Regulation of
            <scp>d</scp>
            -Xylose Metabolism in
            <i>Caulobacter crescentus</i>
            by a LacI-Type Repressor

Stephens, Craig; Christen, Beat; Watanabe, Kelly; Fuchs, Thomas; Jenal, Urs

doi:10.1128/jb.01342-07

Cited by 39 publications

(40 citation statements)

References 28 publications

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“…Second, although induction of lac expression and dehydrogenase activity is clearly observable in C. crescentus, the level of induction appears modest in comparison to other metabolic systems, both in other bacteria and in C. crescentus, including that used for xylose catabolism (the xyl system) (25,42,53). Poindexter (48) has noted that, for the majority of sugar substrates, the quantitative response of the Caulobacter cell to the sudden availability of a new substrate is not impressive and has suggested that, in dilute environments where a nutrient is likely to be available for only a short time at irregular intervals, dramatic shifts to dedicated pathways may be maladaptive; low-level maintenance of different catabolic systems at all times would be more advantageous.…”

Section: Discussionmentioning

confidence: 99%

Identification of a Dehydrogenase Required for Lactose Metabolism inCaulobacter crescentus

Arellano

Ortiz

Manzano

et al. 2010

Appl Environ Microbiol

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Caulobacter crescentus, which thrives in freshwater environments with low nutrient levels, serves as a model system for studying bacterial cell cycle regulation and organelle development. We examined its ability to utilize lactose (i) to gain insight into the metabolic capacities of oligotrophic bacteria and (ii) to obtain an additional genetic tool for studying this model organism, aiming to eliminate the basal enzymatic activity that hydrolyzes the chromogenic substrate 5-bromo-4-chloro-3-indolyl-␤-D-galactopyranoside (X-gal). Using a previously isolated transposon mutant, we identified a gene, lacA, that is required for growth on lactose as the sole carbon source and for turning colonies blue in the presence of X-gal. LacA, which contains a glucose-methanol-choline (GMC) oxidoreductase domain, has homology to the flavin subunit of Pectobacterium cypripedii's gluconate dehydrogenase. Sequence comparisons indicated that two genes near lacA, lacB and lacC, encode the other subunits of the membrane-bound dehydrogenase. In addition to lactose, all three lac genes are involved in the catabolism of three other ␤-galactosides (lactulose, lactitol, and methyl-␤-D-galactoside) and two glucosides (salicin and trehalose). Dehydrogenase assays confirmed that the lac gene products oxidize lactose, salicin, and trehalose. This enzymatic activity is inducible, and increased lac expression in the presence of lactose and salicin likely contributes to the induction. Expression of lacA also depends on the presence of the lac genes, implying that the dehydrogenase participates in induction. The involvement of a dehydrogenase suggests that degradation of lactose and other sugars in C. crescentus may resemble a proposed pathway in Agrobacterium tumefaciens.Caulobacter species inhabit diverse aquatic and soil environments, their ubiquitous distribution reflecting an ability to prosper despite low nutrient levels (47, 48). Unraveling the physiological adaptations that enable these aerobic chemoheterotrophs to thrive under nutrient-poor conditions will facilitate interpretation of microbial activities in oligotrophic environments, such as water bodies (which make up the majority of the earth's surface). Recent studies of Caulobacter have led to novel findings regarding the uptake and catabolism of various carbon sources (6,14,38,44,52). In addition, one particular member of the group, Caulobacter crescentus, has emerged as a prominent model for the study of bacterial cell cycle progression, asymmetric cell division, and organelle development (7,8,34,49). Although factors that regulate the C. crescentus cell cycle appear to respond to changes in metabolic states (3,22,35), details of the connection remain nebulous. Investigation of C. crescentus's metabolic capabilities can improve understanding of bacterial cell cycle control as well as the biogeochemical contributions of oligotrophs.We initiated an examination of C. crescentus's ability to utilize lactose for two reasons. (i) C. crescentus cells predominantly dwell in freshwater pond...

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Section: Discussionmentioning

confidence: 99%

Identification of a Dehydrogenase Required for Lactose Metabolism inCaulobacter crescentus

Arellano

Ortiz

Manzano

et al. 2010

Appl Environ Microbiol

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“…Among the latter, the lac promoter of Escherichia coli, as well as its mutant and hybrid forms lacUV5 (6), Ptac (10), and Ptrc (4), have been extensively exploited in combination with its control protein, LacI. In addition, other regulatory elements have been developed and are widely used, including the arabinose promoter of E. coli (19), the xylene (xyl) promoter of Pseudomonas putida (35), and the xylose (xyl) promoter of Caulobacter crescentus (48).…”

mentioning

confidence: 99%

Broad-Host-Range Expression Vectors with Tightly Regulated Promoters and Their Use To Examine the Influence of TraR and TraM Expression on Ti Plasmid Quorum Sensing

Khan

Gaines

Roop

et al. 2008

Appl Environ Microbiol

306

267

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Experiments requiring strong repression and precise control of cloned genes can be difficult to conduct because of the relatively high basal level of expression of currently employed promoters. We report the construction of a family of vectors that contain a reengineered lacI q -lac promoter-operator complex in which cloned genes are strongly repressed in the absence of inducer. The vectors, all based on the broad-host-range plasmid pBBR1, are mobilizable and stably replicate at moderate copy number in representatives of the alphaand gammaproteobacteria. Each vector contains a versatile multiple cloning site that includes an NdeI site allowing fusion of the cloned gene to the initiation codon of lacZ␣. In each tested bacterium, a uidA reporter fused to the promoter was not expressed at a detectable level in the absence of induction but was inducible by 10-to 100-fold, depending on the bacterium. The degree of induction was controllable by varying the concentration of inducer. When the vector was tested in Agrobacterium tumefaciens, a cloned copy of the traR gene, the product of which is needed at only a few copies per cell, did not confer activity under noninducing conditions. We used this attribute of very tight and variably regulatable control to assess the relative amounts of TraR required to activate the Ti plasmid conjugative transfer system. We identified levels of induction that gave wild-type transfer frequencies, as well as levels that induced correspondingly lower frequencies of transfer. We also used this system to show that the antiactivator TraM sets the level of intracellular TraR required for tra gene activation.

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“…For example, transcriptome analysis of C. crescentus metabolizing xylose revealed induction of xylanases and arabinosidases, putative outer and inner-membrane transporters, and a pathway for oxidative metabolism of xylose [11,12]. The xylose regulon is under the control of XylR, a member of the LacI family of bacterial transcription factors [13]. Our results reveal an analogous galacturonate regulon in C. crescentus that is under the control of another LacI family member, HumR.…”

Section: Introductionmentioning

confidence: 67%

Regulation of D-galacturonate metabolism in <i>Caulobacter crescentus</i> by HumR, a LacI-family transcriptional repressor

Sheikh¹,

Caswell²,

Dick³

et al. 2013

ABB

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The oligotrophic freshwater bacterium Caulobacter crescentus encodes a cluster of genes (CC_1487 to CC_1495) shown here to be necessary for metabolism of D-galacturonate, the primary constituent of pectin, a major plant polymer. Sequence analysis suggests that these genes encode a version of the bacterial hexuronate isomerase pathway. A conserved 14 bp sequence motif is associated with promoter regions of three operons within this cluster, and is conserved in homologous gene clusters in related alpha-Proteobacteria. Embedded in the hexuronate gene cluster is a gene (CC_1489) encoding a member of the LacI family of bacterial transcription factors. This gene product, designated here as HumR (hexuronate metabolism regulator), represses expression of the uxaA and uxaC operon promoters by binding to the conserved operator sequence. Repression is relieved in the presence of galacturonate or, to a lesser extent, by glucuronate. Other genes potentially involved in pectin degradation and hexuronate transport are also under the control of HumR. Adoption of a LacI-type repressor to control hexuronate metabolism parallels the regulation of xylose, glucose, and maltose utilization in C. crescentus, but is distinct from the use of GntRtype repressors to control pectin and hexuronate utilization in gamma-Proteobacteria such as Escherichia coli.

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Regulation of d -Xylose Metabolism in Caulobacter crescentus by a LacI-Type Repressor

Cited by 39 publications

References 28 publications

Identification of a Dehydrogenase Required for Lactose Metabolism inCaulobacter crescentus

Identification of a Dehydrogenase Required for Lactose Metabolism inCaulobacter crescentus

Broad-Host-Range Expression Vectors with Tightly Regulated Promoters and Their Use To Examine the Influence of TraR and TraM Expression on Ti Plasmid Quorum Sensing

Regulation of D-galacturonate metabolism in <i>Caulobacter crescentus</i> by HumR, a LacI-family transcriptional repressor

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Regulation of d -Xylose Metabolism in Caulobacter crescentus by a LacI-Type Repressor

Cited by 39 publications

References 28 publications

Identification of a Dehydrogenase Required for Lactose Metabolism inCaulobacter crescentus

Identification of a Dehydrogenase Required for Lactose Metabolism inCaulobacter crescentus

Broad-Host-Range Expression Vectors with Tightly Regulated Promoters and Their Use To Examine the Influence of TraR and TraM Expression on Ti Plasmid Quorum Sensing

Regulation of D-galacturonate metabolism in &lt;i&gt;Caulobacter crescentus&lt;/i&gt; by HumR, a LacI-family transcriptional repressor

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Regulation of D-galacturonate metabolism in <i>Caulobacter crescentus</i> by HumR, a LacI-family transcriptional repressor