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Previous Article | Next Article 
Journal of Bacteriology, November 1999, p. 7098-7106, Vol. 181, No. 22
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Transcriptional Organization of the Erythromycin
Biosynthetic Gene Cluster of Saccharopolyspora
erythraea
Andrew R.
Reeves,
R. Samuel
English,
J. S.
Lampel,
David A.
Post, and
Thomas J.
Vanden Boom*
Fermentation Microbiology Research and
Development, Abbott Laboratories, North Chicago, Illinois 60064-4000
Received 19 May 1999/Accepted 26 August 1999
 |
ABSTRACT |
The transcriptional organization of the erythromycin biosynthetic
gene (ery) cluster of Saccharopolyspora
erythraea has been examined by a variety of methods, including S1
nuclease protection assays, Northern blotting, Western blotting, and
bioconversion analysis of erythromycin intermediates. The analysis was
facilitated by the construction of novel mutants containing a S. erythraea transcriptional terminator within the
eryAI, eryAIII, eryBIII, eryBIV, eryBV, eryBVI,
eryCIV, and eryCVI genes and additionally by an
eryAI 
10 promoter mutant. All mutant strains demonstrated polar effects on the transcription of downstream ery
biosynthetic genes. Our results demonstrate that the ery
gene cluster contains four major polycistronic transcriptional units,
the largest one extending approximately 35 kb from eryAI to
eryG. Two overlapping polycistronic transcripts extending
from eryBIV to eryBVII were identified. In
addition, seven ery cluster promoter transcription start
sites, one each beginning at eryAI, eryBI,
eryBIII, eryBVI, and eryK and two
beginning at eryBIV, were determined.
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INTRODUCTION |
Saccharopolyspora
erythraea, a mycelium-forming actinomycete, is the major producer
of the clinically important macrolide antibiotic erythromycin.
Extensive genetic studies have provided some insight into the genes
involved in erythromycin biosynthesis (9, 17, 38). The
erythromycin biosynthetic genes are clustered on the S. erythraea chromosome similarly to other secondary metabolic pathway genes (3, 11, 14, 21, 22, 27). The erythromycin gene
cluster contains 20 genes involved in the biosynthesis of erythromycin
A. The genes involved in the biosynthesis of the polyketide ring, the
biosynthesis and attachment of mycarose to the macrolide ring, and the
biosynthesis and attachment of desosamine to the macrolide ring have
been designated eryA, eryB, and eryC genes, respectively. Additionally, there are three genes encoding modifying enzymes, designated eryF, eryG, and
eryK, as well as ermE, encoding the rRNA
methylase conferring erythromycin resistance on the host organism.
Finally, two open reading frames (ORFs), eryBI, which is not
essential for erythromycin A biosynthesis (13), and
orf5, encoding a putative type II thioesterase
(15), are also located in the ery gene cluster.
The central portion of the biosynthetic cluster contains the three
eryA genes encoding a type I polyketide synthase (4, 8). The left flank (conventional ery cluster
orientation [see Fig. 2]) contains two eryB genes
(eryBII and eryBIII); three eryC genes
(eryCI to eryCIII); two genes encoding
erythromycin-modifying enzymes, eryF (a C-6 hydroxylase) and
eryG (an O-methyltransferase); ermE;
eryBI, encoding a proposed 
-glucosidase; and
orf5, encoding a putative type II thioesterase. The right
flank contains four eryB genes (eryBIV to
eryBVII), three eryC genes (eryCIV to
eryCVI), and eryK (encoding a C-12 hydroxylase
[31]).
Previous transcriptional studies by Bibb et al. (2) have
shown that ermE and eryCI are transcribed in
opposite directions. However, a detailed transcriptional analysis of
the entire ery gene cluster has yet to be reported. Reeve
and Baumberg recently reported the effects of low levels of phosphate,
glucose, and ammonium on ery mRNA expression
(25). Here, we present the results of a transcriptional and
biochemical analysis of the majority of the erythromycin biosynthetic
gene cluster. A series of novel mutants containing either an S. erythraea transcriptional terminator inserted into genes located
throughout the ery cluster or an altered eryAI
10 promoter region were constructed and analyzed by either S1
nuclease protection assay, Northern blotting, Western blotting, or
bioconversion analysis with erythromycin intermediates. The results
indicate that the ery gene cluster contains four major polycistronic transcriptional units, the largest one extending approximately 35 kb, from eryAI to eryG. The
transcription start sites for seven ery cluster promoters
were also determined.
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MATERIALS AND METHODS |
Bacterial strains, growth conditions, and plasmids.
The
bacterial strains used in this study are described in Table
1. S. erythraea was grown in
ABB20 medium (corn flour, 5.7 g/liter; soy flour, 11.5 g/liter; dried
brewer's yeast, 1.5 g/liter; sucrose, 1.0 g/liter; CaCO3,
1.7 g/liter; Edsoy oil, 2.5 ml per 50 ml of medium) from spore
preparations maintained on R3M agar plates (16) at 33°C.
After 48 h of growth in ABB20 medium, 2.5 ml of cells was
transferred to 50 ml of SCM medium (23). S. erythraea CA340, an industrially improved erythromycin-producing strain, was maintained as spore preparations on ABB13 (soytone, 5.0 g/liter; soluble starch, 5.0 g/liter; CaCO3, 3.0 g/liter; MOPS (morpholine propane sulfonic acid), 2.1 g/liter; thiamine-HCl, 0.01 g/liter; FeSO4, 0.012 g/liter) agar plates or as
80°C glycerol stocks and grown under the same conditions as
S. erythraea NRRL2338. Escherichia coli was grown
either on Luria-Bertani agar plates or in Luria-Bertani broth
(29) at 33°C. The antibiotics used for the selection of
E. coli plasmids or S. erythraea integrants were
ampicillin (100 µg/ml), thiostrepton (20 µg/ml), and hygromycin (80 to 200 µg/ml).
DNA manipulations.
Restriction digestions, dephosphorylation
reactions with calf alkaline phosphatase, and ligation reactions with
T4 DNA ligase were performed as directed by the manufacturer. All
restriction enzymes and modification enzymes were purchased from New
England Biolabs (Beverly, Mass.). S1 nuclease was purchased from Ambion (Austin, Tex.) and Boehringer Mannheim (Indianapolis, Ind.).
Chromosomal Southern blotting was performed according to standard
procedures (29). All Southern hybridizations were performed
at 68°C. Hybridizing fragments were detected by the procedure
outlined in the Genius system (Boehringer Mannheim) with the
chemiluminescent substrate CDP-Star (Tropix, Bedford, Mass.) as the
detection reagent. DNA sequencing reactions were carried out according
to the dideoxy chain termination method of Sanger et al.
(30) with alkaline-denatured templates (Amersham, Arlington
Heights, Ill.) as described by the manufacturer.
Subcloning of an rrn terminator cassette within
ery cluster biosynthetic genes.
The eryBIII
mutant was constructed by subcloning a 5.1-kb PstI fragment
containing a terminator sequence from pDPE149 into the
BclI/NcoI sites within the eryBIII
gene to generate pDPE218. The S. erythraea strain containing
the terminator in eryBIII was designated
eryBIII::trrn. The eryBIV
mutant was constructed by subcloning a 300-bp BamHI
rrn terminator sequence (obtained from pTERM9) into the
BclI site located within the eryBIV gene
contained on pDPE46 to make plasmid pDPE205. The S. erythraea strain containing the terminator in eryBIV
was designated eryBIV::trrn. The
eryBV mutant was constructed by first subcloning a 300-bp
SpeI/XbaI terminator sequence from pDPE148A into
the SpeI site of pDPE45, forming pARR1. A 3.0-kb
HindIII/EcoRI fragment from pARR1 was subcloned into HindIII/EcoRI-digested pWHM3
(35), yielding pARR2. The S. erythraea strain
containing the terminator in eryBV was designated
eryBV::trrn. The eryBVI
mutant was constructed by first subcloning a 300-bp BamHI
terminator sequence from pTERM12 into the
BamHI/BglII site of pDPE27, generating pKAS132. A
4.6-kb HindIII/SphI fragment from pKAS132 was
then subcloned into HindIII/SphI-digested pWHM3, forming pKAS134. The S. erythraea strain containing
the terminator in eryBVI was designated
eryBVI::trrn. To construct the
eryCIV mutant, the same 300-bp BamHI terminator
sequence from plasmid pTERM12 was ligated into BclI-digested
pDPE27, generating pKAS133. A 4.6-kb
HindIII/SphI fragment from pKAS133 was then ligated into HindIII/SphI-digested pWHM3 to
generate plasmid pKAS135. The S. erythraea strain containing
the terminator inserted into the eryCIV gene was designated
eryCIV::trrn. The eryCVI
mutant was constructed by digesting plasmid pDPE201 with
PstI/StuI and inserting the terminator from
pTERM9 digested with PstI/StuI to generate
pDPE203. Plasmid pEVEH8 was digested with
XhoI/MluI, and the 2-kb fragment was added 3' to
the terminator to generate plasmid pDPE204. pDPE204 was then digested
with SpeI/NsiI and ligated to pWHM3 digested with
XbaI/PstI to generate plasmid pDPE212. The
S. erythraea strain containing the terminator inserted into the eryCVI gene was designated
eryCVI::trrn. The eryAI
mutant was constructed by subcloning a 300-bp
SstI/EcoRI fragment from pDPE148A into the
SstI/EcoRI site of pDPE45, yielding pARR4. To provide additional eryAI sequence downstream of the
terminator, a 1-kb SstI/PstI fragment from pAIX-5
was subcloned into the PstI/EcoRV site of pARR4,
yielding pARR5. The SstI fragment end was converted to a
blunt end, using T4 DNA polymerase. Finally, a 3.5-kb
SspI/PstI fragment from pARR5 was subcloned into
similarly digested pWHM3, yielding pARR8. The S. erythraea
strain containing the terminator in the eryAI gene was
designated eryAI::trrn. The S. erythraea CA340 eryAI mutant was constructed by using
the pJV1-based plasmid pMBE-2. pMBE2 was first digested with
HindIII and SspI to delete the
EcoRI sites. The remaining 5.1 kb of pMBE2 was ligated to a
3.0-kb HindIII/SspI fragment from pARR9,
forming pARR16. A 3.0-kb HindIII fragment from pARR9,
containing the rrn terminator and an additional 1.0 kb of
eryAI DNA, was ligated to HindIII-digested pARR16, forming pARR17. The S. erythraea CA340 strain
containing the terminator inserted into the eryAI gene was
designated CA340 eryAI::trrn. The
eryAIII mutant was constructed by inserting the 5.8-kb
XmnI/XbaI fragment from pGM402 into plasmid pCD1,
which contains the pJV1 replicon. A 2.0-kb cassette containing the
terminator and the hygromycin gene were inserted in the XhoI
site located approximately 1.2 kb from the 3' end of the
eryAIII gene, yielding pSAM14-2. The S. erythraea
strains containing integrated pSAM14-2 were designated NRRL2338
eryAIII::trrn and CA340
eryAIII::trrn. Protoplast
transformation of S. erythraea NRRL2338 was performed according to an adaptation of the procedure originally described by
Hopwood et al. (16). pARR17 and pSAM14-2 were transformed into S. erythraea CA340 by electroporation.
Analysis of ery gene cluster mutants by TLC.
All
integrants were initially screened by thin-layer chromatography (TLC)
as described by Weber et al. (36), for their ability to
produce erythromycin A or the predicted intermediate. Bioconversion assays were performed by adding in separate time course experiments the
erythromycin intermediates 6-deoxyerythronolide B (6-dEB), erythronolide B (EB), 3-mycarosyl erythronolide B (MEB), erythromycin C, or erythromycin D. These substrates were added at the time of
transfer into SCM medium from ABB20 medium. The resulting
biotransformation cultures were analyzed for 1 to 5 days as described
above. All erythromycin intermediates were added at a final
concentration of 25 µg/ml.
RNA isolation.
Ten milliliters of S. erythraea
cells was harvested quickly by vacuum filtration onto a Whatman no. 1 filter over ice and washed with 50 ml of cold 10 mM EDTA. The cells
were resuspended with 5 ml of extraction buffer (20 mM sodium acetate,
4 M guanidinium isothiocyanate, 1 mM EDTA, pH 8.0), dispersed using a
Misonix (Farmingdale, N.Y.) sonicator (50% duty; power setting, 4; 60 pulses; 1-s duration), and vortexed with glass beads. Sodium dodecyl sulfate was added to a final concentration of 2% followed by acidic hot (65°C) phenol (Ambion) extraction. The aqueous phase was
extracted with phenol, phenol-chloroform, and chloroform before
precipitation. Northern blotting was performed according to established
protocols as described by Sambrook et al. (29). Church's
buffer was used in the prehybridization and hybridization reactions
(5).
S1 nuclease protection assays.
Single-stranded DNA probes
for S1 nuclease protection assays were generated by a modification of
the runoff replication procedure described in the manual accompanying
the S1 nuclease kit (Ambion). Plasmids containing the appropriate
ery cluster gene sequences were uniformly labeled with
[32P]dCTP and [32P]dGTP by using
sequence-specific primers and Sequenase. In all cases, the sizes of the
probes were controlled by linearizing the plasmid with a restriction
enzyme that cleaved approximately 200 to 275 bp from the priming site.
Single-stranded, uniformly labeled probes were purified from their
templates by denaturing polyacrylamide gel electrophoresis (5%
acrylamide, 8 M urea-Tris-borate-EDTA). For hybridizations, total
S. erythraea RNA was mixed with 104 to
105 Chelenkov counts per min of probe at 50 to 55°C for
18 h. Detection of S1-protected fragments was performed according
to the procedure outlined in the manual accompanying the S1 nuclease kit.
Oligonucleotide-directed mutagenesis.
In order to alter the
predicted 10 region of eryAI from the native sequence
(TATTGT) to an SmaI site (CCCGGG), the
following PCR primers were designed: Set A,
5'-ATGAATTCTGCGCGCCCTGGCCCGGGAAGACGAA-3' and
5'-TCTCCCGGGTCGCCATTGCGTGGTCGTCG-3', and set B,
5'-TCTCCCGGGTAGGAAGGATCAAGAGGTTGACAT-3' and 5'-CGGAATTCTGATCAATTGACGGGGAATCA-3'. The
PCR product of primer set A was digested with EcoRI and
SmaI and subcloned into
EcoRI/SmaI-digested pUC18, yielding pARR47. The
PCR product of primer set B was digested with SmaI and then subcloned into SmaI-digested pARR47, yielding pARR48.
SmaI digestion and sequencing confirmed the generation of an
SmaI site at the predicted 10 region of eryAI
in the correct orientation. In order to replace the native
eryAI 10 region with the altered sequence, pARR48 was
digested with BclI and ClaI. This generated
4.0-kb and 400-bp fragments. pARR3, which contains the native
eryAI promoter region and an additional 1.6 kb of
eryAI and eryBIV DNAs, was digested with
BclI and ClaI. The larger fragment was resolved and gel purified from the 400-bp BclI/ClaI
fragment and ligated to the mutagenized 400-bp
BclI/ClaI fragment, yielding pARR49. Finally, a
2.0-kb EcoRI/HindIII fragment from pARR49,
containing the entire eryAI-eryBIV promoter region and an
additional 1.6 kb of the eryAI and eryBIV genes,
was subcloned into the S. erythraea insertion vector pWHM3
(35), yielding pARR50. pARR50 was protoplast transformed
into wild-type S. erythraea as described above.
Other procedures.
Western blotting was performed with rabbit
anti-EryG antibodies cross-reacted to soluble cell extracts obtained
from various S. erythraea strains. Samples containing 10 µg of protein per lane were loaded onto a sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (10% acrylamide) gel. The
resolved proteins were electrotransferred onto polyvinylidene
difluoride membranes (Millipore) at 90 V for 2 h according to
standard procedures (29). Cross-reacting proteins were
detected with the ECL kit as described by the manufacturer (Amersham).
Quantitation of S1-protected fragments was performed with a Storm 860 PhosphorImager (Molecular Dynamics, Sunnyvale, Calif.) equipped with
ImageQuant software.
| |
RESULTS |
Construction of ery gene cluster mutants containing an
inserted rrn terminator.
Insertional inactivation of
erythromycin biosynthetic cluster genes by targeted mutagenesis was
performed by constructing S. erythraea mutants containing an
inserted S. erythraea rrn operon terminator at specific
sites within the eryAI, eryAIII,
eryBIII, eryBIV, eryBV,
eryBVI, eryCIV, and eryCVI genes
(Table 1). A flow diagram showing the pathway leading to the production
of erythromycin A in S. erythraea and the genes involved is
given in Fig. 1. Insertion of the
rrn terminator allowed the study of the polar effects on
downstream ery gene cluster expression by blocking
transcription from an upstream promoter(s). The terminator sequence was
obtained from the cloned S. erythraea rrnD operon, which has
been physically mapped on the chromosome (26). A native S. erythraea terminator was chosen to avoid any differences
that might arise among species. The terminator sequence used for
insertion mutagenesis was subcloned as a 227-bp fragment, including 22 bp of the 5S portion of the rrn operon. The region was
analyzed for secondary structure with the MulFold program (18, 19,
41). Two regions containing secondary structure were identified.
The first region, beginning 7 bp downstream from the end of the 5S gene, was predicted to contain a stem structure 17 bp long with a 4-bp
loop immediately followed by a thymidine-rich region, characteristic of
rho-independent terminators (7). The calculated
G of the stem-loop was 30 kcal/mol. A potential second
stem-loop structure was identified 30 bp downstream from the first
stem-loop structure. It had a predicted 18-bp stem with a 4-bp loop
followed by a thymidine-rich region. This stem-loop structure had a
predicted G of 24.5 kcal/mol. The engineered S. erythraea DNA containing the terminator was introduced into the
chromosome by homologous recombination with vector pWHM3
(35), which replicates poorly in S. erythraea. As
an example, the eryBIII mutant was constructed by
transforming plasmid pDPE218 into S. erythraea, and the
resulting mutant strain containing the terminator sequence in
eryBIII was designated
eryBIII::trrn. All integrants derived
by integration with pWHM3 in S. erythraea NRRL2338 were the
result of two separate reciprocal-recombination events which resulted
in the eviction of the selectable marker from the chromosome.
Integrants derived from plasmid pSAM14-2 required that the hygromycin
resistance gene remain in the chromosome. Chromosomal Southern blotting
with fragments that overlapped the junctions of the inserted DNA as
probes confirmed the correct integration of the terminator sequence in
each mutant (data not shown).
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FIG. 1.
Flow diagram indicating the biochemical intermediates
and the genes involved in the biosynthesis of erythromycin A. ErD,
erythromycin D; ErC, erythromycin C; ErA, erythromycin A; CoA, coenzyme
A.
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S1 mapping of the transcription start sites for seven
ery cluster promoters.
As evidenced by the
ery biosynthetic gene cluster map (see below) (Fig.
2), the majority of the promoters
identified in this study were predicted to be tandemly arranged and
divergently transcribed. Figure 3 shows
the results of S1 nuclease mapping of seven transcriptional start sites
within four predicted promoter regions. These promoter regions were the
224-bp eryAI-eryBIV intergenic region, the 188-bp eryBI-eryBIII intergenic region, the 83-bp
eryCVI-eryBVI intergenic region, and the region immediately
upstream of eryK.
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FIG. 2.
Transcriptional map of the 56-kb erythromycin
biosynthetic gene cluster illustrating known and predicted transcripts.
The thick arrows represent monocistronic transcripts identified by S1
mapping in this study and by Bibb et al. (2). The thin
arrows represent polycistronic messages identified in this study, the
longest of which extends 35 kb, from eryAI to
eryG. The dashed arrows represent putative messages which
have not been experimentally verified. The dotted arrow represents a
potentially transcribed gene. The asterisks indicate promoter regions.
The carets below the genetic map indicate the genes for which mutants
containing a transcriptional terminator were constructed in this
study.
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FIG. 3.
S1 nuclease mapping of the 5' endpoints of
ery cluster transcripts. The nucleotide(s) at the side of
each panel indicate the likely transcription start site(s). (A)
eryBIV; (B) eryAI; (C) eryBI; (D)
eryBIII; (E) eryBVI; (F) eryK. The
same primer was used to generate the sequence ladder and the
32P-labeled probe for S1 assays. For clarity,
similar-intensity images of the S1 and sequence ladder lanes from the
same gel were juxtaposed.
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To determine the transcription start site for the eryBIV
transcript, a 262-bp probe extending from the BclI site in
eryBIV to the MluI site located at the beginning
of eryAI was used. Three eryBIV protected
fragments were identified, beginning 84, 88, and 132 bp upstream of the
predicted translation start codon (Fig. 3A). The 84- and 88-bp
protected fragments were consistently more abundant than the 132-bp
fragment, suggesting that this is the location of the major promoter
expressing the eryBIV message (under these experimental
conditions). The 35 region of the minor eryBIV promoter is
predicted to overlap the 35 region of eryAI. The eryAI transcription start site was identified by using a
314-bp probe starting 76 bp within the eryAI gene. A
protected fragment 103 bp in length was observed, beginning 27 bp
upstream of the predicted translation start codon (Fig. 3B).
The eryBI transcription start site was identified by using a
probe that began 45 bp into eryBI and extended to an
NdeI site 35 bp within eryBIII. Two S1-protected
fragments were observed, beginning 17 and 18 bp upstream of the
predicted translational start for eryBI (Fig. 3C). To
determine the eryBIII transcription start site, a 238-bp
probe extending from a priming site 70 bp within eryBIII to
a BclI site 20 bp upstream of eryBI was used. Two
S1-protected fragments were also observed 1 and 2 bp upstream of the
predicted GTG translation start codon for eryBIII (Fig. 3D).
The size of the predicted eryBVI-eryCVI intergenic region
(83 bp), along with biochemical evidence obtained in this study (see
below), suggested that there could be a promoter located upstream of
eryBVI (12, 33). We tested this prediction by performing S1 assays with a 345-bp probe that extended from a site
within the 5' end of eryBVI to a StuI site in
eryCVI. Two S1-protected fragments were observed (Fig. 3E),
beginning 1 and 2 bp upstream of the predicted start codon
(12).
The eryK transcription start site was identified by
generating a 240-bp probe beginning 65 bp within the eryK
gene and extending to a BamHI site within orf21.
Several S1-protected fragments beginning 45 to 50 bp upstream of the
predicted TTG start site (31) and 9 to 14 bp from the
predicted termination codon of orf21 marked the
transcription start site for eryK (Fig. 3F). The predicted 35 and 10 promoter regions and mRNA start sites are also shown (see
Fig. 8).
Characterization of ery gene cluster transcripts by S1
assay.
To test whether the insertion in
eryAI::trrn was having a polar effect
on transcription of the downstream eryG gene (Fig. 2), S1
assays were performed on total RNAs from NRRL2338
eryAI::trrn and CA340
eryAI::trrn with an eryG
probe. A significant reduction of eryG signal in the
insertion mutant strains was observed compared to that in the parental
background strains (Fig. 4). Quantitation of the hybridizing band in NRRL2338
eryAI::trrn showed an approximately 70% reduction in eryG signal compared to NRRL2338, whereas
CA340 eryAI::trrn showed a >90%
reduction of eryG signal compared to CA340.
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FIG. 4.
Comparison by S1 nuclease protection assay of the mRNA
levels of the eryAI transcript in S. erythraea
NRRL2338, NRRL2338 eryAI::trrn, CA340,
and CA340 eryAI::trrn. Lanes: (1)
probe only, untreated; (2) probe only, S1 treated; (3) probe hybridized
with 40 µg of Saccharomyces cerevisiae RNA; (4) probe
hybridized with 40 µg of S. erythraea CA340 RNA; (5) probe
hybridized with 40 µg of S. erythraea CA340
eryAI::trrn RNA; (6) probe hybridized
with 40 µg of S. erythraea NRRL2338
eryAI::trrn RNA; (7) probe hybridized
with 40 µg of NRRL2338 RNA. A total of 104 cpm of probe
was used per S1 nuclease reaction. The asterisk indicates full-length
probe. The arrow at the right indicates the S1-protected fragment. For
clarity, a lower-intensity exposure of lane 1 was used.
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To determine whether the terminators in the eryBIV,
eryBV, and eryCIV genes were having a polar
effect on eryBVII transcription (Fig. 2), S1 assays were
performed on total RNAs from
eryBIV::trrn, eryBV::trrn, and
eryCIV::trrn with a labeled probe that
extended entirely within the eryBVII reading frame. Because
the entire probe was internal to the eryBVII gene,
additional, nonhybridizing DNA (31 bp, composed of a multiple cloning
site) was cloned into the plasmid used to make the probe to distinguish
between undigested full-length probe and the protected fragment.
There was a significant decrease in the amount of eryBVII
hybridization signal. The decrease in eryBVII
hybridization signal in eryBIV::trrn
and eryBV::trrn was similar to the
decrease in eryG signal in
eryAI::trrn. The results showed a
decrease in signal of the hybridizing fragment of roughly 70 and 80%
for the eryBIV and eryBV mutants, respectively, compared to NRRL2338 (data not shown). In the case of
eryCIV::trrn, no defined protected
fragment was observed even after long exposure. This indicated that the
terminator insertions in the eryBIV, eryBV, and
eryCIV mutant strains had a polar effect on
eryBVII expression.
Biochemical evidence (see below) suggested that there could be two
promoters within the right flank producing overlapping transcripts. S1
assays were performed on eryBIV::trrn,
S. erythraea CA340, and
eryAIII::trrn with an
eryBVI probe (Fig. 5).
eryAIII::trrn was used as the positive
control in these experiments. In CA340 (Fig. 5, lane 3) and
eryAIII::trrn (lane 6), two protected
fragments were observed. The larger protected fragment (330 bp)
represents a transcript beginning at the eryBIV promoter,
and the smaller protected fragment (180 bp) represents a transcript
beginning at the eryBVI promoter, suggesting that the two
promoters produce overlapping transcripts. In
eryBIV::trrn (lane 5), only the 180-bp protected fragment is observed, suggesting that the inserted terminator in eryBIV is efficiently terminating transcription.
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FIG. 5.
The right flank of the ery gene cluster
contains two overlapping transcripts from eryBIV to
eryBVII. Lane 1, Full-length eryBVI probe treated
with S1 nuclease; lane 2, same as lane 1 but not treated with S1
nuclease; lane 3, 40 µg of yeast RNA hybridized with probe; lane 4, 40 µg of S. erythraea CA340 RNA hybridized with probe;
lane 5, 40 µg of eryBIV::trrn RNA
hybridized with probe; lane 6, 40 µg of CA340
eryAIII::trrn RNA hybridized with
probe. All samples were treated with 50 U of S1 nuclease. A total of
3 × 104 Chelenkov counts per min were used per
reaction. P, full-length protected fragment; the asterisk marks a
shortened S1-protected fragment.
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Northern and Western blotting of the eryA mutants
reveal a polar effect of the terminator on eryG
expression.
To further analyze ery cluster transcripts
in the eryAI-eryG region, Northern blotting was performed on
total RNAs extracted from 2-day fermentation cultures of S. erythraea CA340 and CA340 eryAIII::trrn. Hybridization of total
RNA from S. erythraea CA340 with an eryG probe
revealed two transcripts approximately 2,600 and 1,200 bp in length
(Fig. 6). The smaller transcript in
NRRL2338 has been described previously by Weber et al. (37).
The same Northern blot was probed with the eryBII gene
located immediately upstream from eryG. The hybridization
pattern was identical to that of the larger transcript from the
eryG hybridization (Fig. 6). This indicates that the larger
transcript contains eryBII and eryG. In the CA340
eryAIII::trrn mutant, no detectable
transcript was observed, even when 15-fold more RNA from the mutant was
used in the hybridization.
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FIG. 6.
Northern blot analysis of the eryG and
eryBII-eryG transcript. Lane 1, 50 µg of CA340 RNA; lane
2, 50 µg of S. erythraea CA340
eryAIII::trrn probed with an
eryG probe; lane 3, 50 µg of CA340 RNA probed with an
eryBII probe.
|
|
Western blot analysis was performed on NRRL2338 and NRRL2338
eryAI::trrn to determine if the
O-methyltransferase protein was present in cell extracts of
these strains. A cross-reacting band corresponding to EryG protein was
observed in NRRL2338 and an E. coli strain overproducing
EryG but not in an S. erythraea strain with eryG
deleted or in the eryAI::trrn mutant
(data not shown). The Northern and Western blot analyses, in
conjunction with the S1 studies, provide strong evidence that the
eryAI, eryAII, eryAIII, eryBII, eryCII, eryCIII, and
eryG genes are primarily cotranscribed from a promoter
upstream of eryAI.
Bioconversion analysis of the mutants supplemented with
erythromycin intermediates.
To verify that the RNA results
correlated with biochemical phenotypes, biotransformation assays were
performed on the insertion mutants with erythromycin intermediates. All
the mutants were initially screened by TLC assay without supplemented
intermediates to confirm the predicted effect of the mutation at the
enzymatic level. All of the mutants showed the expected phenotype
(Table 2). To test the effectiveness of
the terminator to disrupt transcription in the eryA
insertion mutants NRRL2338
eryAI::trrn, CA340
eryAI::trrn, and NRRL2338
eryAIII::trrn, the erythromycin
intermediates 6-dEB, EB, MEB, and erythromycin C (final concentration,
25 µg/ml) were added to 50-ml shake flask fermentations and assayed
for erythromycin A formation over a 4-day period. The results for
erythromycin C bioconversion are shown in Fig.
7. The mutants showed a significant reduction in the formation of erythromycin A and the extent of erythromycin A production from all the intermediates compared to that
of the wild type, which bioconverted all the intermediates to
erythromycin A within 24 h. No dramatic differences in the formation of erythromycin A from the various intermediates were observed. To determine whether the inserted terminator was having an
effect other than on termination of transcription, a mutant (S. erythraea ARR50) was isolated in which the predicted
eryAI AT-rich 10 hexamer sequence (TATTGT) was
replaced with an SmaI site (CCCGGG). No
erythromycin A was observed over a 5-day period in 50-ml shake flask
fermentations of this strain. Additionally, when 50-ml cultures of
ARR50 were supplemented with EB, MEB, erythromycin C, and erythromycin
D in biotransformation experiments over a 5-day period, bioconversion
to erythromycin A was significantly reduced compared to that of the
wild type, as observed similarly in NRRL2338
eryAI::trrn (data not shown). Thus,
mutagenesis of eryAI by either insertion of a terminator or
alteration of the predicted 10 region resulted in the same phenotype.
To determine whether the insertion in the eryB mutant
strains eryBIV::trrn, eryBV::trrn, and
eryBVI::trrn was having a polar effect
on downstream eryC genes, bioconversion assays were
performed with supplemented MEB over a 5-day period. The
eryBIV::trrn and
eryBV::trrn mutants showed a
significant reduction in the amount of erythromycin A formed compared
to that of S. erythraea NRRL2338.
eryBIV::trrn produced erythromycin A
after 1 day of fermentation, whereas it required 5 days to detect
erythromycin A by the TLC assay with strain
eryBV::trrn. Based on the predicted
structural (enzymatic) functions of the EryBIV, EryBV, and EryCVI
proteins, this shows cotranscription of at least eryBIV,
eryBV, and eryCVI.
eryBVI::trrn did not produce any
erythromycin A, even when the sample loaded for TLC analysis was
fivefold concentrated, showing cotranscription (by the same reasoning
used for the predicted cotranscription of eryBIV,
eryBV, and eryCVI) of at least eryBVI
and eryCIV.
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|
TABLE 2.
S. erythraea mutant strains generated by
insertional mutagenesis or alteration of the 10 promoter region
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FIG. 7.
TLC assay to test the ability of the eryA
transcriptional mutants eryAI::trrn
and eryAIII::trrn to bioconvert
erythromycin C to erythromycin A. Erythromycin C (25 µg/ml) was added
separately to 50-ml SCM cultures containing the eryA mutants
and the eryBIV mutant,
eryBIV::trrn. One milliliter of the
culture broth from 0- to 4-day fermentations was extracted with ethyl
acetate and analyzed by TLC. The eryBIV mutant was used as
the positive control. Both S. erythraea NRRL2338 (data not
shown) and eryBIV::trrn completely
bioconverted all the supplemented erythromycin C to erythromycin A in
less than 1 day between days 1 and 2 of the fermentation. 0, no added
erythromycin C; 0+, sample taken at the time of supplementation; 1 to
4, day of sampling following addition of erythromycin C; Std., TLC
standards (M, 3-mycorosyl erythronolide B; E, erythronolide B; B,
erythromycin B; A, erythromycin A; C, erythromycin C).
|
|
In eryC insertion mutants constructed on the right flank of
the ery cluster, it was expected that the biochemical
phenotype would be the same as that observed in the eryB
insertion mutants described above (accumulation of only EB), since it
was predicted that the insertion would exert a polar effect on
downstream eryB genes. In biochemical studies the
eryCVI mutant,
eryCVI::trrn, accumulated both EB and
MEB after 2 days of fermentation, suggesting an effect on the
transcription of downstream eryB genes. However, eryCVI::trrn was able to bioconvert
all the EB formed to MEB after 4 days. This result is consistent with
the S1 assay data suggesting that there is a promoter upstream of
eryBVI. The eryCIV mutant, eryCIV::trrn, accumulated equal
amounts of EB and MEB. In contrast to
eryCVI::trrn,
eryCIV::trrn did not bioconvert any of
the EB to MEB, even after 4 days of fermentation. This suggests that premature transcription termination of a significant fraction of
transcript from both the eryBIV and eryBVI
promoters was occurring in
eryCIV::trrn (see below).
Previous insertion mutagenesis experiments in the region now known to
contain the eryBIII, eryF, and orf5
genes showed that those mutants either were affected in the C-6
hydroxylation step (eryF phenotype) or have an
eryH mutation and accumulate EB (EryB phenotype)
(34). To determine whether an insertion in
eryBIII would have a polar effect on the expression of the
downstream eryF gene, TLC assays were performed on
eryBIII::trrn over a 5-day period.
This strain accumulated only 6-dEB early in the fermentation (24 to
48 h after inoculation), indicating a polar effect on the transcription of eryF.
Thus, although the S1, Northern, and Western assay data suggest an
almost complete absence of transcript downstream from the inserted
terminators, biochemical evidence suggests either that a low level of
read-through of the terminator is occurring or that there are secondary
(minor) promoters producing low levels of the downstream transcripts.
| |
DISCUSSION |
Transcriptional arrangement of the erythromycin biosynthetic gene
cluster.
Figure 2 shows a schematic representation of the
transcriptional organization of the 56-kb ery gene cluster
based on previous work by Bibb et al. (2) and the results
presented in this study. The present work has identified through S1
assay, Northern blot analysis, Western blotting, and biochemical assays
that the ery biosynthetic gene cluster is primarily
transcribed as four polycistronic messages: eryAI-eryG,
eryBIV-eryBVII, eryBVI-eryBVII, and
eryBIII-eryF. The largest transcript is approximately 35 kb
and contains most of the left flank of the biosynthetic gene cluster.
The presence of a very large message on the left flank of the
ery cluster was not totally unexpected, since previous
studies (8, 28, 33) predicted the possibility of
translational coupling of many genes in the eryAI-eryG
region. Bioconversion of erythromycin C to erythromycin A was observed
in the eryAI transcriptional mutants at a much reduced rate,
suggesting that there is a possible minor promoter(s) in the region
downstream of the terminator insertions or that read-through of the
inserted terminator is occurring. The S1 assay with the 5' end of
eryG as a probe was in agreement with the prediction made
from the biochemical data, since greatly reduced levels of eryG message were detected in the eryA mutants.
Possible locations for secondary promoters include the region between
the insertions in eryAI and eryAIII and the
region downstream of the eryAIII insertion.
In order to confirm the transcriptional organization of the
eryAI-eryG region suggested from the analysis of the
transcriptional terminator mutants, a strain was constructed by
oligonucleotide-directed mutagenesis to alter the predicted
eryAI 10 hexamer region. The eryAI 10 region
in S. erythraea is A+T rich, and therefore it was expected
that altering the hexamer to all G+C would dramatically affect
expression from that promoter. This strain had a phenotype similar to
that of the eryA insertion mutants in TLC and
biotransformation assays. No erythromycin A production was observed.
This strain also bioconverted erythromycin intermediates in a manner
similar to that of the eryAI terminator insertion mutant.
This confirms that the predicted 10 region plays an important role in
gene expression at the eryAI promoter and that the mutation
has a polar effect on downstream eryG transcription.
We have identified two major promoter regions expressing the deoxysugar
genes on the right flank of the ery gene cluster. These
promoters produce overlapping transcripts, one beginning upstream of
eryBIV and extending to eryBVII (about 8.0 kb)
and the other beginning at eryBVI and extending to
eryBVII (about 4.8 kb). These data provide additional
evidence of the effectiveness of the terminator in disrupting
transcription. Although the biochemical data indicated that some MEB is
bioconverted to erythromycin A in
eryBIV::trrn, presumably by
read-through of the terminator, no S1-protected fragment corresponding
to the large mRNA (8.0 kb) was detected. This suggests that
eryBIV message has been severely reduced in
eryBIV::trrn but that some transcript
is being made, which is undetectable in the S1 assay, to allow a low
level of enzyme production and bioconversion.
When the initial biochemical assays were performed on the
eryC mutants located on the right flank of the
ery gene cluster, an EryB phenotype was expected, since the
insertion was predicted to have a polar effect on one or more
eryB genes. Surprisingly, both EB and MEB accumulated in the
culture supernatants in these strains. These data, taken together with
the S1 assay results indicating a promoter upstream of
eryBVI, suggest several possibilities: (i) that very little
EryBVII is necessary for the predicted 3,5 epimerization reaction
despite our not being able to visualize an S1-protected fragment; this
would suggest that there is a promoter downstream of eryCIV
or enough read-through of the terminator is occurring to allow
sufficient production of the epimerase; (ii) that the predicted 3,5 epimerization reaction catalyzed by EryBVII is being carried out by
another epimerase, as was suggested by Linton et al. and Salah-Bey et
al. (20, 28); or (iii) that the MEB observed is
unepimerized. Recently, it has been shown that an eryBVII
mutant accumulates mainly EB and small amounts of erythromycin A and
erythromycin B analogs in which the neutral sugar residue might contain
a 3-C-methyl or 3-O-methyl 4-keto-6-deoxyglucose or the 5-epimer of cladinose (13), indicating that the
EryBVII epimerization reaction cannot be complemented by another
epimerase under the growth conditions used. This suggests that what we
observed by TLC analysis in the eryCIV mutant was EB and
possibly unepimerized MEB.
The right flank of the ery gene cluster also contains the
eryK gene, which is transcribed in the opposite direction
from the eryB and eryC genes. eryK
appears to be expressed as a monocistronic message, although we have
not ruled out the possibility that this message is derived from a
larger transcript. Only one eryK transcript was observed in
the S1 assay, suggesting that either the eryK transcript is
rapidly processed from a larger transcript or it is monocistronic. We
consider the former possibility unlikely, since sequence analysis of a
7.0-kb region upstream of eryK by Pereda et al.
(24) indicated no obvious involvement of the ORFs in
erythromycin biosynthesis. Along with eryK and the
previously described ermE and eryCI genes,
eryBI is transcribed as a monocistronic message, bringing
the total number of ery cluster genes contained in their own
transcriptional units to four. Recently, eryBI was shown not
to be essential for erythromycin biosynthesis (13).
Previous work performed on the eryBIII-eryF region
(previously designated the eryH region) showed that these
genes and possibly the undefined orf5, are probably arranged
as an operon, since insertion mutants generated in that study were
determined to be affected in the C-6 hydroxylation step
(eryF mutant) or to have an eryH mutation and
accumulate EB (EryB phenotype) (34). Additionally, the TGA
codon of eryF (previously designated orf4) and
the predicted ATG start of orf5 overlap by 1 bp, potentially
making these two genes translationally coupled (15). Results
of TLC assays of supernatants from a strain containing a terminator in
eryBIII showed an accumulation of 6-dEB. Additionally, the
cultures accumulated other unknown products after several days of
growth in shake flask fermentations. These strains are able to
bioconvert MEB to erythromycin A, indicating that not all genes
involved in downstream synthesis were affected in these mutants. The
precise role of the orf5 gene has yet to be determined.
Haydock et al. (15) have proposed that this gene encodes a
type II thioesterase or acyltransferase. The ORF5 gene product is not
essential for erythromycin production, since insertions in the reading
frame do not eliminate erythromycin biosynthesis (10).
However, a significant decrease in macrolide production (6-dEB in this
strain) was observed, along with the production of other unknown
compounds, in this mutant compared to other engineered strains.
Recently, Cundliffe (6) and Xue et al. (40) have
reported similar decreases in macrolide production of mutant strains
deficient in type II thioesterases. Thus, it appears that
eryBIII, eryF, and possibly orf5 are cotranscribed.
Previous work predicted a promoter region upstream from the
eryG translational start site, since a cloned fragment from
that region gave promoter activity with a luxAB reporter
group system. In addition, the putative transcription start site was
determined in S. erythraea by S1 mapping (37). We
propose in addition to this prediction and as a possible alternative
hypothesis, that what was observed previously was primarily the result
of RNA processing of the eryAI-eryG transcript and not a
major independently transcribed message. The promoter activity observed
might have been due to (i) the introduction and expression of S. erythraea DNA in the heterologous host Streptomyces
lividans and (ii) the high copy number of pIJ702-based vectors in
S. lividans. It is still possible that there is a minor
promoter located in the region upstream of eryG and
downstream of the insertion site in eryAIII, but it would be
significantly weaker than the eryAI promoter, as indicated by the RNA and bioconversion experiments. The basis for the stability of the eryG-containing transcript (observed in the Northern
blot analysis) compared to the mature 35-kb transcript is unknown. Figure 8 shows an alignment of all the
ery cluster promoter regions showing the transcription start
sites and the predicted 10 and 35 regions. Several promoter
sequences have similarity to the E. coli consensus 10 and
35 regions as well as to the modified consensus determined for
Streptomyces (32). All of the 10 and 35
regions determined in this study contain a predicted spacer region
between 16 and 18 bp. In several cases there is a conserved T at
position 6 in the 10 region, which has been shown to be common in
Streptomyces promoters (39). In several cases,
multiple protected fragments were observed at the 5' transcription
endpoint. The transcriptional studies reported here indicate that the
majority of ery biosynthetic genes are transcribed as large
polycistronic messages from several key regulatory regions. This work
should facilitate future studies directed at improving our
understanding of the regulation of this industrially important
secondary metabolic pathway.
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FIG. 8.
Alignment of 10 ery gene cluster promoters.
The predicted 10 and 35 regions are underlined. The predicted start
sites are boldface and underlined. In five cases, more than one 5'
endpoint was identified in the S1 mapping, and all are underlined. The
asterisks mark promoters determined by Bibb et al. (2). a,
E. coli consensus for sigma-70 promoters; b, modified
E. coli consensus determined for Streptomyces
(32).
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|
| |
ACKNOWLEDGMENTS |
We thank Mark Satter for constructing the plasmids used to
generate the eryBVI and eryCIV mutants and Mike
Staver for providing the plasmid containing the cloned S. erythraea rrn operon and pAIX-5. We also acknowledge Marty Babcock
and Sandra Splinter for providing the anti-EryG antibodies and
technical advice with the Western blotting and Steve Kakavas, Diane
Stassi, and Kurt Harris for technical assistance in using the
PhosphorImager. Thanks also to Janet Westpheling for suggesting
site-specific mutagenesis of the 10 hexamer region.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Fermentation
Microbiology Research and Development, Abbott Laboratories, 1401 Sheridan Rd., North Chicago, IL 60064-4000. Phone: (847) 937-4470. Fax: (847) 938-7509. E-mail: thomas.vandenboom{at}abbott.com.
Present address: Fermalogic Inc., Chicago Technology Park,
Chicago, IL 60612.
Present address: College of Health Sciences, Roanoke, VA 24018.
| |
REFERENCES |
| 1.
|
Bailey, C. R.,
C. J. Bruton,
M. J. Butler,
K. F. Chater,
J. E. Harris, and D. A. Hopwood.
1986.
Properties of in vitro recombinant derivatives of pJV1, a multicopy plasmid from Streptomyces phaeochromogenes.
J. Gen. Microbiol.
132:2071-2078[Medline].
|
| 2.
|
Bibb, M. J.,
J. White,
J. M. Ward, and G. R. Janssen.
1994.
The mRNA for the 23S rRNA methylase encoded by the ermE gene of Saccharopolyspora erythraea is translated in the absence of a conventional ribosome binding site.
Mol. Microbiol.
14:533-545[Medline].
|
| 3.
|
Caballero, J. L.,
E. Martinez,
F. Malpartida, and D. A. Hopwood.
1991.
Organization and functions of the actVA region of the actinorhodin biosynthetic gene cluster of Streptomyces coelicolor.
Mol. Gen. Genet.
230:401-412[Medline].
|
| 4.
|
Caffrey, P.,
D. J. Bevitt,
J. Staunton, and P. F. Leadlay.
1992.
Identification of DEBS 1, DEBS 2, and DEBS 3, the multienzyme polypeptides of the erythromycin-producing polyketide synthase from Saccharopolyspora erythraea.
FEBS Lett.
304:225-228[Medline].
|
| 5.
|
Church, G. M., and W. Gilbert.
1984.
Genomic sequencing.
Proc. Natl. Acad. Sci. USA
81:1991-1995[Abstract/Free Full Text].
|
| 6.
| Cundliffe, E. Personal communication.
|
| 7.
|
Deng, Z.,
T. Kieser, and D. A. Hopwood.
1987.
Activity of a Streptomyces transcriptional terminator in Escherichia coli.
Nucleic Acids Res.
15:2665-2675[Abstract/Free Full Text].
|
| 8.
|
Donadio, S.,
M. J. Staver,
J. B. McAlpine,
S. J. Swanson, and L. Katz.
1991.
Modular organization of genes required for complex polyketide biosynthesis.
Science
252:675-679[Abstract/Free Full Text].
|
| 9.
|
Donadio, S.,
D. Stassi,
J. B. McAlpine,
M. J. Staver,
P. J. Sheldon,
M. Jackson,
S. J. Swanson,
E. Wendt-Pienkowski,
Y.-G. Wang,
B. Jarvis,
C. R. Hutchinson, and L. Katz.
1993.
Recent developments in the genetics of erythromycin formation, p. 257-265.
In
R. H. Baltz, G. D. Hegeman, and P. L. Skatrud (ed.), Industrial microorganisms: basic and applied molecular genetics. American Society for Microbiology, Washington, D.C.
|
| 10.
| English, R. S. Unpublished results.
|
| 11.
|
Fernandez-Moreno, M. A.,
E. Martinez,
L. Boto,
D. A. Hopwood, and F. Malpartida.
1992.
Nucleotide sequence and deduced functions of a set of cotranscribed genes of Streptomyces coelicolor A3(2) including the polyketide synthase for the antibiotic actinorhodin.
J. Biol. Chem.
267:19278-19290[Abstract/Free Full Text].
|
| 12.
|
Gaisser, S.,
G. A. Bohm,
J. Cortes, and P. F. Leadlay.
1997.
Analysis of seven genes from the eryAI-eryK region of the erythromycin biosynthetic gene cluster in Saccharopolyspora erythraea.
Mol. Gen. Genet.
256:239-251[Medline].
|
| 13.
|
Gaisser, S.,
G. A. Bohm,
M. Doumith,
M.-C. Raynal,
N. Dhillon,
J. Cortes, and P. F. Leadlay.
1998.
Analysis of eryBI, eryBIII, and eryBVII from the erythromycin biosynthetic gene cluster in Saccharopolyspora erythraea.
Mol. Gen. Genet.
258:78-88[Medline].
|
| 14.
|
Gandecha, A. R.,
S. L. Large, and E. Cundliffe.
1997.
Analysis of four tylosin biosynthetic genes from the tylLM region of the Streptomyces fradiae genome.
Gene
184:197-203[Medline].
|
| 15.
|
Haydock, S. F.,
J. A. Dowson,
N. Dhillon,
G. A. Roberts,
J. Cortes, and P. F. Leadlay.
1991.
Cloning and sequence analysis of genes involved in erythromycin biosynthesis in Saccharopolyspora erythraea: sequence similarities between EryG and a family of S-adenosylmethionine-dependent methyltransferases.
Mol. Gen. Genet.
230:120-128[Medline].
|
| 16.
|
Hopwood, D. A.,
M. J. Bibb,
K. F. Chater,
T. Kieser,
C. J. Bruton,
H. M. 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
|
| 17.
|
Hopwood, D. A., and D. H. Sherman.
1990.
Molecular genetics of polyketides and its comparison to fatty acid biosynthesis.
Annu. Rev. Genet.
24:37-66[Medline].
|
| 18.
|
Jaeger, J. A.,
D. H. Turner, and M. Zuker.
1989.
Improved predictions of secondary structures for RNA.
Proc. Natl. Acad. Sci. USA
86:7706-7710[Abstract/Free Full Text].
|
| 19.
|
Jaeger, J. A.,
D. H. Turner, and M. Zuker.
1989.
Predicting optimal and suboptimal secondary structure for RNA.
Methods Enzymol.
183:281-306.
|
| 20.
|
Linton, K. J.,
B. W. Jarvis, and C. R. Hutchinson.
1995.
Cloning of the genes encoding thymidine diphosphoglucose 4,6-dehydratase and thymidine diphospho-4-keto-6-deoxyglucose 3,5-epimerase from the erythromycin-producing Saccharopolyspora erythraea.
Gene
153:33-40[Medline].
|
| 21.
|
MacNeil, D. J.,
J. L. Occi,
K. M. Gewain,
T. MacNeil,
P. H. Gibbons,
C. L. Ruby, and S. J. Danis.
1992.
Complex organization of the Streptomyces avermitilis genes encoding the avermectin polyketide synthase.
Gene
115:119-125[Medline].
|
| 22.
|
Martin, J. F., and P. Liras.
1989.
Organization and expression of genes involved in the biosynthesis of antibiotics and other secondary metabolites.
Annu. Rev. Microbiol.
43:173-206[Medline].
|
| 23.
|
Paulus, T. J.,
J. S. Tuan,
V. E. Luebke,
G. T. Maine,
J. P. DeWitt, and L. Katz.
1990.
Mutation and cloning of eryG, the structural gene for erythromycin O-methyltransferase from Saccharopolyspora erythraea, and expression of eryG in Escherichia coli.
J. Bacteriol.
172:2541-2546[Abstract/Free Full Text].
|
| 24.
|
Pereda, A.,
R. Summers, and L. Katz.
1997.
Nucleotide sequence of the ermE distal flank of the erythromycin biosynthesis cluster in Saccharopolyspora erythraea.
Gene
193:65-71[Medline].
|
| 25.
|
Reeve, L. M., and S. Baumberg.
1998.
Physiological controls of erythromycin production by Saccharopolyspora erythraea are exerted at least in part at the level of transcription.
Biotechnol. Lett.
20:585-589.
|
| 26.
|
Reeves, A. R.,
D. A. Post, and T. J. Vanden Boom.
1998.
Physical-genetic map of the erythromycin-producing organism Saccharopolyspora erythraea.
Microbiology
144:2151-2159[Abstract].
|
| 27.
|
Ruan, X.,
D. Stassi,
S. A. Lax, and L. Katz.
1997.
A second type-I PKS gene cluster isolated from Streptomyces hygroscopicus ATCC 29253, a rapamycin-producing strain.
Gene
203:1-9[Medline].
|
| 28.
|
Salah-Bey, K.,
M. Doumith,
J.-M. Michel,
S. Haydock,
J. Cortes,
P. F. Leadlay, and M.-C. Raynal.
1998.
Targeted gene inactivation for the elucidation of deoxysugar biosynthesis in the erythromycin producer Saccharopolyspora erythraea.
Mol. Gen. Genet.
257:542-553[Medline].
|
| 29.
|
Sambrook, J.,
E. F. Fritsch, and T. Maniatis.
1989.
Molecular cloning: a laboratory manual, 2nd ed.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y
|
| 30.
|
Sanger, F.,
S. Nicklen, and A. R. Coulson.
1977.
DNA sequencing with chain-terminating inhibitors.
Proc. Natl. Acad. Sci. USA
74:5463-5467[Abstract/Free Full Text].
|
| 31.
|
Stassi, D.,
S. Donadio,
M. J. Staver, and L. Katz.
1993.
Identification of a Saccharopolyspora erythraea gene required for the final hydroxylation step in erythromycin biosynthesis.
J. Bacteriol.
175:182-189[Abstract/Free Full Text].
|
| 32.
|
Strohl, W. R.
1992.
Compilation and analysis of DNA sequences associated with apparent streptomycete promoters.
Nucleic Acids Res.
20:961-974[Abstract/Free Full Text].
|
| 33.
|
Summers, R. G.,
S. Donadio,
M. J. Staver,
E. Wendt-Pienkowski,
C. R. Hutchinson, and L. Katz.
1997.
Sequencing and mutagenesis of genes from the erythromycin biosynthetic gene cluster of Saccharopolyspora erythraea that are involved in L-mycarose and D-desosamine production.
Microbiology
143:3251-3262[Abstract].
|
| 34.
|
Tuan, J. S.,
J. M. Weber,
M. J. Staver,
J. O. Leung,
S. Donadio, and L. Katz.
1990.
Cloning of genes involved in erythromycin biosynthesis from Saccharopolyspora erythraea using a novel actinomycete-Escherichia coli cosmid.
Gene
90:21-29[Medline].
|
| 35.
|
Vara, J.,
M. Lewandowska-Skarbek,
Y.-G. Wang,
S. Donadio, and C. R. Hutchinson.
1989.
Cloning of genes governing the deoxysugar portion of the erythromycin biosynthesis pathway in Saccharopolyspora erythraea (Streptomyces erythreus).
J. Bacteriol.
171:5872-5881[Abstract/Free Full Text].
|
| 36.
|
Weber, J. M.,
C. K. Wierman, and C. R. Hutchinson.
1985.
Genetic analysis of erythromycin production in Streptomyces erythreus.
J. Bacteriol.
164:425-433[Abstract/Free Full Text].
|
| 37.
|
Weber, J. M.,
B. Schoner, and R. Losick.
1989.
Identification of a gene required for the terminal step in erythromycin A biosynthesis in Saccharopolyspora erythraea (Streptomyces erythreus).
Gene
75:235-241[Medline].
|
| 38.
|
Weber, J. M.,
J. O. Leung,
G. T. Maine,
R. H. B. Potenz,
T. J. Paulus, and J. P. DeWitt.
1990.
Organization of a cluster of erythromycin genes in Saccharopolyspora erythraea.
J. Bacteriol.
172:2372-2383[Abstract/Free Full Text].
|
| 39.
|
Westpheling, J., and M. Brawner.
1989.
Two transcribing activities are involved in expression of the Streptomyces galactose operon.
J. Bacteriol.
171:1355-1361[Abstract/Free Full Text].
|
| 40.
|
Xue, Y.,
L. Zhao,
H.-W. Liu, and D. H. Sherman.
1998.
A gene cluster for macrolide antibiotic biosynthesis in Streptomyces venezuelae: architecture of metabolic diversity.
Proc. Natl. Acad. Sci. USA
95:12111-12116[Abstract/Free Full Text].
|
| 41.
|
Zuker, M.
1989.
On finding all suboptimal foldings of an RNA molecule.
Science
244:48-52[Abstract/Free Full Text].
|
Journal of Bacteriology, November 1999, p. 7098-7106, Vol. 181, No. 22
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
