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Journal of Bacteriology, July 1999, p. 3920-3927, Vol. 181, No. 13
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Coordinate Transcriptional Control in the
Hyperthermophilic Archaeon Sulfolobus solfataricus
Cynthia
Haseltine,
Rafael
Montalvo-Rodriguez,
Elisabetta
Bini,
Audrey
Carl, and
Paul
Blum*
George Beadle Center for Genetics, School of
Biological Sciences, University of Nebraska, Lincoln, Nebraska
68588-0666
Received 5 March 1999/Accepted 19 April 1999
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ABSTRACT |
The existence of a global gene regulatory system in the
hyperthermophilic archaeon Sulfolobus solfataricus is
described. The system is responsive to carbon source quality and acts
at the level of transcription to coordinate synthesis of three
physically unlinked glycosyl hydrolases implicated in carbohydrate
utilization. The specific activities of three enzymes, an
-glucosidase (malA), a 
-glycosidase
(lacS), and an -amylase, were reduced 4-, 20-, and
10-fold, respectively, in response to the addition of supplementary carbon sources to a minimal sucrose medium. Western blot analysis using
anti--glucosidase and anti--glycosidase antibodies indicated that
reduced enzyme activities resulted exclusively from decreased enzyme
levels. Northern blot analysis of malA and lacS
mRNAs revealed that changes in enzyme abundance arose primarily from
reductions in transcript concentrations. Culture conditions
precipitating rapid changes in lacS gene expression were
established to determine the response time of the regulatory system in
vivo. Full induction occurred within a single generation whereas full
repression occurred more slowly, requiring nearly 38 generations. Since
lacS mRNA abundance changed much more rapidly in response
to a nutrient down shift than to a nutrient up shift, transcript
synthesis rather than degradation likely plays a role in the regulatory response.
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INTRODUCTION |
Microbial survival and proliferation
in boiling acid environments has been accompanied by the evolution of a
diversity of mechanisms for energy generation and carbon assimilation.
Members of the domain Archaea, particularly the crenarchaeal
subdivision, dominate these extreme environments. Many of the organisms
assigned to this subdivision are members of the order
Sulfolobales, which includes the genus Sulfolobus
(3, 11). This genus is comprised of obligate aerobes which
conduct both lithoautotrophic (3, 23) and chemoheterotrophic
(11, 14) metabolism. One member of this genus,
Sulfolobus solfataricus, uses a wide range of reduced organic compounds, including starch and its derivative maltose, as sole
carbon and energy sources (20, 43).
Bacteria and eukaryotes typically employ transcriptional regulatory
mechanisms to coordinate expression of genes involved in carbohydrate
utilization. These types of genes generally are subject to a process
termed the glucose effect, which includes three components: inducer
exclusion, transient repression, and catabolite repression
(27). Among the gram-negative bacteria, coordination of
expression of such genes entails the action of cyclic AMP (cAMP) and
cAMP receptor protein (CRP) acting to balance utilization of low- and
high-quality carbon resources (46). In certain gram-positive
bacteria, cAMP and CRP are absent and CcpA, a negative-acting
transcription factor is used to affect promoter activity of target
genes (12, 21). Coordinated expression in eukaryotes of
genes involved in carbon catabolism also is accomplished by
trans-acting transcription factors including the proteins
CREA and CREB (9, 42). In all of these organisms, catabolite
repression is mediated at the level of transcription initiation.
However, a key feature distinguishing the gene regulatory mechanisms
employed in bacterial prokaryotes from that in eukaryotes arises from
their fundamentally distinct basal transcription systems.
Interestingly, transcription in archaeal prokaryotes closely resembles
that employed by eukaryotes and not bacteria. This includes conserved
promoter sequences (17, 37), TATA binding protein homologs
(29, 34, 45), TFIIB homologs (13, 35, 36), and an
RNA polymerase II homolog (24). Transcriptional regulatory
systems in archaea must therefore accommodate their eukaryotic-like
basal transcription components.
Archaea do conduct metabolism and therefore must control the expression
of genes encoding metabolic enzymes. However little is yet known about
how this might occur. For example, it is unknown if the key features
which distinguish bacterial and eukaryotic catabolite repression
systems are present in the archaea such as global transcriptional gene
regulation, signal molecules, or trans-acting factors. Gene
regulatory systems have been found in the euryarchaea, which comprise
the other major archaeal subdivision. In the halophilic archaea,
examples include the regulation of synthesis of bacteriorhodopsin
(bob [49]), halocins (6), gas
vacuoles (vac [41, 52]), and the heat shock
response (cct [31, 51]). In the
methanogenic archaea, examples include the regulation of methane
biosynthesis (22, 32), histones (47), carbon
monoxide dehydrogenase (cdh [50]), and
nitrogen fixation (nif [7]). However, for
the hyperthermophilic archaea which lie in both archaeal subdivisions,
gene regulatory studies are less common perhaps because many of these
organisms are obligate anaerobes with fastidious growth requirements
(10).
In the aerobic hyperthermophile S. solfataricus, starch
utilization necessitates the inducible synthesis and secretion of a
highly stable -amylase (20). The resulting hydrolytic
products including dextrins and maltodextrins are further hydrolyzed by the action of a cell-associated -glucosidase encoded by
malA (43). Expression of malA is
modestly affected by carbon source type, while levels of the
-amylase are strongly influenced (20, 44). The variation
in levels of these glycosyl hydrolases in response to carbon source
type represents one of the hallmarks of catabolite repression, that is,
carbon source preference (27). It remains unclear, however,
if these changes occur through action at the level of enzyme activity,
translation, or transcription. To better understand the catabolite
repression-like response of S. solfataricus, a set of
glycosyl hydrolase genes were characterized and used to probe the
consequences of nutrient supplementation of a minimal medium. The
observed pattern of gene expression indicates this organism employs a
global transcriptional regulatory system to coordinate its response to
carbon sources.
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MATERIALS AND METHODS |
Archaeal strains and cultivation.
S. solfataricus was
grown as described previously (43) at 80°C at a pH of 3 in
screw-cap flasks and aerated by vigorous shaking. The medium used
contained 20 mM ammonium sulfate, 4 mM dibasic potassium phosphate, 4 mM magnesium sulfate, 1 mM calcium chloride, 0.2 mM iron chloride, 18 mM manganese chloride, 0.02 mM sodium borohydride, 1.5 µM zinc
sulfate, 0.74 µM copper chloride, 0.25 µM sodium molybdenate, 0.37 µM vanadium sulfate, and 0.13 µM cobalt sulfate. Cyanocobalamin was
used at a final concentration of 0.2 µg/liter, while all other
vitamins were used at final concentrations of 50 µg/liter.
Nucleosides and amino acids were used at final concentrations of 10 and
50 mg/liter, respectively. Sucrose was added at a final concentration
of 0.2% (wt/vol), and yeast extract and tryptone were added at a final
concentration of 0.1% (wt/vol) and 0.2% (wt/vol), respectively. The
growth medium was adjusted with sufficient sulfuric acid to yield a pH
of 3.0. Growth was monitored spectrophotometrically at a wavelength of
540 nm.
Molecular biology methods.
Restriction digestion and
ligation of DNA were performed as described previously (2).
Plasmid transformation was performed with E. coli DH5 as
described previously (18). Plasmid DNA was isolated by the
alkali lysis procedure (1). DNA sequence analysis was done
as described elsewhere (39), and DNA alignment and analysis
were performed with the fragment assembly programs of the Wisconsin
Package (version 9.0; Genetics Computer Group, Inc.). All other
manipulations of Escherichia coli strains were done as
described previously (38).
Enzyme assays.
Assays for the -glucosidase and the
-glycosidase used S. solfataricus cell extracts prepared
by sonicating cells resuspended in 100 mM sodium acetate (pH 4.5) and
10 mM Tris hydrochloride (pH 7.0), respectively. The hydrolysis of
p-nitrophenyl--glucopyranoside (-PNPG) was used to
measure the -glucosidase as described previously (43).
Substrate was used at a concentration of 10 mM in a reaction buffer
consisting of 100 mM sodium acetate (pH 4.5). Reactions were initiated
by the addition of crude cell sonicates or enzyme to prewarmed
solutions and terminated by addition of 1 M sodium carbonate resulting
in a sample pH of 10.0. Hydrolysis of
p-nitrophenyl--D-glucopyranoside (-PNPG)
was used to measure the -glycosidase, using the same procedure as
employed for the -glucosidase. The extent of substrate hydrolysis
was determined by the absorbance of the sample at a wavelength of 420 nm with correction for spontaneous substrate hydrolysis. A unit of
either -glucosidase or -glycosidase activity is defined as the
amount of enzyme required to liberate 1 µmol of
p-nitrophenol per min per mg of protein. Measurement of
secreted -amylase enzyme activity used cell-free culture
supernatants concentrated by ultrafiltration as necessary as described
previously (20). -Amylase activity was determined as
described elsewhere (20) by monitoring the loss of iodine
binding to added starch (25, 28). The iodine binding assay
was performed with a reaction mixture containing clarified culture
supernatant, 2% (wt/vol) starch, 100 mM sodium acetate, and 2 mM
calcium chloride (pH 3.0) at 80°C for 30 min. The reaction was
terminated by cooling at 4°C. Color was developed by addition of
0.015 ml of an iodine solution (4% [wt/vol] potassium iodide, 1.25%
[wt/vol] iodine). The sample absorbance was determined at a
wavelength of 600 nm and was corrected for a sample lacking added
substrate. One unit of -amylase activity was equivalent to the
amount of protein which hydrolyzed 1 µg of starch in 1 min. All
samples were assayed in duplicate, and the averages of the sample
results are reported.
Protein purification and antibody production.
Recombinant
enzyme purification used transformants of E. coli DH5
(Gibco-BRL) harboring either the malA expression plasmid pBN56, a pLITMUS 29 (New England Biolabs) derivative (44),
or the lacS expression plasmid pBN55 (this work). These
strains were grown at 37°C with vigorous shaking in 4 liters of LB
medium containing ampicillin (100 µg/ml) until they reached
stationary phase. Cells were harvested by centrifugation, resuspended
in 30 mM morpholinepropanesulfonic acid, pH 8.0 (MOPS buffer), and
lysed by sonication at 4°C. The resulting lysates were clarified by
centrifugation (3,000 × g for 30 min) and then heated
at 85°C for 30 min and reclarified by centrifugation. The heating and
centrifugation procedure was then repeated a second time. The
heat-treated supernatants were concentrated by ultrafiltration using a
YM3 (Amicon) membrane.
The concentrated supernatants were applied to a Mono Q FPLC (fast
protein liquid chromatography) column (Pharmacia) previously equilibrated with MOPS buffer. The recombinant -glycosidase and the
recombinant -glucosidase were eluted with linear gradients of sodium
chloride in MOPS buffer. Active fractions for each enzyme were
identified by enzyme assay, pooled, concentrated by ultrafiltration using a PM10 (Amicon) membrane, and dialyzed into 100 mM sodium phosphate buffer (pH 6.0). The dialyzed samples were applied to a
Superdex 200 HR 10/30 FPLC column (Pharmacia) previously equilibrated with 100 mM sodium phosphate (pH 6.0). Active fractions were again pooled and concentrated by ultrafiltration.
The purified enzymes were hydrolyzed by using cyanogen bromide in 70%
formic acid as described (
16,
30). The resulting
peptides
for the recombinant
-glucosidase were dialyzed into
5 mM Tris-Cl (pH
7.0), lyophilized to dryness, and resuspended
in water. The recombinant
-glycosidase was diluted to 0.07% formic
acid with 5 mM Tris-Cl (pH
7.0) and lyophilized to near dryness,
and the pH was adjusted to 7.0 with 10 M sodium hydroxide. Anti-
-glucosidase
antibodies were raised
in mice as described previously (
2).
Anti-
-glycosidase
polyclonal antibodies were produced by injection
of 0.1 mg of purified
protein into New Zealand White rabbits as
previously described
(
40). Polyclonal sera were further purified
by precipitation
with acetone powder as previously described (
2).
Protein electrophoresis and Western blot analysis.
Proteins
were resolved by sodium dodecyl sulfate (SDS)-polyacrylamide gel
electrophoresis under reducing conditions using unstained low- and
high-molecular-weight markers (Bio-Rad). Prior to electrophoresis,
samples were adjusted to 2% (wt/vol) SDS and 3 mM -mercaptoethanol
and boiled for 10 min. SDS-polyacrylamide gels were stained with
Coomassie blue R250 to visualize protein. Chemiluminescent Western blot
analysis using the Tropix system was performed as described elsewhere
(40). The -glucosidase and -glycosidase protein
standards were prepared as described above for use in the preparation
of antibodies, with some modification. The recombinant E. coli extracts were subjected to only one heat treatment at 85°C
for 1 h and then clarified at 14,000 × g at ambient temperature. The relative abundance of the two proteins in
these extracts was determined by comparison to purified samples.
Isolation and DNA sequence analysis of lacS.
The
S. solfataricus library was constructed by using genomic DNA
prepared as described previously (44). Genomic DNA was partially digested with Sau3AI and then fractionated by
electrophoresis; DNA between 3 and 5 kb in size was ligated into the
BamHI site of pUC19 (New England Biolabs) and transformed
into E. coli DH5 with selection for ampicillin
resistance. Two thousand individual colonies were picked and propagated
in 96-well microtiter plates in rich medium containing ampicillin. The
S. solfataricus lacS gene was identified by screening these
isolates, which had been preheated at 80°C for 1 h, for the
ability to hydrolyze -PNPG at 80°C. One such isolate was
identified by this method, and its recombinant plasmid was called
pBN55. The insert of pBN55 was subcloned for sequencing by restriction
digestion with EcoRI. This digestion yielded three
fragments, the first of which consisted of the 725-bp 5' end of the
insert and the pUC19 vector. It was religated to itself to generate the
5'-end subclone. The remaining two fragments produced by the
EcoRI digestion were 491 and 552 bp and represented the
central and 3' portions of the insert, respectively. They were each
ligated into the EcoRI site of pUC19 to generate the middle
and 3'-end subclones. The inserts of all three subclones were then sequenced.
Northern blot analysis.
S. solfataricus total RNA was
extracted as described previously (5) from wet cell paste
obtained by filtration of cells at the mid-exponential phase of growth
on the indicated carbon sources. Electrophoresis of RNA samples was as
described elsewhere (4), and the RNA was electrophoretically
transferred to Hybond N+ (Amersham) membranes and cross-linked by
shortwave UV irradiation. RNA riboprobes were generated by using a
riboprobe buffer kit (Promega) and the manufacturer's protocol.
Riboprobe templates were a 2,081-bp fragment encoding the
malA region comprising base pair positions 141 to 2,265 relative to the malA start codon (44) and a
493-bp EcoRI lacS fragment including positions
544 to 1,037 relative to the lacS start codon. The
lacS sense-strand RNA standard was synthesized by using the
pBN55 lacS insert; the malA sense-strand RNA
standard was synthesized by using the same fragment as employed for
malA riboprobe synthesis. The DNA fragments used to generate the riboprobes and sense-strand RNA standards were cloned into plasmid
pT7T3 18U (Pharmacia). Northern hybridizations were performed at 55°C
with 50% formamide. Washed membranes were used to prepare autoradiograms with Kodak X-Omat film. Molecular weight standards were
RNATranscripts (United States Biochemical).
Nucleotide sequence accession number.
The lacS
sequence determined in this study has been deposited in GenBank under
accession no. AF133096.
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RESULTS |
Glycosyl hydrolase levels vary in response to use of supplemental
carbon sources.
Three enzymes were selected to help define the
catabolite regulation-like system in S. solfataricus: the
-amylase (20), the -glucosidase (43, 44),
and the -glycosidase (8, 15). Levels of each of the three
enzymes were determined from cells in the mid-exponential phase of
growth in a minimal sucrose medium with or without nutrient
supplementation (Table 1).
Cell-associated activities (-glucosidase and -glycosidase) were
determined as specific activities, while activity levels of the
secreted -amylase were normalized to total cell protein present at
the time of assay. Yeast extract is a common medium additive widely
used for the growth of this organism (11, 14, 34, 37). Yeast
extract supplementation of a minimal sucrose medium decreased cell
generation times 13%, from 7.5 to 6.5 h, and increased cell
yields 28%, from 4.5 to 5.8 OD540 (optical density at 540 nm) units/ml. This supplement simultaneously resulted in significant
reductions in enzyme levels, approximately 4-fold for the
-glucosidase, 20-fold for the -glycosidase, and at least 10-fold
for the -amylase (Table 1). No alterations in glycosyl hydrolase
activities were noted when other methods were used to perturb cell
growth rates and culture yields. Decreasing the temperature of
incubation by 10°C (from 80 to 70°C) resulted in over a 50%
increase in generation time with no concomitant alteration in the
measured glycosyl hydrolase activities.
Previous studies had indicated a role for certain amino acids acting as
sole carbon and energy sources in glycosyl hydrolase
expression
(
19,
20). When tryptone was used to supplement
a sucrose
minimal medium, levels of all three glycosyl hydrolase
activities were
reduced relative to levels in the unsupplemented
sucrose medium (Table
1). However, comparison of glycosyl hydrolase
activities produced
during growth in tryptone without added sucrose
indicates that sucrose
does not act as an inducer of enzyme activities.
The reduction in
glycosyl hydrolase activities observed upon tryptone
addition could be
further ascribed to the action of a subset of
nine amino acids.
Addition of a pool comprising all other amino
acids and excluding these
nine amino acids had no effect on the
levels of the measured
activities. Medium supplementation with
a pool of vitamins including
biotin, folate, pyridoxine, cyanocobalamin,
thiamine, riboflavin,
nicotinate, pantothenate,
p-aminobenzoate,
and thioctate
also had no effect on the measured activities. Similarly,
medium
supplementation with a pool of nucleosides including guanosine,
adenosine, cytosine, and thymidine had no effect on glycosyl hydrolase
activities. The effective amino acids could be further divided
into two
groups. A mixture of alanine, arginine, asparagine, and
aspartate added
to a sucrose minimal medium was inhibitory and
resulted in a
-glycosidase specific activity 45% of maximum levels,
while
supplementation with a mixture of glutamate, glutamine,
glycine,
leucine, and histidine had no inhibitory effect. These
results
demonstrated that medium supplementation with certain
amino acids was
in part responsible for the observed change in
glycosyl hydrolase
levels caused by yeast extract addition. The
magnitude of the effect of
these amino acids as a group or as
individual supplements, however, was
significantly smaller than
that observed with more complex additives.
Since yeast extract
addition produced the largest change in glycosyl
hydrolase activities,
it was used in subsequent studies as a medium
supplement to facilitate
analysis of the
S. solfataricus
regulatory
response.
Variation in enzyme activities result from alterations in enzyme
levels.
Western blot analysis was performed to test the
possibility that the observed changes in enzyme levels resulted from
changes in enzyme abundance rather than enzyme activity. Mouse
polyclonal antibodies to the -glucosidase were prepared by using
hydrolyzed recombinant protein as an immunogen which was purified from
an S. solfataricus malA E. coli expression system
(44). Antibodies specific for the -glycosidase were
prepared in a similar manner using hydrolyzed protein purified from an
S. solfataricus lacS E. coli expression system. The
lacS gene initially was recovered from an S. solfataricus 98/2 plasmid-based E. coli expression library. The library was screened for isolates which produced thermostable -glycosidase activity. One such isolate identified carried a plasmid expressing the S. solfataricus lacS gene
under control of the lac promoter. The plasmid contained an
insert of 1,768 bp and contained the entire lacS coding
sequence of 1,467 bp as well as 176 bp 5' to the start codon and 117 bp
3' to the termination codon. The resulting deduced amino acid sequence
exhibited one nonconservative change relative to the lacS
sequence derived from S. solfataricus MT4 (8).
This change resulted from three contiguous substitution mutations
(CAT
GCA) beginning at bp 703 relative to the lacS start
codon. The S. solfataricus 98/2 sequence encodes alanine at
this position, while strain MT4 encodes a histidine. This DNA sequence
difference also results in the elimination of an NdeI site
and the creation of a BsrDI site, as indicated by restriction endonuclease analysis of the recombinant plasmid.
Chemiluminescent Western blot analysis of
S. solfataricus
cell extracts derived from cells growing in a sucrose minimal medium
with or without added yeast extract revealed a large difference
in
levels of both the
-glucosidase and the
-glycosidase (Fig.
1).
-Glucosidase levels differed
4-fold (Fig.
1A, lanes 7 and
8), and
-glycosidase levels differed
17-fold (Fig.
1B, lanes
6 and 7). Protein abundance was determined by
transmittance densitometry
and comparison with recombinant
-glucosidase and
-glycosidase
protein standards added as controls
on the immunoblots. The intensity
of the chemiluminescent signal
obtained from the protein standards
was linear in the range of the
measured proteins (Fig.
1C). The
observed variation in abundance of
both enzymes as determined
by Western blot analysis was directly
proportional to the variation
in enzyme activity detected in cell
extracts (Table
1). These
results indicate that allosteric control over
enzyme activity
or other forms of regulation operating at the
posttranslational
level are not significant factors in the observed
regulatory response.
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FIG. 1.
Western blot analysis of steady-state levels of
-glucosidase and -glycosidase. (A) Levels of -glucosidase.
Lanes: 1, nonrecombinant E. coli extract; 2 to 6, recombinant -glucosidase at (9, 4.5, 2.25, 1.4, and 1 ng,
respectively); 7, S. solfataricus extract (30 µg) from
cells grown in sucrose medium with yeast extract; 8, S. solfataricus extract (30 µg) from cells grown in sucrose medium.
(B) Levels of -glycosidase. Lanes: 1, nonrecombinant E. coli extract; 2 to 5, recombinant -glycosidase (40, 13.4, 4.7, and 1.3 ng, respectively); 6, S. solfataricus extract (31 µg) from cells grown in sucrose medium with yeast extract; 7, S. solfataricus extract (18 µg) from cells grown in
sucrose medium. Arrowheads on the right indicate positions of
-glucosidase and -glycosidase; molecular mass markers in
kilodaltons are shown on the left. (C) Densitometry of recombinant
-glucosidase (open circles) and recombinant -glycosidase (closed
circles) standards.
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Variation in enzyme levels result from changes in mRNA
abundance.
Northern blot analysis was conducted to determine if
the observed variation in abundance of the -glucosidase and
-glycosidase detected by Western blot analysis resulted from
corresponding changes in levels of the malA and
lacS transcripts. Riboprobes complementary to
lacS and malA mRNA were used to probe blots
of total S. solfataricus RNA derived from cells in the
exponential phase of growth in a sucrose minimal medium with or without
added yeast extract. In vivo levels of both mRNAs were
significantly reduced as a consequence of yeast extract medium
supplementation (Fig. 2). The levels of
malA mRNA were reduced 4-fold (Fig. 2A, lanes 6 and 7),
while levels of lacS mRNA were reduced 14-fold (Fig. 2B,
lanes 6 and 7). Levels of total cellular RNA (5 µg/lane) were
comparable for these samples, as indicated by ethidium bromide staining
(Fig. 2A and B, lanes 8 and 9). The magnitudes of these changes in
malA and lacS mRNA levels were proportional
to those observed for differences in enzyme abundance and enzyme
activity. To minimize the possibility of differential RNA transfer or
hybridization in the blotting procedures, lacS and
malA sense-strand RNA standards were prepared in vitro and
were included as internal controls on each blot (Fig. 2A and B, lanes 1 to 5). The malA template for sense-strand RNA standard
synthesis was 2,081 bp; however, transcription terminates approximately
500 bp into the vector backbone and results in an RNA close to the
apparent size of 2.5 kb for the native malA mRNA (Fig.
2A and reference 44). The lacS
sense-strand RNA standard has a predicted size of 1.7 kb but an
apparent size of 1.8 kb and is therefore of a size greater than the
apparent size of 1.5 kb for the natural lacS mRNA. This resulted from the use of a lacS riboprobe template which
included 100 bp of lacS flanking sequence derived from
regions located both 5' and 3' to the lacS open reading
frame. The intensity of the autoradiographic signal obtained from the
sense RNA standards was linear in the range of the measured natural
lacS and malA mRNAs (Fig. 2C). The apparent
variation in lacS and malA mRNA levels
suggest that either mRNA synthesis or mRNA degradation, rather
than protein stability or turnover, is the primary target for the
S. solfataricus regulatory response.
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FIG. 2.
Northern blot analysis of steady-state levels of
malA and lacS mRNAs. Total cellular
S. solfataricus RNA was loaded in 5-µg amounts per
lane. (A) Levels of malA mRNA. Lanes: 1 to 5, dilution
series of malA antisense standards (1.06, 0.26, 0.066, 0.017, and 0.004 pg of RNA); 6, RNA from cells grown on sucrose medium
with yeast extract; 7, RNA from cells grown on sucrose medium; 8 and 9, identical to lanes 6 and 7 but stained with ethidium bromide and
visualized by UV irradiation. (B) Levels of lacS mRNA.
Lanes: 1 to 5, dilution series of lacS antisense
standards (2.15, 0.54, 0.13, 0.033, and 0.008 pg of RNA); 6, RNA from
cells grown on sucrose medium with added yeast extract; 7, RNA from
cells grown on sucrose medium; 8 and 9, identical to lanes 6 and 7 but
stained with ethidium bromide and visualized by UV irradiation.
Arrowheads indicate positions of malA and
lacS mRNAs; molecular weight markers in kilobases
are shown on the left; 16S and 23S rRNAs are shown on the right.
(C) Densitometry of malA (open circles) and
lacS (closed circles) antisense standards.
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A global gene regulatory mechanism.
Since mRNA levels of
both malA and lacS were affected by presence of
yeast extract in the growth medium, coordinated expression resulting
from physical linkage such as the occurrence of these genes in a
polycistronic operon might explain the observations. However, DNA
sequence analysis of regions flanking malA exclude presence
of lacS within 4.01 kb 5' to malA and 0.96 kb 3'
to malA (44). In addition, sequence analysis of
regions flanking lacS exclude presence of malA
within 1.32 kb 5' to lacS and 2.07 kb 3' to lacS
(8, 33). These results indicate that the minimum aggregate
distance between lacS and malA is 2.28 kb.
Further, Northern blot analysis presented here excludes presence of a
large polycistronic mRNA which might encode both these genes.
Instead the apparent sizes of the transcripts encoding both enzymes
were close to the sizes of the corresponding open reading frames as expected for monocistronic mRNAs. In addition, levels of the
-amylase were also responsive to medium composition. Though the gene
encoding the -amylase in this organism has not been characterized,
there are no open reading frames of the expected size based on the
apparent subunit mass of the native enzyme (20) adjacent to
either the lacS or malA gene. Therefore, there
are at least three enzymes encoded by physically unlinked genes whose
concentrations are coordinately regulated.
Induction of lacS expression.
These results
indicate there are steady-state differences in glycosyl hydrolase gene
expression during balanced growth. Variations in levels of the
lacS transcript under the two growth conditions, however,
were noticeably more dramatic than for malA. The expression of lacS was therefore selected as a more sensitive measure
of the S. solfataricus regulatory response. To better
understand how this organism accomplishes changes in gene expression,
the response time of the regulatory system was determined. Cells were subjected to a nutrient down shift and monitored for transient alterations in lacS expression. S. solfataricus was grown to mid-exponential phase in sucrose minimal
medium supplemented with yeast extract. Cells were recovered by
centrifugation and resuspended in sucrose medium with or without added
yeast extract. The two cultures were then incubated, and the levels of
-glycosidase activity were monitored. -Glycosidase activity
remained unchanged in cells maintained in sucrose minimal medium
supplemented with yeast extract but was quickly activated in cells
which had been down shifted to the sucrose minimal medium without yeast
extract addition (Fig. 3A). An increase
was evident after 2 h of incubation and reached maximum levels
6 h after the shift. The induced levels of enzyme activity were
equivalent to those observed during balanced growth in a sucrose
minimal medium. The entire change in enzyme activity was accomplished
within one generation. Simultaneous analysis of -glycosidase levels
was conducted by Western blot analysis using purified -glycosidase
protein standards (Fig. 3B). -Glycosidase abundance increased in the
downshifted cells in parallel to the observed changes in
-glycosidase activity, while enzyme levels remained unchanged in the
unshifted culture.
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FIG. 3.
Induction of -glycosidase levels by nutrient down
shift. (A) Growth of S. solfataricus in sucrose medium
with yeast extract (open symbols) and in sucrose medium (closed
symbols), OD540 (squares), and -glycosidase specific
activity (circles). (B) Western blot analysis of -glycosidase
levels. Lane 1 and 2 contain 40 and 4 ng recombinant -glycosidase,
respectively; lanes 3 to 9 contain S. solfataricus
extracts following a nutrient down shift from growth in sucrose medium
with yeast extract to a sucrose medium. Lanes and sample times after
onset of the shift: 3, 0 h; 4, 1 h; 5, 2 h; 6, 3 h;
7, 4 h; 8, 5 h; 9, 7 h. Cell extracts were loaded in
24-µg amounts per lane. The arrowhead on the right indicates the
position of -glycosidase; molecular mass markers in kilodaltons are
shown on the left.
|
|
Variation in
lacS mRNA abundance in response to removal
of yeast extract was examined by Northern blot analysis to determine
how rapidly
lacS mRNA levels readjusted and how closely
such readjustments
might be to changes observed in
-glycosidase
levels. Sense-strand
lacS RNAs made in vitro were included
on the blots to control
for variation in transfer efficiency and for
use in quantitative
analysis of
lacS mRNA. Levels of
lacS mRNA began to increase within
2 h of the
nutrient down shift and reached maximum levels in 6
h, slightly
ahead of the maximum levels seen in
-glycosidase
activity and
protein levels (Fig.
4A). Transmittance
densitometry
of ethidium bromide-stained gels prior to Northern
blot transfer
indicated that the levels of both 16S rRNA and 23S rRNA
were equivalent
for all cell extract samples (Fig.
4B).
View larger version (76K):
[in this window]
[in a new window]
|
FIG. 4.
Northern blot analysis of lacS expression in
response to nutrient down shift. Total cellular S. solfataricus RNA was loaded in 5-µg amounts per lane. (A)
Northern blot. Lanes 1 to 3, lacS antisense RNA standards
(2.2, 0.54, and 0.13 pg, respectively); lanes 4 to 11, total RNA from
cells following a nutrient down shift from sucrose medium with yeast
extract to sucrose medium. Lanes and sample times after onset of the
shift: 4, 0 h; 5, 1 h; 6, 2 h; 7, 3 h; 8, 4 h;
9, 5 h; 10, 6 h; 11, 7 h. The arrowhead on the right
indicates the position of lacS mRNA; molecular weight
markers in kilobases are shown on the left. (B) Ethidium
bromide-stained total RNA. Lanes 4 to 11 are identical to those shown
in panel A but were stained with ethidium bromide and visualized by UV
irradiation. The positions of the 16S and 23S rRNAs are indicated.
|
|
Repression of lacS expression.
The change in
lacS mRNA levels precipitated by nutrient down shift
could result from increased lacS mRNA synthesis or
decreased lacS mRNA degradation. To discern between
these two mechanisms, nutrient up shift conditions were used to measure
how rapidly lacS expression could readjust to the
lower levels seen during steady-state growth on sucrose
minimal medium containing yeast extract. Yeast extract was added
to cells growing exponentially in a sucrose minimal medium, and levels
of -glycosidase activity were monitored until minimum levels
were observed; cells were repeatedly subcultured to maintain conditions
of balanced growth (Fig. 5).
-Glycosidase levels decreased in response to the nutrient up shift
and after 245 h reached minimum levels. The elapsed time necessary
for complete repression of -glycosidase activity was 35 times that
observed for the increase in enzyme activity produced in response to
the nutrient down shift (Fig. 3A). For comparative purposes, the
anticipated rate is presented for the change in -glycosidase
activity resulting from dilution due to cell division combined with
ongoing repressed levels of enzyme production (Fig. 5).
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 5.
Repression of -glycosidase levels by nutrient up
shift, determined by measurement of OD540 (open circles)
and -glycosidase specific activity (closed circles). Cells were
maintained in exponential phase by repeated subculturing into prewarmed
medium. At the time indicated by the arrow, the sucrose medium was
supplemented with yeast extract resulting in a nutrient up shift. The
theoretical rate of decrease in -glycosidase activity resulting from
an immediate reduction in synthesis to repressed levels combined with
dilution of the activity by ongoing cell division is indicated by the
dotted line.
|
|
The slow readjustment in
-glycosidase activity caused by nutrient up
shift could occur independently of changes in
lacS mRNA
abundance. For example,
-glycosidase might be proteolytically
insensitive, and thus changes in its levels would depend on
dilution
resulting from cell division.
lacS mRNA could
also be intrinsically
stable and require dilution to achieve new
cellular concentrations.
Alternatively,
lacS mRNA levels
could readjust rapidly through
an RNA degradation mechanism. To
distinguish between these possibilities,
levels of
lacS
mRNA were determined by Northern blot analysis
in cell samples
subjected to nutrient up shift (Fig.
6).
Readjustment
in
lacS mRNA levels exhibited a pattern
similar to that of
-glycosidase
activity. Minimum levels of
lacS mRNA were achieved only after
245 h of cell
growth. The observed rate of readjustment in
lacS mRNA
abundance greatly lags behind that resulting from cell dilution
due to
ongoing cell division (Fig.
5). Since transcription inhibitors
are not
yet available for in vivo studies in hyperthermophilic
archaea,
measurements of the rate of change in gene expression
were used to
discern between possible gene regulatory mechanisms
(Table
2). It is apparent from these values that
the difference
in the rate of change in
lacS transcript
abundance in response
to the two nutrient shift conditions (down shift
and up shift)
was 85-fold, while that for differences in the rate of
change
of
-glycosidase enzyme activity was 43-fold. These results
suggest
that an active mechanism is employed for induction of
lacS expression
(down shift) whereas a passive mechanism
involving cell dilution
is used to repress
lacS expression
(up shift).
View larger version (92K):
[in this window]
[in a new window]
|
FIG. 6.
Northern blot analysis of lacS expression in
response to nutrient up shift. Total cellular S. solfataricus RNA samples derived from cultures treated as shown in
Fig. 5 were loaded in 5-µg amounts per lane. (A) Northern blot. Lanes
1 to 7 contain total RNA from cells shifted from sucrose medium with
added yeast extract to sucrose medium. Lanes and sample times: 1, 0 h; 2, 35 h; 3, 63 h; 4, 103 h; 5, 159 h; 6, 178 h; 7, 204 h. Lanes 8 to 10 contain lacS
antisense RNA standards (0.13, 0.54, and 2.2 pg, respectively). The
arrowhead on the right indicates the position of lacS
mRNA; molecular weight markers in kilobases are shown on the left.
(B) Ethidium bromide-stained total RNA. Lanes 1 to 7 are identical to
those in panel A but were stained with ethidium bromide and visualized
by UV irradiation. Positions of the 16S and 23S rRNAs are indicated.
|
|
| |
DISCUSSION |
The results presented here demonstrate the existence of a global
gene regulatory system in the hyperthermophilic crenarchaeote S. solfataricus. The system exhibits features found
previously in the catabolite repression systems of eukaryotes and
bacterial prokaryotes such as the coordinate regulation of expression
of genes involved in the metabolism of secondary carbon and energy sources. However, certain aspects such as inducer exclusion and transient repression (27) are not apparent. Though glycosyl hydrolase expression appears maximal during growth in a sucrose minimal
medium, sucrose is not an inducer. Growth on sole carbon and energy
sources other than sucrose resulted in near-maximal levels of glycosyl
hydrolase activity (20, 44), and sucrose supplementation of
a complex medium (tryptone) did not result in an elevation of glycosyl
hydrolase activities relative to levels found during growth on tryptone
alone. Similarly, yeast extract supplementation or removal led to a
permanent and not a transient change in glycosyl hydrolase levels.
The S. solfataricus catabolite repression-like system
acts at the level of mRNA abundance to coordinate levels of
glycosyl hydrolases in response to changing medium nutrient status.
Increased nutrient availability in the form of amino acids supplied
primarily as yeast extract to a minimal sucrose growth medium increased the growth rate and cell yield of S. solfataricus,
suggesting that these supplements support critical anabolic
requirements. Amino acid supplementation therefore can be viewed as an
increase in the quality of available nutrients. Previous work on this
organism identified an important metabolic role for certain amino acids acting as sole carbon and energy sources on the production of the
S. solfataricus -amylase (2). These amino
acids influenced production of the -amylase in either a positive or
a negative fashion. These effects could result from differences in
their metabolic entry points into the citric acid cycle, again a
reflection of some distinction in carbon source quality (20,
23). In the work presented here, however, amino acids and more
complex additives were not used as sole carbon and energy sources but instead as supplements to an otherwise complete sucrose minimal medium.
The effect of these supplements on glycosyl hydrolase expression is
most likely a result of their consumption as alternative carbon and
energy sources rather than as nitrogen sources. There is no apparent
correlation between the identity of amino acids which exert a
regulatory effect in the work presented here and the ability of these
amino acids to act as nitrogen sources (14). In addition,
nitrogen is supplied in the medium in the form of ammonium at a level
(20 mM) which is in excess for maximal growth rates and cell yields. It
should be noted that ammonium chloride is readily available in the hot
springs environment and represents the only natural occurrence of this
mineral (sal ammoniac). Ultimately, the ability of S. solfataricus to modulate gene expression and avoid unnecessary
protein production in response to improved nutrient resources would
help it conserve energy and promote survival.
Since growth rate and cell yields were correlated with altered gene
expression, it remains possible that any condition altering growth
leads to altered glycosyl hydrolase gene expression. This is apparently
not true in at least some instances. Growth rate could be altered by
varying culture incubation temperature without a noticeable effect on
glycosyl hydrolase gene expression. Thus, the observed results using
medium supplements are relatively specific in their effect on gene
expression and appear to act through their role as carbon sources
rather than as a result of their ability to change cell growth per se.
The regulatory mechanism that controls glycosyl hydrolase mRNA
levels in response to medium composition could operate either at the
level of mRNA synthesis or mRNA turnover. If transcript turnover were the primary mechanism, then a reduction in mRNA degradation resulting possibly by terminated synthesis of a putative RNase would lead to transcript accumulation. The rate of transcript accumulation should be proportional to the level of remaining RNase. If
the RNase were stable, its levels would in turn be controlled by
dilution resulting from ongoing cell division. Since the rate of
increase in lacS mRNA precipitated by nutrient down
shift is nearly 35 times faster than the rate of reduction in this
transcript precipitated by nutrient up shift, synthesis rather than
degradation is the more likely route for regulation of lacS
expression. Additional approaches, however, will be necessary to more
rigorously distinguish between these two possibilities. Interestingly
these results also suggest that the lacS mRNA is
unusually stable and possibly more so than most bacterial prokaryotic
mRNAs. The stability of mRNA in archaeal prokaryotes in general
is still largely unexamined, though some studies suggest that archaeal
mRNAs may be quite stable (22).
The responsiveness of glycosyl hydrolase gene expression to medium
composition could be readily distinguished at the transcriptional level. The difference in lacS mRNA was 14-fold, while
the difference for malA mRNA was 4-fold. This indicates
that if there is a common regulatory mechanism, it displays some
preference in the degree of its action on target gene expression. Since
the affected genes are physically unlinked, such a regulatory mechanism
must be trans acting and therefore involve a
diffusible factor such as a small molecule or a protein. In eukaryotes
and gram-negative prokaryotes, cAMP is used as a
trans-acting signal molecule to effect changes in gene
transcription in response to changing nutrient status (27,
46). In both groups of organisms, cAMP-interacting proteins play
critical roles. It is of interest, therefore, that this molecule has
been found in archaea (26). However, the other
well-characterized intracellular prokaryotic signal molecule, guanosine
tetraphosphate, appears to be absent in these organisms
(48).
The evolution of transcription systems now points to a common origin
between archaea and eukaryotes. Basal transcription components including promoter sequence, promoter recognition factors, and RNA
polymerase are closely related and clearly distinct in lineage from
those of bacterial prokaryotes. How gene regulation is accomplished, and particularly how regulatory factors interact with the basal archaeal transcription system, is unknown. Ongoing studies extending the work presented here are focused on developing a better
understanding of this process.
| |
ACKNOWLEDGMENTS |
This work was supported by grant MCB-9604000 to P.B. from the
National Science Foundation.
We thank Mike Rolfsmeier, Jimmy Soto, Robyn Kaiser, and the other
members of the Blum laboratory for help and encouragement.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: E234 Beadle
Cntr., University of Nebraska, Lincoln, NE 68588-0666. Phone: (402)
472-2769. Fax: (402) 472-8722. E-mail:
pblum{at}biocomp.unl.edu.
| |
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Journal of Bacteriology, July 1999, p. 3920-3927, Vol. 181, No. 13
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
