorter transcript was produced by degradation of the longer one, rather than by an early termination of transcription after the gap gene.

Gene organization and transcription of a late-expressed region of a Lactococcus lactis phage

The lactococcal phage bIL41 belongs to the small isometric-headed phages of the 936 quasi-species and is resistant to the abortive infection determined by abiB. A 10.2-kb segment from this phage, in which late transcription is initiated, has been sequenced. Thirteen open reading frames (ORFs) organized in one transcriptional unit have been identified. The location of two of them and the structural features of the proteins they code for are evocative of terminase subunits. Five other ORFs specify proteins which are highly homologous to structural proteins from the closely related phage F4-1. By comparing the phage bIL41 sequence with partial sequences available for four related phages, we were able to deduce a chimerical phage map covering the middle- and a large part of the late-expressed regions. Phages from this quasi-species differ by the insertion or deletion of either 1 to about 400 bp in noncoding regions or an entire ORF. Transcription was initiated 9 min after infection at a promoter with a -10 but no -35 consensus sequence. Synthesis of a phage activator protein was needed for initiation of transcription. A large 16-kb transcript covering all of the late-expressed region of the genome was synthesized. This transcript gave rise to smaller units. One of these units most probably resulted from a RNase E processing.

Citrate utilization gene cluster of the Lactococcus lactis biovar diacetylactis: organization and regulation of expression

The transport of citrate in Lactococcus lactis biovar diacetylactis is mediated by the citrate permease P. This polypeptide is encoded by the citP gene carried by plasmid pCIT264. In this report, we characterize the citP transcript, identify a cluster of two genes cotranscribed with citP and describe their post-transcriptional regulation. The transcriptional promoter is located 1500 nucleotides upstream of the citP gene and the transcriptional terminator is positioned next to the 3'-end of this gene. The DNA sequence was determined of the region upstream of the citP gene, including the promoter. Two partially overlapping open reading frames, citQ and citR were identified, which could encode polypeptides of 3.9 and 13 kDa respectively. These two genes, together with citP, constitute the cit cluster. Moreover, an IS-like element located between the cit promoter and the citQ open reading frame was identified. This element includes an open reading frame ORF1, which could encode a 33 kDa polypeptide. A translational fusion between the citP and a cat reporter gene showed that translation of citR and citP is coupled, and regulated by CitR. The cit mRNA was subjected to specific cleavage after addition of rifampicin to the bacterial cultures. We propose that expression of the cit cluster is controlled at the post-transcriptional level by mRNA processing at a putative complex secondary structure and by translational repression mediated by CitR.

Molecular cloning and characterization of the extracellular sucrase gene (sacC) of Zymomonas mobilis

The Zymomonas mobilis gene sacC that encodes the extracellular sucrase (protein B46) was cloned and expressed in Escherichia coli. The gene was found to be present downstream to the already described levansucrase gene sacB in the cloned chromosomal fragment of Z. mobilis. The expression product was different from SacB and exhibited sucrase but not levansucrase activity; therefore, SacC behaves like a true sucrase. Expression of sacC in E. coli JM109 and XL1 was very low; overexpression was observed in E. coli BL21 after induction of the T7 polymerase expression system with IPTG. Subcellular fractionation of the E. coli clone carrying plasmid pLSS2811 showed that more than 70% of the sucrase activity could be detected in the cytoplasmic fraction, suggesting that the enzyme was soluble and not secreted in E. coli. The nucleotide sequence analysis of sacC revealed an open reading frame 1239bp long coding for a 413 amino acid protein with a molecular mass of 46 kDa. The first 30 deduced amino acids from this ORF were identical with those from the N-terminal sequence of the extracellular sucrase (protein B46) purified from Z. mobilis ZM4. No leader peptide sequence could be identified in the sacC gene. The amino acid sequence of SacC showed very little similarity to those of other known sucrases, but was very similar to the levansucrases of Z. mobilis (61.5%), Erwinia amylovora (40.2%) and Bacillus subtilis (25.6%).

The groESL operon of Agrobacterium tumefaciens: evidence for heat shock-dependent mRNA cleavage

The heat shock response of the groESL operon of Agrobacterium tumefaciens was studied at the RNA level. The operon was found to be activated under heat shock conditions and transcribed as a polycistronic mRNA that contains the groES and groEL genes. After activation, the polycistronic mRNA appeared to be cleaved between the groES and groEL genes and formed two monocistronic mRNAs. The groES cleavage product appeared to be unstable and subjected to degradation, while the groEL cleavage product appeared to be stable and became the major mRNA representing the groESL operon after long periods of growth at a high temperature. The polycistronic mRNA containing the groES and groEL genes was the major mRNA representing the groESL operon at a low temperature, and it reappeared when the cells were returned to the lower growth temperature after heat shock induction. These findings indicate that the cleavage event is part of the heat shock regulation of the groESL operon in A. tumefaciens.

In vivo restriction by LlaI is encoded by three genes, arranged in an operon with llaIM, on the conjugative Lactococcus plasmid pTR2030

The LlaI restriction and modification (R/M) system is encoded on pTR2030, a 46.2-kb conjugative plasmid from Lactococcus lactis. The llaI methylase gene, sequenced previously, encodes a functional type IIS methylase and is located approximately 5 kb upstream from the abiA gene, encoding abortive phage resistance. In this study, the sequence of the region between llaIM and abiA was determined and revealed four consecutive open reading frames (ORFs). Northern (RNA) analysis showed that the four ORFs were part of a 7-kb operon with llaIM and the downstream abiA gene on a separate transcriptional unit. The deduced protein sequence of ORF2 revealed a P-loop consensus motif for ATP/GTP-binding sites and a three-part consensus motif for GTP-binding proteins. Data bank searches with the deduced protein sequences for all four ORFs revealed no homology except for ORF2 with MerB, in three regions that coincided with the GTP-binding motifs in both proteins. To phenotypically analyze the llaI operon, a 9.0-kb fragment was cloned into a high-copy-number lactococcal shuttle vector, pTRKH2. The resulting construct, pTRK370, exhibited a significantly higher level of in vivo restriction and modification in L. lactis NCK203 than the low-copy-number parental plasmid, pTR2030. A combination of deletion constructions and frameshift mutations indicated that the first three ORFs were involved in LlaI restriction, and they were therefore designated llaI.1, llaI.2, and llaI.3. Mutating llaI.1 completely abolished restriction, while disrupting llaI.2 or llaI.3 allowed an inefficient restriction of phage DNA to occur, manifested primarily by a variable plaque phenotype. ORF4 had no discernible effect on in vivo restriction. A frameshift mutation in llaIM proved lethal to L. lactis NCK203, implying that the restriction component was active without the modification subunit. These results suggested that the LlaI R/M system is unlike any other R/M system studied to date and has diverged from the type IIS class of restriction enzymes by acquiring some characteristics reminiscent of type I enzymes.

Cloning, sequencing, and expression of the Zymomonas mobilis phosphoglycerate mutase gene (pgm) in Escherichia coli

Phosphoglycerate mutase is an essential glycolytic enzyme for Zymomonas mobilis, catalyzing the reversible interconversion of 3-phosphoglycerate and 2-phosphoglycerate. The pgm gene encoding this enzyme was cloned on a 5.2-kbp DNA fragment and expressed in Escherichia coli. Recombinants were identified by using antibodies directed against purified Z. mobilis phosphoglycerate mutase. The pgm gene contains a canonical ribosome-binding site, a biased pattern of codon usage, a long upstream untranslated region, and four promoters which share sequence homology. Interestingly, adhA and a D-specific 2-hydroxyacid dehydrogenase were found on the same DNA fragment and appear to form a cluster of genes which function in central metabolism. The translated sequence for Z. mobilis pgm was in full agreement with the 40 N-terminal amino acid residues determined by protein sequencing. The primary structure of the translated sequence is highly conserved (52 to 60% identity with other phosphoglycerate mutases) and also shares extensive homology with bisphosphoglycerate mutases (51 to 59% identity). Since Southern blots indicated the presence of only a single copy of pgm in the Z. mobilis chromosome, it is likely that the cloned pgm gene functions to provide both activities. Z. mobilis phosphoglycerate mutase is unusual in that it lacks the flexible tail and lysines at the carboxy terminus which are present in the enzyme isolated from all other organisms examined.

Molecular characterization of the Zymomonas mobilis enolase (eno) gene

The Zymomonas mobilis gene encoding enolase was cloned by genetic complementation of an Escherichia coli eno mutant. An enzyme assay and sodium dodecyl sulfate-polyacrylamide gel electrophoresis confirmed the overexpression of enolase in E. coli clones carrying the Z. mobilis eno gene. The eno gene is present in a single copy of the Z. mobilis genome. Nucleotide sequence analysis of the eno region revealed an open reading frame of 1,293 bp that encodes a protein of 428 amino acids with a predicted molecular weight of 45,813. Comparison of the sequence of Z. mobilis enolase with primary amino acid sequences for other enolases indicates that the enzyme is highly conserved. Unlike all of the previously studied glycolytic genes from Z. mobilis that possess canonical ribosome binding sites, the eno gene is preceded by a modest Shine-Dalgarno sequence. The transcription initiation site was mapped by primer extension and found to be located within a 115-bp sequence that is 55.7% identical to a highly conserved consensus sequence found within the regulatory regions of highly expressed Z. mobilis genes. Northern RNA blot analysis revealed that eno is encoded on a 1.45-kb transcript. The half-life of the eno mRNA was determined to be 17.7 +/- 1.7 min, indicating that it is unusually stable. The abundance of the eno message is proposed to account for enolase being the most prevalent protein in Z. mobilis.

The Entner-Doudoroff pathway: history, physiology and molecular biology

The Entner-Doudoroff pathway is now known to be very widely distributed in nature. Biochemical and physiological studies show that the Entner-Doudoroff pathway can operate in a linear and catabolic mode, in a 'cyclic' mode, in a modified mode involving non-phosphorylated intermediates, or in alternative modes involving C1 metabolism and anabolism. Molecular and genetic analyses of the Entner-Doudoroff pathway in Zymomonas mobilis, Escherichia coli and Pseudomonas aeruginosa have led to an improved understanding of some fundamental aspects of metabolic controls. It can be argued that the Entner-Doudoroff pathway is more primitive than Embden-Meyerhof-Parnas glycolysis.

The Zymomonas mobilis glf, zwf, edd, and glk genes form an operon: localization of the promoter and identification of a conserved sequence in the regulatory region

The Zymomonas mobilis genes that encode the glucose-facilitated diffusion transporter (glf), glucose-6-phosphate dehydrogenase (zwf), 6-phosphogluconate dehydratase (edd), and glucokinase (glk) are clustered on the genome. The data presented here firmly establish that the glf, zwf, edd, and glk genes form an operon, in that order. The four genes of the operon are cotranscribed on a 6.14-kb mRNA. The site of transcriptional initiation for the polycistronic message was mapped by primer extension and nuclease S1 protection analysis. The glf operon promoter region showed significant homology to other highly expressed Z. mobilis promoters, but not to consensus promoters from other bacteria. The highly expressed Z. mobilis promoter set contains two independent, overlapping, conserved sequences that extend from approximately bp -100 to +15 with respect to the transcriptional start sites. Expression of the glf operon was shown to be subject to carbon source-dependent regulation. The mRNA level was threefold higher in cells grown on fructose than in cells grown on glucose. This increase was not the result of differential mRNA processing when cells were grown on the different carbon sources, nor was it the result of differential transcript stability. Degradation of the 6.14-kb glf operon mRNA was biphasic, with initial half-lives of 11.5 min in fructose-grown cells and 12.0 min in glucose-grown cells. Thus, the higher level of glf operon mRNA in fructose-grown cells is the result of an increased rate of transcription. The importance of increasing glf expression in cells growing on fructose is discussed.