©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Identification of the Repressor Subdomain within the Signal Reception Module of the Prokaryotic Enhancer-binding Protein XylR of Pseudomonas putida(*)

(Received for publication, October 25, 1995; and in revised form, January 16, 1996)

José Pérez-Martín Víctor de Lorenzo (§)

From the Centro de Investigaciones Biológicas, Consejo Superior de Investigaciones Científicas, Velázquez 144, 28006 Madrid, Spain

ABSTRACT
FOOTNOTES
REFERENCES

ABSTRACT

In the presence of m-xylene, the protein XylR encoded by the TOL plasmid of Pseudomonas putida, activates the -dependent promoter Pu. Early activation stages involve the release of the intramolecular repression caused by the signal reception N-terminal (A domain) of XylR on the central module of the protein. A genetic approach has been followed to locate the specific segment within A domain of XylR that is directly responsible for its down-regulation in the absence of inducer, as compared to that involved in effector (m-xylene) binding. For this, a reporter Escherichia coli strain carrying a monocopy transcriptional fusion of Pu to lacZ was transformed with a collection of plasmids encoding equivalent truncated varieties of XylR, consisting of nested and internal deletions throughout the entire A domain. Examination of the resulting phenotypes allowed the assignment of the A domain region near the central activation domain, as the portion of the protein responsible for the specific repression of XylR activity in the absence of m-xylene.

Strains of the genus Pseudomonas harboring the TOL plasmid pWW0 can grow on toluene, m-xylene, and p-xylene as the only carbon source owing to the activity of a complex catabolic pathway (summarized in Fig. 1) that proceeds in two major biochemical steps (Nakazawa et al., 1990). These are determined by two independent operons that become coordinately transcribed when bacteria face pathway substrates such as m-xylene (see Marqués and Ramos(1993) for a review). The main regulator of the system is the so-called XylR protein, a member of the family of prokaryotic enhancer-binding regulators that act in concert with the alternative factor (Morett and Segovia, 1993; North et al., 1993). In the presence of xylenes, XylR bound to upstream sequences activates the Pu promoter of the upper-TOL operon, thus triggering expression of the corresponding catabolic genes (de Lorenzo et al., 1991; Abril et al., 1991). The very early chain of events that translates the presence of xylenes into activation of Pu, involve effector-mediated conversion of XylR into a transcriptionally competent form. For this, the inducer binds directly to the N-terminal, signal reception module of XylR termed the A domain (Delgado and Ramos, 1994; Fernández et al., 1995; see Fig. 1) and triggers the release of the repression caused by this domain on the central portion of the protein that is involved in the contact and activation of the -containing RNA polymerase (Pérez-Martín and de Lorenzo, 1995). This notion is based on the observation that deleting the entire A domain of XylR gives rise to a truncated protein that activates constitutively Pu in the absence of aromatic effectors, both in vivo (Fernández et al., 1995) and in vitro (Pérez-Martín and de Lorenzo, 1996). It seems, therefore, that the A domain of XylR has at least two functions: (a) recognition of the aromatic inducers and (b) intramolecular repression. Since these two are obviously connected, the question arises as whether discrete subdomains within the N-terminal module can be assigned to each of them.


Figure 1: The TOL system of plasmid pWW0 and domain organization of XylR. The TOL system for degradation of toluene and m-/p-xylene includes two gene clusters, the upper-operon and the meta-operon, as well as two regulatory genes, xylS and xylR, downstream of the meta-operon. The -dependent promoters Pu and Ps (underlined) are activated by the cognate activator XylR in the presence of m-xylene, while the Pm promoter is activated by XylS in the presence of benzoate or toluates. Functional domains of XylR are shown expanded, with an indication of the amino acid positions corresponding to the boundaries of each domain (Inouye et al., 1988; Shingler, 1996). These include a signal reception N-terminal module (A domain), the central (C) activation domain, and the C-terminal segment (D domain) containing a helix-turn-helix (HTH) motif for DNA binding. The lower part of the figure sketches the strategy used to amplify with the polymerase chain reaction (PCR) specific DNA segments corresponding to different portions of the XylR protein for expression of truncated variants of the A domain. These include N-terminal deleted or internally truncated proteins (see legends to Fig. 2and Fig. 3).




Figure 2: Effect of sequential N-terminal deletions through the A domain in the transcriptional activity of XylR. The activity of the N-terminal truncated derivatives of the A module of XylR (211 amino acids, Fig. 1) indicated in the figure was monitored as accumulation of beta-galactosidase in the E. coli strain RSPu, that carried a chromosomal Pu-lacZ fusion. For construction and expression of each of the truncated proteins, the following strategy was pursued. A DNA fragment containing the wild-type xylR sequence was subjected to a PCR reaction using as direct primers (Fig. 1) various oligonucleotides (33-mers) that attached an EcoRI site to the left of the site of deletion desired. For the reverse priming of the reaction, the same oligonucleotide was used in all cases, that generated a BamHI site following the STOP codon of the xylR sequence, TAG. The amplified products were cloned as EcoRI-BamHI fragments of different sizes at the same sites of vector pPr. This is a derivative of pCG1 (Myers et al., 1987) in which the native Pr promoter of xylR within the TOL plasmid (Fig. 1) has been engineered in front of the same polylinker as pTrc99A (Amman et al., 1988), that is led by an NcoI site overlapping a first structural ATG. This allowed all truncated proteins to be expressed through the very same native promoter and translation initiation regions as the wild-type xylR. The use of the direct EcoRI primers in the PCR reaction introduced in all cases amino acid residues EF (corresponding to 5`-GAA TTC-3`), next to the leading methionine of the truncated products. Replacement of the second (Ser) and third (Leu) amino acid residue of the wild-type XylR protein by EF had no effect on protein activity (not shown). For the experiment of the figure, each of the E. coli RSPu transformants were grown in LB medium (Miller, 1972) at 30 °C up to an A = 0.5, after which they were exposed, as indicated, to saturating vapors of m-xylene. Accumulation of beta-galactosidase (Miller, 1972) was then measured after 5 h of induction. The figures for the reporter product are indicated with respect to the site of the deletions corresponding to each truncated regulator. The values shown are the average of 3 independent experiments carried out with duplicate samples. The approximate location of the repression subdomain suggested by the results is indicated on top.




Figure 3: Phenotypes endowed by internal truncations of the A domain of XylR. The ability of xylR alleles carrying the internal deletions within the A domain indicated in the figure was examined as for the sequential N-terminal deletions (Fig. 2). The strategy to generate the internally truncated proteins involved the production by PCR of two restriction fragments that were sequentially assembled in vector pPr (see legend to Fig. 2). The ``left'' restriction fragments (flanked by EcoRI-XbaI sites) were produced by amplifying the desired part of the A domain sequence with a direct EcoRI primer and a reverse XbaI primer (Fig. 1). The ``right'' restriction fragments were similarly produced with a direct XbaI primer, targeted to the site of interest within the sequence of the A domain, and a reverse BamHI primer at the end of the xylR sequence (Fig. 1). Their assembly downstream of the Pr promoter in pPr gave rise to the truncated proteins under examination. Accumulation of beta-galactosidase by each of the reporter strains, transformed with the corresponding plasmids, was examined as described in the legend to Fig. 2. The hatched portion of the A module shows the position of the repression subdomain.



To explore the presence and the location of specific portions within the A module of XylR that are accountable for the central domain repression, we chose a reporter system in which the effect of changes in the regulator could be related immediately to a distinct phenotype in activation of Pu. Since all transcriptional control elements can be faithfully reproduced in Escherichia coli, this reporter system employs a derivative of E. coli YMC10 that had been lysogenized with an specialized phage containing a transcriptional Pu-lacZ fusion (Pérez-Martín and de Lorenzo, 1995). This strain (E. coli RSPu) was transformed independently with each one of a collection of plasmids bearing truncated xylR alleles that differed only in A domain sequences (Fig. 1). These were generated with a polymerase chain reaction-based strategy (PCR) (^1)described in the legends of Fig. 2and Fig. 3. The activity of the truncated products expressed in trans was measured as the accumulation in vivo of beta-galactosidase in the presence or absence of the XylR effector m-xylene. Simultaneously to each activity assay, we examined the level of expression of each XylR-derived protein through Western blot assays (Fernández et al., 1995) to ensure that the proteins were produced at similar levels (not shown).

To have a preliminary indication on the portion of the A domain of XylR involved in intramolecular repression, we sought to divide the A domain (211 amino acids, Inouye et al.(1988) and Shingler et al.(1993); see Fig. 2) in 6 large segments, that were progressively deleted from the N terminus (Fig. 2). These deletions were generated by amplifying with PCR the sequences of interest with an adequate collection of primers, so that the resulting products were flanked by EcoRI and BamHI sites as specified in the legend to Fig. 1. Transfer of the resulting DNA fragments to the specialized expression vector pPr (Pérez-Martín and de Lorenzo(1995); see legend to Fig. 2) provided a translation initiation sequence and a leading ATG for expression of the six xylR deletion alleles shown in Fig. 2. These were named, respectively, Delta30, Delta120, Delta150, Delta180, Delta210, and Delta226. The corresponding proteins were produced in vivo at levels comparable to those of the wild-type XylR with the same expression system, as assessed by Western blot, and they were equally able to shut down expression of the Pr promoter of the xylR gene in an in vivo autorepression assay (Fernández et al. (1995); not shown). These experiments verified that the proteins were expressed at similar levels and that they were efficiently able to bind DNA. Intermediate deletions between positions 30 and 120 neither produced any detectable protein nor gave positive in an autorepression assay, and, thus, they were not further considered (not shown). The six productive deletions displayed very distinct phenotypes when the corresponding plasmids were transformed in the Pu-lacZ E. coli reporter strain (Fig. 2). While truncation of the 30 leading amino acids (XylRDelta30) gave rise to a protein with only a residual responsiveness to the XylR inducer, m-xylene (Fig. 2), subsequent removal of the protein segment up to position 120 (XylRDelta120) and beyond (XylRDelta150) gave rise to proteins unable to activate the Pu promoter to any significant extent. However, deletion of 30 additional amino acids (XylRDelta180) partially restored the ability of the protein to promote transcription (Fig. 2), although responsiveness to m-xylene was lost and the activity became constitutive. Deletion of 30 additional amino acids (XylRDelta210), which removed the A domain entirely, increased beta-galactosidase accumulation to its highest level. Further deletions entering the Q-linker (XylRDelta226) did not result in an additional increase of promoter activity, while deletions beyond position 233, entering into the central C domain (Fig. 1), abolished any transcriptional activity of the resulting truncated proteins (not shown).

The results above confirmed the existence of a specific region within the A domain of XylR directly involved in intramolecular repression located between amino acid positions 150 and 210. To narrow down the location of the boundary, we made two additional deletions in 10-amino acid increments called XylRDelta160 and XylRDelta170. As shown in Fig. 2, while Delta160 remained inactive, Delta170 gave a substantial, but not full, constitutive activation of Pu, as compared to the maximum promoter activation caused by the deletion of the entire A domain (XylRDelta210, XylRDelta226). These results located the leftward limit of the repressor subdomain at around amino acid position 170, and, therefore, the whole functional module may span no more than 40 residues (or 60, if we also include some amino acids present at the hinge B domain, Fig. 1).

To verify the location of the repressor segment of the A domain suggested by the phenotypes caused by the N-terminal deletions, we constructed additional xylR alleles bearing sequential truncations of the A domain starting in position 210 (i.e. at the C-terminal end of the module) and spanning increasingly larger segments toward the N-terminal end (see legend of Fig. 3for the procedure employed for their construction). As before, production in vivo of the predicted mutant proteins was verified through autorepression assays and Western blot of the corresponding cell extracts (not shown). The phenotypes endowed by each of the constructions listed in Fig. 3were examined as before with the results summarized in Fig. 3. As expected, deletions spanning large portions of the A domain (Delta60/210, Delta120/210, and Delta150/210) originated truncated proteins that were fully constitutive. It was most remarkable, however, that deletions Delta160/210, Delta180/210, and Delta190/210 (that are totally or partially deleted of the repressor subdomain), although capable of activating transcription in the absence of inducer, maintained a significant degree of responsiveness to m-xylene. Such responsiveness was lost when the leading N terminus was deleted also (truncation Delta30-Delta190/210). This suggested that such a leading region is involved in effector recognition, lifting of intramolecular repression, or both. Since deletions Delta160/210, Delta180/210, and Delta190/210 are predicted to offset considerably the relative positioning of the remaining A sequence with respect to the central domain of the protein, the regulation by m-xylene retained by these proteins indicated that effector binding and associated changes in protein structure do not involve per se specific interdomain interactions. In addition, simultaneous deletion of the segment 190-210 and the leading 30 amino acids gave rise to a constitutive low activity regulator (Fig. 3), that may reflect the need of an intact N terminus for any responsiveness to the effector. Specific repression seems, therefore, to be due exclusively to the portion of the A domain encompassing positions 160 to 226. Furthermore, the fact that the internal deletion Delta160/185 (that lacks the leftmost boundary of the repressor subdomain with the rest of the protein) is virtually inactive (Fig. 3) suggested that the protein segments determining the response to effector recognition may be connected to each other close to positions 160-170. In fact, deletion of the zone around 170 seems to originate a protein that is inhibited unspecifically by the remainder of the A domain (see below). Interestingly, Delgado and Ramos(1994) found that a mutation in residue 172 made the protein to respond to a new effector (m-nitrotoluene), thus indicating that some direct or indirect determinants of ligand specificity may lie also around position 170.

The semiconstitutive phenotype of deletions Delta160/210, Delta180/210, and Delta190/210 (Fig. 3) indicated also that elimination of the repressor subdomain still affords a degree of down-regulation of XylR by the remainder of the A module. This phenomenon can be easily understood in light of the observations reported elsewhere (Fernández et al., 1995) on the inactivation of XylR through substitution of its A domain by a bulky heterologous protein module. On this basis, it is very likely that although deletions Delta160/210, Delta180/210, and Delta190/210 have lost the specific region involved in intramolecular repression, they still retain a portion of the protein that inhibits its full activity in the absence of inducer by a mere physical hindrance of an activation surface and not because of an specific interdomain interaction. The same argument explains the phenotype of the deletion Delta160/185 (Fig. 3), that is virtually inactive in vivo in spite of having lost a protein segment that enters a region involved in specific intramolecular repression (see above). In this case, the lower activity of Delta160/185 (Fig. 3) as compared to Delta180 (Fig. 2) is the likely result of the steric hindrance caused by the remainder of the A domain present in the truncated protein.

Taken together, these results led to the conclusion that a protein segment as short at 40-50 amino acids fully accounts for the repression caused by the whole A domain on XylR in the absence of m-xylene. Our data are consistent also with the notion that only that portion of the A module maintains specific interactions with the central domain of the protein. In addition, the phenotypes originated by the internally truncated proteins (Fig. 3) suggest that the XylR portion involved in effector recognition may exist as a separate subdomain within the N-terminal module. Prediction of secondary structure within the region carried out with the PHD profile network method (Burkhard and Sander, 1993) indicated that amino acids 219 to 221 could be organized as a somewhat long (21 residues) alpha-helix. Interestingly, when compared to the library of protein crystal coordinates of the Brookhaven data bank, part of that alpha-helix and a few preceding residues (portion 204-222 of the A domain) bear significant resemblance to the region of the eukaryotic protein c-Fos (residues 168 to 186) that is involved in protein-protein interactions within a c-Fos/c-Jun/DNA co-crystal (Brookhaven ID code: 1FOS). This structural resemblance might be related to the specific interactions between the A domain and the central domain of XylR proposed to control the activity of the regulator (Pérez-Martín and de Lorenzo, 1995). On the contrary, no portion of the 160-220 region of XylR showed any structural similarity to the N-terminal domain of DctD, another member of the family of -dependent regulators whose activity is regulated through intramolecular repression as well (Gu et al., 1994).

The A domain of XylR is the key component of this activator that endows specificity in the response to m-xylene (Delgado and Ramos, 1994; Shingler and Moore, 1994), so that direct effector binding is translated into release of intramolecular repression (Delgado et al., 1995; Pérez-Martín and de Lorenzo, 1995). Although the precise mechanism by which this happens remains unsolved, the data presented in this work suggest that different portions of the A domain have specific roles in the process. It is possible that, similarly to what may happen to NtrC (Fiedler and Weiss, 1995), derepression could involve the dimerization of the N-terminal module in response to the reception of the activating signal. The different predictions raised by this hypothesis and other alternatives are currently under study in our laboratory.


FOOTNOTES

*
This work was supported by Grant BIO95-0788 of the Spanish Comisión Interministerial de Ciencia y Tecnología (CICYT) and Contract BIOTECH BIO2-CT92-0084 of the European Union. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed. Present address: Centro Nacional de Biotecnología-CSIC, Campus de Cantoblanco, 28049 Madrid, Spain. vdlorenzo{at}samba.cnb.uam.es.

(^1)
The abbreviation used is: PCR, polymerase chain reaction.


REFERENCES

  1. Abril, M. A., Buck, M., and Ramos, J. L. (1991) J. Biol. Chem. 266, 15832-15838 [Abstract/Free Full Text]
  2. Amann, E., Ochs, B., and Abel, K. J. (1988) Gene (Amst.) 69, 301-315 [CrossRef][Medline] [Order article via Infotrieve]
  3. Burkhard, R., and Sander, C. (1993) J. Mol. Biol. 232, 584-599 [CrossRef][Medline] [Order article via Infotrieve]
  4. Delgado, A., and Ramos, J. L. (1994) J. Biol. Chem. 269, 8059-8062 [Abstract/Free Full Text]
  5. Delgado, A., Salto, R., Marqués, S., and Ramos, J. L. (1995) J. Biol. Chem. 270, 5144-5150 [Abstract/Free Full Text]
  6. de Lorenzo, V., Herrero, M., Metzke, M., and Timmis, K. N. (1991) EMBO J. 10, 1159-1167 [Abstract]
  7. Fernández, S., de Lorenzo, V., and Pérez-Martín, J. (1995) Mol. Microbiol. 16, 205-213 [Medline] [Order article via Infotrieve]
  8. Fiedler, U., and Weiss, V. (1995) EMBO J. 14, 3696-3705 [Abstract]
  9. Gu, B., Lee, J. H., Hoover, T. R., Scholl, D., and Nixon, B. T. (1994) Mol. Microbiol. 13, 51-56 [Medline] [Order article via Infotrieve]
  10. Inouye, S., Nakazawa, A., and Nakazawa, T. (1988) Gene (Amst.) 66, 301-306 [CrossRef][Medline] [Order article via Infotrieve]
  11. Marqués, S., and Ramos, J. L. (1993) Mol. Microbiol. 9, 923-929
  12. Miller, J. H. (1972) Experiments in Molecular Genetics , Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
  13. Morett, E., and Segovia, L. (1993) J. Bacteriol. 175, 6067-6074 [Medline] [Order article via Infotrieve]
  14. Myers, R., Maniatis, T., and Lerman, L. (1987) Methods Enzymol. 155, 501-527
  15. Nakazawa, T., Inouye, S., and Nakazawa, A. (1990) in Pseudomonas: Biotransformations, Pathogenesis and Evolving Bio/Technology (Silver, S., Chakrabarty, A., Iglewski, B., and Kaplan, S., eds) pp. 133-140, American Society of Microbiology, Washington, D. C.
  16. North, A. K., Klose, K. E., Stedman, K. M., and Kustu, S. (1993) J. Bacteriol. 175, 4267-4273 [Medline] [Order article via Infotrieve]
  17. Pérez-Martín, J., and de Lorenzo, V. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 9392-9396 [Abstract]
  18. P é rez-Mart í n, J., and de Lorenzo, V. (1996) J. Mol. Biol. , in press
  19. Shingler, V. (1996) Mol. Microbiol. 19, 409-416 [Medline] [Order article via Infotrieve]
  20. Shingler, V., and Moore, T. (1994) J. Bacteriol. 176, 1555-1560 [Abstract]
  21. Shingler, V., Bartilson, M., and Moore, T. (1993) J. Bacteriol. 175, 1596-1604 [Abstract]

©1996 by The American Society for Biochemistry and Molecular Biology, Inc.