- Email: [email protected]
Mutants of Trichoderma reesei are defective in cellulose induction, but not basal expression of cellulase-encoding genes
Gene, 173 (1996) 1999203 0 1996 Elsevier Science B.V. All rights reserved.
199
0378-1119/96/$15.00
GENE 09816
Mutants of Trichoderma reesei are defective in cellulose induction, but not basal expression of cellulase-encoding genes (Endoglucanase
activity; coordinate expression; genomic analysis; hygromycin-B; promoter; transcript expression)
E. Torigoi, F. Henrique-Silva, and S. El-Gogary
J. Escobar-Vera,
J.C. Carle-Urioste,
0. Crivellaro,
H. El-Dorry
Department of Biochemistry, Institute of Chemistry, University of Sdo Paulo, S&o Paula, 05508-900 SP, Brazil Received by J.R. Kinghorn:
26 November
1995; Revised/Accepted:
27 December/28
December
1995; Received at publishers:
7 March
1996
SUMMARY
Four mutants of Trichoderma reesei defective in cellulose utilization were characterized at the molecular level. Genomic analysis of the cellulase-encoding genes (eel) and transcript induction using two well-established inducers of the ccl system ~ the insoluble polymer, cellulose and the soluble inducer, sophorose, - revealed that these mutants are defective in the transcription of ccl genes. The results also indicate that the ccl genes are coordinately expressed and most probably are regulated by the same mechanism. Using a heterologous gene construct, in which the hygromycin-B-resistanceencoding gene was placed under the control of the promoter of the major ccl gene, cbhl, we showed that the mutants synthesize basic levels of cellulase, but are defective in the ccl induction.
INTRODUCTION
Cellulose, the major constituent of lignocellulosic materials, is a linear polymer of glucose units joined by 1,4-B-glycosidic bonds. Cycling of this plant polysaccharide is brought about mostly by ubiquitous and abundant cellulolytic microorganisms (Coughlan and Ljungdahl, 1988). The utilization of cellulose as an energy carbon source by those microorganisms is achieved by an extracellular cellulase system that catalyzes the hydrolysis of cellulose to glucose (Montenecourt, 1983). Cellulose-degrading enzymes (Cel) of the filamentous Correspondence
to: Dr. S. El-Gogary,
Department
of Biochemistry,
Institute of Chemistry, University of SLo Paulo, Avenida Prof. Lineu Prestes 748, SBo Paulo, 05508-900 SP, Brazil. Tel. (55-11) 818-3848; Fax (55-11) 815-5579; e-mail: [email protected] Abbreviations:
Ab, antibody(ies);
lase; cbh, gene encoding
bp, base pair(s); CBH, cellobiohydro-
CBH; Cel, cellulase;
ccl, gene (DNA,
RNA)
encoding Cel; EG, endoglucanase; egl, gene encoding EG; Hph, hygromycin-B phosphotransferase; hph, gene encoding Hph; Hy, hygromycinB; kb, kilobase or 1000 bp; nt, nucleotide(s); Tr, Trichoderma reesei. PII SO378-1 119(96)00219-3
R, resistance/resistant;
fungus Trichoderma reesei (Tr) are among the best characterized; this cellulolytic system consists of three major classes of Cel: cellobiohydrolases (CBH), which cleave cellobiosyl units from the nonreducing ends of cellulose chains; endoglucanases (EG), which cleave internal glycosidic bonds; and B-glucosidases, which cleave cellooligosaccharides to produce glucose (for a review, refer to Beguin, 1990). The genes coding for CBHI, CBHII, EGI, EGII, and b-glucosidase have been isolated and characterized (Shoemaker et al., 1983; Penttila et al., 1986; Chen et al., 1987; Teeri et al., 1987; Van Arsdell et al., 1987; Saloheimo et al., 1988; Barnett et al., 1991). The ability of Tr to utilize different carbon sources, such as cellulose or glucose, is tightly regulated. Growth on cellulose as the sole carbon source results in induction of at least 1200-fold of the ccl transcripts (J.C.C.-U., F. H.-S., S. E.-G., O.C. and H. E.-D., unpublished), whereas glucose strongly represses the expression of those transcripts (Abrahao-Neto et al., 1995). Compelling evidences have implicated basal expression of the Cel activity in triggering the induction of the cellulase transcripts; this basal expression seems necessary to catalyze the forma-
200
tion of soluble inducer from cellulose (El-Gogary et al., 1989; Kubicek, 1987). A potential soluble inducer of the Cel activity (Mandels et al., 1962) is the disaccharide sophorose (2-O-B-glucopyranosyl-D-glucose). This inducer was shown to be one of the products catalyzed by the Tr Cel system and was detected during growth of TV on cellobiose (Mandels and Reese, 1960; Mandels et al., 1962; Vaheri et al., 1979). The aim of this report was to characterize Tr mutants defective in Cel activity. We found that these mutations affect cellulose-induced expression, but not basal expression, of those genes.
A
1
I
o
20
30
42
52
Cdf
0
0
20
49
75
&I-
O
0
0
0
0
(h)
B Sophorose
(h)
CelldOSe
4
-----
6
19
21
24
.
Cd+ Cd-
1 EXPERIMENTAL
cbhl
AND DISCUSSION
(a) Induction of the ccl activity by cellulose
The Tr expresses an extracellular cellulolytic system when grown on cellulose. The activity of this cellulolytic system was measured in the growth media filtrate during induction with cellulose (Fig. 1A). No activity was detectable in the growth medium of the four mutants (QM9136, 9977, 9978, and 9979) after more than 50 h induction. Under the same condition, substantial amount of the cellulolytic activity was measured in the growth medium of Tr QM9414; this activity was detectable after 20 h of induction.
Fig. 1. (A) Effect of cellulose activity.
QM9414,
American
The Tr expresses at least two cellobiohydrolases, CBHI and CBHII (Shoemaker et al., 1983; Chen et al., 1987) two endoglucanases, EGI and EGII (Penttila et al., 1986; Saloheimo et al., 1988; Van Arsdell et al., 1987) and a P-glucosidase (Barnett et al., 1991); this enzymatic system catalyzes, synergistically, the hydrolysis of crystalline cellulose to soluble sugars (Henrissat et al., 1985). The expression of the transcripts of this system was analyzed after induction of Tr cells with two known inducers of the Cel system: cellulose, the insoluble inducer and sophorose, a soluble disaccharide. Fig. 1B shows that the expression of the ccl transcripts, cbhl, cbh2, egll and egl2, were detected 19 h after the addition of cellulose to Tr QM9414 cells; the transcripts were also expressed 4 h after induction with sophorose. However, no transcripts were detected when the mutant cells were exposed to either cellulose or sophorose. Similar results were obtained for @-glucosidase (E.T.; F.H.-S; J.E.-V.; J.C.C.-U.; O.C.; H.E.-D. and S.E.-G., unpublished). It is important to note that, in Tr QM9414, the time course of the induction of the ccl transcripts by cellulose or sophorose appears to be the same. Therefore, it appears that the Cel system genes of the Tr QM9414 strain are expressed coordinately. The results also indicate that the
Type Culture
Collection
mutants
QM9977,
obtained
from the US Department
Inoculum
preparation
(El-Gogary incubated
twice with
on a rotary
26921);
The
All cultures
negative
mutants
to Hybond-N
previously
were incubated
1982) and aliquots
electrophoretically
membranes
(refer to Abrahao-Neto
was
cellulose)
et al., 1989). (B) of the ccl
strain
cellulase-
9414 and
by cellulose
time. RNAs were isolated containing
in 1.2% agarose
and hybridized
on a
on the expression
9136, 9977, 9978 and 9979, were induced (3 mM) for the indicated
and
in culture
time. Cel activity
(El-Gogary
cellulose and sophorose,
and Botstein,
were fractionated
buffer (pH 6.0)
media using Avicel (microcrystalline
Tr cells, cellulase-positive
( 1%) or sophorose
described
spores were centri-
100 mM K.phosphate
as described
mRNAs.
IL, USA.
shaker for 2 h. Mycelia were suspended
in the culture
Effect of inducers,
cellulase-negative Peoria,
from germinated
was added.
Cel from
et al., 1971) were
of Agriculture,
shaker (200 rpm) at 28°C for the indicated
as a substrate,
(Carlson
(ATCC
was obtained
and culture medium were as previously
media and 1% cellulose rotary
of the extracellular
Tr strain,
9978, 9979 and 9136 (Mandels
et al., 1989). Mycelia
fuged, washed
measured
(b) Expression of the cef transcripts
on the induction
a cellulase-positive
10 ug of RNA gel, transferred
to labeled probes as indicated
et al., 1995, for labeled probes).
inability of the mutants to utilize cellulose is not due to posttranscriptional events, such as translation or secretion processes. In addition, the failure of soluble inducer to induce cellulase transcripts in the mutants, indicates that the lack of induction is not due to the inability of the mutants to form the soluble inducer from cellulose. (c) Restriction analysis of the ccl genes
Since the defect in the expression of the ccl genes in these mutants is neither at translation nor at secretion processes, we therefore examined if these mutations are due to deletion in the structural genes of the cellulase or in the regulatory elements controlling the expression of those genes. To that end, we performed restriction analyses of the cellulase genes, cbhl, egll, cbh2 and egl2 (Fig. 2). No differences in the restriction pattern were
201
TAA
ATG 0.72
TAA
ATG
kb
kb
BamHl
4.4
w
kb
HindIll
I
I
“A
h
I y TAA
Af G
I
1.3 kb I
I I
I
ATG
I
I
kb
Nae I
TAA 1.1 kb
Hind III/Xho
2.6 I
1.8
kb 2.2 1.6
Fig. 2. Restriction restriction
enzymes,
analysis
of the ccl genes. DNAs
as indicated,
and fractionated
from the Tr Gel’ strain electrophoretically
labeled probes. The restriction map for each gene is presented hybridization. (A) and (B), cbhl. (C) and (D), egll.
above
observed between the Gel+ strain QM9414 and the four Cell mutants. It is impoitant to note that the probes and the restriction sites used in the analyses of each gene were chosen to produce a DNA pattern covering the entire structural gene and at least 1.5 kb of the 5’ flanking region of the gene. Moreover, no difference was observed in the restriction map analyzed for the B-glucosidase gene in QM9414 strain and the four mutants (data not shown). Therefore, it seems that the inability of those mutants to express the ccl transcripts is not due to deletion of the structural genes or of the promoters controlling the expression of those transcripts. (d) Basal expression of the ceCgenes
The insoluble polymer cellulose is the natural inducer of the eel transcripts. Low basal level of the Cel activity is implicated in triggering the expression of the ccl tran-
9414 and Gel-
in 0.8% agarose the blot; arrow
mutants
gel, transferred below
9136, 9977, 9978 and 9979 were digested to Hybond-N
each restriction
membranes
map presents
and hybridized the probes
with to
used for
scripts; this basal level is needed to generate from cellulose a soluble inducer such as sophorose (Mandels and Reese, 1960; Vaheri et al., 1979). This conclusion was reached from experiments in which the induction of the cbhl transcript by cellulose, but not sophorose, was impaired when antibodies (Ab) to the major members of the cellulase system were added to the culture medium (El-Gogary et al., 1989). To examine whether the basic expression of the eel genes is defective in the examined mutants, we analyzed the expression of a heterologous bacterial gene, the HyR gene (Gritz and Davies, 1983) placed under the control of the cbhl promoter. The vectors pCBHl-Hph-2.2 and pCBHlR-Hph-2.2 contain a 2.2-kb DNA fragment of the 5’ region of chhl fused to the hph gene in the correct and the opposite orientation respectively (J.C.C.-U., F.H.S., S.E.-G., O.C. and H.E.-D., unpublished). The plasmids
202 Transforming
Hygromycin
Plasmids
B
pBluescript
TAT.4
pCBHl-Hph-2.2
+
cbh
TVpCBH1 R-Hph-2.2
-2.2
_K
1
>I hph
kbl
cbh 1
1hph
TATA
ACKNOWLEDGMENTS
This study was supported by grants from PADCTCNPq (62.0622/91.1) and FAPESP (92/3558-4).
Mph Fig. 3. Expression
from the Pcbhl
Hy resistance
Tr eel-
to
pCBHlR-Hph-2.2
contain
in cbhl::hph fusion confers
Plasmids
F.H.S.,
transformation,
cells were plated
pCBHl-Hph-2.2
and the opposite
S.E.-G., O.C. and H.E.-D., on minimal
orientation,
medium
was 0.3 mg/ml, and cells were grown for 48 h. A 2.5cm the top of minimal days. A Bluescript
medium plasmid
used also as controls. presented;
similar
was removed containing
results
essentially
circle (containing
construct
with mutant
with the other
(pHph) QM9978
REFERENCES
as
of MgSO,
200 ug Hy/ml and grown for 4
obtained
were obtained
After
from each plate and placed on
and a promoter-less
The results
respec-
unpublished).
et al., 1988) except that the concentration
at least 15 transformants)
and
of the 5’ region of the cbhl
a 2.2-kb fragment
tively (J.C.C-U.,
(Penttila
promoter
mutants.
gene fused to hph in the correct
described
induce expression of four cellulase and the l%glucosidase transcripts, and that a point mutation or small deletion(s) in the elements controlling these genes is unlikely to occur simultaneously in the promoters of all examined genes. (3) The mutants are defective in the induction process but not in the basal expression of the ccl genes.
were are
three mutants
and the ccl+ strain QM9414.
Abrahao-Neto,
J., Rossini,
Crivellaro,
C.H.B.,
0. and El-Dorry,
cellulase
El-Gogary,
S., Henrique-Silva,
H.: Mitochondrial
Barnett, of
in Trichoderma reesei. Biochemistry
gene expression
CC., the
Berka,
gene
R.M. and Fowler,
encoding
an
Trichoderma reesei: evidence of cellulosic
Carlson,
(e) Conclusions (I) The data suggest that the mutants QM9136, 9977, 9978 and QM9979 are most probably defective in transcription factor(s) required for induction and/or the uptake of the soluble inducer formed from cellulose. Recently it was shown that one of these mutants, QM9979, is indeed defective in P-diglucoside permease (Kubicek et al., 1993). (2) The results also indicate that the ccl transcripts are coordinately expressed and most probably are regulated by the same transcriptional factor(s). This conclusion is based on the fact that all examined mutants failed to
F.,
mediate 34
(1995) 10456610462.
substrates.
T.: Cloning
extracellular for improved
Bio/Technology
M. and Botstein,
Chen, C.M., Gritzali, deduced
primary
9 (1991) 562-567.
reesei. Bio/Technology Coughlan, fungal Btguin,
P. and
Cellulose El-Gogary,
Millet,
J. (Eds.), Academic
by which
of hygromycin
Biochemistry
triggers
Pranz,
Natl.
Saccharomyces
H., Viet, C. and Schulein,
B-glucosidase
by cellulose
(1987) 1481-1487. Kubicek, C.P., Messner, E.M.:
of J.-P.,
Genetics
D. and El-Dorry, Acad.
hygromycin
Bio/Technology 3 (1985) 7222726. Kubicek, C.P.: Involvement of a conidial synthesis
and
cellobiohydrolase
B phosphotransferase and
In: Aubert,
of
Sci. USA 86
B resistance:
25
M.: Synergism
of
of cellulose. and a plasma-
of endoglucanase
in Trichoderma reesei. J. Gen. Microbial. R., Gruber,
F., Mandels,
the
cereoisiae. Gene
endoglucanase
in the induction
H.:
I gene
gene and its expres-
from Trichoderma reesei in the degradation
membrane-bound
and
Biochemistry
systems.
O., Eveleigh,
cellulose
sion in Escherichia coli
cellulases
sequence
Press, New York, 1988, pp. 11-30.
in Trichoderma reesei. Proc.
(1983) 179-188. Henrissat, B., Driguez,
of yeast
II from Trichoderma
Comparative
enzyme
(1989) 613886141. Gritz, L. and Davies, J.: Plasmid-encoded sequence
mRNAs with forms
D.W.: Nucleotide
L.G.:
cellulolytic
S., Leite, A., Crivellaro,
expression
Rev.
5 (1987) 274-278.
Degradation.
Mechanism
Annu.
regulated
of cellobiohidrolase
M.P. and Ljungdahl, and bacterial
degradation.
and intracellular
M. and Stafford, structure
from
rates of saccharification
D.: Two differentially
different 5’ ends encode secreted invertase. Cell 28 (1982) 145-154.
and amplification
beta-glucosidase
Beguin, P.: Molecular biology of cellulose Microbial. 44 (1990) 219-248.
were transformed into mutants cells and transformants were tested for their ability to grow on a minimal medium containing Hy. Fig. 3 shows that the cbhl promoter fused to hph gene in the correct but not the opposite orientation conferred HyR to mutants cells. The same result was obtained in at least five independent transformations. In addition, no HyR transformants were obtained using the cbhl promoter placed in the opposite orientation or with the promoter-less constructs, while between 100 to 200 transformants per ug of plasmid DNA were obtained with the construct having the cbhl promoter in the correct orientation. The results indicate that those mutants are not defective in the basal expression of the cellulase genes.
functions
133
M. and Kubicek-
Triggering
involvement of a inhibited P-diglucoside
of cellulase biosynthesis by cellulose: sophorose-inducible, glucoseconstitutive, permease.
J.
Biol.
Chem
268
(1993)
19364419368. Mandels, M. and Reese, E.T.: Induction of cellulase in fungi by cellobiose. J. Bacterial. 79 (1960) 816-826. Mandels, M., Parrish, F.W. and Reese, E. T.: Sophorose as an inducer of cellulase in Trichoderma uiride. J. Bacterial. 83 (1962) 400-408.
203 Mandels,
M., Weber, J. and Parizek,
R. Enhanced
cellulase
of Trichoderma uiride. Appl.
by a mutant
Shoemaker,
production
Microbial.
21 (1971)
152-154. B.S.: Regulation
in fungi. Trends
Bio/Technol.
M., Lehtovaara,
Knowles,
of cellulase
nucleotide
biosynthesis
and secretion
1 (1983) 156-161.
P., Nevalainen,
J.: Homology
reesei: complete
M., Nevalainen,
A versatile fungus
and
between
cellulase
sequence
genes
R. and
of Trichoderma
of the endoglucanase
I gene.
M., Salminen,
system
E. and Knowles,
for the cellulolytic
J.:
filamentous
Trichoderma reesei. Gene 61 (1988) 1555164.
Saloheimo,
M., Lehtovaara,
Johansson, Knowles,
G., Pettersson, J.K.C.:
EGIII,
reesei: the characterization (1988) 11-22.
P., Pentilla,
G., Claeyssens,
M., Tomme,
a new endoglucanase of both
gene
and
from
J.,
P. and
Trichodermu
enzyme.
Gene
63
M.:
M., Gelfand, Molecular
D., Kwok,
cloning
of
S., exo-
I derived from Trichoderma reesei strain L27. Bio/
1 (1983) 691-696. P., Kauppinen,
domains
gene
and
sequence
S., Salovuori,
I. and Knowles,
in Trichoderma reesei cellulolytic
expression
of cellobiohydrolase
enzymes:
II. Gene
51
(1987) 43-52. M., Leisola,
M. and Kauppinen,
V.: Transglycosylation
ducts of the cellulase system of Trichoderma reesei. Biotechnol. 1 (1979) 41-46. Van Arsdell, J.N., Kwok,
M., Teeri, T.T., Stahlberg,
V., Ladner,
Innis,
J.: Homologous
Vaheri,
H., Ratto,
transformation
Technology
Teeri, T.T., Lehtovaara,
H., Bhikhabhai,
Gene 45 (1986) 253-263. Penttila,
K.
cellobiohydrolase
Montenecourt, Penttila,
S., Schweickart,
Myambo,
and
Innis.
M.:
Saccharomyces
S., Schweickart,
Cloning,
V., Ladner,
characterization,
cereuisiae of endoglucanase
reesei. Bio/Technology
5 (1987) 60-64.
proLett.
M., Gelfand,
D.
expression
in
and I from
Trichoderma
199
0378-1119/96/$15.00
GENE 09816
Mutants of Trichoderma reesei are defective in cellulose induction, but not basal expression of cellulase-encoding genes (Endoglucanase
activity; coordinate expression; genomic analysis; hygromycin-B; promoter; transcript expression)
E. Torigoi, F. Henrique-Silva, and S. El-Gogary
J. Escobar-Vera,
J.C. Carle-Urioste,
0. Crivellaro,
H. El-Dorry
Department of Biochemistry, Institute of Chemistry, University of Sdo Paulo, S&o Paula, 05508-900 SP, Brazil Received by J.R. Kinghorn:
26 November
1995; Revised/Accepted:
27 December/28
December
1995; Received at publishers:
7 March
1996
SUMMARY
Four mutants of Trichoderma reesei defective in cellulose utilization were characterized at the molecular level. Genomic analysis of the cellulase-encoding genes (eel) and transcript induction using two well-established inducers of the ccl system ~ the insoluble polymer, cellulose and the soluble inducer, sophorose, - revealed that these mutants are defective in the transcription of ccl genes. The results also indicate that the ccl genes are coordinately expressed and most probably are regulated by the same mechanism. Using a heterologous gene construct, in which the hygromycin-B-resistanceencoding gene was placed under the control of the promoter of the major ccl gene, cbhl, we showed that the mutants synthesize basic levels of cellulase, but are defective in the ccl induction.
INTRODUCTION
Cellulose, the major constituent of lignocellulosic materials, is a linear polymer of glucose units joined by 1,4-B-glycosidic bonds. Cycling of this plant polysaccharide is brought about mostly by ubiquitous and abundant cellulolytic microorganisms (Coughlan and Ljungdahl, 1988). The utilization of cellulose as an energy carbon source by those microorganisms is achieved by an extracellular cellulase system that catalyzes the hydrolysis of cellulose to glucose (Montenecourt, 1983). Cellulose-degrading enzymes (Cel) of the filamentous Correspondence
to: Dr. S. El-Gogary,
Department
of Biochemistry,
Institute of Chemistry, University of SLo Paulo, Avenida Prof. Lineu Prestes 748, SBo Paulo, 05508-900 SP, Brazil. Tel. (55-11) 818-3848; Fax (55-11) 815-5579; e-mail: [email protected] Abbreviations:
Ab, antibody(ies);
lase; cbh, gene encoding
bp, base pair(s); CBH, cellobiohydro-
CBH; Cel, cellulase;
ccl, gene (DNA,
RNA)
encoding Cel; EG, endoglucanase; egl, gene encoding EG; Hph, hygromycin-B phosphotransferase; hph, gene encoding Hph; Hy, hygromycinB; kb, kilobase or 1000 bp; nt, nucleotide(s); Tr, Trichoderma reesei. PII SO378-1 119(96)00219-3
R, resistance/resistant;
fungus Trichoderma reesei (Tr) are among the best characterized; this cellulolytic system consists of three major classes of Cel: cellobiohydrolases (CBH), which cleave cellobiosyl units from the nonreducing ends of cellulose chains; endoglucanases (EG), which cleave internal glycosidic bonds; and B-glucosidases, which cleave cellooligosaccharides to produce glucose (for a review, refer to Beguin, 1990). The genes coding for CBHI, CBHII, EGI, EGII, and b-glucosidase have been isolated and characterized (Shoemaker et al., 1983; Penttila et al., 1986; Chen et al., 1987; Teeri et al., 1987; Van Arsdell et al., 1987; Saloheimo et al., 1988; Barnett et al., 1991). The ability of Tr to utilize different carbon sources, such as cellulose or glucose, is tightly regulated. Growth on cellulose as the sole carbon source results in induction of at least 1200-fold of the ccl transcripts (J.C.C.-U., F. H.-S., S. E.-G., O.C. and H. E.-D., unpublished), whereas glucose strongly represses the expression of those transcripts (Abrahao-Neto et al., 1995). Compelling evidences have implicated basal expression of the Cel activity in triggering the induction of the cellulase transcripts; this basal expression seems necessary to catalyze the forma-
200
tion of soluble inducer from cellulose (El-Gogary et al., 1989; Kubicek, 1987). A potential soluble inducer of the Cel activity (Mandels et al., 1962) is the disaccharide sophorose (2-O-B-glucopyranosyl-D-glucose). This inducer was shown to be one of the products catalyzed by the Tr Cel system and was detected during growth of TV on cellobiose (Mandels and Reese, 1960; Mandels et al., 1962; Vaheri et al., 1979). The aim of this report was to characterize Tr mutants defective in Cel activity. We found that these mutations affect cellulose-induced expression, but not basal expression, of those genes.
A
1
I
o
20
30
42
52
Cdf
0
0
20
49
75
&I-
O
0
0
0
0
(h)
B Sophorose
(h)
CelldOSe
4
-----
6
19
21
24
.
Cd+ Cd-
1 EXPERIMENTAL
cbhl
AND DISCUSSION
(a) Induction of the ccl activity by cellulose
The Tr expresses an extracellular cellulolytic system when grown on cellulose. The activity of this cellulolytic system was measured in the growth media filtrate during induction with cellulose (Fig. 1A). No activity was detectable in the growth medium of the four mutants (QM9136, 9977, 9978, and 9979) after more than 50 h induction. Under the same condition, substantial amount of the cellulolytic activity was measured in the growth medium of Tr QM9414; this activity was detectable after 20 h of induction.
Fig. 1. (A) Effect of cellulose activity.
QM9414,
American
The Tr expresses at least two cellobiohydrolases, CBHI and CBHII (Shoemaker et al., 1983; Chen et al., 1987) two endoglucanases, EGI and EGII (Penttila et al., 1986; Saloheimo et al., 1988; Van Arsdell et al., 1987) and a P-glucosidase (Barnett et al., 1991); this enzymatic system catalyzes, synergistically, the hydrolysis of crystalline cellulose to soluble sugars (Henrissat et al., 1985). The expression of the transcripts of this system was analyzed after induction of Tr cells with two known inducers of the Cel system: cellulose, the insoluble inducer and sophorose, a soluble disaccharide. Fig. 1B shows that the expression of the ccl transcripts, cbhl, cbh2, egll and egl2, were detected 19 h after the addition of cellulose to Tr QM9414 cells; the transcripts were also expressed 4 h after induction with sophorose. However, no transcripts were detected when the mutant cells were exposed to either cellulose or sophorose. Similar results were obtained for @-glucosidase (E.T.; F.H.-S; J.E.-V.; J.C.C.-U.; O.C.; H.E.-D. and S.E.-G., unpublished). It is important to note that, in Tr QM9414, the time course of the induction of the ccl transcripts by cellulose or sophorose appears to be the same. Therefore, it appears that the Cel system genes of the Tr QM9414 strain are expressed coordinately. The results also indicate that the
Type Culture
Collection
mutants
QM9977,
obtained
from the US Department
Inoculum
preparation
(El-Gogary incubated
twice with
on a rotary
26921);
The
All cultures
negative
mutants
to Hybond-N
previously
were incubated
1982) and aliquots
electrophoretically
membranes
(refer to Abrahao-Neto
was
cellulose)
et al., 1989). (B) of the ccl
strain
cellulase-
9414 and
by cellulose
time. RNAs were isolated containing
in 1.2% agarose
and hybridized
on a
on the expression
9136, 9977, 9978 and 9979, were induced (3 mM) for the indicated
and
in culture
time. Cel activity
(El-Gogary
cellulose and sophorose,
and Botstein,
were fractionated
buffer (pH 6.0)
media using Avicel (microcrystalline
Tr cells, cellulase-positive
( 1%) or sophorose
described
spores were centri-
100 mM K.phosphate
as described
mRNAs.
IL, USA.
shaker for 2 h. Mycelia were suspended
in the culture
Effect of inducers,
cellulase-negative Peoria,
from germinated
was added.
Cel from
et al., 1971) were
of Agriculture,
shaker (200 rpm) at 28°C for the indicated
as a substrate,
(Carlson
(ATCC
was obtained
and culture medium were as previously
media and 1% cellulose rotary
of the extracellular
Tr strain,
9978, 9979 and 9136 (Mandels
et al., 1989). Mycelia
fuged, washed
measured
(b) Expression of the cef transcripts
on the induction
a cellulase-positive
10 ug of RNA gel, transferred
to labeled probes as indicated
et al., 1995, for labeled probes).
inability of the mutants to utilize cellulose is not due to posttranscriptional events, such as translation or secretion processes. In addition, the failure of soluble inducer to induce cellulase transcripts in the mutants, indicates that the lack of induction is not due to the inability of the mutants to form the soluble inducer from cellulose. (c) Restriction analysis of the ccl genes
Since the defect in the expression of the ccl genes in these mutants is neither at translation nor at secretion processes, we therefore examined if these mutations are due to deletion in the structural genes of the cellulase or in the regulatory elements controlling the expression of those genes. To that end, we performed restriction analyses of the cellulase genes, cbhl, egll, cbh2 and egl2 (Fig. 2). No differences in the restriction pattern were
201
TAA
ATG 0.72
TAA
ATG
kb
kb
BamHl
4.4
w
kb
HindIll
I
I
“A
h
I y TAA
Af G
I
1.3 kb I
I I
I
ATG
I
I
kb
Nae I
TAA 1.1 kb
Hind III/Xho
2.6 I
1.8
kb 2.2 1.6
Fig. 2. Restriction restriction
enzymes,
analysis
of the ccl genes. DNAs
as indicated,
and fractionated
from the Tr Gel’ strain electrophoretically
labeled probes. The restriction map for each gene is presented hybridization. (A) and (B), cbhl. (C) and (D), egll.
above
observed between the Gel+ strain QM9414 and the four Cell mutants. It is impoitant to note that the probes and the restriction sites used in the analyses of each gene were chosen to produce a DNA pattern covering the entire structural gene and at least 1.5 kb of the 5’ flanking region of the gene. Moreover, no difference was observed in the restriction map analyzed for the B-glucosidase gene in QM9414 strain and the four mutants (data not shown). Therefore, it seems that the inability of those mutants to express the ccl transcripts is not due to deletion of the structural genes or of the promoters controlling the expression of those transcripts. (d) Basal expression of the ceCgenes
The insoluble polymer cellulose is the natural inducer of the eel transcripts. Low basal level of the Cel activity is implicated in triggering the expression of the ccl tran-
9414 and Gel-
in 0.8% agarose the blot; arrow
mutants
gel, transferred below
9136, 9977, 9978 and 9979 were digested to Hybond-N
each restriction
membranes
map presents
and hybridized the probes
with to
used for
scripts; this basal level is needed to generate from cellulose a soluble inducer such as sophorose (Mandels and Reese, 1960; Vaheri et al., 1979). This conclusion was reached from experiments in which the induction of the cbhl transcript by cellulose, but not sophorose, was impaired when antibodies (Ab) to the major members of the cellulase system were added to the culture medium (El-Gogary et al., 1989). To examine whether the basic expression of the eel genes is defective in the examined mutants, we analyzed the expression of a heterologous bacterial gene, the HyR gene (Gritz and Davies, 1983) placed under the control of the cbhl promoter. The vectors pCBHl-Hph-2.2 and pCBHlR-Hph-2.2 contain a 2.2-kb DNA fragment of the 5’ region of chhl fused to the hph gene in the correct and the opposite orientation respectively (J.C.C.-U., F.H.S., S.E.-G., O.C. and H.E.-D., unpublished). The plasmids
202 Transforming
Hygromycin
Plasmids
B
pBluescript
TAT.4
pCBHl-Hph-2.2
+
cbh
TVpCBH1 R-Hph-2.2
-2.2
_K
1
>I hph
kbl
cbh 1
1hph
TATA
ACKNOWLEDGMENTS
This study was supported by grants from PADCTCNPq (62.0622/91.1) and FAPESP (92/3558-4).
Mph Fig. 3. Expression
from the Pcbhl
Hy resistance
Tr eel-
to
pCBHlR-Hph-2.2
contain
in cbhl::hph fusion confers
Plasmids
F.H.S.,
transformation,
cells were plated
pCBHl-Hph-2.2
and the opposite
S.E.-G., O.C. and H.E.-D., on minimal
orientation,
medium
was 0.3 mg/ml, and cells were grown for 48 h. A 2.5cm the top of minimal days. A Bluescript
medium plasmid
used also as controls. presented;
similar
was removed containing
results
essentially
circle (containing
construct
with mutant
with the other
(pHph) QM9978
REFERENCES
as
of MgSO,
200 ug Hy/ml and grown for 4
obtained
were obtained
After
from each plate and placed on
and a promoter-less
The results
respec-
unpublished).
et al., 1988) except that the concentration
at least 15 transformants)
and
of the 5’ region of the cbhl
a 2.2-kb fragment
tively (J.C.C-U.,
(Penttila
promoter
mutants.
gene fused to hph in the correct
described
induce expression of four cellulase and the l%glucosidase transcripts, and that a point mutation or small deletion(s) in the elements controlling these genes is unlikely to occur simultaneously in the promoters of all examined genes. (3) The mutants are defective in the induction process but not in the basal expression of the ccl genes.
were are
three mutants
and the ccl+ strain QM9414.
Abrahao-Neto,
J., Rossini,
Crivellaro,
C.H.B.,
0. and El-Dorry,
cellulase
El-Gogary,
S., Henrique-Silva,
H.: Mitochondrial
Barnett, of
in Trichoderma reesei. Biochemistry
gene expression
CC., the
Berka,
gene
R.M. and Fowler,
encoding
an
Trichoderma reesei: evidence of cellulosic
Carlson,
(e) Conclusions (I) The data suggest that the mutants QM9136, 9977, 9978 and QM9979 are most probably defective in transcription factor(s) required for induction and/or the uptake of the soluble inducer formed from cellulose. Recently it was shown that one of these mutants, QM9979, is indeed defective in P-diglucoside permease (Kubicek et al., 1993). (2) The results also indicate that the ccl transcripts are coordinately expressed and most probably are regulated by the same transcriptional factor(s). This conclusion is based on the fact that all examined mutants failed to
F.,
mediate 34
(1995) 10456610462.
substrates.
T.: Cloning
extracellular for improved
Bio/Technology
M. and Botstein,
Chen, C.M., Gritzali, deduced
primary
9 (1991) 562-567.
reesei. Bio/Technology Coughlan, fungal Btguin,
P. and
Cellulose El-Gogary,
Millet,
J. (Eds.), Academic
by which
of hygromycin
Biochemistry
triggers
Pranz,
Natl.
Saccharomyces
H., Viet, C. and Schulein,
B-glucosidase
by cellulose
(1987) 1481-1487. Kubicek, C.P., Messner, E.M.:
of J.-P.,
Genetics
D. and El-Dorry, Acad.
hygromycin
Bio/Technology 3 (1985) 7222726. Kubicek, C.P.: Involvement of a conidial synthesis
and
cellobiohydrolase
B phosphotransferase and
In: Aubert,
of
Sci. USA 86
B resistance:
25
M.: Synergism
of
of cellulose. and a plasma-
of endoglucanase
in Trichoderma reesei. J. Gen. Microbial. R., Gruber,
F., Mandels,
the
cereoisiae. Gene
endoglucanase
in the induction
H.:
I gene
gene and its expres-
from Trichoderma reesei in the degradation
membrane-bound
and
Biochemistry
systems.
O., Eveleigh,
cellulose
sion in Escherichia coli
cellulases
sequence
Press, New York, 1988, pp. 11-30.
in Trichoderma reesei. Proc.
(1983) 179-188. Henrissat, B., Driguez,
of yeast
II from Trichoderma
Comparative
enzyme
(1989) 613886141. Gritz, L. and Davies, J.: Plasmid-encoded sequence
mRNAs with forms
D.W.: Nucleotide
L.G.:
cellulolytic
S., Leite, A., Crivellaro,
expression
Rev.
5 (1987) 274-278.
Degradation.
Mechanism
Annu.
regulated
of cellobiohidrolase
M.P. and Ljungdahl, and bacterial
degradation.
and intracellular
M. and Stafford, structure
from
rates of saccharification
D.: Two differentially
different 5’ ends encode secreted invertase. Cell 28 (1982) 145-154.
and amplification
beta-glucosidase
Beguin, P.: Molecular biology of cellulose Microbial. 44 (1990) 219-248.
were transformed into mutants cells and transformants were tested for their ability to grow on a minimal medium containing Hy. Fig. 3 shows that the cbhl promoter fused to hph gene in the correct but not the opposite orientation conferred HyR to mutants cells. The same result was obtained in at least five independent transformations. In addition, no HyR transformants were obtained using the cbhl promoter placed in the opposite orientation or with the promoter-less constructs, while between 100 to 200 transformants per ug of plasmid DNA were obtained with the construct having the cbhl promoter in the correct orientation. The results indicate that those mutants are not defective in the basal expression of the cellulase genes.
functions
133
M. and Kubicek-
Triggering
involvement of a inhibited P-diglucoside
of cellulase biosynthesis by cellulose: sophorose-inducible, glucoseconstitutive, permease.
J.
Biol.
Chem
268
(1993)
19364419368. Mandels, M. and Reese, E.T.: Induction of cellulase in fungi by cellobiose. J. Bacterial. 79 (1960) 816-826. Mandels, M., Parrish, F.W. and Reese, E. T.: Sophorose as an inducer of cellulase in Trichoderma uiride. J. Bacterial. 83 (1962) 400-408.
203 Mandels,
M., Weber, J. and Parizek,
R. Enhanced
cellulase
of Trichoderma uiride. Appl.
by a mutant
Shoemaker,
production
Microbial.
21 (1971)
152-154. B.S.: Regulation
in fungi. Trends
Bio/Technol.
M., Lehtovaara,
Knowles,
of cellulase
nucleotide
biosynthesis
and secretion
1 (1983) 156-161.
P., Nevalainen,
J.: Homology
reesei: complete
M., Nevalainen,
A versatile fungus
and
between
cellulase
sequence
genes
R. and
of Trichoderma
of the endoglucanase
I gene.
M., Salminen,
system
E. and Knowles,
for the cellulolytic
J.:
filamentous
Trichoderma reesei. Gene 61 (1988) 1555164.
Saloheimo,
M., Lehtovaara,
Johansson, Knowles,
G., Pettersson, J.K.C.:
EGIII,
reesei: the characterization (1988) 11-22.
P., Pentilla,
G., Claeyssens,
M., Tomme,
a new endoglucanase of both
gene
and
from
J.,
P. and
Trichodermu
enzyme.
Gene
63
M.:
M., Gelfand, Molecular
D., Kwok,
cloning
of
S., exo-
I derived from Trichoderma reesei strain L27. Bio/
1 (1983) 691-696. P., Kauppinen,
domains
gene
and
sequence
S., Salovuori,
I. and Knowles,
in Trichoderma reesei cellulolytic
expression
of cellobiohydrolase
enzymes:
II. Gene
51
(1987) 43-52. M., Leisola,
M. and Kauppinen,
V.: Transglycosylation
ducts of the cellulase system of Trichoderma reesei. Biotechnol. 1 (1979) 41-46. Van Arsdell, J.N., Kwok,
M., Teeri, T.T., Stahlberg,
V., Ladner,
Innis,
J.: Homologous
Vaheri,
H., Ratto,
transformation
Technology
Teeri, T.T., Lehtovaara,
H., Bhikhabhai,
Gene 45 (1986) 253-263. Penttila,
K.
cellobiohydrolase
Montenecourt, Penttila,
S., Schweickart,
Myambo,
and
Innis.
M.:
Saccharomyces
S., Schweickart,
Cloning,
V., Ladner,
characterization,
cereuisiae of endoglucanase
reesei. Bio/Technology
5 (1987) 60-64.
proLett.
M., Gelfand,
D.
expression
in
and I from
Trichoderma