Autophosphorylation of a Bacterial Serine/Threonine Kinase, AfsK, Is Inhibited by KbpA, an AfsK-Binding Protein

doi:10.1128/JB.183.19.5506-5512.2001

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Journal of Bacteriology, October 2001, p. 5506-5512, Vol. 183, No. 19
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.19.5506-5512.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Autophosphorylation of a Bacterial Serine/Threonine Kinase, AfsK, Is Inhibited by KbpA, an AfsK-Binding Protein

Takashi Umeyama and Sueharu Horinouchi^*

Department of Biotechnology, Graduate School of Agriculture and Life Sciences, The University of Tokyo, Bunkyo-ku, Tokyo 113-8657, Japan

Received 9 April 2001/Accepted 2 July 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

A protein serine/threonine kinase, AfsK, and its target protein AfsR globally control physiological and morphological differentiationin the bacterial genus Streptomyces. A protein (KbpA) of 252 aminoacids encoded by an open reading frame in a region upstream ofafsK in Streptomyces coelicolor A3(2) was identified as an AfsK-interactingprotein. The interaction site of AfsK was in the N-terminal portioncontaining the kinase catalytic domain. KbpA bound a nonphosphorylatedform of AfsK and inhibited its autophosphorylation at serine andthreonine residues. KbpA in the reaction mixture containing AfsKand AfsR also inhibited the phosphorylation of AfsR by AfsK, presumablybecause KbpA inhibited the conversion from the inactive, nonphosphorylatedform of AfsK to the active, phosphorylated form. kbpA was transcribedthroughout growth, and the transcription was enhanced when productionof actinorhodin had already started. KbpA thus appeared to playan inhibitory role in a negative feedback system in the AfsK-AfsRregulatory pathway. Consistent with these in vitro observations,kbpA served as a repressor for actinorhodin production in S. coelicolorA3(2); disruption of kbpA greatly enhanced actinorhodin production,and overexpression of kbpA reduced theproduction.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

In the gram-positive, soil-living, filamentous bacteria Streptomyces coelicolor A3(2) and Streptomyces griseus, a serine/threoninekinase, AfsK, and its target protein AfsR control secondary metabolismand morphological development, respectively (17, 25). Disruptionof either one of the two genes reduced actinorhodin productionin S. coelicolor A3(2) (9, 17). In S. griseus, disruptionof either afsK or afsR resulted in the failure of aerial myceliumformation on medium containing glucose at concentrations higherthan 1% (25). Even under the usual culture conditions in thelaboratory, the AfsK-AfsR system in S. coelicolor A3(2) contributesconsiderably to pigment production because of reduced productionof the pigment by afsK and afsR mutants. The wide distributionof afsK and afsR in various Streptomyces spp. (9, 17) showstheir general and important roles in the regulation of secondarymetabolism and morphogenesis in this genus. Biochemical and geneticstudies of AfsK-AfsR have led us to assume that AfsK on the innerside of the membrane activates its own kinase activity by autophosphorylatingits serine and threonine residues on sensing some external stimuliand then phosphorylates serine and threonine residues of AfsR;the phosphorylated AfsR serves as a transcriptional factor formany genes required for antibiotic production and morphogenesis(2, 6). Wietzorrek and Bibb (28) pointed out the possibilitythat AfsR is a DNA-binding protein. The genome project for S.coelicolor A3(2) has predicted the presence of more than 20 AfsKhomologues with a serine/threonine kinase catalytic domain (www.sanger.ac.uk/Projects/S coelicolor/),and some AfsK homologues have been cloned from this species (21,26) and other Streptomyces spp. (20, 27). Although someof these kinases are perhaps capable of autophosphorylation, itis not known what their targets are and how their autophosphorylationiscontrolled.

In S. griseus, the AfsK-AfsR system is involved in aerial mycelium and spore formation in response to glucose in the medium(25). However, transcription of neither afsK nor afsR dependedon the concentration of glucose. These observations led us toassume that autophosphorylation of AfsK and phosphorylation ofAfsR by AfsK may be controlled by some mechanism other than oneat the transcriptional level. We focused on an open reading frame(ORF) that is located upstream of afsK and conserved in S. coelicolorA3(2) and S. griseus. Because the AfsK-AfsR system in S. coelicolorA3(2) could be assessed by monitoring actinorhodin (blue pigment)production, we studied the possible relationship between the conservedORF and the AfsK-AfsR system in S. coelicolor A3(2). The ORF productwas found to bind specifically to the nonphosphorylated form ofAfsK and inhibit its autophosphorylation. Consistent with thisin vitro observation, gene disruption and overexpression experimentssuggested a role of this ORF as a repressor for actinorhodin production.We here describe control by this ORF product, named KbpA (forAfsK-binding protein A), of AfsK autophosphorylation by meansof protein-proteininteraction.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains, plasmids, and growth conditions. Escherichia coli JM109 and pUC19 (29) were used for DNA manipulation. E. coli AD494(DE3) and pET32a(+), purchased from Novagen,were used for expression of proteins fused to thioredoxin (TRX).E. coli BL21 and pGEX5X-1, purchased from Amersham Pharmacia Biotech,were used for expression of proteins fused to glutathione S-transferase(GST). E. coli BL21 trxB(DE3), purchased from Novagen, was usedfor preparation of ³²P-labeled AfsK fusion proteins. E. coli JM110 dam dcm, deficientin the methylases, was purchased from Takara Shuzo. A high-copy-numberplasmid, pIJ6021, containing a thiostrepton-inducible promoterwas obtained from M. J. Bibb (24). S. coelicolor A3(2) was routinelycultured at 30°C on Trypto-Soya broth (TSB) (Nissui), which wassupplemented with 10 µg of thiostrepton or kanamycin per ml whennecessary.

Construction of plasmids. DNA manipulations in E. coli were as described by Maniatis et al. (16), and those in Streptomyces were as described by Hopwoodet al. (8). The kbpA coding sequence was amplified with thetwo primers 5'-GCCGAATTCCATATGGCCGAAAACGGGGCATTC-3' (theunderlined and italic letters indicate EcoRI and NdeI sites, respectively;the boldface letters indicate the start codon of kbpA) and 5'-GGCAAGCTTCTCGAGTCAGCGTCGCAGCAGCGCGAAC-3'(the underlined and italic letters indicate HindIII and XhoI sites,respectively; the boldface letters indicate the stop codon ofkbpA) and cloned between the EcoRI and HindIII sites of pUC19,resulting in pUC19-kbpA. After the kbpA coding sequence had beenchecked for errors in amplification, it was inserted between theEcoRI and HindIII sites of pET32a(+) to construct pTRX-KbpA. Similarly,kbpA as an EcoRI-XhoI fragment was inserted in pGEX5X-1 to generatepGST-KbpA. The kbpA sequence as an NdeI-HindIII fragment was alsoinserted in pIJ6021 to construct pIJ6021-kbpA.

For placing the afsR coding sequence in pGEX5X-1, a procedure similar to that used for constructing pGST-AfsR-g (25) wasemployed. The pGST-AfsR thus constructed directed the synthesisof an AfsR protein fused to GST. For construction of pTRX-AfsKand pGST-AfsK, directing the synthesis of TRX-AfsK and GST-AfsK,respectively, the afsK sequence was divided into two. The sequencefor the N-terminal portion was amplified by PCR with the primers5'-GCCGAATTCATGGTGGATCAGCTGACGCAG-3' (the underlined andboldface letters indicate an EcoRI site and the initiation codonof afsK [originally GTG], respectively) and 5'-GGCAAGCTTTCAGCGGCCGCCGGCCGTGGTGGCGGGC-3'(the underlined and italic letters indicate HindIII and NotI sites,respectively; the boldface letters indicate an artificial stopcodon), and the EcoRI-HindIII fragment was inserted in pUC19 toconstruct pUC19-AfsK $Delta$ C, containing the region from Met-1 to Arg-311.The sequence for the C-terminal portion was amplified with 5'-GCCGAATTCGGCGGCCGCGGCCACGGCCACGGCC-3'and 5'-GGCAAGCTTCTCGAGTCACGTCGTACGGGCGGTCCCCGTG-3' (theitalic and boldface letters indicate an XhoI site and the stopcodon of afsK, respectively; the underlined letters indicate restrictionsites used for cloning) and inserted between the EcoRI and HindIIIsites of pUC19, resulting in pUC19-AfsK $Delta$ N, containing the regionfrom Gly-309 to the stop codon of afsK. The EcoRI-NotI fragmentfrom pUC19-AfsK $Delta$ C, the NotI-HindIII fragment from pUC19-AfsK $Delta$ N,and the EcoRI-HindIII fragment from pET32a(+) were connected bythree-fragment ligation to construct pTRX-AfsK, which would directthe synthesis of TRX-His₆-S tag-AfsK. The EcoRI-NotI fragmentfrom pUC19-AfsK $Delta$ C, the NotI-XhoI fragment from pUC19-AfsK $Delta$ N, andthe EcoRI-XhoI fragment from pGEX5X-1 were similarly connectedto construct pGST-AfsK. pTRX-K $Delta$ C_wt, which would direct the synthesisof the kinase domain (Met-1 to Arg-311) of AfsK, was constructedby inserting the EcoRI-HindIII fragment from pUC19AfsK $Delta$ C in pET32a(+).For site-directed mutagenesis to replace Lys-44 with Ala, 5'-CGGCGCGTGGCGATCGCGACGGTGCGC-3'(the nucleotides in boldface were originally AA) as a mutant primerand the Mutan-Super Express Km kit (Takara Shuzo) were used accordingto supplier's manual. The EcoRI-HindIII fragment containing themutation was inserted in pET32a(+) to construct pTRX-K $Delta$ C_K44A withessentially the same construction as pTRX-K $Delta$ C_wt.

Production and preparation of GST- and TRX-fused proteins. An overnight culture (1 ml) of E. coli harboring each of the expression plasmids was inoculated in 9 ml of L broth. Aftercultivation at 30°C for 2 h, isopropyl- $beta$ -D-thiogalactopyranoside(IPTG) was added at a final concentration of 1 mM and the culturewas continued at 30°C for 3 h, except for E. coli harboring pGST-AfsK.GST-AfsK appeared to readily form inclusion bodies and was culturedat 20°C for 8 h. The E. coli cells were harvested by centrifugation,suspended in 0.5 ml of buffer A (10 mM Tris-HCl [pH 7.2] and 10%glycerol), and sonicated to prepare soluble fractions by centrifugationat 24,000 × g for 30 min. TRX and TRX-KbpA were purified withan Ni-nitrilotriacetic acid Spin kit (Qiagen) for GST pull-downassays. GST, GST-KbpA, and GST-AfsR were purified with a MicroSpinGST purification module (Amersham Pharmacia Biotech) for in vitrophosphorylation assay. TRX-AfsK, TRX-K $Delta$ C_wt, and TRX-K $Delta$ C_K44A weremainly produced as inclusion bodies, and these were solubilizedwith 6 M urea, purified with the Ni-bound resin, and finally refoldedinto active forms by gradual dialysis against buffer A, as describedpreviously (25). Protein concentrations were measured with theBio-Rad protein assay kit using bovine serum albumin as thestandard.

AfsK-KbpA interaction assay. The soluble fraction (10 µg of protein) containing GST-AfsK was incubated with 10 µl of glutathione-Sepharose 4B (AmershamPharmacia Biotech) at 4°C for 1 h in 0.5 ml of pull-down assaybuffer (PDA buffer) (10 mM Tris-HCl [pH 7.2], 100 mM NaCl, 1 mMMgCl₂, 0.025% $beta$ -mercaptoethanol, 1% Triton X-100, and 10% glycerol).Glutathione-Sepharose was collected by centrifugation, and thepellet was washed twice with 1 ml of PDA buffer. The pellet wassuspended in 0.5 ml of PDA buffer, and 5 µg of purified TRX-KbpAwas added. After incubation at 4°C for 1 h, the Sepharose wascollected by centrifugation and washed three times with 1 ml ofPDA buffer. The pellet was suspended in 15 µl of sodium dodecylsulfate (SDS) loading buffer (58 mM Tris-HCl [pH 6.8], 1.7% SDS,6% glycerol, 100 mM dithiothreitol, and 0.002% bromophenol blue)and boiled for 5 min to release GST complexes from the Sepharose.A portion (10 µl) of the supernatant obtained by centrifugationof the boiled sample was subjected to SDS-12.5% polyacrylamidegel electrophoresis (PAGE). After the proteins had been transferredto a nitrocellulose membrane, TRX-KbpA was detected by Westernblotting with S protein horseradish peroxidase (HRP) conjugate(Novagen) and the ECL Western blotting reagents (Amersham PharmaciaBiotech). The membrane was reprobed with anti-GST antibody HRPconjugate (Santa Cruz Biotechnology) to detect the GST-fused proteins.As negative controls, the soluble fractions containing GST andGST-AfsR, instead of GST-AfsK, were used. TRX itself, insteadof TRX-KbpA, was also used as a negative control. The interactionsof TRX-K $Delta$ C_wt and TRX-K $Delta$ C_K44A with GST-KbpA were similarly assayed,but with the proteins purified with the Ni or GST resins, as describedabove.

For preparation of ³²P-TRX-K $Delta$ C_wt and TRX-K $Delta$ C_K44A, E. coli BL21 trxB(DE3) harboring pTRX-K $Delta$ C_wt or pTRX-K $Delta$ C_K44A was cultured inthe presence of 100 µCi of phosphorus-32 (Amersham Pharmacia Biotech).The E. coli cells were collected and disrupted with the BugBusterprotein extraction reagent containing Benzonase nuclease (Novagen).The TRX proteins were solubilized and purified as describedabove.

In vitro phosphorylation assay. The standard reaction mixture, containing 15 pmol of TRX-AfsK in 10 mM Tris-HCl (pH 7.2)-5 mM MnCl₂-10 mM MgCl₂-0.1 mM ATP-10µCi of [ $gamma$ -³²P]ATP-1 mM dithiothreitol, was incubated at 30°C for 5 min. Forphosphorylation of GST-AfsR by TRX-AfsK, 30 pmol of GST-AfsR wasadded. Autophosphorylation of TRX-AfsK and GST-AfsR phosphorylationby TRX-AfsK were examined in the presence of 300 pmol of GST-KbpA.In this case, the reaction mixture without ATP and MgCl₂ was placedon ice for 1 h to allow formation of the complex between TRX-AfsKand GST-KbpA. The reaction was started by adding ATP and MgCl₂and continued at 30°C for 5 min. After separation of the proteinsby SDS-PAGE, the gel was placed on a Fuji BAS2000 image analyzer.Phosphoamino acid analysis by one-dimensional electrophoresison a cellulose thin-layer plate was carried out with hydrolyzedsamples, as described previously (4, 12).

Disruption of chromosomal kbpA. A 1,014-bp region upstream of kbpA was amplified by PCR with primers 5'-GGCGAATTCGGGGTCGTCACGGTGCTGAACTTC-3' (the underliningindicates an EcoRI site) and 5'-GCCAAGCTTTCTAGACATGCCGTCAAAGTAACCGC-3'(the underlined and italic letters indicate HindIII and XbaI sites,respectively; the boldface letters indicate the start codon ofkbpA). A 1,154-bp region downstream of kbpA was amplified with5'-GGCGAATTCTCTAGATGACCCGGCGGCCACGGCG-3' (the underlinedand italic letters indicate EcoRI and XbaI sites, respectively;the boldface letters indicate the stop codon of kbpA) and 5'-GCCAAGCTTGGATCCGCGGCCGCCGGCCGTGGTGGCGGGCTTG-3'(the underlined and italic letters indicate HindIII and BamHIsites, respectively). The regions upstream and downstream of kbpAwere each cloned between the EcoRI and HindIII sites of pUC19.The two regions in the pUC19 plasmids were then connected by useof the XbaI sites, generating pDisKbpA, which contained a 2,192-bpinsertion with complete deletion of the kbpA sequence. The thiostreptonresistance (tsr) gene, obtained as a BamHI-HindIII fragment frompKU209 (11), was inserted between the BamHI and HindIII sitesof pDisKbpA. The circular form of the resultant plasmid preparedfrom E. coli JM110 was alkali denatured (22) and introducedby protoplast transformation into S. coelicolor A3(2) M130 toisolate mutants in which the whole plasmid was integrated in thechromosome by homologous recombination. Thiostrepton-resistantcolonies were incubated on TSB for 7 days in the absence of thiostrepton,and spores were recovered. Of the isolated spores, thiostrepton-sensitivecolonies were selected to obtain mutants containing the deletionof kbpA due to double crossover. Correct deletion of the kbpAsequence was checked by Southern hybridization with the 0.7-kbEcoRI-HindIII fragment containing kbpA on pUC19-kbpA and the 2.3-kbEcoRI-SphI fragment containing kbpA and part of afsK (Fig. 1B).

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FIG. 1. Effects of overexpression and disruption of kbpA in S. coelicolor A3(2) M130. (A) Strain M130 harboring pIJ6021 produces the blue pigment actinorhodin, whereas that harboring kbpA on pIJ6021 produces a much smaller amount of the pigment. (B) Schematic representation of the chromosomal kbpA disruption. The kbpA coding region is completely deleted so that this deletion does not affect the promoter in front of kbpA or afsK. Abbreviations: Ec, EcoRI; Not, NotI; Sp, SphI; Xb, XbaI. (C) The kbpA disruptant produces a larger amount of actinorhodin than strain M130.

Transcriptional analysis of kbpA. RNA was purified from mycelium grown on TSB agar medium (13). For S1 nuclease mapping of kbpA, a 342-bp fragment was preparedby PCR with 5'-AGCATTTCGCTGAGGCAGTCGAGCAGTTTC-3' and 5'-TCCTGGAAGGTCCAGCCGAACAGCTCGCCG-3'(corresponding to positions $-$ 217 to +125, taking the transcriptionalstart point of kbpA as +1, which was later determined) and usedas the ³²P-labeled probe, as described previously (13). Transcriptionof afsK and hrdB was determined as described previously (25).For reverse transcription-PCR, two primers containing the startcodons of kbpA and afsK were used: 5'-ATGGCCGAAAACGGGGCATTCGAGAAG-3'(the boldface letters indicate the start codon of kbpA) and 5'-ATCGTGCTGCGTCAGCTGATCCACCAC-3'(the boldface letters indicate the start codon of afsK).

Nucleotide sequence accession number. The nucleotide sequence of kbpA has been deposited in the DDBJ, EMBL, and GenBank databases under accession number D45382.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Repression of actinorhodin production by kbpA. The ORF products (KbpAs) that are encoded by a region upstream of afsK in S. coelicolor A3(2) and S. griseus showed 47% identityto each other. The KbpA of 252 amino acids in S. coelicolor A3(2)also showed 36 and 33% identity to SgaA, which is involved insuppression of the growth disturbance caused by high osmolalityin S. griseus (1), and to DnrV, which is located in the doxorubicinbiosynthetic gene cluster in Streptomyces peucetius (15), respectively.The functions of these products, however, are not understood.In the database of the S. coelicolor A3(2) genome, there are sixKbpA homologues (5H1.9.C, 9B10.0C, 2G4.09, F1.07, 4C6.24C, and4G10.18C). Since in prokaryotes, genes for the same biologicalfunction comprise a cluster in most cases, we examined a possiblerole of kbpA in actinorhodin production in S. coelicolor A3(2).Overexpression of kbpA in strain M130 by means of placing kbpAunder the control of the thiostrepton-inducible promoter tip ina high-copy-number plasmid, pIJ6021, severely reduced actinorhodinproduction on TSB agar (Fig. 1A). The reduction was independentof the nutritional conditions, because strain M130 harboring pIJ6021-kbpAproduced a much smaller amount of actinorhodin on media containingvarious carbon and nitrogen sources. The degree of reduction wasalmost the same as that in afsK disruptants (data not shown).On the other hand, complete deletion of the kbpA coding region(Fig. 1B) caused overproduction of actinorhodin on various media(Fig. 1C). This mutant also produced undecylprodigiosin at anearlier stage and accumulated it in a larger amount than strainM130 (data not shown). The $Delta$ kbpA mutant produced spores normally,which showed that the mutation did not affect morphological differentiation.The AfsK-AfsR system in S. coelicolor A3(2) caused no detectableeffect on morphogenesis (7, 17). We thus concluded that kbpAacted as a repressor for actinorhodin production, irrespectiveof the cultureconditions.

Transcription of kbpA. Because of the involvement of kbpA in actinorhodin production, we determined the course of its transcription, in relationto actinorhodin production, using RNA from mycelium grown on agarmedium. afsK was constantly transcribed from two promoters throughoutgrowth. Constant transcription from two promoters was also observedfor the afsK gene of S. griseus (2). hrdB mRNA, encoding themajor sigma factor of RNA polymerase, is known to be transcribedconstantly. kbpA was transcribed from a single promoter throughoutgrowth, but transcription was enhanced when production of bothundecylprodigiosin and actinorhodin and aerial mycelium formationhad already started (Fig. 2A). It thus appeared that under usualculture conditions, KbpA repressed secondary metabolism when thesepigments had been produced and accumulated. High-resolution S1mapping revealed the transcriptional start point to be the firstA of the start codon (Fig. 2B). A sequence, TACTTT, similar tothe $-$ 10 consensus sequence was present at an appropriate positionfrom the transcriptional start point, but no sequence similarto the $-$ 35 consensus sequence was present. Transcription of leaderlessmRNA is not uncommon in Streptomyces. For example, the 23S rRNAmethylase gene mediating erythromycin resistance in Streptomyceserythraeus (3) and afsA, which probably encodes an A-factorbiosynthetic enzyme in S. griseus (10), are transcribed fromleaderless transcripts.

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FIG. 2. Transcription of kbpA. (A) Low-resolution S1 mapping of kbpA, afsK, and hrdB. kbpA and hrdB contain a single promoter, and afsK contains two promoters. On agar medium, production of the red pigment undecylprodigiosin (red) and the blue pigment actinorhodin (act) started at 48 and 72 h, respectively. Aerial mycelium (am) was formed at 60 h. (B) High-resolution S1 mapping of kbpA. In this particular experiment, the strongest signal of the S1-protected fragments corresponds to the second residue of the translational start codon ATG, since S1-protected fragments run slower than the chemically cleaved fragments (23). It is reasonable, however, to assume that transcription of kbpA starts at the first nucleotide of the ATG.

kbpA and afsK are separated by 219 nucleotides, which suggested that the genes were transcribed independently. Reverse transcription-PCRwith primers containing the start codons of kbpA and afsK yieldedonly a weak signal representing a 1,004-bp DNA fragment after30 cycles of amplification (data not shown). We thus concludedthat kbpA and afsK were transcribed mainly from their own promoterand that very little kbpA transcript leaked into afsK.

Direct interaction of AfsK with KbpA. For examining possible KbpA-AfsK interaction, we produced TRX-KbpA with the structure of TRX-His₆-S tag-KbpA (419 amino acids,45 kDa), detectable with S protein HRP conjugate, and GST-AfsK(1,029 amino acids, 110 kDa), precipitable with glutathione-Sepharose.The S tag consisted of 15 amino acids derived from RNase S protein.TRX-KbpA was produced in the soluble fraction of E. coli and purifiedwith His-bind resin. GST-AfsK was produced in a soluble fractionof E. coli when the cells were cultured at 20°C to avoid formationof inclusion bodies. After the soluble fraction (10 µg of protein)containing GST-AfsK had been incubated with 5 µg of purified TRX-KbpA,the GST complexes were pulled down with glutathione-Sepharoseand separated by SDS-PAGE. TRX complexes and GST complexes weredetected by Western blotting with the S protein HRP conjugateand the antibody for GST, respectively (Fig. 3A). This pull-downassay recovered TRX-KbpA (Fig. 3A, lane 4), indicating that GST-AfsKformed a complex with TRX-KbpA. The lack of recovery of proteinsreactive with the antibody in the control experiments with TRXinstead of TRX-KbpA or with GST instead of GST-AfsK showed thatthe complex was formed via parts of KbpA and AfsK. In addition,KbpA did not interact with AfsR, since the same experiment withGST-AfsR (1,223 amino acids, 132 kDa) instead of GST-AfsK didnot recover TRX-KbpA.

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FIG. 3. Interaction of KbpA and AfsK. (A) The pull-down of GST-AfsK with glutathione-Sepharose coprecipitated TRX-KbpA, which was detected with S protein by Western blotting (immunoblotting [IB]) (lane 4). TRX-KbpA was not recovered when GST or GST-AfsR was used. The pull-down of GST-AfsR (132 kDa), GST-AfsK (110 kDa), and GST (28 kDa) with glutathione-Sepharose was apparent by Western blotting with the antibody for GST ( $alpha$ -GST). The small protein found in lanes 5 and 6 is a degradation product derived from GST-AfsR. (B) Autophosphorylation of TRX-K $Delta$ C_wt (51 kDa) and phosphorylation of GST-AfsR by TRX-K $Delta$ C_wt. TRX-K $Delta$ C_wt (5 µg) was incubated at 30°C for 10 min in the presence of [ $gamma$ -³²P]ATP, subjected to SDS-PAGE, and analyzed by autoradiography. GST-AfsR (3 µg) in the reaction mixture was also phosphorylated. Neither autophosphorylation nor phosphorylation of GST-AfsR occurred for TRX-K $Delta$ C_K44A. (C) SDS-PAGE of the TRX-K $Delta$ C proteins labeled in vivo. Coomassie brilliant blue (CBB) staining revealed smeared bands for TRX-K $Delta$ C_wt, as indicated by an asterisk, which represent phosphorylated forms of TRX-K $Delta$ C_wt, as found by autoradiography. (D) The pull-down of GST-KbpA (54 kDa) with glutathione-Sepharose coprecipitated TRX-K $Delta$ C_wt (lane 3) and TRX-K $Delta$ C_K44A (lane 4) without recovering smeared, phosphorylated forms of TRX-K $Delta$ C_wt. The small protein recovered by anti-GST antibody in lanes 3 and 4 is a degradation product. GST itself did not pull down the TRX-K $Delta$ C proteins (lanes 1 and 2). TRX-K $Delta$ C_wt gave smeared bands (lane 5), but TRX-K $Delta$ C_K44A did not (lane 6).

During the pull-down assay, we noticed that the amount of TRX-KbpA recovered as a complex of TRX-KbpA and GST-AfsK appearedto depend on the degree of phosphorylation of GST-AfsK. The amountof TRX-KbpA recovered and detected by Western blotting was decreasedas the amount of the phosphorylated form of GST-AfsK was increased.The degree of autophosphorylation of GST-AfsK in E. coli couldbe estimated by the intensity of smeared, slow-moving bands onSDS-PAGE. We examined this observation in detail by reducing thesize of AfsK and by using a K44A mutant that lost the abilityto autophosphorylate because of the mutation at one of the active-siteresidues, Lys-44. The TRX-K $Delta$ C proteins (478 amino acids, 51 kDa)contained the kinase domain (Met-1 to Arg-311). In vitro phosphorylationassay of TRX-K $Delta$ C_wt revealed autophosphorylation and phosphorylationof AfsR (Fig. 3B). Phosphoamino acid analysis showed that bothcontained phosphorylated serine and threonine residues (data notshown), as does the native AfsK-AfsR phosphorylation system. Nophosphorylation occurred for TRX-K $Delta$ C_K44A.

To confirm that the smeared bands observed for TRX-K $Delta$ C_wt represented the phosphorylated forms, we purified the TRX-K $Delta$ C proteinsfrom recombinant E. coli cells grown in the presence of ³²P-labeled inorganic phosphate. TRX-K $Delta$ C_wt showed a smeared patternon SDS-PAGE, but TRX-K $Delta$ C_K44A did not (Fig. 3C). Autoradiographyof the gel indicated the presence of ³²P in the smeared bands of TRX-K $Delta$ C_wt and the absence of ³²P in TRX-K $Delta$ C_K44A.

We did pull-down assays to examine the interaction between GST-KbpA and TRX-K $Delta$ C_wt or TRX-K $Delta$ C_K44A (Fig. 3D). TRX-K $Delta$ C proteinslabeled in vivo were used. After incubation, the GST complexeswere precipitated with glutathione-Sepharose and separated bySDS-PAGE. TRX complexes and GST complexes were detected by Westernblotting with S protein and the antibody for GST, respectively.Both TRX-K $Delta$ C_wt and TRX-K $Delta$ C_K44A were coprecipitated with GST-KbpA(Fig. 3D, lanes 3 and 4). Only a sharp band, with no smeared bands,was detected for TRX-K $Delta$ C_wt, although the TRX-K $Delta$ C_wt preparationcontained smeared bands (lane 5). These observations suggestedthat GST-KbpA interacted only with the nonphosphorylated formof AfsK. In fact, the TRX-K $Delta$ C_wt that was coprecipitated with GST-KbpAcontained noradioactivity.

Inhibition of AfsK autophosphorylation by KbpA. Because KbpA was found to bind the kinase domain in the nonphosphorylated form of AfsK, we examined the effect of KbpA bindingto AfsK on autophosphorylation. Incubation of TRX-AfsK (966 aminoacids, 102 kDa) in the presence of [ $gamma$ -³²P]ATP yielded the autophosphorylated form (Fig. 4A), because theTRX-AfsK preparation contained a large population of the nonphosphorylatedform. GST-KbpA inhibited this phosphorylation by about 40% whenanalyzed with an image analyzer (Fig. 4B). The inhibition of autophosphorylationto a small extent may be attributed to the equilibrium of associationand dissociation between AfsK and KbpA and rapid autophosphorylationof dissociated AfsK. Coincubation of TRX-AfsK and GST-AfsR yieldeda phosphorylated form of GST-AfsR, in addition to the autophosphorylatedform of TRX-AfsK. The presence of GST-KbpA inhibited the phosphorylationof AfsR by AfsK, because GST-KbpA reduced the amount of the phosphorylated,active form of TRX-AfsK by inhibiting the autophosphorylation.The small extent of inhibition can be attributed to the autophosphorylated,active AfsA that was inevitably present in a small amount in theAfsK preparation. GST-KbpA also inhibited autophosphorylationof TRX-K $Delta$ C_wt to a similar extent (data not shown). It is thusapparent that KbpA binds the kinase domain of AfsK and inhibitsits autophosphorylation.

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FIG. 4. Inhibition of AfsK autophosphorylation by KbpA. (A) Incubation of TRX-AfsK (15 pmol) in the presence of [ $gamma$ -³²P]ATP and GST (300 pmol) yielded the autophosphorylated form (lane 1). The presence of GST-KbpA (300 pmol) instead of GST inhibited the autophosphorylation. Phosphorylation of GST-AfsR (30 pmol) was also inhibited by GST-KbpA but not by GST (lane 4). The amounts of the proteins contained in the reaction mixture were monitored by staining the gel with Coomassie brilliant blue (CBB). (B) The gels were analyzed on an image analyzer, and the inhibition of autophosphorylation of TRX-AfsK and phosphorylation of GST-AfsR by TRX-AfsK was plotted. The degrees of inhibition are the means of values obtained from three independent experiments. Error bars indicate standard deviations.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The in vitro experiments have shown that KbpA directly binds the nonphosphorylated form of AfsK and inhibits the autophosphorylationof AfsK. This is consistent with the in vivo observations thatKbpA serves as a repressor for actinorhodin production. Also consistentwith this are the observations that a mutant AfsK unable to autophosphorylatedid not complement the reduced actinorhodin production by an afsKmutant (unpublished results). The kinase domain at the N-terminalportion of AfsK interacts with KbpA. Recovery of only nonphosphorylatedforms of TRX-K $Delta$ C_wt and TRX-K $Delta$ C_K44A by the pull-down assay withGST-KbpA suggests that the presence of even a single phosphorylatedsite at either serine or threonine residue prevents KbpA frombinding to AfsK, although the numbers and the exact positionsof serine and threonine residues to be autophosphorylated arestill unknown. We thus assume that the population of the phosphorylated,active form of AfsK is modulated by the amount of KbpA, as a resultof which the degree of phosphorylation of AfsR is controlled (Fig.5). At a later stage of growth under usual culture conditionson agar medium, KbpA binds the nonphosphorylated form of AfsK,which has not yet autophosphorylated or which has been dephosphorylatedby protein phosphatases, and inhibits its autophosphorylationat serine and threonine residues. It is unclear whether the AfsK-KbpAcomplex is associated with the membrane. The nonphosphorylatedAfsK is inactive and unable to activate the positive regulatorAfsR by phosphorylating it at serine and threonine residues, asa result of which secondary metabolism, including actinorhodinproduction, is repressed. Thus, KbpA serves as an inhibitor ina negative feedback system in the AfsK-AfsR regulatory pathway.The $Delta$ kbpA mutation, allowing AfsK activation by autophosphorylation,would result in accumulation of a larger amount of the phosphorylatedform of AfsR and in overproduction of actinorhodin and undecylprodigiosin,as is observed in strains overexpressing afsR. A larger amountof KbpA would result in a decrease of the amount of the activeform of AfsR and a reduction of the pigment production, as isfound in afsR and afsK mutants. The hydropathy plot of KbpA excludesthe possibility that it is a membrane protein. Therefore, KbpAseems not to control the localization of AfsK inside the hyphae,unlike the many kinase-anchoring proteins that determine the specificitiesand activities of kinase-mediated signaling pathways in eukaryotes(5, 14, 18). AfsK appears to bind loosely to the innerside of the membrane, because it is recovered from the membranefraction by mild treatment with detergents during purification(17). A seven-repeat sequence in the C-terminal portion maybe a motif to anchor a membrane protein, as pointed out by Nadvorniket al. (20).

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FIG. 5. Model of inhibition of AfsK autophosphorylation by KbpA.

kbpA is transcribed throughout growth, and its transcription is enhanced when production of actinorhodin and undecylprodigiosinhas already started. Since afsK is transcribed constantly throughoutgrowth, KbpA appears to put a brake on the unlimited productionof the pigments that has been commenced by the AfsK-AfsR system.AfsK-AfsR seems to operate independently of the pathway-specificregulatory proteins to mainly control pigment production, suchas ActII-ORF4 for actinorhodin and RedD for undecylprodigiosin(6), suggesting an inhibitory role of KbpA in a negative feedbacksystem in the AfsK-AfsR regulatorypathway.

The genome project for S. coelicolor A3(2) revealed the presence of six KbpA homologues and more than 20 AfsK homologues containinga catalytic domain of protein serine/threonine kinases. AfsR isphosphorylated not only by AfsK but also by an additional kinase(17). We have recently found that two other kinases are capableof phosphorylation of AfsR at serine and threonine residues (unpublishedresults). By analogy with the eukaryotic systems, these AfsK homologuesrecognize their respective signals and transfer them to AfsR bymeans of phosphorylation. It is unclear whether KbpA and the sixKbpA homologues discriminate and bind these kinases and modulatetheir activity. Functionally unknown KbpA homologues found inStreptomyces and various bacteria may be elucidated through anapproach based on the assumption that KbpA homologues serve asa modulator by protein-protein interaction. Among KbpA homologuesin various bacteria, PA1672, encoded by the region just downstreamof sty1 encoding a serine/threonine kinase in Pseudomonas aeruginosa(19) (www.pseudomonas.com/), may serve as a StyI-bindingprotein.

	ACKNOWLEDGMENTS

T. Umeyama was supported by the Japan Society for the Promotion of Science (JSPS). This work was supported by the Asahi GlassFoundation, by the "Research for the Future" Program of JSPS,and by the Bio Design Program of the Ministry of Agriculture,Forestry, and Fisheries of Japan (BDP-01-VI-2-1).

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biotechnology, Graduate School of Agriculture and Life Sciences, TheUniversity of Tokyo, Bunkyo-ku, Tokyo 113-8657, Japan. Phone:81-3-5841-5123. Fax: 81-3-5841-8021. E-mail: asuhori{at}mail.ecc.u-tokyo.ac.jp.

Present address: National Institute of Infectious Diseases, Shinjuku-ku, Tokyo 162-8640,Japan.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Ando, N., K. Ueda, and S. Horinouchi. 1997. A Streptomyces griseus gene (sgaA) suppresses the growth disturbance caused by high osmolality and a high concentration of A-factor during early growth. Microbiology 143:2715-2723[Abstract/Free Full Text].

2. Arias, P., M. A. Fernandez-Moreno, and F. Malpartida. 1999. Characterization of the pathway-specific positive transcriptional regulator for actinorhodin biosynthesis in Streptomyces coelicolor A3(2) as a DNA-binding protein. J. Bacteriol. 181:6958-6968[Abstract/Free Full Text].

3. Bibb, M. J., G. R. Janssen, and J. M. Ward. 1986. Cloning and analysis of the promoter region of the erythromycin resistance gene (ermE) of Streptomyces erythraeus. Gene 41:E357-E368[CrossRef].

4. Cooper, J. A., B. M. Sefton, and T. Hunter. 1983. Detection and quantification of phosphotyrosine in proteins. Methods Enzymol. 99:387-402[Medline].

5. Edwards, A. S., and J. D. Scott. 2000. A-kinase anchoring proteins: protein kinase A and beyond. Curr. Opin. Cell Biol. 12:217-221[CrossRef][Medline].

6. Floriano, B., and M. Bibb. 1996. afsR is a pleiotropic but conditionally required regulatory gene for antibiotic production in Streptomyces coelicolor A3(2). Mol. Microbiol. 21:385-396[CrossRef][Medline].

7. Hong, S.-K., M. Kito, T. Beppu, and S. Horinouchi. 1991. Phosphorylation of the afsR product, a global regulatory protein for secondary-metabolite formation in Streptomyces coelicolor A3(2). J. Bacteriol. 173:2311-2318[Abstract/Free Full Text].

8. Hopwood, D. A., M. J. Bibb, K. F. Chater, T. Kieser, C. J. Bruton, H. Kieser, D. J. Lydiate, C. P. Smith, J. M. Ward, and H. Schrempf. 1985. Genetic manipulation of Streptomyces: a laboratory manual. John Innes Foundation, Norwich, United Kingdom.

9. Horinouchi, S., M. Kito, M. Nishiyama, K. Furuya, S.-K. Hong, K. Miyake, and T. Beppu. 1990. Primary structure of AfsR, a global regulatory protein for secondary metabolite formation in Streptomyces coelicolor A3(2). Gene 95:49-56[CrossRef][Medline].

10. Horinouchi, S., H. Suzuki, M. Nishiyama, and T. Beppu. 1989. Nucleotide sequence and transcriptional analysis of the Streptomyces griseus gene (afsA) responsible for A-factor biosynthesis. J. Bacteriol. 171:1206-1210[Abstract/Free Full Text].

11. Kakinuma, S., Y. Takada, H. Ikeda, H. Tanaka, and S. Omura. 1991. Cloning of large DNA fragments, which hybridize with actinorhodin biosynthesis genes, from kalafungin and nanaomycin A methyl ester producers and identification of genes for kalafungin biosynthesis of the kalafungin producer. J. Antibiot. 44:995-1005[Medline].

12. Kamps, M. P., and B. M. Sefton. 1989. Acid and base hydrolysis of phosphoproteins bound to Immobilon facilitates analysis of phosphoamino acids in gel-fractionated proteins. Anal. Biochem. 176:22-27[CrossRef][Medline].

13. Kelemen, G. H., G. L. Brown, J. Kormanec, L. Potuckova, K. F. Chater, and M. J. Buttner. 1996. The position of the sigma-factor genes, whiG and sigF, in the hierarchy controlling the development of spores chains in the aerial hyphae of Streptomyces coelicolor A3(2). Mol. Microbiol. 21:593-603[CrossRef][Medline].

14. Kolch, W. 2000. Meaningful relationships: the regulation of the Ras/Raf/MEK/ERK pathway by protein interactions. Biochem. J. 351:289-305.

15. Lomovskaya, N., S. L. Otten, Y. Doi-Katayama, L. Fonstein, X.-C. Liu, T. Takatsu, A. Inventi-Solari, S. Filippini, F. Torti, A. L. Colombo, and C. R. Hutchinson. 1999. Doxorubicin overproduction in Streptomyces peucetius: cloning and characterization of the dnrU ketoreductase and dnrV genes and the doxA cytochrome P-450 hydroxylase gene. J. Bacteriol. 181:305-318[Abstract/Free Full Text].

16. Maniatis, T., E. F. Fritsch, and J. Sambrook. 1982. Molecular cloning: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

17. Matsumoto, A., S.-K. Hong, H. Ishizuka, S. Horinouchi, and T. Beppu. 1994. Phosphorylation of the AfsR protein involved in secondary metabolism in Streptomyces species by a eukaryotic-type protein kinase. Gene 146:47-56[CrossRef][Medline].

18. Mochly-Rosen, D., and A. S. Gordon. 1998. Anchoring proteins for protein kinase C: a means for isozyme selectivity. FASEB J. 12:35-42[Abstract/Free Full Text].

19. Mukhopadhyay, S., V. Kapatral, W. Xu, and A. M. Chakrabarty. 1999. Characterization of a Hank's type serine/threonine kinase and serine/threonine phosphoprotein phosphatase in Pseudomonas aeruginosa. J. Bacteriol. 181:6615-6622[Abstract/Free Full Text].

20. Nadvornik, R., T. Vomastek, J. Janecek, Z. Technikova, and P. Branny. 1999. Pkg2: a novel transmembrane protein Ser/Thr kinase of Streptomyces granaticolor. J. Bacteriol. 181:15-23[Abstract/Free Full Text].

21. Ogawara, H., N. Aoyagi, M. Watanabe, and H. Urabe. 1999. Sequences and evolutionary analyses of eukaryotic-type protein kinases from Streptomyces coelicolor A3(2). Microbiology 145:3343-3352[Abstract/Free Full Text].

22. Oh, S. H., and K. F. Chater. 1997. Denaturation of circular or linear DNA facilitates targeted integrative transformation of Streptomyces coelicolor A3(2): possible relevance to other organisms. J. Bacteriol. 179:122-127[Abstract/Free Full Text].

23. Sollner-Webb, B., and R. H. Reeder. 1979. The nucleotide sequence of the initiation and termination sites for ribosomal RNA transcription in X. leavis. Cell 18:485-499[CrossRef][Medline].

24. Takano, E., J. White, C. J. Thompson, and M. J. Bibb. 1995. Construction of thiostrepton-inducible, high-copy-number expression vectors for use in Streptomyces spp. Gene 166:133-137[CrossRef][Medline].

25. Umeyama, T., P.-C. Lee, K. Ueda, and S. Horinouchi. 1999. An AfsK/AfsR system involved in the response of aerial mycelium formation to glucose in Streptomyces griseus. Microbiology 145:2281-2292[Abstract/Free Full Text].

26. Urabe, H., and H. Ogawara. 1995. Cloning, sequencing and expression of serine/threonine kinase-encoding genes from Streptomyces coelicolor A3(2). Gene 153:99-104[CrossRef][Medline].

27. Vomastek, T., R. Nadvornik, J. Janecek, Z. Technikova, J. Weiser, and P. Branny. 1998. Characterization of two putative protein Ser/Thr kinases from actinomycete Streptomyces granaticolor both endowed with different properties. Eur. J. Biochem. 257:55-61[Medline].

28. Wietzorrek, A., and M. Bibb. 1997. A novel family of proteins that regulate antibiotic production in streptomycetes appears to contain an OmpR-like DNA-binding fold. Mol. Microbiol. 25:1181-1184[CrossRef][Medline].

29. Yanisch-Perron, C., J. Vieira, and J. Messing. 1985. Improved M13 phage cloning vectors and host strains: nucleotide sequences of M13mp18 and pUC19 vectors. Gene 33:103-119[CrossRef][Medline].

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1.	Ando, N., K. Ueda, and S. Horinouchi. 1997. A Streptomyces griseus gene (sgaA) suppresses the growth disturbance caused by high osmolality and a high concentration of A-factor during early growth. Microbiology 143:2715-2723[Abstract/Free Full Text].
2.	Arias, P., M. A. Fernandez-Moreno, and F. Malpartida. 1999. Characterization of the pathway-specific positive transcriptional regulator for actinorhodin biosynthesis in Streptomyces coelicolor A3(2) as a DNA-binding protein. J. Bacteriol. 181:6958-6968[Abstract/Free Full Text].
3.	Bibb, M. J., G. R. Janssen, and J. M. Ward. 1986. Cloning and analysis of the promoter region of the erythromycin resistance gene (ermE) of Streptomyces erythraeus. Gene 41:E357-E368[CrossRef].
4.	Cooper, J. A., B. M. Sefton, and T. Hunter. 1983. Detection and quantification of phosphotyrosine in proteins. Methods Enzymol. 99:387-402[Medline].
5.	Edwards, A. S., and J. D. Scott. 2000. A-kinase anchoring proteins: protein kinase A and beyond. Curr. Opin. Cell Biol. 12:217-221[CrossRef][Medline].
6.	Floriano, B., and M. Bibb. 1996. afsR is a pleiotropic but conditionally required regulatory gene for antibiotic production in Streptomyces coelicolor A3(2). Mol. Microbiol. 21:385-396[CrossRef][Medline].
7.	Hong, S.-K., M. Kito, T. Beppu, and S. Horinouchi. 1991. Phosphorylation of the afsR product, a global regulatory protein for secondary-metabolite formation in Streptomyces coelicolor A3(2). J. Bacteriol. 173:2311-2318[Abstract/Free Full Text].
8.	Hopwood, D. A., M. J. Bibb, K. F. Chater, T. Kieser, C. J. Bruton, H. Kieser, D. J. Lydiate, C. P. Smith, J. M. Ward, and H. Schrempf. 1985. Genetic manipulation of Streptomyces: a laboratory manual. John Innes Foundation, Norwich, United Kingdom.
9.	Horinouchi, S., M. Kito, M. Nishiyama, K. Furuya, S.-K. Hong, K. Miyake, and T. Beppu. 1990. Primary structure of AfsR, a global regulatory protein for secondary metabolite formation in Streptomyces coelicolor A3(2). Gene 95:49-56[CrossRef][Medline].
10.	Horinouchi, S., H. Suzuki, M. Nishiyama, and T. Beppu. 1989. Nucleotide sequence and transcriptional analysis of the Streptomyces griseus gene (afsA) responsible for A-factor biosynthesis. J. Bacteriol. 171:1206-1210[Abstract/Free Full Text].
11.	Kakinuma, S., Y. Takada, H. Ikeda, H. Tanaka, and S. Omura. 1991. Cloning of large DNA fragments, which hybridize with actinorhodin biosynthesis genes, from kalafungin and nanaomycin A methyl ester producers and identification of genes for kalafungin biosynthesis of the kalafungin producer. J. Antibiot. 44:995-1005[Medline].
12.	Kamps, M. P., and B. M. Sefton. 1989. Acid and base hydrolysis of phosphoproteins bound to Immobilon facilitates analysis of phosphoamino acids in gel-fractionated proteins. Anal. Biochem. 176:22-27[CrossRef][Medline].
13.	Kelemen, G. H., G. L. Brown, J. Kormanec, L. Potuckova, K. F. Chater, and M. J. Buttner. 1996. The position of the sigma-factor genes, whiG and sigF, in the hierarchy controlling the development of spores chains in the aerial hyphae of Streptomyces coelicolor A3(2). Mol. Microbiol. 21:593-603[CrossRef][Medline].
14.	Kolch, W. 2000. Meaningful relationships: the regulation of the Ras/Raf/MEK/ERK pathway by protein interactions. Biochem. J. 351:289-305.
15.	Lomovskaya, N., S. L. Otten, Y. Doi-Katayama, L. Fonstein, X.-C. Liu, T. Takatsu, A. Inventi-Solari, S. Filippini, F. Torti, A. L. Colombo, and C. R. Hutchinson. 1999. Doxorubicin overproduction in Streptomyces peucetius: cloning and characterization of the dnrU ketoreductase and dnrV genes and the doxA cytochrome P-450 hydroxylase gene. J. Bacteriol. 181:305-318[Abstract/Free Full Text].
16.	Maniatis, T., E. F. Fritsch, and J. Sambrook. 1982. Molecular cloning: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
17.	Matsumoto, A., S.-K. Hong, H. Ishizuka, S. Horinouchi, and T. Beppu. 1994. Phosphorylation of the AfsR protein involved in secondary metabolism in Streptomyces species by a eukaryotic-type protein kinase. Gene 146:47-56[CrossRef][Medline].
18.	Mochly-Rosen, D., and A. S. Gordon. 1998. Anchoring proteins for protein kinase C: a means for isozyme selectivity. FASEB J. 12:35-42[Abstract/Free Full Text].
19.	Mukhopadhyay, S., V. Kapatral, W. Xu, and A. M. Chakrabarty. 1999. Characterization of a Hank's type serine/threonine kinase and serine/threonine phosphoprotein phosphatase in Pseudomonas aeruginosa. J. Bacteriol. 181:6615-6622[Abstract/Free Full Text].
20.	Nadvornik, R., T. Vomastek, J. Janecek, Z. Technikova, and P. Branny. 1999. Pkg2: a novel transmembrane protein Ser/Thr kinase of Streptomyces granaticolor. J. Bacteriol. 181:15-23[Abstract/Free Full Text].
21.	Ogawara, H., N. Aoyagi, M. Watanabe, and H. Urabe. 1999. Sequences and evolutionary analyses of eukaryotic-type protein kinases from Streptomyces coelicolor A3(2). Microbiology 145:3343-3352[Abstract/Free Full Text].
22.	Oh, S. H., and K. F. Chater. 1997. Denaturation of circular or linear DNA facilitates targeted integrative transformation of Streptomyces coelicolor A3(2): possible relevance to other organisms. J. Bacteriol. 179:122-127[Abstract/Free Full Text].
23.	Sollner-Webb, B., and R. H. Reeder. 1979. The nucleotide sequence of the initiation and termination sites for ribosomal RNA transcription in X. leavis. Cell 18:485-499[CrossRef][Medline].
24.	Takano, E., J. White, C. J. Thompson, and M. J. Bibb. 1995. Construction of thiostrepton-inducible, high-copy-number expression vectors for use in Streptomyces spp. Gene 166:133-137[CrossRef][Medline].
25.	Umeyama, T., P.-C. Lee, K. Ueda, and S. Horinouchi. 1999. An AfsK/AfsR system involved in the response of aerial mycelium formation to glucose in Streptomyces griseus. Microbiology 145:2281-2292[Abstract/Free Full Text].
26.	Urabe, H., and H. Ogawara. 1995. Cloning, sequencing and expression of serine/threonine kinase-encoding genes from Streptomyces coelicolor A3(2). Gene 153:99-104[CrossRef][Medline].
27.	Vomastek, T., R. Nadvornik, J. Janecek, Z. Technikova, J. Weiser, and P. Branny. 1998. Characterization of two putative protein Ser/Thr kinases from actinomycete Streptomyces granaticolor both endowed with different properties. Eur. J. Biochem. 257:55-61[Medline].
28.	Wietzorrek, A., and M. Bibb. 1997. A novel family of proteins that regulate antibiotic production in streptomycetes appears to contain an OmpR-like DNA-binding fold. Mol. Microbiol. 25:1181-1184[CrossRef][Medline].
29.	Yanisch-Perron, C., J. Vieira, and J. Messing. 1985. Improved M13 phage cloning vectors and host strains: nucleotide sequences of M13mp18 and pUC19 vectors. Gene 33:103-119[CrossRef][Medline].