Journal of Bacteriology, December 2003, p . 7019-7023, Vol . 185, No . 23

We present a mutational analysis of the crr-ptsI gene locus and demonstrate that EI and IIA^Crr are part of a PTS^Nag in S . coelicolor . We provide evidence that the two genes form an operon and that their expression, together with the third general gene of the PTS, ptsH, is induced by N-acetylglucosamine . The data suggest that the PTS of S . coelicolor is biased for N-acetylglucosamine metabolism, a novel feature that will be discussed .

Knockout mutation of crr and ptsI. Gene replacement plasmids pFT50 and pFT52 were constructed by several cloning steps to generate a crr and a ptsI mutant (Table 1) . Protoplasts of M145 were transformed and mutants were isolated as described previously (4, 8) . The resulting strain BAP2 (crr::aacC4) carried a deletion in crr ranging from nucleotides (nt) 146 to 280, in which the apramycin gene cassette (aacC4) was placed . The ptsI gene in strain BAP3 (ptsI::aacC4) was interrupted by the apramycin gene at nt 665 . Mutations were verified by PCRs that revealed the presence of aac4 and the correct chromosomal position by the use of oligonucleotides that hybridized in aac4 and on the chromosome just outside the recombination area (data not shown) . As can be seen from the Western blots in Fig . 1, no IIA^Crr (Fig . 1A, lane 2) and no EI (Fig . 1B, lane 3) were detectable in cell extracts of BAP2 and BAP3, respectively . Both mutations had no polar effect on the expression of the adjacent gene, since an immunosignal for EI was present in BAP2 (Fig . 1B, lane 2) extract and vice versa (Fig . 1A, lane 3) .

 
Phenotypes. BAP2 and BAP3 were examined regarding their growth phenotype on mineral medium (MM) agar plates (14) . Both mutants could not grow on N-acetylglucosamine, whereas utilization of galactose, glucosamine, glucose, glutamate, glycerol, lactose, maltose, mannitol, mannose, ribose, sorbitol, sorbose, sucrose, and xylose was not affected . The ptsI mutant was additionally impaired in fermentation of fructose, which is in agreement with previous publications (14, 16, 17) . A growth curve in MM supplemented with 0.1% Casamino Acids and either 50 mM glycerol, glucose, or N-acetylglucosamine was recorded as described to corroborate the N-acetylglucosamine-negative phenotype (14) . Within the first 35 h, the strains showed similar increases in biomass (Fig . 2A) . BAP2 and BAP3 then entered stationary phase when N-acetylglucosamine was present in the medium while the wild type continued growing for 20 h . The mutants and the wild type showed similar growth curves when glucose or glycerol served as the source of carbon (data not shown) .

 
Transport of N-[¹⁴C]acetyl-D-glucosamine (6.2 mCi mmol^-1) at a final concentration of 20 µM was performed (23) . BAP2 and BAP3 showed no detectable transport (<10 pmol of N-acetylglucosamine min^-1 mg [dry weight]^-1), while the wild type incorporated N-acetylglucosamine at a rate of 87 ± 5 U when grown on glycerol and 344 ± 31 U when grown on glycerol plus N-acetylglucosamine . Hence, under these conditions transport of N-acetylglucosamine was inducible by a factor of four in the wild type and was impaired in both mutants . PTS assays were carried out to investigate whether EI and IIA^Crr are directly required for PTS^Nag activity (17) . Phosphoenolpyruvate-dependent phosphorylation of N-acetylglucosamine in cell extracts of the wild type increased about fivefold (from 7.3 ± 0.3 to 40.5 ± 2.1 nmol of N-acetylglucosamine-phosphate min^-1 mg of protein^-1) when grown in the presence of N-acetylglucosamine (MM plus 0.1% Casamino Acids, 50 mM glycerol, ± 50 mM N-acetylglucosamine) . This activity was absent in cell extracts of BAP2 and BAP3 but could be restored upon addition of His-tagged EI or His-tagged IIA^Crr, respectively .

Carbon source-dependent synthesis. Since IIA^Crr and EI as well as the previously characterized HPr protein can be considered pleiotropically acting PTS proteins, we raised the question whether their synthesis is stimulated by growth on PTS substrates in comparison to growth on non-PTS carbon sources like glycerol and glucose . Protein levels of IIA^Crr, EI, and HPr were monitored by Western blotting (Fig . 3) . All three proteins showed 8- to 10-fold-higher amounts in mycelia grown on N-acetylglucosamine than in mycelia grown on fructose, glycerol, or glucose . Interestingly, growth on the other PTS sugar, fructose, did not lead to an enhanced synthesis of the PTS proteins .

 
Transcription of crr and ptsI. Next, we studied transcription of the crr-ptsI locus . Promoter activities were examined by taking advantage of the reporter gene mycgfp2⁺, a GC-rich variant of an improved gfp gene (24) . The mycgfp2⁺ gene was amplified from pMN406 by using oligonucleotides GFP1 (5'-TGCCACGGATCTGCAGGCTTAATTAACTGAAAGG-3') and GFP2 (5'-CGACGGATCCGATAAAATAAAAAAGGGG-3') introducing PstI and BamHI restriction sites (underlined) and stop codons in all reading frames (italics) prior to the ribosomal binding site and ligated in the Streptomyces-Escherichia coli shuttle plasmid pUWL-SK digested with the same endonucleases, giving plasmid pFT73 (Fig . 4A) (30) . A set of transcriptional fusions of putative promoter fragments was cloned into pFT73, yielding plasmids pFT102 to pFT105 (Table 1) . They were transformed into the wild type . Each strain was grown on glycerol, fructose, glucose, and N-acetylglucosamine and subjected to green fluorescent protein fluorescence quantification . The results revealed the presence of an N-acetylglucosamine-dependent promoter upstream of crr between nt -256 and -57 . This promoter was also active when the strains were grown in the presence of glycerol, glucose, and fructose . A second promoter was found to precede ptsI . This promoter was also inducible by N-acetylglucosamine .

 
Reverse transcription-PCR (RT-PCR) experiments were performed to corroborate these findings (Fig . 4B) . RNA of S . coelicolor grown on MM in the presence of 0.1% Casamino Acids plus a 50 mM concentration of either glycerol, fructose, glucose, or N-acetylglucosamine was prepared as described previously (14) . The One-Step RT-PCR kit (Qiagen) was applied according to the manufacturer's instructions with gene-specific oligonucleotides . Analysis of the mRNA of ptsH, crr, and ptsI and of a potential crr-ptsI operon transcript showed that they all were increased in RNA preparations from wild-type mycelia grown in the presence of N-acetylglucosamine, while RNA from fructose-, glucose-, or glycerol-grown mycelia exhibited lower amounts of transcript . Hence, the gene expression data confirmed the observed stimulation by N-acetylglucosamine of HPr, EI, and IIA^Crr synthesis and revealed that crr and ptsI constitute an operon .

In Bacillus subtilis, ptsH and ptsI form an operon that is constitutively expressed and that is localized downstream of ptsG, the gene for the glucose-specific PTS permease (6, 26) . In E . coli, ptsH, ptsI, and crr form a tricistronic operon, which is regulated in a complex fashion by the globally acting transcription factors catabolite activator protein and Mlc (18) . The expression varies about three- to fourfold and is stimulated either by cyclic AMP or by the presence of PTS substrates (3, 12, 21) . Hence, the N-acetylglucosamine-specific induction of the genes of the S . coelicolor PTS is a novel feature that distinguishes this PTS from others .

What can be the physiological rationale for an N-acetylglucosamine-biased PTS? Streptomycetes are an integral part of the indigenous soil microflora . Chitin (a ß-1,4-linked polymer of N-acetylglucosamine) and its breakdown products are commonly found in the soil . As chitin cannot directly enter the cell, it has to be degraded to chito-oligosaccharides and N-acetylglucosamine (22, 25) . It is obvious that the genes for chitin and N-acetylglucosamine metabolism are coordinately regulated . We found a common cis element, a 12-bp palindrome that is present in one copy 122 nt upstream of crr, in two copies in the promoter region of ptsH, and in front of chitinase genes (16, 17) . Transcriptional analyses of chitinase genes revealed that the cis element is involved in substrate induction and glucose repression (13, 22) . Thus, it will be worthwhile to identify the trans-acting element(s) to uncover the regulation of chi and pts genes and to determine whether both pathways are subject to a common regulatory mechanism .

The work was supported by grant SFB473 of the Deutsche Forschungsgemeinschaft .

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