Human enhancer of rudimentary is a molecular partner
of PDIP46/SKAR, a protein interacting with DNA
polymerase d and S6K1 and regulating cell growth
Amelia Smyk
1
, Magdalena Szuminska
1
, Katarzyna A. Uniewicz
1
, Lee M. Graves
2
and Piotr Kozlowski
1
1 Institute of Biochemistry, Warsaw University, Warsaw, Poland
2 Department of Pharmacology, University of North Carolina at Chapel Hill, NC, USA
The enhancer of rudimentary (ER) gene has been iden-
tified in eukaryotic organisms ranging from protists to
plants to humans with the exception of fungi, in which
this gene has not been isolated so far [1–5]. Moreover,
it seems to be absent in the sequenced genomes of Sac-
charomyces cerevisiae and Schizosaccharomyces pombe.
Keywords
ER; POLDIP3; pyrimidine; RNA recognition
motif; yeast two-hybrid system
Correspondence
P. Kozlowski, Institute of Biochemistry,
Warsaw University, Miecznikowa 1,
02-096 Warsaw, Poland
Fax: +48 22 5543116
Tel: +48 22 5543108
E-mail:

Databases
The nucleotide sequence reported in this
paper has been submitted to the
DDBJ ⁄ EMBL ⁄ GenBank databases with the
accession number DQ887818.
The DDBJ ⁄ EMBL ⁄ GenBank accession
numbers: U66871 (ER), AL160111 and
AL160112 (POLDIP3).
The UniProtKB ⁄ SwissProt accession
numbers: P84090 (ER), P05990 (CAD),
Q91901 (DCoH ⁄ PCD), O00267 (SPT5),
Q9Y5B0 (FCP1), Q9BY77 (PDIP46 ⁄ SKAR)
and P23443 (S6K1).
(Received 25 April 2006, revised 18 August
2006, accepted 18 August 2006)
doi:10.1111/j.1742-4658.2006.05477.x
Enhancer of rudimentary (ER) is a small protein that has a unique amino
acid sequence and structure. Its highly conserved gene has been found in
all eukaryotic kingdoms with the exception of fungi. ER was proposed to
be involved in the metabolism of pyrimidines and was reported to act as a
transcriptional repressor in a cell type-specific manner. To further elucidate
ER functions, we performed the yeast two-hybrid screen of the human lung
cDNA library for clones encoding proteins interacting with the human ER
protein. The screen yielded polymerase d interacting protein 46 or S6K1
Aly ⁄ REF-like target (PDIP46 ⁄ SKAR), a protein possessing one RNA
recognition motif (RRM) and being a protein partner of both the p50 sub-
unit of DNA polymerase d and p70 ribosomal protein S6 kinase 1 (S6K1).
This interaction was further confirmed in vitro by the glutathione S-trans-
ferase-ER pull-down of a protein of 46 kDa from a nuclear extract from
human cells which was identified as PDIP46 ⁄ SKAR by tandem mass

spectrometry. The bipartite region of PDIP46 ⁄ SKAR interacting with ER
comprising residues 274–421 encompasses the docking site for S6K1 within
the RRM and two serines phosphorylated by S6K1. ER and both isoforms
of PDIP46 ⁄ SKAR share the same nuclear localization in the mammalian
cells and their genes display a ubiquitous pattern of expression in a variety
of human tissues, so the interaction between ER and PDIP46 ⁄ SKAR has
an opportunity to occur universally in mammalian cells. Because
PDIP46 ⁄ SKAR is involved in the regulation of cell growth its interaction
with ER may suggest some function for ER in that control.
Abbreviations
CK2, casein kinase II; DCoH/PCD, dimerization cofactor of hepatocyte nuclear factor 1 (HNF1)/pterin-4a-carbinolamine dehydratase; EGFP,
enhanced green fluorescent protein; ER, enhancer of rudimentary; FCP1, TFIIF-associating component of CTD phosphatase; GAL4, galactose
utilization gene 4; GST, glutathione S-transferase; HNF1, hepatocyte nuclear factor 1; IPTG, isopropyl thio-b-
D-galactoside; MEK1, mitogen-
activated protein kinase or extracellular signal-regulated kinase 1; PDIP46, polymerase d interacting protein 46; RRM, RNA recognition motif;
S6K1, S6 kinase 1; SKAR, S6K1 Aly ⁄ REF-like target; SP5, suppressor of Ty 5; X-gal, 5-bromo-4-chloroindol-3-yl b-
D-galactoside.
4728 FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS
In the genomes of the species possessing ER no para-
logs have been identified so far [1–5]. ER genes code
for small proteins that usually consist of 100–105
amino acids [1–5]. However, in plants ER proteins
have some additional amino acids at their N-termini
[2,5]. Analysis of ER amino acid sequences has not
shown the presence of any known protein motifs or
domains that could reveal their possible biochemical
or cellular function or their intracellular localization;
only one or two putative casein kinase II (CK2) phos-
phorylation sites have been identified within them [2].
Yet their comparisons have revealed that ER proteins

are highly conserved, especially among the vertebrates
[2]. The mammalian (human, Mus musculus) and
amphibian (Xenopus laevis) ER proteins are fully iden-
tical and differ from their counterpart in fish (Danio
rerio) by a single, conservative amino acid substitution
[2,4]. The former proteins and the Drosophila melano-
gaster ER differ only in 26 amino acids, showing a
76% identity; their identity to the Caenorhabditis
elegans and Arabidopsis thaliana ER proteins is lower,
52% and 42%, respectively [2].
ER was first identified in a genetic screen in
D. melanogaster for the P element (paternal strain-spe-
cific transposon) induced mutations that changed the
phenotype of mutations in the rudimentary (r) gene [1].
The r gene encodes carbamoyl-phosphate synthase
(glutamine-hydrolyzing) aspartate carbamoyl transfer-
ase and dihydroorotase (CAD), a multifunctional
enzyme that catalyses the first three steps in the
de novo pathway of the biosynthesis of pyrimidines
[6,7]. Mutations in r are manifested in a characteristic
truncation of the wings [8]. This phenotype results
from a depletion in pyrimidines because mutations in
two other genes coding for the subsequent enzymatic
activities in the pathway, dhod and r-l also lead to the
truncated wings [9,10]. The performed screen brought
a recessive hypomorphic mutation mapped to an
unknown gene that enhanced the wing truncation
phenotype of some hypomorphic r mutants [1].
Because in the wildtype r background the mutation
did not display any mutant wing phenotype and the

flies appeared otherwise normal, the gene was named
enhancer of rudimentary [1]. There are two ER tran-
scripts in Drosophila that differ only in the length of
the 3¢ UTR caused by alternative polyadenylation; the
shorter one is found in equal amounts in adult flies of
both sexes, the longer one is found in the nurse cells of
the ovaries and in the preblastoderm embryos [1].
After gastrulation, the maternal transcript disappears
and the zygotic transcript and protein are found in a
subset of cells expressing DmcycE, which encodes
cyclin E, and undergoing DNA replication [2]. In
Drosophila the severity of the wing truncation is
thought to reflect the level of r expression [11].
Although the effects of the P element generated muta-
tion in ER are due to a drastic reduction in the
amounts of both of its transcripts, it does not seem
that ER acts as a regulator of r as this mutation does
not significantly affect the level of the r transcript in
adult flies [1]. It was also excluded that ER is one of
the genes for the enzymes in the biosynthesis or degra-
dation of pyrimidines [1]. Rather, it was suggested that
it may be involved in the regulation of the metabolism
of pyrimidines [1]. The Drosophila ER contains two
sites for CK2 that undergo phosphorylation in vitro
resulting in a putative shift in the secondary structure
of ER which suggests that CK2 may regulate the activ-
ity of ER [2].
The Xenopus ER was identified as one of the pro-
teins interacting with dimerization cofactor of hepato-
cyte nuclear factor 1 (HNF1)/pterin-4a-carbinolamine

dehydratase (DCoH ⁄ PCD) by the use of the yeast
two-hybrid system [4]. DCoH ⁄ PCD is a bifunctional
protein. It serves as a dimerization cofactor of the
HNF1 homeobox transcription factors which also
enhances their transcriptional activity [12]. DCoH ⁄
PCD also acts as an enzyme, pterin-4a -carbinolamine
dehydratase, which is involved in the regeneration of
tetrahydrobiopterin, an essential cofactor of several
metabolic reactions not directly related to the metabo-
lism of pyrimidines [13,14]. The Xenopus ER is
expressed ubiquitously in adult frogs [4]. The ER tran-
script is also present in the egg and at an increased
level during organogenesis; it was detected in tissues
derived from the ectoderm such as the eyes, parts of
the brain, the spinal cord and branchial arches [4]. The
Xenopus ER expressed in HeLa cells was predomin-
antly localized in the cytoplasm [4]. Because in the
same cells, the Xenopus ER alone was found to inhibit
the DCoH ⁄ PCD-dependent enhancement of the
HNF1a-mediated transcription from a corresponding
reporter gene and the Xenopus ER fused to the galac-
tose utilization gene 4 (GAL4) DNA binding domain
was able to repress the activity of a GAL4 reporter
construct, it was proposed that ER acts as a transcrip-
tional repressor [4]. Unlike ER, DCoH ⁄ PCD is
expressed tissue specifically in adult frogs (mainly in
the kidney and liver) [15]. Therefore, the existence of
other proteins interacting with ER was predicted [4].
The human ER transcript was found in many nor-
mal tissues, including fetal ones [3]. The level of the

ER transcript in two nondividing mammalian cell lines
examined, primary hepatocytes and adult liver was
very low, whereas it was easily detected in rapidly pro-
liferating cells of four different hepatoma cell lines [2].
A. Smyk et al. Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR
FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS 4729
The human ER was found to be one of the proteins
copurifying with suppressor of Ty 5 (SPT5), a tran-
scription elongation factor, when an extract from cells
expressing FLAG epitope-tagged SPT5 was subjected
to FLAG antibody affinity chromatography [16]. In a
similar approach, the human ER was reported to
copurify with TFIIF-associating component of CTD
phosphatase (FCP1), a phosphatase specific for the
carboxy-terminal domain of the large subunit of RNA
polymerase II; this interaction was also confirmed by
coimmunoprecipitation [17]. It was proposed that ER
might be involved in the regulation of transcription as
a counteracting protein of FCP1 and SPT5, positive
transcription elongation factors for RNA polym-
erase II [17]. A 32 amino acid fragment of ER isolated
from the swine small intestine, referred to as peptide
3910, also showed antibacterial activity [18]. Recently,
the high-resolution crystal structures of the human and
murine ER proteins were reported [5,19,20]. These
studies demonstrated that ER folds into a single
domain consisting of a four-stranded antiparallel b
sheet with three amphipathic a helices situated on one
face of the b sheet that does not have significant struc-
tural homologs in databases. The studies also showed

that ER can function as a homodimer through interac-
tions between the b sheet regions and that phosphory-
lation at the CK2 sites might disrupt its dimerization
and potential interactions with other proteins.
In plants, apart from the identification of ER in the
Arabidopsis genome, ER was reported to be induced
during programmed cell death in response to infection
of soybean with pathogenic bacteria [2,21].
We were interested in the regulation of the metabo-
lism of pyrimidines [22], therefore we decided to use
an ER-oriented approach to identify its protein inter-
actors, hoping that it would aid in assigning a more
specific role to ER in the cell. Employing the yeast
two-hybrid system, we identified the PDIP46 ⁄ SKAR
protein encoded by the polymerase (DNA-directed),
delta interacting protein 3 (POLDIP3) gene as a bind-
ing partner of the human ER. PDIP46⁄ SKAR had
been reported to be an interacting partner of the p50
subunit of DNA polymerase d and S6K1 that regulates
the cell growth [23,24]. A bipartite region of
PDIP46 ⁄ SKAR necessary for interaction with ER
encompassing the S6K1 binding and phosphorylation
sites was mapped. In addition, the intracellular distri-
bution of ER was revised from the predominantly
cytoplasmic localization [4] to the nuclear one, and
was compared with the localization of both isoforms
of PDIP46 ⁄ SKAR. We also show highly accurate
tissue expression profiles of ER and POLDIP3 in
humans.
Results

Yeast two-hybrid screening
The yeast two-hybrid system with the full-length
human ER protein as a bait was employed. The cloned
cDNA of the human ER gene was inserted into the bait
plasmid, pHybLex ⁄ Zeo in frame with the LexA DNA
binding domain coding sequence. The obtained con-
struct (pHybLex ⁄ Zeo-ER) was transformed into the
L40 yeast strain alone and together with the prey plas-
mid, pYESTrp2, encoding the B42 transcriptional acti-
vation domain. The resulting strains were tested for the
transactivation of two reporter genes, HIS3 and lacZ
exhibiting neither the capability to grow in the absence
of histidine nor a detectable b-galactosidase activity
(the His
–
LacZ
–
phenotype, for both plasmids in L40;
Fig. 1). Thus, the ability of ER to nonspecifically trans-
activate the reporter genes was excluded. Roughly one
third of the human lung cDNA library in the
pYESTrp2 plasmid with 5.95 · 10
6
independent clones
was screened by transformation into the L40 strain
expressing the bait. There were 364 histidine proto-
trophs after a 6-day selection, of which 83 also dis-
played b-galactosidase activity [yielded blue color in
the 5-bromo-4-chloroindol-3-yl b-d-galactoside (X-gal)
colony-lift filter assay]. Using PCR followed by agarose

gel electrophoresis, cDNA inserts from the His
+
LacZ
+
transformants were sorted into groups. The
Fig. 1. Interaction between ER and the truncated protein encoded
by the partial clone of the POLDIP3 gene (the L7 insert) examined
by the yeast two-hybrid system using lacZ and HIS3 as reporter
genes. Yeasts L40 were transformed with the original bait plasmid,
pHybLex ⁄ Zeo-ER and the empty prey plasmid, pYESTrp2 (1), the
retrieved prey plasmid, pYESTrp2 with the L7 insert and the empty
bait plasmid, pHybLex ⁄ Zeo (2), the retrieved prey plasmid,
pYESTrp2 with the L7 insert and the original bait plasmid, pHyb-
Lex ⁄ Zeo-ER (3) or the retrieved prey plasmid, pYESTrp2 with the
L7 insert and the irrelevant bait plasmid, pHybLex ⁄ Zeo-Lamin (4).
The b-galactosidase activity examined by the X-gal colony-lift filter
assay is shown as a strong gray color of the lysed yeasts (A) and
the positive result of the histidine prototrophy assay is shown as
the capability of yeasts to grow on minimal medium lacking histi-
dine (B).
Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR A. Smyk et al.
4730 FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS
prey plasmid from each group of transformants was
retrieved and the cDNA insert was sequenced. After
characterization of the inserts by using the BLAST
algorithm [25], one of them (L7) that turned out to be
a partial clone of the poorly characterized human gene
POLDIP3 was selected for the present study.
To determine the specificity of the interaction, the
retrieved prey plasmid with the L7 insert was trans-

formed into the L40 strain. The obtained strain (YL7)
did not exhibit activity of the reporter genes (data not
shown). Next, the YL7 strain was transformed with (i)
the empty bait plasmid, pHybLex ⁄ Zeo, (ii) the original
bait plasmid, pHybLex ⁄ Zeo-ER, or (iii) the irrelevant
bait plasmid, pHybLex ⁄ Zeo-Lamin, and the obtained
strains were again tested for the activity of the reporter
genes. The interaction was specific, as only the YL7
strain expressing ER as a bait exhibited the His
+
LacZ
+
phenotype, whereas the YL7 strains expressing
either the LexA DNA binding domain alone or this
domain fused to lamin, were not able to grow on a
medium lacking histidine and did not show the
b-galactosidase activity (Fig. 1).
There are at least two splicing variants of the human
POLDIP3 gene encoding proteins of 421 amino acids
with a molecular mass of 46 kDa and 392 amino acids
with a molecular mass of 43 kDa, which differ only by
an insertion of 29 amino acids in the middle of the
protein. These proteins are also known either as
PDIP46 (polymerase d interacting protein 46) isoform
1 and 2, respectively, or as SKAR (S6K1 Aly ⁄ REF-
like target) isoform a and b, respectively [23,24]. The
L7 cDNA insert was found to consist of 666 bp con-
taining the 3¢ end of the POLDIP3 coding sequence
(with the stop codon) and coded for 163 amino acids
present at the C-terminus of both isoforms of

PDIP46 ⁄ SKAR, including the amino acids of the
RNA recognition motif (RRM) also known as the
RNA binding domain (Fig. 2) [26].
Interaction of the human proteins ER and
PDIP46/SKAR in vitro
In order to confirm the physical interaction of the
human ER protein with PDIP46 ⁄ SKAR we performed
the glutathione S-transferase (GST) pull-down assay
using the GST-fusion protein of the L7 insert (the last
163 amino acids of the C-terminal sequence of
PDIP46 ⁄ SKAR) bound to glutathione-agarose beads
and the recombinant full-length ER protein with a
FLAG epitope tag at its C-terminus (Fig. 3A). Western
blot analysis with antibody raised against the FLAG
epitope showed that ER was precipitated with GST-
tagged PDIP46 ⁄ SKAR(L7)-coated glutathione-agarose
beads but not with GST-coated glutathione-agarose
beads nor glutathione-agarose beads alone (Fig. 3B).
To further confirm the interaction between ER and
PDIP46 ⁄ SKAR GST-tagged ER-coated glutathione-
agarose beads or GST-coated glutathione-agarose
beads were incubated with a nuclear extract obtained
from human epithelial cells, HeLa S3. Among proteins
specifically pulled down by the ER bait and separated
by one-dimensional SDS ⁄ PAGE there was a band of a
protein with electrophoretic mobility of approximately
46 kDa, which corresponds to the molecular mass of
isoform 1 ⁄ a of PDIP46 ⁄ SKAR (Fig. 3C). The band of
this protein was excised from a gel and after digestion
with trypsin was subjected to tandem mass spectrome-

try (MS ⁄ MS) analysis that revealed the presence of
three peptide sequences derived from the PDIP46 ⁄
SKAR protein in the examined protein sample
(Fig. 3D). One of these peptides, TIQVPQQK (resi-
dues 148–155) overlaps the region encoded by the
extra exon characteristic of isoform 1 ⁄ a of PDIP46 ⁄
SKAR.
Fig. 2. Proteins encoded by the POLDIP3 gene and the L7 insert.
(A) Schematic representation of both isoforms of the PDIP46 ⁄
SKAR protein encoded by POLDIP3 and the truncated form of
PDIP ⁄ SKAR encoded by the L7 insert. The region corresponding to
the RNA recognition motif (RRM) is shaded in gray and amino acids
encoded by an extra exon present in the isoform 1 ⁄ a are represen-
ted as the striped box. Numbering of the truncated protein encoded
by the L7 insert is according to the isoform 1 ⁄ a. (B) Amino acid
sequence of PDIP46(1) ⁄ SKAR(a). Amino acids encoded by an extra
exon present in the isoform 1 ⁄ a are in bold. Amino acids of the
RNA recognition motif are shaded in gray. Amino acids encoded by
the L7 insert are underlined. Two serines (383 and 385) phosphoryl-
ated by S6K1 are double underlined. The ends of the RRM on both
panels are as in [24], however, according to PROSITE the RRM is
shifted by three residues toward the C-terminus [280–351 in
PDIP46(1) ⁄ SKAR(a)] [27].
A. Smyk et al. Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR
FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS 4731
Comparison of the intracellular localizations of
the human ER and PDIP46/SKAR proteins
We examined the intracellular localization of the
human ER and PDIP46 ⁄ SKAR proteins fused with
enhanced green fluorescent protein (EGFP) in the

mammalian cells. The cloned cDNA of the human
ER gene was introduced into the pEGFP-N1 plasmid
in frame with the EGFP coding sequence. Because
only the partial clone of the POLDIP3 gene coding
for PDIP46 ⁄ SKAR was retrieved from the two-hybrid
library (the L7 insert), cDNAs coding for both full-
length isoforms of the PDIP46 ⁄ SKAR protein were
cloned. The two cloned cDNAs were also introduced
into the pEGFP-N1 plasmid. In individual experi-
ments, the obtained constructs were transiently trans-
fected into two different cell lines, HeLa, human
epithelial cells, and NIH ⁄ 3T3, murine fibroblasts.
Visualization of the fluorescent chimera proteins, ER,
isoform 1 ⁄ a of PDIP46 ⁄ SKAR or isoform 2 ⁄ b of
PDIP46 ⁄ SKAR fused to a C-terminal EGFP tag was
performed in the living cells. The direct fluorescence
microscopic observations revealed that all three pro-
teins were undoubtedly localized in the nucleus in a
very similar diffuse pattern that excluded the nucleoli,
in both HeLa and NIH ⁄ 3T3 cells (Fig. 4A–C). In the
same cells the mitogen-activated protein kinase or
extracellular signal-regulated kinase 1 (MEK1) pro-
tein fused to a C-terminal EGFP tag and expressed
from the same vector was used as a control showing
a diffuse cytoplasmic localization characteristic of this
kinase (Fig. 4D) [28].
Comparison of the expression profiles of the
human ER and POLDIP3 genes
The array of polyA
+

RNA isolated from 61 different
human adult tissues, seven human fetal tissues and
eight human cancer cell lines that was normalized to
eight different housekeeping genes was used to accu-
rately determine tissue expression profiles of the
human ER and POLDIP3 genes. High stringency
hybridization with the
32
P-labeled cloned human ER
cDNA probe showed that ER is expressed in all tis-
sues and cell lines examined (Fig. 5A). The level of the
ER transcript showed a very modest variation across
all polyA
+
RNA samples and, in this respect, was
similar to the pattern of the human housekeeping gene
coding for ubiquitin (data provided by the array
manufacturer, Clontech). In adults, the highest level of
the ER transcript was observed in the pituitary gland
and it was 2.5-fold higher than that in the peripheral
blood leukocytes in which the lowest level of the tran-
script was detected. In fetal tissues, the ER transcript
was the most abundant in the lung, whereas in the
brain its level was the lowest (2-fold difference).
After stripping, the array was reprobed for the
POLDIP3 expression with the radiolabeled partial
cDNA probe, which was unable to discriminate between
AB
C
D

Fig. 3. Interaction between ER and PDIP46 ⁄ SKAR examined by the
GST pull-down assays. (A) Proteins used in the assay with recom-
binant proteins expressed in E. coli and purified separated on a
12% SDS ⁄ polyacrylamide gel and stained with Coomassie brilliant
blue. (B) Precipitates obtained after incubation of ER-FLAG with
glutathione-agarose beads or protein-coated glutathione-agarose
beads, as indicated, were analyzed by western blot with anti-FLAG
antibody followed by the enhanced chemiluminescence reaction.
Input, 1 ⁄ 20 of ER-FLAG used in the assay. (C) Proteins pulled
down with GST-tagged ER-coated glutathione-agarose beads or
GST-coated glutathione-agarose beads from a nuclear extract from
HeLa S3 cells separated on a 10% SDS ⁄ polyacrylamide gel and
stained with silver. The arrow indicates a protein of approximately
46 kDa pulled down with the GST-ER bait that was subjected to
analysis by mass spectrometry. (D) The peptide sequences of
PDIP46 ⁄ SKAR identified by tandem mass spectrometry analysis
and their position in isoform 1 ⁄ a of PDIP46 ⁄ SKAR. The asterisk
indicates the peptide identified by manual analysis of MS ⁄ MS
spectra.
Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR A. Smyk et al.
4732 FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS
the alternative transcripts of the POLDIP3 gene. Simi-
larly to ER, POLDIP3 is expressed in all tissues and cell
lines examined and the level of expression shows a min-
imal variation between the samples (Fig. 5B). Among
adult tissues, the expression of POLDIP3 was the
strongest in the testis and right cerebellum, and the
weakest in the esophagus and left ventricle (2.2-fold dif-
ference). In fetal tissues, the highest level of the
POLDIP3 transcript was in the kidney, whereas the low-

est level was observed in the brain (1.7-fold difference).
Yeast two-hybrid analysis of the interaction
between the human proteins ER and PDIP46/
SKAR
In order to analyze the details of the interaction between
the human ER and PDIP46 ⁄ SKAR proteins a series of
constructs (A–K) in the pYESTrp2 plasmid coding for
fragments of the truncated form of the PDIP46 ⁄ SKAR
protein encoded by the L7 insert was generated. In sub-
sequent experiments, each construct was transformed
into the L40 yeast strain expressing the full-length
human ER protein. The interaction between the gener-
ated fragments of PDIP46 ⁄ SKAR and ER was analyzed
by the yeast two-hybrid assay employing the histidine
prototrophy and b-galactosidase assays as earlier. The
positive and negative species are summarized in Fig. 6
as ‘+’ and ‘–’, respectively. The 148 amino acid long
region of PDIP46 ⁄ SKAR that was found to interact
with ER constitutes the C-terminal part of PDIP46 ⁄
SKAR comprising residues 274–421 [PDIP46 ⁄
SKAR(K); all position numbering according to isoform
1 ⁄ a of PDIP46 ⁄ SKAR]. This region is not continuous
and could be further split into two subregions. The
larger one (subregion I) comprised residues 274–368
[PDIP46 ⁄ SKAR(D)] encompassing all amino acids of
the RNA recognition motif (residues 277–348, Fig. 2)
and the smaller one (subregion II) comprised residues
379–421 [PDIP46 ⁄ SKAR(I)] with an at least 10 amino
acid gap between them suggesting a bipartite nature of
the interface on the PDIP46 ⁄ SKAR side.

Discussion
A conserved and essential function still awaiting eluci-
dation has been predicted for ER. ER was proposed
to play a role in the regulation of the metabolism of
pyrimidines because a mutation in ER augmented the
wing truncation phenotype caused by mutations in
r that codes for CAD, a multifunctional enzyme
involved in the de novo biosynthesis of pyrimidines [1].
However, no protein partners in this context have been
identified so far. In addition, ER seems to take part in
the process of transcription. ER was shown to bind
and inhibit DCoH ⁄ PCD, a cell-specific positive cofac-
tor for the HNF1 homeobox transcription factors [4].
ER was also reported to copurify with SPT5 and
FCP1, proteins involved in the elongation phase of the
transcription driven by RNA polymerase II [16,17].
Finally, because ER is expressed at an increased level
in rapidly dividing cells and ER is phosphorylated by
CK2, a kinase required at the G
1
⁄ S and G
2
⁄ M transi-
tions, a role for ER in the progression through the cell
cycle was suggested [2].
In an attempt to understand the role of ER in the
cell, we decided to screen the human proteome for
Fig. 4. Comparison of the intracellular local-
ization of ER and PDIP46 ⁄ SKAR fused to
EGFP in the mammalian cells. NIH ⁄ 3T3 cells

(upper) and HeLa cells (lower) were transi-
ently transfected with plasmids coding for
ER-EGFP (A), PDIP46(1) ⁄ SKAR(a)-EGFP (B),
PDIP46(2) ⁄ SKAR(b)-EGFP (C) or MEK1-
EGFP used as a control (D) and their
localization was determined by direct
fluorescence of EGFP in living cells. Repre-
sentative images obtained with a confocal
laser scanning microscope are shown.
A. Smyk et al. Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR
FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS 4733
molecular partners of ER. In the present study,
employing the yeast two-hybrid screening and using
the human ER as bait, the C-terminal fragment of
PDIP46 ⁄ SKAR was found to interact with ER. The
binding was specific, as only interaction between
PDIP46 ⁄ SKAR and ER was positive, whereas neither
PDIP46 ⁄ SKAR nor ER was able to activate reporter
genes alone or in the presence of negative control pro-
teins. Recombinant PDIP46 ⁄ SKAR and ER were able
to bind each other in vitro in the GST pull-down assay
and ER fused to GST pulled down a protein of
46 kDa from a nuclear extract that was identified as
PDIP46 ⁄ SKAR by tandem mass spectrometry, thus
providing independent confirmations of the interaction
identified by the yeast two-hybrid assay.
Here, we also address the issue of the intracellular
localization of ER. The Xenopus ER was predomin-
antly localized in the cytoplasm with only minute
amounts in the nucleus, whereas DCoH ⁄ PCD was pre-

sent in both the cytoplasm and nucleus, in agreement
with the involvement of its dehydratase activity in the
regeneration of tetrahydrobiopterin in the cytoplasm
and the involvement of its dimerization activity for
HNF1 in the nucleus [4]. It was, however, the nuclear
aspect of the DCoH ⁄ PCD activity that was inhibited
by ER [4]. Similarly, SPT5 and FCP1 are nuclear pro-
teins [29,30]. The difference in the intracellular local-
ization between ER and its molecular partners makes
the predominant localization of ER in the cytoplasm
questionable unless the observed traces of ER in the
nucleus could indeed exert its role in this compartment
and the pool of ER in the cytoplasm would be devoted
to other functions. Contrary to the study on the Xen-
opus ER, we have found that the human ER predom-
inantly localizes to the nucleus of mammalian cells,
including HeLa cells used in that study [4]. It should
be noted that this observation is in accordance with
the localization of all known molecular partners of
ER, DCoH ⁄ PCD, SPT5 and FCP1 [4,29,30]. ER con-
tains no obvious nuclear localization signal, however,
its small size (approximately 12 kDa) might allow it to
enter the nucleus by passive diffusion through the nuc-
lear pores [31]. We do not know the reasons for the
discrepancy between the studies but it is not due to the
fact that the ER proteins from two different species,
human and Xenopus were used, because they are iden-
tical [4]. One of the possible explanations is that differ-
ent tags and consequently methods were employed for
their visualization. The Xenopus ER was His-tagged

and detected by indirect immunofluorescence in meth-
anol-fixed cells [4], whereas in the present study the
human ER was EGFP-tagged and direct fluorescence
detection in living cells was performed.
The revised intracellular localization of ER is instru-
mental in validating the results of the performed
screen. Both isoforms of PDIP46 ⁄ SKAR are also
A
B
C
Fig. 5. Comparison of the expression profiles of the ER and
POLDIP3 genes. Array of 76 polyA
+
RNA samples isolated from
various human adult and fetal tissues and cancer cell lines was
hybridized with the radiolabeled ER cDNA probe (A) and after
stripping again with the radiolabeled POLDIP3 cDNA probe (B). The
used POLDIP3 probe detects both POLDIP3 transcripts. The tissue
origin and position of the examined polyA
+
RNAs are shown in (C).
Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR A. Smyk et al.
4734 FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS
localized in the same cell compartment as ER, the nuc-
leus, in a pattern that is hardly distinguishable from
that of ER, thereby arguing in favor of the possibility
of the interaction between ER and PDIP46 ⁄ SKAR in
the cell. Furthermore, both genes, ER and POLDIP3,
coding for PDIP46 ⁄ SKAR are expressed in the same
set of human tissues and cell lines. Therefore, it is

conceivable that ER and PDIP46 ⁄ SKAR can really
meet and interact in numerous if not all human tissues
because both genes exhibit the expression pattern char-
acteristic of a housekeeping gene.
PDIP46 ⁄ SKAR is the only putative interactor
brought by the performed screen whose interaction
with ER has been validated so far. Evaluation of the
others is in progress and the results will be published
elsewhere. None of them turned out to be an already
known molecular partner of ER (data not shown). As
far as DCoH ⁄ PCD is concerned, the only protein
whose interaction with ER has been a subject of a
more detailed study so far [4], its lack can be
explained, at least in part, by its highly tissue-specific
expression. Both in Xenopus and mouse, DCoH⁄ PCD
is expressed in the kidney and liver mainly; while in
the lung, the tissue that was a source of polyA
+
RNA
for the screened cDNA library, DCoH ⁄ PCD and the
DCoH ⁄ PCD transcript are hardly detected [12,15].
PDIP46 was first identified in the yeast two-hybrid
assay designed to find molecular partners of the p50
subunit of DNA polymerase d [23]. No further data
on this interaction and the possible role of PDIP46 in
processes in which this polymerase takes part have
been reported so far. The same protein was also iden-
tified in a similar approach as a binding partner of
p70 ribosomal protein S6 kinase 1, S6K1 [24].
Sequence analysis of PDIP46 revealed the presence of

the RNA recognition motif (RRM) in both its iso-
forms showing the highest homology to the Aly ⁄ REF
family of RNA binding proteins so it was named
SKAR for S6K1 Aly ⁄ REF-like target. S6K1 binds
PDIP46 ⁄ SKAR within the RRM (amino acids 277–
348) and phosphorylates two serines at positions 383
and 385 (Fig. 2). Interestingly, we have found that the
bipartite region of PDIP46 ⁄ SKAR interacting with
ER (amino acids 274–421) encompasses both the
RRM (subregion I) and two serines phosphorylated by
S6K1 (subregion II) (Fig. 6). The significance of this
observation is not clear at the present time, however,
a plausible hypothesis is that the interaction of
Fig. 6. Identification of the PDIP46 ⁄ SKAR region interacting with ER using the yeast two-hybrid assay. Yeasts L40 expressing the full-length
ER from the original bait plasmid, pHybLex ⁄ Zeo-ER were transformed with a series of the pYESTrp2-based plasmids coding for fragments
of the truncated form of the PDIP46 ⁄ SKAR protein encoded by the L7 insert [PDIP46 ⁄ SKAR(A-K)] and the b-galactosidase X-gal colony-lift fil-
ter and histidine prototrophy assays were performed. Results are shown as ‘+’ and ‘–’ in the presence (both tests were positive) and
absence (both tests were negative) of the interaction, respectively. The RNA recognition motif (RRM) is shaded in gray. Two serines (383
and 385) phosphorylated by S6K1 are indicated. Numbering is according to isoform 1 ⁄ a of PDIP46 ⁄ SKAR. The dotted lines indicate the ends
of the two subregions capable of interacting with ER individually.
A. Smyk et al. Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR
FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS 4735
PDIP46 ⁄ SKAR with ER could block the PDIP46 ⁄
SKAR phosphorylation by S6K1. S6K1 is involved in
the cell and organism growth control; mice with a
knockout in S6K1 display the small mouse phenotype;
a decrease in the size of the whole organism, and over-
expression of S6K1 in mammalian cells results in the
increased cell size [32,33]. PDIP46 ⁄ SKAR seems to be
involved in the same processes because an RNAi

knockdown of PDIP46 ⁄ SKAR resulted in the smaller
cell size [24]. PDIP46 ⁄ SKAR is a nuclear protein and
based on its homology to the Aly ⁄ REF family of
proteins it was proposed that PDIP46 ⁄ SKAR as
Aly ⁄ REF proteins could be involved in the coupling
of transcription, premRNA splicing and transport of
mRNA from the nucleus to cytoplasm to ‘govern the
biogenesis of transcripts in response to S6K1 activa-
tion, ultimately leading to changes in cell growth’ [24].
PDIP46 ⁄ SKAR is so far the only identified substrate
of S6K1 that has been shown to influence cell size.
Our finding that ER is a molecular partner of
PDIP46 ⁄ SKAR and that interaction has an opportun-
ity to occur universally in the mammalian cells raises
a question about the role for ER in the cell growth
control. This intriguing possibility is currently under
investigation but it is already worth pointing out that
ER itself does not seem to be another substrate of
S6K1 as it contains no consensus sequence for this
kinase (R ⁄ KxRxxS ⁄ Tx) [34]. ER, however, connects
PDIP46 ⁄ SKAR with two molecular partners of ER,
SPT5 and FCP1 which also play roles in coupling
transcription to premRNA processing [35]. It is tempt-
ing to propose that ER could be a novel cog in a
machine from ‘gene expression factories’ [35]. Another
molecular partner of ER, DCoH ⁄ PCD is also involved
in transcription, however, it seems to be restricted to
some tissues and no satisfactory evidence has been
found that DCoH ⁄ PCD interacts with components of
the general transcriptional machinery [12]. Finally, it

should be noted in this context that the truncated
wings in the Drosophila r mutants display a reduction
in total number of cells per wing and a reduction in
the area of individual cells [8]. If indeed ER is
involved in the cell growth control a mutation in ER
could add to the effects of an r mutation leading to
the enhancement of the wing truncation with no direct
influence on the metabolism of pyrimidines.
Experimental procedures
cDNA cloning and DNA constructs
cDNAs of the human genes, ER and POLDIP3 (both iso-
forms) corresponding to their coding sequences (including
the first ATG and stop codons) were obtained using total
RNA from HeLa cells, AMV reverse transcriptase and
gene-specific primers from 3¢ UTRs of these genes to syn-
thesize the first strand followed by PCR amplifications with
a high-fidelity DNA polymerase, Pfx (Invitrogen, Carlsbad,
CA, USA) and pairs of gene-specific primers from the
beginning and end of their coding sequences, based on
the records from the DDBJ ⁄ EMBL ⁄ GenBank databases
(accession numbers U66871, AL160111 and AL160112;
Table 1). All three PCR products coding for 104 amino
acids (ER), 421 amino acids (isoform 1 ⁄ a of PDIP46 ⁄
SKAR) and 392 amino acids (isoform 2 ⁄ b of PDIP46 ⁄
SKAR) after adding 3¢ A overhangs with Taq DNA polym-
erase were inserted into the pCR2.1 plasmid (Invitrogen),
transformed into the bacterial host strain Escherichia coli
XL1 Blue MRF¢ and their fidelity was verified by nucleo-
tide sequencing.
For the following plasmid constructs all necessary

restriction sites and a FLAG epitope tag were added and
the unnecessary codons were removed during PCR amplif-
ications by Pfx DNA polymerase, using the pCR2.1
plasmid harboring the suitable cDNA as a template and
gene-specific primers (Table 1). Cloning was performed
according to standard procedures [36] and the fidelity of
the constructs was confirmed by restriction digestions and
nucleotide sequencing. pHybLex ⁄ Zeo-ER was obtained by
subcloning the ER cDNA (without the first ATG codon
and with the stop codon) into EcoRI and XhoI sites
of pHybLex ⁄ Zeo (Invitrogen) in-frame with LexA.
pQE30 ⁄ ER-FLAG was generated by inserting the ER
cDNA (without the first ATG codon and with codons for
the FLAG epitope tag amino acids (DYKDDDDK) at
the C-terminus followed by the stop codon) into BamHI
and HindIII sites of pQE30 (Qiagen, Hilden, Germany)
in-frame with 6· His. pEGFP-N1 ⁄ ER was constructed by
inserting the ER cDNA (with the first ATG codon and
without the stop codon) into HindIII and BamHI sites of
pEGFP-N1 (Clontech, Palo Alto, CA, USA) in-frame with
EGFP. pGEX-4T1 ⁄ PDIP46 ⁄ SKAR(L7) and pGEX-
4T1 ⁄ ER were generated by subcloning the L7 cDNA
insert (with the stop codon) and the ER cDNA (without
the first ATG codon and with the stop codon), respect-
ively, into BamHI and NotI sites of pGEX-4T1
(Amersham, Little Chalfont, UK) in-frame with GST.
pEGFP-N1 ⁄ PDIP46(1) ⁄
SKAR(a) and pEGFP-N1 ⁄
PDIP46(2) ⁄ SKAR(b) were obtained by subcloning the
POLDIP3 cDNAs (with the first ATG codon and without

the stop codon) into PstI site of pEGFP-N1 in-frame with
EGFP. A series of pYESTrp2 ⁄ PDIP46 ⁄ SKAR(A–K) plas-
mids was generated by subcloning the tested fragments of
the L7 cDNA insert (with the stop codon) into BamHI
and NotI sites of pYESTrp2 (Invitrogen) in-frame with
B42. For pEGFP-N1 ⁄ MEK1 the rat MEK1 cDNA was
amplified (with the first ATG codon and without the stop
codon) using the pAX142-MEK1(WT) plasmid [37] as a
Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR A. Smyk et al.
4736 FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS
template and was inserted into HindIII and BamHI sites
of pEGFP-N1 in-frame with EGFP.
Yeast two-hybrid screening
The Hybrid Hunter yeast two-hybrid system from Invitrogen
was employed. The pHybLex ⁄ Zeo-ER plasmid conferring
resistance to zeocin was transformed into the yeast strain
L40 [MATa his3D200 trp1-901 leu2-3112 ade2 LYS2::(4-
lexAop-HIS3) URA3::(8lexAop-lacZ) GAL4]. Five independ-
ent zeocine-resistant transformants expressed the chimeric
protein LexA-ER at the same level [checked in crude lysates
by western blotting by using the anti-(LexA) rabbit polyclo-
nal antibody] and displayed no activation of HIS3 and lacZ
Table 1. Primer sets for construction of plasmids used in this study.
Plasmid Primer set
pCR2.1 ⁄ ER ATTTCATCTAATACAGTC
GCGGGATCCACGATGTCTCACACCATTTTGC
GCGGAATTCTTATTTCCCAGCCTGTTGGGCCTG
pCR2.1 ⁄ PDIP46(1) ⁄ SKAR(a) CTTCTGGCTGCCTCACTCC
GCGCGATATCGCAAGATGGCGGACATCTCCCTGG
CTCAAAGCTTGATTTTGAATTCTGTG

pCR2.1 ⁄ PDIP46(2) ⁄ SKAR(b) CTTCTGGCTGCCTCACTCC
GCGCGATATCGCAAGATGGCGGACATCTCCCTGG
CTCAAAGCTTGATTTTGAATTCTGTG
pHybLex ⁄ Zeo-ER GCGGAATTCTCTCACACCATTTTGCTGGT
GCGCTCGAGTTATTTCCCAGCCTGTTGGGCCTG
pQE30 ⁄ ER-FLAG GCGGGATCCCACACCATTTTGCTGGTACA
GCGAAGCTTTTATTTGTCATCGTCATCCTTGTAGTCTTTCCCAGCCTGTTGGGCCTG
pGEX-4T1 ⁄ ER GCGGGATCCCACACCATTTTGCTGGTACA
ATAAGAATGCGGCCGCCTATTTCCCAGCCTGTTGGGCCTG
pGEX-4T1 ⁄ PDIP46 ⁄ SKAR(L7) GCGGGATCCAACAAGGAAGAACCCCCC
ATAAGAATGCGGCCGCTCAAAGCTTGATTTTGAATTCTG
pEGFP-N1 ⁄ ER GCGAAGCTTCACGATGTCTCACACCATTT
GCGGGATCCCGTTTCCCAGCCTGTTGGGCCT
pEGFP-N1 ⁄ PDIP46(1) ⁄ SKAR(a) AAACTGCAGGATGGCGGACATCTCCCTGGAC
AAACTGCAGAAGCTTGATTTTGAATTCTGT
pEGFP-N1 ⁄ PDIP46(2) ⁄ SKAR(b) AAACTGCAGGATGGCGGACATCTCCCTGGAC
AAACTGCAGAAGCTTGATTTTGAATTCTGT
pEGFP-N1 ⁄ MEK1 GCGAAGCTTCACGATGCCCAAGAAGAAGCCGACGCC
GCGGGATCCCGGATGCTGGCAGCGTGGGTTGG
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(A) GCGGGATCCAACAAGGAAGAACCCCCC
ATAAGAATGCGGCCGCTCAAGGCAGCTCGCTCTCCTTTTT
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(B) GCGGGATCCCTCAGCCCATTGGAAGGCACC
ATAAGAATGCGGCCGCTCAAGGCAGCTCGCTCTCCTTTTT
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(C) GCGGGATCCGTGAATAATCTGCACCCTCGA
ATAAGAATGCGGCCGCTCAAGGCAGCTCGCTCTCCTTTTT
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(D) GCGGGATCCCTCAGCCCATTGGAAGGCACC
ATAAGAATGCGGCCGCTCAGCTGTCACTCAGCCGCAGCAG
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(E) GCGGGATCCAACAAGGAAGAACCCCCC
ATAAGAATGCGGCCGCTCAGTCTGAGGTGATAACATTCCC
pYESTrp2 ⁄ PDIP46

⁄ SKAR(F) GCGGGATCCCTGGACGGGCAGCCGATGAAG
ATAAGAATGCGGCCGCTCAAAGCTTGATTTTGAATTCTGT
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(G) GCGGGATCCCAGCCCATCCTGCTGCGGCTG
ATAAGAATGCGGCCGCTCAAAGCTTGATTTTGAATTCTGT
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(H) GCGGGATCCCAGCCCATCCTGCTGCGGCTG
ATAAGAATGCGGCCGCTCAGGGCTGCGTGGTCACAGAGGC
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(I) GCGGGATCCCGCAGGGTGAACTCTGCCTCC
ATAAGAATGCGGCCGCTCAAAGCTTGATTTTGAATTCTGT
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(J) GCGGGATCCCCCCCTGCCGAAGTGGACCCT
ATAAGAATGCGGCCGCTCAAAGCTTGATTTTGAATTCTGT
pYESTrp2 ⁄ PDIP46 ⁄ SKAR(K) GCGGGATCCCTCAGCCCATTGGAAGGCACC
ATAAGAATGCGGCCGCTCAAAGCTTGATTTTGAATTCTGT
A. Smyk et al. Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR
FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS 4737
reporter genes (no growth on a minimal medium lacking
histidine and lack of the b-galactosidase activity in the
colony-lift filter assay [38], respectively). A randomly chosen
transformant displaying neither HIS3 nor lacZ activity after
introducing the empty prey plasmid, pYESTrp2 was used
further as a bait strain.
The human lung cDNA expression library in pYESTrp2
(5.95 · 10
6
independent clones, Invitrogen #A213-01) was
transformed into the bait strain according to the manu-
facturer’s recommended protocol with the efficiency of
2.2 · 10
6
tryptophan prototrophs. Using primers specific for
the prey plasmid (included in the Hybrid Hunter kit), cDNA

inserts from the His
+
LacZ
+
transformants were amplified
by PCR, subjected to a 2% (w ⁄ v) agarose gel electrophor-
esis and sorted into groups based on their sizes. Nucleotide
sequence of the cDNA insert from each group was estab-
lished and compared with the sequences from the public
databases of the National Center for Biotechnology Infor-
mation. The prey plasmid with one of the cDNA inserts, L7
[pYESTrp2 ⁄ PDIP46 ⁄ SKAR(L7), DDBJ ⁄ EMBL ⁄ GenBank
accession number DQ887818] was retransformed into yeast
L40 alone and together with pHybLex ⁄ Zeo, pHybLex ⁄ Zeo-
ER or pHybLex ⁄ Zeo-Lamin (included in the Hybrid Hunter
kit) to verify the specificity of the interaction.
Production and purification of recombinant
proteins
The pQE30 ⁄ ER-FLAG plasmid was transformed into
E. coli XL1 Blue MRF¢ and production of ER-FLAG was
induced at A
600
of 0.7 [0.5 mm isopropyl thio-b-d-galacto-
side (IPTG), 3 h, 37 °C]. The pGEX-4T1 and pGEX-
4T1 ⁄ PDIP46 ⁄ SKAR(L7) plasmids were transformed into
E. coli BL21(DE3) and expression of proteins was induced
at A
600
of 0.9–1.0 (1 mm IPTG, 4 h, 37 °C). The pGEX-
4T1 ⁄ ER plasmid was introduced into E. coli BL21(DE3)

and production of GST-ER was induced at A
600
of 0.8
(0.1 mm IPTG, 3 h, 37 °C). Cells were harvested by centrif-
ugation, resuspended in lysis buffer recommended by the
resin supplier and lysed by sonication. ER-FLAG was puri-
fied using Ni-nitrilotriacetic acid resin (Qiagen) under
native conditions according to the manufacturer’s protocol
while GST-, GST-PDIP46 ⁄ SKAR(L7)- or GST-ER-coated
beads were purified using glutathione-agarose as suggested
by the supplier (Sigma, St Louis, MO, USA). All purified
proteins were analyzed by SDS ⁄ PAGE followed by staining
with Coomassie brilliant blue, showing near homogeneity.
GST pull-down assay with recombinant proteins
For the GST pull-down assay, GST-PDIP46 ⁄ SKAR(L7)-
coated beads, GST-coated beads or beads alone (20 lLof
the 50% slurry each) were incubated for 2 h at 4 °C with
gentle rotation with ER-FLAG in a final volume of 1 mL
of binding buffer [137 mm NaCl; 20 mm Tris ⁄ HCl, pH 7.5;
10% (v ⁄ v) glycerol; 1% (v ⁄ v) Triton X-100; 2 mm EDTA;
0.1 mm phenylmethanesulfonyl fluoride]. Following incuba-
tion, beads were pelleted and washed four times with 1 mL
of binding buffer and twice with 1 mL of NaCl ⁄ P
i
and
boiled in sample loading buffer. Protein samples were
resolved on a 15% SDS ⁄ polyacrylamide gel and electro-
blotted to a poly(vinylidene difluoride) membrane (Bio-
Rad, Hercules, CA, USA). The membrane was incubated
with the anti-FLAG epitope M2 monoclonal antibody

(dilution 1 : 10000, Sigma) followed by an incubation with
the horseradish peroxidase-conjugated goat antimouse sec-
ondary antibody (dilution 1 : 2000; Santa Cruz, Santa
Cruz, CA, USA). The bound antibody was visualized using
the enhanced chemiluminescence reaction (Amersham).
GST pull-down from a nuclear extract
Human HeLa S3 cells were grown as a suspension culture
in Dulbecco’s modified Eagle’s medium (DMEM) with
10% (v ⁄ v) fetal bovine serum and antibiotics (100 UÆmL
)1
penicillin and 100 lgÆmL
)1
streptomycin) in a glass bottle
on top of a magnetic stirrer in a humidified 5% carbon
dioxide atmosphere at 37 °C to the density of 1.3 · 10
6
cells per mL. One point two millilitres of the nuclear extract
from 1.3 · 10
8
cells were prepared as described in [39] with
a minor modification. Namely, proteins were extracted
from nuclei with the P2 buffer supplemented with 420 mm
NaCl and 1% (v ⁄ v) Triton X-100. GST-ER-coated beads
or GST-coated beads (50 lL of the 50% slurry each) were
incubated with the obtained nuclear extract (12 mg of
total protein) in a final volume of 12 mL of binding
buffer (20 mm NaCl; 20 mm Tris ⁄ HCl, pH 7.4; 1 mm
dithiothreitol; 1 mm phenylmethanesulfonyl fluoride; 100·
diluted protease inhibitor cocktail from Sigma) at 4 °C
overnight with gentle rotation. After washing twice with

12 mL of binding buffer 1 ⁄ 10 of bound protein was
resolved on a 10% SDS ⁄ polyacrylamide gel and stained
with silver [40].
Mass spectrometry
A protein band was excised from a gel and analyzed by
tandem mass spectrometry at Laboratory of Mass Spectr-
ometry, Institute of Biochemistry and Biophysics PAS,
Warsaw, Poland. Briefly, after reduction and alkylation by
dithiothreitol and iodoacetamide, respectively, the protein
was in-gel digested with trypsin [42]. The resulting pep-
tides were analyzed on a nano-HPLC-ESI-LTQ-FT-ICR
platform (a Finnigan LTQ FT hybrid mass spectrometer;
Thermo, Waltham, MA, USA) using collision-induced
dissociation for ion fragmentation. For protein identifica-
tion MS ⁄ MS spectra were searched against the NCBInr
database by using the mascot algorithm (Matrix Science,
London, UK) [41] supplemented by manual analysis of
spectra.
Enhancer of rudimentary interacts with PDIP46 ⁄ SKAR A. Smyk et al.
4738 FEBS Journal 273 (2006) 4728–4741 ª 2006 The Authors Journal compilation ª 2006 FEBS
Mammalian cell transfections and EGFP
visualization
Human HeLa cells were maintained in Dulbecco’s modified
Eagle’s medium with 10% (v ⁄ v) fetal bovine serum and anti-
biotics (100 UÆmL
)1
penicillin and 100 lgÆmL
)1
streptomy-
cin) on plates in a humidified 5% carbon dioxide atmosphere

at 37 °C. For murine NIH ⁄ 3T3 cells DMEM was supple-
mented with 10% (v ⁄ v) calf serum instead of fetal bovine
serum. For chimeric protein expression and visualization,
cells were seeded onto a 60 mm plate with a glass coverslip
on the bottom 24 h prior to transfection and transfected with
the pEGFP-N1 ⁄ ER, pEGFP-N1 ⁄ PDIP46(1) ⁄ SKAR(a),
pEGFP-N1 ⁄ PDIP46(2) ⁄ SKAR(b) or pEGFP-N1 ⁄ MEK1
plasmids using Lipofectamine Reagent according to the
manufacturer’s suggested protocol (Invitrogen). Briefly, a
mixture of 2 lg of the plasmid DNA and 8 lL of Lipofecta-
mine in 2 mL of antibiotic- and serum-free DMEM was
placed on cells at 30–40% confluence and incubated for 5 h
at 37 °C. After that time, the medium was replaced with
regular DMEM. Two days later, coverslips with transfected
cells were rinsed briefly with NaCl ⁄ P
i
(with calcium and mag-
nesium), inverted onto microscope slides and cells were
immediately viewed on a confocal laser scanning microscope
(an LSM510 unit coupled to an Axiovert 100M inverted
microscope equipped with a Plan-Apochromat 63·⁄1.4 Oil
DIC objective; Zeiss, Jena, Germany) using the 488 nm exci-
tation line of an argon laser and a BP505–550 nm band pass
filter for detecting green fluorescence.
Array hybridizations with cDNA probes
The human multiple tissue expression array from Clontech
(#7775-1) was hybridized with two radiolabeled human
cDNA probes. The cloned ER cDNA was labeled using the
Megaprime labeling system (Amersham), purified from the
unincorporated [

32
P]dATP[aP] (Amersham) with a QIA-
quick nucleotide removal kit (Qiagen). High stringency
hybridization was carried out in a rotation hybridization
oven at 65 °C overnight. Denatured human C
0
t1 DNA
(Roche, Mannheim, Germany), sheared salmon testis DNA
(Sigma) and 1.5 · 10
7
c.p.m. of the radiolabeled probe were
added to PerfectHyb Plus hybridization buffer (Sigma). The
membrane was washed at 65 °C four times for 20 min with
2· NaCl ⁄ Cit, 1% SDS and twice for 10 min with 0.5·
NaCl ⁄ Cit, 0.1% SDS and exposed for three days to an
X-ray film with an intensifying screen at )70 °C. Stripping
of the membrane was performed according to the manufac-
turer’s instructions. After assuring of the positive result of
the stripping procedure by another exposure to an X-ray
film, the array was reprobed with the labeled 237 bp frag-
ment of POLDIP3 corresponding to amino acids 280–358
of isoform 1 ⁄ a of PDIP46 ⁄ SKAR as above. The autoradio-
grams were digitized and the signal intensities were quanti-
tated using the quantity one software (Bio-Rad).
Acknowledgements
We thank Dr A. Czubaty for advice on the GST pull-
down from a nuclear extract, Drs M. Dadlez and
J. Debski for help with the mass spectrometry analysis,
and Drs S. Bartoszewski, R. Derlacz and J. Fronk for
critical reading of the manuscript. This work was

supported by grant 6P04A04121 from the State
Committee for Scientific Research (KBN) in Poland (to
P.K.).
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