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Molecular and Cellular Biology, January 1999, p. 471-483, Vol. 19, No. 1
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The Yeast RER2 Gene, Identified by Endoplasmic
Reticulum Protein Localization Mutations, Encodes
cis-Prenyltransferase, a Key Enzyme in Dolichol
Synthesis
Miyuki
Sato,1
Ken
Sato,1
Shuh-ichi
Nishikawa,2
Aiko
Hirata,3
Jun-ichi
Kato,4 and
Akihiko
Nakano1,*
Molecular Membrane Biology Laboratory, RIKEN,
Wako, Saitama 351-0198,1
Department of
Chemistry, Graduate School of Science, Nagoya University, Chikusa-ku,
Nagoya 464-8602,2
Institute of Molecular
and Cellular Biosciences, University of Tokyo, Yayoi, Bunkyo-ku,
Tokyo 113-0032,3 and
Department of
Molecular Biology, Institute of Medical Science, University of
Tokyo, Tokyo 108-8639,4 Japan
Received 27 July 1998/Returned for modification 11 September
1998/Accepted 16 September 1998
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ABSTRACT |
As an approach to understand the molecular mechanisms of
endoplasmic reticulum (ER) protein sorting, we have isolated yeast rer mutants that mislocalize a Sec12-Mf
1p fusion protein
from the ER to later compartments of the secretory pathway (S. Nishikawa and A. Nakano, Proc. Natl. Acad. Sci. USA 90:8179-8183,
1993). The temperature-sensitive rer2 mutant mislocalizes
different types of ER membrane proteins, suggesting that
RER2 is involved in correct localization of ER proteins in
general. The rer2 mutant shows several other
characteristic phenotypes: slow growth, defects in N and O
glycosylation, sensitivity to hygromycin B, and abnormal accumulation
of membranes, including the ER and the Golgi membranes. RER2 and SRT1, a gene whose
overexpression suppresses rer2, encode novel proteins
similar to each other, and their double disruption is lethal.
RER2 homologues are found not only in eukaryotes but also
in many prokaryote species and thus constitute a large gene family
which has been well conserved during evolution. Taking a hint from
the phenotype of newly established mutants of the Rer2p
homologue of Escherichia coli, we discovered that the
rer2 mutant is deficient in the activity of
cis-prenyltransferase, a key enzyme of dolichol synthesis.
This and other lines of evidence let us conclude that members of the
RER2 family of genes encode cis-prenyltransferase itself. The difference in
phenotypes between the rer2 mutant and previously
obtained glycosylation mutants suggests a novel, as-yet-unknown role of dolichol.
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INTRODUCTION |
In the secretory pathway, the
endoplasmic reticulum (ER) is the compartment from which the
biosynthetic membrane flow begins. Newly synthesized proteins are
folded and modified in the lumen of the ER and then transported to
their destinations by vesicular processes. On the other hand, a set of
proteins is sorted from these proteins and retained in the ER to carry
out their functions. Such ER localization is known to be fulfilled by
the recognition of signals that are present in the ER resident
proteins. Well-known examples of the ER localization signals
include the C-terminal H(K)DEL and KKXX sequences, which are
involved in the retrieval of proteins from the Golgi apparatus to the
ER (19, 25, 26, 33, 46).
Sec12p is a type II transmembrane glycoprotein of the yeast
Saccharomyces cerevisiae and is essential for the formation
of COPII vesicles from the ER (4, 5, 10, 27, 32). Although Sec12p has neither HDEL nor KKXX signals, most Sec12p is localized to
the ER in the steady state and is not detected on the purified transport vesicles (4, 27, 29). However, a significant portion of Sec12p receives cis-Golgi-specific modification
on its N-linked oligosaccharide chains (27, 29). From these
observations, we postulated that the ER localization of Sec12p involves
two different mechanisms: static retention in the ER and dynamic
retrieval from the early Golgi (29, 42, 44). To identify
factors participating in these sorting events, we isolated two mutants,
the rer1 and rer2 (for return to the ER or
retention in the ER) mutants, which mislocalize a Sec12-Mf1 fusion
protein beyond the early Golgi (29).
The RER1 gene has been extensively studied by ourselves and
others; it encodes a protein possessing four transmembrane domains which is located in the early Golgi compartment (6, 42). We
have also demonstrated that Sec12p contains two signals for ER
localization: an Rer1p-dependent retrieval signal in the transmembrane domain and an Rer1p-independent retention signal in the cytoplasmic domain (44). Furthermore, we have recently shown that Rer1p is required for the retrieval of not only Sec12p but also a variety of
ER membrane proteins (43). From these studies, we propose that Rer1p is a component of the machinery required for the Golgi-to-ER retrograde traffic, which constitutes a major retrieval pathway in addition to the KDEL- and KKXX-dependent mechanisms (43).
In this paper, we report the characterization of the rer2
mutant. The rer2 mutant shows quite pleiotropic defects in
the normal endomembrane system, suggesting that RER2 is very
important for maintaining the integrity of organelles. Cloning by
complementation has revealed the presence of a suppressor gene,
SRT1, in addition to the authentic RER2 gene.
RER2 and SRT1 are similar to each other, and
their products belong to a new protein family that is well conserved in
many organisms. Finally, we present evidence that RER2
encodes a key enzyme of dolichol synthesis. The analysis of the
rer2 mutant provides new insight into the physiological roles of dolichol.
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MATERIALS AND METHODS |
Strains and culture conditions.
The S. cerevisiae
strains used in this study are listed in Table
1. Yeast cells were grown in YPD (1%
[wt/vol] Bacto yeast extract [Difco Laboratories, Detroit, Mich.],
2% [wt/vol] polypeptone [Nihon Seiyaku, Tokyo, Japan], and 2%
[wt/vol] glucose) or in MVD (0.67% yeast nitrogen base without amino
acids [Difco Laboratories] and 2% glucose) supplemented
appropriately. MCD medium is MVD containing 0.5% Casamino Acids (Difco
Laboratories). Hygromycin B (Wako Junyaku Kogyo, Osaka, Japan) and
sodium orthovanadate (Sigma-Aldrich Japan, Tokyo, Japan) were added to
YPD medium to give final concentrations of 50 µg/ml and 4 mM,
respectively.
Antibodies.
Rabbit anti-Kar2p, anti-Ypt1p, and anti-Gas1p
polyclonal antibodies were generous gifts from M. Rose of the
Massachusetts Institute of Technology; D. Gallwitz of the Max Planck
Institute of Biophysical Chemistry, Göttingen, Germany; and H. Riezman of the University of Basel, respectively. Affinity-purified
rabbit anti-Dap2p polyclonal antibody was kindly provided by Y. Amaya of Niigata University and Y. Wada of Osaka University. Rabbit anti-Sec12p and anti-carboxypeptidase Y (anti-CPY) polyclonal antibodies were prepared as described previously (27, 49). The 16B12 mouse monoclonal antihemagglutinin (anti-HA) antibody was
purchased from Berkeley Antibody Company (Richmond, Calif.). Rabbit
anti-Kex2p and anti-Pgk1p polyclonal antibodies were prepared through
the support of Suntory Limited, Osaka, Japan.
Cloning of RER2 and SRT1.
To clone
RER2, hygromycin B sensitivity was used. SNH23-7D
(rer2-2) was transformed with a yeast genomic library on
YEp13 (56), and the transformants were replicated onto YPD
plates containing 50 µg of hygromycin B per ml. Plasmids were
recovered from the colonies that grew on the hygromycin B plates and
subcloned into pRS316 (48). The 1.6-kb
SpeI-NdeI fragment (pR7) was capable of
complementing both the hygromycin B and temperature sensitivities of
rer2 cells. To test the linkage between this clone and the RER2 locus, the 5.2-kb SalI (in
vector)-BglII fragment from the original clone was inserted
into the BamHI-SalI sites of YIp5, an integration
vector with a URA3 marker (50). This plasmid was
digested with SacI and integrated in the chromosome of a
wild-type strain (YPH500) by homologous recombination (to give strain
SMY2). SMY2 was crossed with HS23-3BA (rer2-2) and
sporulated. Tetrad analysis showed a tight linkage between the
URA3 marker and the rer2 locus (11 parental
ditypes of 13 tetrads), indicating that this clone contained the
authentic RER2 gene. We also tried to clone the
RER2 gene by complementation of the temperature sensitivity of rer2 cells. The same yeast genomic library was introduced
into SNH23-10A (rer2-2), and the transformants that grew at
37°C were selected. Plasmids recovered from these colonies contained
two overlapping clones which were different from RER2. They
were subcloned into pRS316 and pQR326 (35), and the 2.4-kb
XhoI-BglII fragment was the smallest subclone
that suppressed rer2-2. We named the gene in this subclone
SRT1.
Disruption of RER2 and SRT1.
The 0.7-kb
AflII-SplI region of RER2 was replaced
by the LEU2 gene in pY1, which contained the 5.5-kb
SalI (in vector of the original clone)-NheI
fragment in YEp352 (18). The disrupted copy of
RER2 was excised by HindIII digestion and
introduced into a diploid strain constructed by crossing SNY9 and an
isogenic MATa strain. A Leu+ haploid
segregant (SMY41) was obtained by tetrad dissection. The 2.4-kb
XhoI-BglII fragment of SRT1 was
subcloned into pBluescript SK(+) (Stratagene Cloning Systems, La Jolla,
Calif.) to give pRER206. The SRT1 gene was disrupted by
replacing the 0.6-kb EcoO109I-BamHI region with
TRP1 in pRER206. This plasmid was digested with
XhoI and PvuII and introduced into diploid
(YPH501) and haploid (SKY1) strains. A viable haploid strain whose
chromosomal SRT1 was disrupted (SMY13) was obtained.
To construct a 
rer2 srt1 double mutant, one of the
RER2 loci was disrupted with LEU2 by the same
strategy as described above in a diploid strain, ANY200, to give SMY1.
One of the SRT1 loci was further disrupted with
TRP1 to give SMY5. For this disruption, the TRP1
fragment was inserted at the essential BamHI site in pRER206, and the resulting plasmid was introduced into SMY1 after digestion with XhoI and SpeI. SMY5 itself and
SMY5 transformed with pR7 (RER2 in pRS316) were sporulated
and subjected to tetrad dissection. The LEU2 and
TRP1 genes were excised from pJJ283 and pJJ248
(21), respectively. The disruption of RER2 and
SRT1 in these experiments was confirmed by Southern blotting.
Construction of 3HA-RER2.
To insert the 3HA
fragment, a SpeI site was created at the fourth and
fifth codons of RER2 by PCR-mediated, site-directed mutagenesis with the oligonucleotide
5'-AAAGACGGTATGGAAACGACTAGTGGTATACCTGGTCAT-3' and the complementary sequence. A DNA cassette encoding 3HA was excised from pYT11 (52) with NheI and inserted
into this SpeI site in RER2 to construct
3HA-RER2. The AflII-SphI fragment of pR7 was replaced by the corresponding fragment of the tagged
3HA-RER2 gene (pR7HA). 3HA-RER2 was also
subcloned into pSQ326 (pR7HA-4) and pRS314 (pR7HA-2) (35,
48).
Pulse-chase experiments.
Metabolic labeling of yeast cells
with Tran35S-label (ICN Biomedicals, Costa Mesa, Calif.),
preparation of cell extracts, and immunoprecipitation were performed as
described previously (30). Immunoprecipitates were analyzed
by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)
and fluorography.
Immunofluorescence microscopy.
Indirect immunofluorescence
microscopy was performed as described previously (28, 42).
To amplify the fluorescent signals, a system using a biotinylated
goat anti-rabbit antibody and streptavidin-fluorescein (42)
was employed.
Subcellular fractionation.
Subcellular fractionation
was performed as described by Sato et al. (42) with some
modifications. Cells were grown to 107 cells/ml in
MVD medium at 30°C and spheroplasted as described previously
(28). Spheroplasts (109) were suspended in 1 ml
of ice-chilled lysis buffer (0.2 M sorbitol, 50 mM K-acetate, 2 mM
EDTA, 20 mM HEPES-KOH [pH 6.8], 1 mM dithiothreitol, 20 µg of
phenylmethylsulfonyl fluoride per ml, 5 µg of antipain per ml, 5 µg
of aprotinin per ml, 5 µg of leupeptin per ml, and 5 µg of
pepstatin per ml) (15) and homogenized with a 1-ml Dounce homogenizer (Wheaton, Millville, N.J.). The lysates were subjected to a
series of centrifugation steps: 300 × g for 5 min in a
15M-18AL rotor (Sakuma, Tokyo, Japan), 13,000 × g for
15 min in the same rotor, and 100,000 × g for 45 min
in an RP100AT rotor (Hitachi Ltd., Tokyo, Japan) (all at 4°C).
Aliquots were taken from the pellet fraction of the 13,000 × g centrifugation (P13) and the pellet (P100) and supernatant
(S100) fractions of the 100,000 × g centrifugation and
analyzed by SDS-PAGE and immunoblotting. The amounts of 3HA-Rer2p in
these fractions were analyzed by SDS-PAGE and immunoblotting. The
membrane association of 3HA-Rer2p was examined by a method described
previously (28).
cis-Prenyltransferase assay.
The
cis-prenyltransferase activity was measured by the methods
of Bukhtiyarov et al. (7) and Quellhorst et al.
(36). The P13 membrane fractions which were enriched in
3HA-Rer2p were prepared as described above. The standard assay mixture
contained membranes (100 µg of protein), 1.4 nmol of farnesyl
diphosphate (FPP) (American Radiolabeled Chemicals Inc., St. Louis,
Mo.), 5 nmol of [1-14C]isopentenyl diphosphate (IPP)
(Amersham), 25 mM sodium phosphate (pH 7.4), 4 mM MgCl2, 20 mM KF, and 20 mM 
-mercaptoethanol in a final volume of 100 µl. The
mixture was incubated at 30°C for 1 h, and the reaction was
terminated by the addition of 400 µl of 4 mM MgCl2 and
2.5 ml of chloroform-methanol (3:2). After phase separation, the lower
phase was washed with 1 ml of the upper phase obtained by mixing with
water-methanol-chloroform (1:2:3) and then evaporated and resuspended
in chloroform. An appropriate aliquot was analyzed by thin-layer
chromatography on a Silica Gel G-60 plate (Merck) with the solvent
system of benzene-ethyl acetate (95:5) to confirm that the products
were mostly dolichol and dehydrodolichol compounds. Another aliquot of
this chloroform suspension was subjected to liquid scintillation
counting to measure the total radioactivity incorporated into the
dolichol fraction. The total cell lysates prepared as described above
were also incubated under the same assay conditions, and the products
were similarly analyzed by thin-layer chromatography. The reference
molecules, i.e., dolichol from porcine liver, ficaprenol (polyprenol
from Ficus elastica), solanesol
(all-trans-nonaprenpol), and squalene, were purchased from Sigma.
Other methods.
Halo assays were performed on MCD plates with
a tester MATa sst2 strain as described
previously (29). For electron microscopy, thin sections of
yeast cells were prepared by the freeze-substitution fixation method
(51). Yeast transformation was carried out by the lithium
thiocyanate method (22) or by electroporation
(16). DNA manipulations were performed by standard techniques (41). DNA sequences of RER2,
SRT1, and their derivatives were determined by the
dideoxy method with a DNA sequencer (model 373A; Applied Biosystems,
Tokyo, Japan).
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RESULTS |
The rer2 mutant mislocalizes a variety of ER
proteins.
To monitor the localization of Sec12p within a cell, we
have devised an in vivo method utilizing the fusion protein with a yeast -mating-factor precursor (Mf1p) as a reporter. If this fusion protein (Sec12-Mf1p) is transported to the late Golgi, the
Mf1p moiety is processed, leading to the secretion of mature -factor. The secreted -factor can be detected by the halo assay (Halo+). By this method, rer mutants were
isolated as cells defective in correct localization of Sec12-Mf1p
(29). The rer1 mutant cells show no obvious
growth defect at any temperatures in spite of a clear Halo+
phenotype. In contrast, the rer2 mutant exhibits severe
growth inhibition even at 23°C and no longer grows at 37°C
(29). The halo formed around the rer2 cells is
visible but small, which may be due to the slow growth of the cells.
The halo assay method can be applied to monitor the localization of
Sec71p and Sec63p, which are also membrane proteins localized
to the ER
in the wild-type cells. Sec71p is a type III transmembrane
protein
(topology opposite to that of Sec12p), and Sec63p spans
the membrane
three times. These proteins form a multimeric complex
required for the
ER translocation of newly synthesized proteins
(
11,
12,
23,
39,
40). We constructed fusion proteins
of these proteins and Mf
1p
and recently demonstrated that both
Mf
1-Sec71p and Mf
1-Sec63p are
mislocalized in
rer1, indicating
that Rer1p is a
component of the general machinery involved in
the ER localization of
these proteins (
43). In the present study,
we introduced
these fusions into the
rer2 mutant on a single-copy
plasmid
and performed the halo assay at 23°C. As shown in Fig.
1A, both fusions produced larger halos in
rer2 cells than in the
wild-type cells, indicating that the
rer2 mutant is constitutively
defective in the correct
localization of Sec71p and Sec63p. It
is also noteworthy that the
rer2 mutant missecretes a significant
amount of
immunoglobulin heavy-chain binding protein (BiP), a
soluble ER protein
possessing the HDEL signal (Fig.
1B) (
29,
42). Because the
intracellular level of BiP was not appreciably
different in the
wild-type and the
rer2 cells (data not shown),
the
missecretion is not simply due to the overflow of the Erd2p-dependent
retrieval system. The
rer2 mutant appears to have a lesion
that
disturbs the localization of various ER proteins.
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FIG. 1.
(A) Secretion of mature -factor by cells producing
Mf1-Sec71p and Mf1-Sec63p. Wild-type (WT) (SNY9),
rer1 (SKY7), and rer2-2 (SNH23-7D) cells
expressing Mf1-Sec71p or Mf1-Sec63p on a single-copy vector were
examined by the halo assay at 23°C. (B) The rer2 mutants
missecrete BiP. Wild-type (SNY9), rer2-2 (SNH23-16C),
rer2 (SMY41), and srt1 (SNY25) cells were
grown in YPD medium at 23°C to the early logarithmic phase. Proteins
from the medium (equivalent to 1.5 × 106 cells) were
analyzed by immunoblotting with the anti-BiP antibody.
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The rer2 mutant shows glycosylation defects.
To
examine the level of expression of Sec12p in rer2 cells,
immunoblotting was performed with an anti-Sec12p antibody (Fig. 2A). Sec12p acquires both N- and O-linked
oligosaccharide modifications and is usually detected as a fuzzy band
around 70 kDa (27). The steady-state amount of Sec12p in
rer2 cells was comparable to that in the wild type. In
rer2 cells, however, a ladder of smaller species was
detected in addition to the fuzzy band corresponding to the normal
Sec12p in the wild-type cells. After endoglycosidase H (endo H)
treatment, the smaller species of Sec12p in rer2 cells were
still present (data not shown). These results suggest that the
rer2 mutant is defective in both N- and O-linked
glycosylation in the ER.
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FIG. 2.
(A) Underglycosylation phenotype of rer2
mutants. Wild-type (WT) RER2 (SNY9) and rer2-2
(SNH23-7D) cells were grown in YPD medium to 107 cells/ml
at 23°C and then shifted to 37°C for the indicated times. Total
cell extracts were prepared, and proteins (70 µg) were analyzed by
immunoblotting with the anti-Sec12p antibody. (B) Biosynthesis of CPY
in rer2 mutants. The rer2-2 mutant (SNH23-7A) and
wild-type (SNY9) cells were preincubated for 1 h at 23 or 37°C
and then labeled for 4 min with Tran35S-label and chased
for the indicated times at the same temperature. CPY was
immunoprecipitated from cell extracts and treated with or without endo
H. Samples were analyzed by SDS-PAGE and fluorography. p1, ER form; p2,
Golgi form; m, mature vacuolar form; *, unglycosylated pro-CPY. (C)
Biosynthesis of a GPI anchor protein, Gas1p, in rer2
mutants. After preincubation at 37°C for 1 h, rer2-2
(SNH23-7A) and wild-type (SNY9) cells were labeled for 4 min with
Tran35S-label and chased at 37°C. Gas1p was
immunoprecipitated and analyzed by SDS-PAGE and fluorography.
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We also performed a pulse-chase experiment with CPY, a vacuolar enzyme
(
49), to investigate the vesicular biosynthetic pathway
of
the mutant (Fig.
2B). In the wild-type cells, the conversion
from the
ER form through the Golgi form to the mature vacuolar
form of CPY takes
place in about 30 min. The same conversion of
CPY species with a
similar time course was also observed with
the
rer2 mutant
at 23°C. However, a ladder of bands was detected
throughout the chase
time, the major species of which migrated
even faster than the mature
form. The mobility of this band was
the same as that of endo H-treated
pro-CPY, suggesting again that
the
rer2 mutant has a defect
in N glycosylation. The endo H treatment
also revealed that about 30%
of the CPY molecules had experienced
the proteolytic processing in 30 min, indicating that the vesicular
trafficking itself was not blocked
in the mutant. The deficiency
of glycosylation was more severe at
37°C (Fig.
2B, lower
panels).
A pulse-chase experiment was also performed for Gas1p, a
glycosylphosphatidylinositol (GPI)-anchored protein which is also
modified by N- and O-linked glycosylation (
53). As shown in
Fig.
2C, the major band migrated with an apparent molecular mass
of 70 kDa in the
rer2 mutant, which coincided with the size of
the
polypeptide moiety (
14). Taken together, the data indicate
that the
rer2 mutant apparently possesses a profound
temperature-sensitive
defect in both N and O
glycosylation.
In liquid culture,
rer2 cells tend to form aggregates, which
is typical for glycosylation mutants. This could be due to alterations
in the cell wall structure resulting from the glycosylation defect.
The
rer2 mutant also shows sensitivity to hygromycin B and
resistance
to sodium orthovanadate. Such drug sensitivity and tolerance
are
generally observed in various mutants that have defects in
glycosylation
in either the ER or the Golgi (
3,
9).
Abnormal membrane structures accumulate in the
rer2 mutants.
The intracellular membrane structures of
the rer2 mutant were observed by indirect immunofluorescence
microscopy with antibodies against organelle-specific marker
proteins. As shown by staining with the anti-BiP antibody (Fig.
3), the rer2 mutant showed
accumulation of the ER membranes, which developed in the cytoplasm. The
morphology of the Golgi apparatus also looked abnormal in the
rer2 mutant (Fig. 4). The
antibody against Ypt1p, which is localized mostly to the early Golgi
(34), stained enlarged structures which often had a
ring-like shape. These abnormal membrane structures were seen even at
23°C but were recognized more clearly at 37°C.
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FIG. 3.
Immunofluorescence localization of an ER marker protein,
BiP. Wild-type (SNY9) (A and B) and rer2-2 (SNH23-7D) (C
and D) cells growing at 23°C were subjected to indirect
immunofluorescence microscopy with the anti-BiP antibody. (A and C)
Fluorescence images with the antibody. (B and D) DNA staining with
DAPI.
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FIG. 4.
Immunofluorescence localization of a
cis-Golgi marker protein, Ypt1p. Wild-type (SNY9) (A and B)
and rer2-2 (SNH23-7D) (C and D) cells were incubated at
37°C for 4 h and subjected to indirect immunofluorescence
microscopy with the anti-Ypt1p antibody. (A and C) Fluorescence images
with the antibody. (B and D) DNA staining with DAPI.
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We further observed the organellar morphology by electron
microscopy by the freeze-substitution fixation method. As shown
in Fig.
5, membrane structures were
dramatically altered in the
rer2 mutant. At 23°C (Fig.
5B
and D), ER-like membranes piled
up in the cytoplasm and the nuclear
envelope, a part of the ER,
looked twisted, as often seen for some
early
sec mutants (
31).
In addition, ring-
and cup-shaped membranes 150 to 200 nm in diameter
and numerous small
vesicles accumulated throughout the cytoplasm.
The ring- and cup-shaped
structures are reminiscent of Berkeley
bodies, which are formed in
sec7 and
sec14 mutants, resulting
from the
deformation of accumulating Golgi membranes (
31), and
presumably correspond to the structures visualized by
immunofluorescence
of Ypt1p. Apparently, multiple secretory organelles
accumulated
in the
rer2 mutant even at 23°C.
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FIG. 5.
Electron micrographs of rer2 cells.
Wild-type (SNY9) (A) and rer2-2 (SNH23-10D) (B to E) cells
were incubated at 23°C (A, B, and D) or shifted to 37°C for
2 h (C and E) and then subjected to freeze-substitution
fixation and electron microscopic observation. Panels D and E are
enlargements of panels B and C, respectively.
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When the mutant cells were incubated at 37°C for 2 h, the
intracellular membranes became more aberrant (Fig.
5C and E). The
ER-like membrane further developed and expanded in the cytoplasm.
The
boundary of the membranes became unclear compared to the normal
ER
membrane. In addition, irregularly shaped unidentifiable
structures
and many fragmented vacuoles were observed. Thus,
RER2 appears
to be required to maintain the normal functions
and structures
of the whole central vacuolar
system.
Cloning of the RER2 and SRT1 genes.
To
obtain the wild-type RER2 gene, we first tried to isolate a
clone that complements the temperature-sensitive growth of the
rer2 mutant. The rer2-2 mutant (SNH23-10A)
was transformed with a YEp13-based yeast genomic library
(56), and the transformants that grew at 37°C were
selected. We obtained two clones which overlap in the DNA inserts and
identified the common fragment (the 2.4-kb
XhoI-BglII fragment) that complements
rer2 temperature sensitivity. This DNA fragment contained a
single open reading frame (YMR101c) encoding a protein of 343 amino
acids and was able to complement the temperature-sensitive growth of
the rer2 mutant on a single-copy plasmid. However, the
integration analysis indicated that this clone did not map at the
rer2 locus. We concluded that this clone is a suppressor of
rer2 and named it SRT1 for suppressor of
rer two.
The authentic
RER2 gene was isolated by complementation of
the hygromycin B sensitivity of the
rer2 mutant.
rer2-2 cells (SNH23-7D)
were transformed with the same yeast
genomic library, and transformants
were replicated onto YPD plates
containing 50 µg of hygromycin
B per ml. Four independent clones that
complement
rer2 were identified.
They had an overlapping
genomic fragment, and the 1.6-kb
SpeI-
NdeI
fragment completely complemented the hygromycin B sensitivity
of the
rer2-2 mutant on a single-copy plasmid. This subclone also
complemented the temperature sensitivity of growth and the
Halo
+ phenotype of the
rer2 mutant on a
single-copy plasmid. We sequenced
this DNA fragment and revealed a
single open reading frame (YBR002c)
that encodes a protein of 286 residues. By integration mapping,
this gene was confirmed to be the
bona fide
RER2 (see Materials
and
Methods).
Figure
6 shows the growth phenotypes of
the original
rer2 mutant, the
rer2 mutant
suppressed by
SRT1, and the
rer2 mutant
complemented by
RER2. The
SRT1 gene on a
single-copy plasmid (
CEN)
suppresses the
temperature-sensitive growth of the
rer2 mutant
like the
authentic
RER2 gene but does not suppress the hygromycin
B
sensitivity very well. On a multicopy plasmid (2µm), it suppresses
both phenotypes. It should be noted that the single-copy
SRT1 gene also suppressed the Halo
+ phenotype of
the
rer2 mutant (data not shown).
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FIG. 6.
Growth phenotypes of the rer2 mutant and
complementation by RER2 and SRT1. rer2-2 cells
(SNH23-7D) were transformed with RER2 or SRT1 on
a single-copy (CEN) or multicopy (2µm) plasmid. The
transformants were streaked on MCD plates and incubated at 23 or 37°C
for 4 days. The same cells were also streaked on a YPD plate containing
50 µg of hygromycin B per ml and incubated at 23°C for 4 days.
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Proteins encoded by
RER2 and
SRT1 (Rer2p and
Srt1p, respectively) show high sequence homology (30% identical) over
the whole
polypeptide (Fig.
7A).
Hydropathy analysis (
24) indicated no
hydrophobic region in
either Rer2p or Srt1p that is capable of
acting as a signal sequence or
transmembrane domain. Database
searches revealed many homologues
of Rer2p in various organisms,
as shown in Fig.
7B. Srt1p is the only
S. cerevisiae homologue
of Rer2p. High degrees of
identity to the
Schizosaccharomyces pombe SPAC4D7.04c and
the
Caenorhabditis elegans T01G1.b gene
products (40 and
31%, respectively), products of open reading
frames identified by
sequencing projects, were found. A higher
plant,
Arabidopsis
thaliana, also seems to have a homologue of
Rer2p. Interestingly,
similar proteins can be found in many prokaryote
species, including
Haemophilus influenzae,
Escherichia coli, and
Bacillus subtilis. These proteins show ~30% identity to
Rer2p
throughout the molecule. Thus, Rer2p seems to belong to a family
that contains well-conserved members from prokaryotes to
eukaryotic
multicellular organisms. However, these entries in the
database
are all hypothetical proteins. It should be also noted here
that
Mycoplasma, a microbe lacking a cell wall, is the
only organism
that does not possess any Rer2p homologue among
those whose genomes
were completely sequenced.
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FIG. 7.
Sequence comparison of Rer2p with its homologues. The
boxes show identical amino acid residues, and the borderless shading
indicates similar residues. (A) Sequences of yeast Rer2p and Srt1p. (B)
Rer2p homologues in various organisms, including both eukaryotes and
prokaryotes. They are all hypothetical proteins found by the genome
projects. The proteins are S. pombe SPAC4D7.04c, C. elegans T01G1.1, E. coli o253, H. influenzae
HI0920, B. subtilis yluA, Synechocystis strain
PCC6803 SLL0506, and Methanococcus jannaschii MJ1372.
Asterisks indicate the mutation points found in the rer2-1
(G164D) and rer2-2 (S209N) alleles.
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We determined the mutation points of the
rer2 mutants. The
genomic DNA fragments containing the
rer2 locus were
recovered
by PCR and sequenced. The
rer2-1 and
rer2-2 alleles harbored missense
mutations that led to
G164-to-D and S209-to-N amino acid replacements,
respectively. These
residues are well conserved in the
RER2 gene
family from
prokaryotes to higher eukaryotes (Fig.
7B). The two
mutants were very
similar in every phenotype we
examined.
The Rer2p family is essential for vegetative growth.
We
constructed RER2 and SRT1 null mutants. In a
diploid strain (SMY3), one RER2 locus was disrupted by
replacing the AflII-SplI fragment of
RER2 with a LEU2 fragment (Fig.
8A). The
disruption was confirmed by Southern blotting (data not shown).
Tetrad dissection identified Leu+ haploid cells
(rer2), which were viable but grew very slowly even at
23°C (Fig. 8B). This growth defect was more severe than that of the
original rer2 mutants. The rer2 strain showed
phenotypes similar to those of the rer2 mutants:
temperature-sensitive growth at 37°C, missecretion of BiP, hygromycin
B sensitivity, and vanadate resistance. These observations suggest that
rer2-1 and rer2-2 were both decrease-of-function
type mutations, although not null. We could not observe the
mislocalization of Sec12-Mf1p, because the rer2
mutant grew too slowly to be examined by the halo assay. SRT1 was also able to suppress the
temperature-sensitive and slow-growth phenotypes of the
rer2 mutant (data not shown).
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FIG. 8.
Disruption of the RER2 gene. (A) The
AflII-SplI region of RER2 was replaced
by the LEU2 fragment. The disrupted copy of RER2
was excised with HindIII and introduced into a diploid
strain. (B) Tetrad analysis of the resulting strain
(RER2/rer2::LEU2) at 23°C. All small
colonies were Leu+, indicating that the disruption of
RER2 causes a severe growth defect.
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The disruption of
SRT1 was performed by replacement of the
EcoO109I-
BamHI fragment with the
TRP1
gene. We could obtain a haploid
strain (SMY13) whose chromosomal
SRT1 gene was disrupted, indicating
that the
SRT1
gene is not essential for growth. The correct disruption
was confirmed
by Southern blotting (data not shown). The
srt1 strain
grew normally at any temperature examined and did not show
a
significant difference from the wild type in hygromycin B sensitivity.
The localizations of Sec12-Mf
1p (data not shown) and BiP (Fig.
1B)
were also normal in the
srt1 mutant.
Double disruption of the
RER2 and
SRT1 genes was
performed with
LEU2 and
TRP1, respectively, in a
diploid strain (SMY5) (see
Materials and Methods). In dissection of 16 tetrads after sporulation,
no Leu
+ Trp
+
segregants were able to grow, suggesting that the double disruption
of
RER2 and
SRT1 was lethal. To confirm this, the
RER2 gene was
introduced into SMY5 on the pRS316 plasmid,
and tetrad dissection
was carried out again. We could obtain five
Leu
+ Trp
+ Ura
+ segregants, but none
of them grew on a plate containing fluoro-orotic
acid, a reagent
that forces elimination of the
URA3 plasmid, even
at 23°C.
Thus,
RER2 and
SRT1 constitute a family
that has an essential
function for cell
viability.
Subcellular localization of Rer2p.
To analyze the biochemical
characteristics of the RER2 gene product, the 3HA tag was
introduced in the N-terminal part of Rer2p. This 3HA-Rer2p was
completely functional, because the 3HA-RER2 gene was able to
complement both the temperature and hygromycin B sensitivities of the
rer2 mutant on a single-copy plasmid (data not shown).
Total cell lysates were prepared from rer2 cells harboring 3HA-RER2 on a single-copy or multicopy plasmid,
and immunoblotting was performed with an anti-HA monoclonal antibody (16B12). A single band migrating at around 39 kDa was detected in a
dose-dependent manner; this mass was slightly larger than the predicted
molecular mass of 36 kDa (data not shown).
To assess the localization of 3HA-Rer2p, subcellular fractionation was
performed. A total cell lysate was prepared from the
rer2
strain expressing 3HA-Rer2p on a single-copy plasmid and
subjected to
differential centrifugation at 13,000 ×
g and
100,000
×
g (Fig.
9A).
Although Rer2p has no hydrophobic region, most
of the 3HA-Rer2p was
fractionated in the P13 fraction, suggesting
that 3HA-Rer2p is
peripherally associated with membranes. This
fractionation pattern
coincided with that of an ER membrane protein,
Sec12p, and a
vacuolar enzyme, Dap2p, but not with that of a cytosolic
enzyme,
phosphoglycerate kinase, or a late-Golgi marker, Kex2p,
which
were detected mostly in the S100 and P100 fractions,
respectively
(
15,
37,
38,
42). We further characterized the
nature
of the membrane association of 3HA-Rer2p by using several
chemical
reagents. The total homogenate was treated with reagents
as indicated
in Fig.
9B and centrifuged at 436,000 ×
g for 30 min. 3HA-Rer2p
was not extracted with 1 M NaCl or 2 M urea but was partially
solubilized with 0.1 M sodium carbonate (pH
11.5) and 1% (wt/vol)
Triton X-100. This result indicates that
3HA-Rer2p is tightly
associated with membranes.
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FIG. 9.
(A) Subcellular fractionation of 3HA-Rer2p.
rer2 cells expressing 3HA-Rer2p on a single-copy vector
were spheroplasted, homogenized, and subjected to a series of
centrifugations: 300 × g for 5 min, 13,000 × g for 15 min, and 100,000 × g for 45 min.
Aliquots were taken from the pellet of the 13,000 × g
centrifugation (P13) and the pellet (P100) and supernatant (S100)
fractions of the 100,000 × g centrifugation and
analyzed by immunoblotting. (B) Extraction of 3HA-Rer2p. The total
homogenate was treated with the reagents indicated and centrifuged at
436,000 × g for 1 h. The pellets and supernatants
were analyzed by Western blotting with the anti-HA antibody. TX-100,
Triton X-100.
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Indirect immunofluorescence microscopy was also performed
for the
rer2 strain expressing 3HA-Rer2p on a
single-copy plasmid.
The cells were fixed and prepared for
immunofluorescence with
the anti-HA monoclonal antibody (16B12)
(Fig.
10). We expected
that 3HA-Rer2p
would be localized to the ER from the result of
the fractionation
experiment, but the staining pattern of 3HA-Rer2p
was quite
different from the typical ER pattern. As shown in Fig.
10C,
the anti-HA antibody stained punctate structures. These structures
did
not look like vacuoles either. We realized that these punctate
structures were frequently observed alongside the nuclei (compare
with
the DAPI [4',6-diamidino-2-phenylindole] staining in Fig.
10D) and
near the cell surface. Since these regions are where ER
membranes often
exist, we carried out double-staining immunofluorescence
with
anti-HA and anti-BiP antibodies. As shown in Fig.
11, the
staining of 3HA-Rer2p (Fig.
11B) overlaps at least partly with
the staining of the ER protein BiP,
suggesting that 3HA-Rer2p
is localized in a subregion of the ER.
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FIG. 10.
Subcellular localization of 3HA-Rer2p.
rer2 cells (SMY41) harboring RER2 (A and B) or
3HA-RER2 (C and D) on a single-copy plasmid were grown at
30°C and prepared for indirect immunofluorescence microscopy with the
anti-HA antibody (16B12). (A and C) Fluorescence images with the
antibody. (B and D) DNA staining with DAPI.
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FIG. 11.
Double immunofluorescence staining of BiP and
3HA-Rer2p. rer2 cells (SMY41) harboring
3HA-RER2 on a single-copy plasmid were grown at 30°C and
prepared for indirect immunofluorescence microscopy. (A) Rhodamine
fluorescence corresponding to the anti-BiP antibody. (B) Fluorescein
fluorescence corresponding to the anti-HA antibody (16B12). (C) DNA
staining with DAPI.
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The rer2 mutants are deficient in the
cis-prenyltransferase activity required for dolichol
synthesis.
As described above, the rer2 mutants
showed deficiencies in early glycosylation steps. Hygromycin B
sensitivity, vanadate resistance, and cell aggregation are also
phenotypes often observed for glycosylation mutants. However, we
hesitated to consider a direct role of Rer2p in protein glycosylation
at this point, because the Rer2p family is conserved not only in
eukaryotes but also in a variety of prokaryotic species. An
important clue to reveal their function was obtained from our
study of the o253 gene, the sole E. coli homologue of
RER2. The o253 gene was cloned by PCR and found to be an
essential gene in E. coli. Temperature-sensitive mutants, which were constructed by random mutagenesis on the plasmid, showed abnormal swollen cell shapes at the nonpermissive
temperature, and many cells appeared to eventually die due to cell
bursting (21a). This suggested that o253 plays an
important role in the cell wall synthesis. The fact that
Mycoplasma, a parasitic eubacterium lacking a cell wall,
does not possess any RER2 homologue in the genome supported
this possibility.
The major constituent of the bacterial cell wall is peptidoglycan. By
looking into the metabolic map, we realized that peptidoglycan
synthesis in bacteria and glycosylation in eukaryotes employ very
similar reactions. Both pathways utilize a specific lipid as the
carrier of donor sugars: undecaprenyl phosphate (UP-P) for
peptidoglycan
and dolichyl phosphate (Dol-P) for oligosaccharides.
Dol-P is
made from dehydrodolichyl diphosphate (Dedol-PP) by reduction,
dephosphorylation, and phosphorylation. Dehydrodolichol
(C
65 to
C
100) and undecaprenol
(C
55) are both long-chain polyprenols and
are synthesized
by condensation of IPP units onto FPP with a
cis configuration (Z-type), the reaction catalyzed by a single enzyme,
cis-prenyltransferase (see Fig.
14). The genes coding for
cis-prenyltransferase
were not known for either prokaryotes
or
eukaryotes.
The possibility that the
RER2 gene encodes the
cis-prenyltransferase to synthesize Dedol-PP was
tested as follows. Membrane
fractions were prepared from
wild-type and
rer2 cells and assayed
for
cis-prenyltransferase activity by measuring synthesis of
polyprenol
from IPP and FPP. The results are shown in Table
2. In
rer2 cells, the
activity of this enzyme was remarkably decreased. The
residual
activity, 2.7% of the wild type, may be due to the
SRT1 gene. The deficiency of
cis-prenyltransferase was
efficiently
complemented by the
RER2 gene on a single-copy
plasmid. Moreover,
the wild-type cells overexpressing Rer2p on a
multicopy plasmid
showed 1.6-fold higher activity of this enzyme. To
rule out the
possibility that the decrease of the activity was due to
the mislocalization
of the enzyme, the whole activities of the
isoprenoid biosynthesis
utilizing FPP and IPP were investigated with
total cell lysates
(Fig.
12). The
rer2-2 and
rer2 mutants synthesized compounds
that
comigrate with squalene (an intermediate of ergosterol synthesis)
and all-
trans-polyprenol (comigrating with solanesol) in
amounts
comparable (or even better in the case of squalene) to those
for
the wild-type cells. However, the synthesis of dolichol compounds
was quite deficient in the mutants. This deficiency was observed
at
either 20 or 30°C. Thus, the activity for synthesis of dolichol
was
almost lost in the
rer2 mutant cells. These observations let
us conclude that the
RER2 gene is in fact responsible for
the
cis-prenyltransferase activity in yeast.
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FIG. 12.
Isoprenoid biosynthesis activities in rer2
mutants. Total lysates were prepared from RER2 (SNY9) (lanes
1 and 3), rer2-2 (SNH23-7D) (lanes 2 and 4), and
rer2 (SMY20) (lane 5) cells, rer2 (SMY20)
cells harboring RER2 on a single-copy plasmid (lane 6), and
RER2 (SNY9) cells harboring RER2 on a multicopy
plasmid (lane 7) and incubated with [1-14C]IPP and FPP at
20°C (lanes 1 and 2) or 30°C (lanes 3 to 7). The lipidic products
were extracted with chloroform-methanol, spotted on a
thin-layer chromatography plate, and developed with the benzene-ethyl
acetate (95:5) solvent system (see Materials and Methods). Dolichol
from porcine liver, ficaprenol (polyprenol from F. elastica), solanesol (all-trans-nonaprenpol), and
squalene were used as standards.
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SEC59 has been known to encode dolichol kinase, an
enzyme required to complete the Dol-P synthesis pathway (see Fig.
14) (
17).
RER2 on a multicopy plasmid partially
suppressed the temperature-sensitive
growth of the
sec59 mutant at 35°C (Fig.
13). This observation
strengthens our
conclusions described above. Perhaps the elevated
amount of de
novo-synthesized dolichol from the overexpression
of
RER2
suppresses the partial defect of dolichol kinase.
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FIG. 13.
Overexpression of RER2 suppresses the
temperature-sensitive growth of sec59 cells. The
sec59 mutant (SF604-9C) was transformed with RER2
on a multicopy vector, SRT1 on a multicopy vector, or a
vector only. These and the control wild-type strain (ANY21) harboring
an empty vector were incubated on an MCD plate at 35°C for 3 days.
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| |
DISCUSSION |
In this paper, we have presented genetic and biochemical evidence
that the yeast RER2 gene encodes the
cis-prenyltransferase enzyme Dedol-PP synthase. The in
vivo function of dolichol and its derivatives, which was never
assessed before, is discussed below.
Dolichol synthesis and rer2 mutant phenotypes.
Dolichol, a polyisoprenoid derivative, has been known to play essential
roles in protein glycosylation (8). In N-linked glycosylation, the precursor oligosaccharide is preassembled on Dol-P
and then transferred to proteins. Dol-P is also needed for O-linked glycosylation and GPI precursor synthesis in yeast.
However, its biosynthesis has remained one of the least understood
reactions in the metabolic pathways. Basically all isoprenoid compounds of eukaryotes, including sterols, ubiquinones, and dolichol, are synthesized from mevalonate. The first branch in this pathway to the
synthesis of dolichol is the formation of long-chain (C65 to C100) polyprenyl diphosphate (Dedol-PP) by addition of
isoprenyl units from IPP to FPP. This reaction is catalyzed by a single enzyme, cis-prenyltransferase (Fig.
14). Although the activity of this
enzyme can be detected in crude extracts and membrane fractions
(1, 2, 55), the gene encoding this enzyme was never
identified. The details of the later steps of dolichol synthesis, including -saturation, dephosphorylation, and
phosphorylation, are not well established either.
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FIG. 14.
(A) Role of carrier lipids in two systems. The unit of
peptidoglycan is preassembled on UP-P in prokayotes, whereas the core
oligosaccharide complex in N glycosylation is synthesized on Dol-P in
eukaryotes. Both lipids are derivatives of long-chain polyprenol. (B)
Biosynthetic pathway of dolichol.
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|
rer2 mutants, yeast mutants which we isolated as defective
in the correct localization of Sec12p, show defects in early steps
of
N- and O-linked glycosylation. However, their other phenotypes,
including mislocalization of multiple ER proteins and accumulation
of
aberrant ER and Golgi, were not previously reported for many
known
glycosylation mutants. Moreover, Rer2p homologues are found
not only in
eukaryotes but also in prokaryotes. Thus, we were
interested in
determining the general function of this protein
family.
The Rer2p family is cis-prenyltransferase, an enzyme
conserved from prokaryotes to eukaryotes.
The link between the
Rer2p family and cis-prenyltransferase was revealed by our
study of the E. coli RER2 homologue, the o253 gene. This
gene turned out to be essential for growth in E. coli, and
its temperature-sensitive, conditional-lethal mutants showed a defect
in cell wall synthesis. The synthesis of bacterial peptidoglycan, the
major constituent of the cell wall, also utilizes a polyprenol compound, UP-P, as the sugar carrier. The unit of peptidoglycan (a
disaccharide with a peptide side chain) is preassembled on UP-P,
a reaction similar to the oligosaccharide synthesis on Dol-P (Fig. 14).
The synthesis of UP-P is also catalyzed by a
cis-prenyltransferase enzyme, undecaprenyl
diphosphate (UP-PP) synthase, and the only difference from
Dedol-PP synthase is the chain length of the product. We
measured the activity of UP-PP synthase for the o253
temperature-sensitive mutants and found that it was in fact markedly
decreased in the mutants (21a). Furthermore, while these
studies were in progress, we learned that Koyama's group at Tohoku
University cloned a Micrococcus luteus gene that encodes
UP-PP synthase (47). This gene was the M. luteus counterpart of the E. coli o253 gene. They
showed not only that the overexpression of this gene increases the
synthesis of UP-PP but also that the purified gene product has the
enzyme activity (47). These results lead to the conclusion
that these prokaryotic genes encode UP-PP synthase, which is essential
for peptidoglycan biosynthesis.
For the yeast
RER2, we have demonstrated that the
rer2 mutants are deficient in the Dedol-PP synthase
activity. The overexpression
of
RER2 results in an increase
of the activity. Furthermore, the
overexpression of
RER2
partially suppresses the temperature sensitivity
of the
sec59 mutant, a dolichol kinase mutant. Taking all of
these
observations together, we conclude that members of the
RER2 gene
family encode
cis-prenyltransferase,
which synthesizes Dedol-PP
in eukaryotes and UP-PP in prokaryotes.
Since Dedol-PP is the
precursor of dolichol, which is essential for
protein glycosylation
and GPI synthesis, the glycosylation defects of
the
rer2 mutants
are all well explained.
SRT1
probably encodes an isozyme of Dedol-PP
synthase, although it
appears to play a minor role in the in vivo
activity.
Subcellular localization of Rer2p.
It has been reported that
the cis-prenyltransferase activity is associated with
microsomal membranes (2, 55). This is consistent with the
results of our fractionation experiment that 3HA-Rer2p is a peripheral
but tightly associated membrane protein and colocalizes with an
ER marker. However, immunofluorescence microscopy has revealed
that 3HA-Rer2p is not continuously present in the ER but rather shows a
quite restricted localization. A fascinating explanation for this may
be that Rer2p is localized to a subregion of the ER membrane that is
specialized for dolichol synthesis. In the yeast Saccharomyces
carlsbergensis, the formation of dolichol was observed when an in
vitro assay was performed with the intact membrane, but Dedol-PP was
not efficiently converted to dolichol when the enzyme was solubilized
(7). The enzymes in dolichol synthesis might form a complex
or be concentrated in the ER subdomain to increase the efficiency of
the sequence of reactions.
Physiological function of dolichol.
Do the defects in N and O
glycosylation as well as in GPI anchor synthesis due to the deficient
dolichol synthesis explain all of the phenotypes of the rer2
mutants? Formally, glycosylation mutants can have quite pleiotropic
phenotypes, because they are deficient in a variety of glycoproteins.
However, among a large number of yeast glycosylation mutants so far
isolated, several phenotypes may be unique to the rer2
mutants. For example, intracellular membrane structures are quite
abnormal in the rer2 mutants. The ER membranes are
extensively elongated and accumulated, and the Golgi membranes form
ring-like structures. Although information on the intracellular
morphology in glycosylation mutants is very limited, the
sec53 mutant, a phosphomannomutase mutant, was reported to
show no appreciable lesion in the membrane structures (13). The sec59 mutant, a dolichol kinase mutant, was reported to
exhibit some extension and fragmentation of the ER membrane, but this was not drastic like that of the rer2 mutants
(13). Tunicamycin treatment, which shuts off N-linked
glycosylation, does not seem to affect organellar morphologies so
dramatically. We would argue that the accumulation of abnormal
membranes in the rer2 mutants is not a general outcome of
glycosylation deficiency. The most important phenotype of the
rer2 mutants from the viewpoint of membrane trafficking is
that they mislocalize various ER proteins (Sec12-Mf1p,
Mf1-Sec63p, Mf1-Sec71p, and BiP) to later compartments of the
secretory pathway. Examination of such a phenotype has not been
performed for other glycosylation mutants and is now under way
in our laboratory.
The difference between the
rer2 and
sec59 mutants
is particularly intriguing, because both are defective in the supply of
the final product of the lipid carrier, Dol-P, and the greatest
difference is that the
rer2 mutant lacks all of the
derivatives
of polyprenol but the
sec59 mutant can make
dolichol. If they
indeed differ in phenotypes, this will provide a good
clue to
understand a novel, as-yet-unknown physiological function of
dolichol.
There are some reports that the presence of dolichol or Dol-P
in the lipid bilayer alters the membrane properties of model liposomes
(
8,
20,
45,
54). It is possible that dolichol and its
derivatives have a structural role in membranes. The regulation
of the
dolichol level and its phosphorylation may be important
to maintain the
organellar membrane integrity. An interesting
observation along this
line is that ergosterol synthesis seems
to be activated in
rer2 mutants (Fig.
12), suggesting that a mechanism
to
balance dolichol and sterol exists. Alternatively, dolichol
might
positively participate in various cellular functions, such
as
protein sorting in the secretory organelles.
rer2 and
srt1 mutants will provide important tools to reveal
the physiological
roles of this least-studied lipid in eukaryotes, and
we will continue
these efforts in our future
projects.
| |
ACKNOWLEDGMENTS |
We are grateful to M. Rose of the Massachusetts Institute of
Technology; D. Gallwitz of the Max Planck Institute of Biophysical Chemistry, Göttingen, Germany; H. Riezman of the University
of Basel; Y. Amaya of Niigata University; Y. Wada of Osaka
University; and Suntory Limited, Osaka, Japan, for antibodies. We also
thank A. Ohta of the University of Tokyo, K. Hosaka of Gunma
University, M. Wachi of Tokyo Institute of Technology, H. Hara of
Saitama University, and S. Fujisaki of Toho University for helpful
discussions on the functions of the Rer2p family. We are particularly
indebted to S. Fujisaki for valuable advice on the assay of
cis-prenyltransferase. Thanks are also due to T. Koyama of
Tohoku University for providing information prior to publication.
Finally, we appreciate valuable discussions with the members of the
Nakano laboratory.
This work was supported by grants-in-aid from the Ministry of
Education, Science, Sports and Culture of Japan, by a research grant
from the Human Frontier Science Program, and by funds from the Inamori
Foundation and from the Biodesign Project of RIKEN. M. Sato and
K. Sato are recipients of the Research Fellowship for Young
Scientists from the Japan Society for the Promotion of Science.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Molecular
Membrane Biology Lab., RIKEN, Wako, Saitama 351-0198, Japan. Phone:
81-48-467-9547. Fax: 81-48-462-4679. E-mail:
nakano{at}postman.riken.go.jp.
| |
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1987.
Characterization of the Saccharomyces cerevisiae cis-prenyltransferase required for dolichyl phosphate biosynthesis.
Arch. Biochem. Biophys.
259:589-596[Medline].
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Adair, W. L. J., and R. K. Keller.
1982.
Dolichol metabolism in rat liver. Determination of the subcellular distribution of dolichyl phosphate and its site and rate of de novo biosynthesis.
J. Biol. Chem.
257:8990-8996[Abstract/Free Full Text].
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Ballou, L.,
R. A. Hitzeman,
M. S. Lewis, and C. E. Ballou.
1991.
Vanadate-resistant yeast mutants are defective in protein glycosylation.
Proc. Natl. Acad. Sci. USA
88:3209-3212[Abstract/Free Full Text].
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Molecular and Cellular Biology, January 1999, p. 471-483, Vol. 19, No. 1
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Abstract
Introduction
