Definition of a Consensus Transportin-specific Nucleocytoplasmic
Transport Signal*
Hal P.
Bogerd
,
R. Edward
Benson
,
Ray
Truant
,
Andrea
Herold§,
Meranee
Phingbodhipakkiya§, and
Bryan R.
Cullen
§¶
From the
Howard Hughes Medical Institute and the
§ Department of Genetics, Duke University Medical Center,
Durham, North Carolina 27710
 |
ABSTRACT |
The low cytoplasmic and high nuclear
concentration of the GTP-bound form of Ran provides directionality for
both nuclear protein import and export. Both import and export factors
bind RanGTP directly, yet this interaction produces opposite effects;
in the former case, RanGTP binding induces nuclear cargo release,
whereas in the latter, RanGTP binding induces nuclear cargo assembly. Therefore, nuclear import and export receptors and their protein recognition sites are predicted to be distinct. Nevertheless, the
~38-amino acid M9 sequence present in heterogeneous nuclear ribonucleoprotein A1 has been reported to serve as both a nuclear localization signal and a nuclear export signal, even though only one
protein, the nuclear import factor transportin, has been shown to bind
M9 directly. We have used a combination of mutational randomization
followed by selection for transportin binding to exhaustively define
amino acids in M9 that are critical for transportin binding in
vivo. As expected, the resultant ~12-amino acid
transportin-binding consensus sequence is also predictive of nuclear
localization signal activity. Surprisingly, however, this extensive
mutational analysis failed to dissect M9 nuclear localization signal
and nuclear export signal function. Nevertheless, transportin appears unlikely to be the M9 export receptor, as RanGTP can be shown to block
M9 binding by transportin not only in vitro, but also in
the nucleus in vivo. This analysis therefore predicts the
existence of a nuclear export receptor distinct from transportin that
nevertheless shares a common protein-binding site on heterogeneous
nuclear ribonucleoprotein A1.
 |
INTRODUCTION |
Recent progress in understanding the mechanisms that drive the
nucleocytoplasmic transport of proteins and RNAs suggests that both
nuclear import and export are mediated by a family of proteins related
to the prototypic import factor importin
/karyopherin
1
(Imp-
)1 (reviewed in Refs.
1-3). Directionality of movement appears, at least in part, to be
controlled by the low cytoplasmic and high nuclear concentration of the
GTP-bound form of Ran (4, 5). Thus, import factors, such as Imp-
,
are believed to bind to nuclear localization signals (NLSs) or adaptor
molecules, such as importin/karyopherin
, in the cytoplasm, where
RanGTP is found at very low concentrations. Once the resultant import
receptor-substrate complex reaches the nucleus, where RanGTP exists at
high concentrations, the direct interaction of Imp-
with RanGTP
induces the release of the protein cargo (5-7). Conversely,
Imp-
-related nuclear export factors such as Cas and Crm1 are
believed to bind proteins containing a cognate nuclear export signal
(NES) in the nucleus only in the form of a ternary complex involving
RanGTP (8, 9). Once the resultant export receptor-substrate complex
reaches the cytoplasm, RanGTP is hydrolyzed to RanGDP by the
cytoplasmic RanGAP and RanBP1 or RanBP2 proteins, thereby inducing the
release of the export receptor from both Ran and the export substrate.
A prediction of the hypothesis that RanGTP is critical for both NES
substrate binding and NLS substrate release in the cell nucleus is that
Imp-
-like transport factors should be dedicated to either import or
export, depending on whether RanGTP induces substrate release or
binding (1-3). A corollary of this prediction is that protein NES and
NLS sequences should be recognized by different transport factors and
should therefore be distinct. In general, this is indeed the case.
Thus, leucine-rich NES sequences of the type first identified in human
immunodeficiency virus type 1 Rev function only in nuclear export,
whereas basic NLS sequences of the type found in SV40 T-antigen and
nucleoplasmin function only to mediate nuclear import (1-3). Yet, one
clear exception to this prediction exists, i.e. a sequence
termed M9 that is present in heterogeneous nuclear ribonucleoprotein A1
(hnRNP A1) and related mRNA-binding proteins and that has been
reported to function as both an NLS and an NES (10-12).
One group has defined the M9 NLS/NES as a 38-amino acid sequence
located between residues 268 and 305 of hnRNP A1 (10), whereas a second
group, which primarily analyzed nuclear import, has localized the hnRNP
A1 NLS to a largely overlapping sequence extending from residues 260 to
289 (12), thus suggesting that the core of the M9 NLS is likely to be
located between hnRNP A1 residues 268 and 289. Little additional
information on the identity of the M9 NLS/NES has been published,
although it is known that mutation of either glycine 274 or proline 275 to alanine blocks both NLS and NES function (10). Attempts to identify
a protein that might mediate M9 function resulted in the cloning of an
Imp-
-related transport factor termed transportin (Trn) or
karyopherin b2 (13-15). Trn not only binds the M9 NLS/NES specifically
both in vitro and in vivo, but also can mediate
the specific import of substrate proteins bearing the M9 NLS into
isolated nuclei in vitro.
Because of the expectation that the M9 NLS and NES functions should
reflect the interaction of M9 with distinct nuclear import and export
receptors (1-3) and given that the M9 sequence remains both large and
ill defined, we have attempted to dissect the M9 NLS/NES by using a
previously reported strategy (16) of sequence randomization followed by
in vivo selection for M9 sequences that retain their ability
to bind Trn. Using this approach, we have defined the sequence
requirements for M9 NLS function in detail and report that these are
indistinguishable from those required for M9 NES function. Possible
interpretations of this surprising result are discussed.
 |
EXPERIMENTAL PROCEDURES |
Construction of Molecular Clones--
Alanine-scanning mutants
of the M9 NLS/NES were constructed in the previously described pGBT9/M9
yeast expression plasmid, which expresses the Gal4 DNA-binding domain
fused to hnRNP A1 residues 256-320 (15). Mutations were generated
using the Quick Change site-directed mutagenesis kit (Stratagene) using
complementary oligonucleotide primers that introduced the sequence
5'-GCGGCCGCTGCA-3' in place of wild-type M9 sequences. This
mutation substitutes four alanines for each set of four targeted M9
residues, as shown in Table I, and also introduces a unique
NotI site (underlined). Carboxyl-terminal deletion mutants
of M9 sequence 256-320 were generated by annealing an oligonucleotide
to the relevant inserted NotI restriction enzyme site that
introduced a translation termination codon after the first two alanine
codons. Sequences encoding M9 residues 256-263 were deleted by
polymerase chain reaction mutagenesis and substituted by two
glycine codons. All scanning mutants were verified by DNA sequence
analysis, and their expression levels were quantitated by Western blot
analysis as described previously (16).
Libraries of randomized M9 sequences were constructed in the pGBT9/M9
sequence context as described previously (17) using two flanking
primers and two overlapping primers that introduced either 9 or 12 random bases into the M9 sequence context. Amplification products were
cleaved with EcoRI and XhoI and then ligated into pGBT9 digested with EcoRI and SalI. The ligated
randomized libraries were then phenol/chloroform-extracted,
ethanol-precipitated, and introduced into XL1-Blue bacteria
(Stratagene) by electroporation. Each library contained >5 × 105 independent clones. Yeast transformants expressing M9
variants that retained the ability to interact with Trn in the
two-hybrid assay were then identified as described previously (17).
The two synthetic M9 derivatives 8.4.10 and 11.4.11, which express M9
variants mutated between residues 269 and 280, were each generated by a
two-step polymerase chain reaction procedure using two flanking primers
and two overlapping core primers. Both mutants were confirmed by DNA
sequence analysis. Prokaryotic expression plasmids (pGST-M9) encoding
glutathione S-transferase (GST) linked to wild-type or
mutant forms of M9 residues 256-320 were generated by insertion of the
relevant EcoRI-XhoI DNA fragment encoding M9, as
described above, into pGEX4T-1 (Amersham Pharmacia Biotech).
The parental two-hybrid vectors pGBT9 (CLONTECH)
and pVP16 and their derivatives, pGBT9/M9 and pVP16/Trn-(541-890),
have been described (15). Full-length cDNA forms of human Trn and
Trn2 were excised from the previously described pGEM3-Trn and pBS-Trn2 expression plasmids (15, 18) by cleavage with NcoI and
XhoI and were then cloned into pVP16 to generate
pVP16/Trn-(1-890) and pVP16/Trn2-(1-894), respectively. Similarly, a
plasmid encoding a fusion protein consisting of the Gal4 DNA-binding
domain linked to full-length human Ran was generated by excision of the
Ran cDNA from a previously described pGex4T-1/Ran expression
plasmid (19) by cleavage with BamHI and XhoI
followed by ligation into pGBT9.
A plasmid (pGEM3-Trn) that permits efficient expression of full-length
human Trn in a coupled in vitro transcription/translation system has been described (15). Also described is a prokaryotic expression plasmid encoding GST linked to wild-type human Ran (19).
This latter plasmid was modified to encode GST linked to the Ran mutant
Q69L (20), which is GTPase-deficient.
Yeast Two-hybrid Analysis--
All two-hybrid assays were
performed as described previously (15). Briefly, Y190 yeast cells (21)
were transformed with the appropriate Gal4 (pGBT9-TRP+) and
VP16 (pVP16-LEU+) fusion protein expression plasmids, and
transformants were plated on drop-out plates lacking tryptophan and
leucine. Four days later, colonies were pooled into liquid-selective
medium and grown an additional 20 h. At this time,
-galactosidase assays were performed as described previously
(15).
Protein Purification--
Wild-type and mutant GST/M9 proteins
were expressed in bacteria and purified by standard protocols in the
absence of detergents as described previously (15). Purified proteins
were dialyzed against phosphate-buffered saline and then concentrated
by centrifugation using Centricon 10 concentrators (Amicon, Inc.).
Recombinant non-fusion Ran Q69L mutant protein (20) was expressed and
purified as described previously for wild-type Ran protein (19).
Cell Culture and Microinjection--
HeLa cells were cultured in
Dulbecco's modified Eagle's medium containing 5% fetal bovine serum,
gentamycin, and Fungizone. Two days prior to injection, 2 × 105 cells were plated on glass coverslips in 35-mm culture
plates. To increase the prevalence of binuclear cells, the culture
medium was replaced with serum-free Dulbecco's modified Eagle's
medium on the evening prior to microinjection. At ~16 h later, the
cells were refed with Dulbecco's modified Eagle's medium containing 5% fetal bovine serum and cultured for a further 4-6 h prior to use
in microinjection assays.
Prior to microinjection, each GST/M9 fusion protein was diluted to ~2
mg/ml in phosphate-buffered saline and supplemented with 1 mg/ml rabbit
IgG (Jackson ImmunoResearch Laboratories, Inc.). After microinjection,
which took from 8 to 10 min/sample at room temperature, each coverslip
was incubated with fresh Dulbecco's modified Eagle's medium
containing 5% fetal bovine serum at 37 °C for between 1 and 30 min
(cytoplasmic injections) or for 20 min (nuclear injections) prior to
fixation using 3% paraformaldehyde. The subcellular localization of
each injected protein was then determined by double-label
immunofluorescence as described previously (15).
In Vitro Protein Binding
Assays--
GST/M9·35S-Trn complexes were formed in the
presence of binding buffer (20 mM Tris, pH 7.5, 200 mM NaCl, and 10 mM magnesium acetate) for 30 min at 25 °C and then collected by addition of glutathione-Sepharose
4B beads (Amersham Pharmacia Biotech). Beads containing M9·Trn
complexes were washed once with binding buffer and then incubated for
30 min at 25 °C in Ran buffer alone (phosphate-buffered saline and 1 mM magnesium acetate) or with 10 µg of Ran Q69L in the
presence of 5 mM GTP or GDP. After washing with Ran buffer, proteins still bound to the Sepharose beads were eluted with 1 M MgCl2 and analyzed by SDS-polyacrylamide gel
electrophoresis (10% gel). In vitro translated (TNT,
Promega), 35S-labeled Trn was visualized by fluorography
(ENHANCE, NEN Life Science Products).
 |
RESULTS |
As noted above, Michael et al. (10) have localized the
M9 NLS/NES by deletion mutagenesis to between residues 268 and 305 of
hnRNP A1, whereas Weighardt et al. (12), using a comparable approach, localized the hnRNP A1 NLS to between hnRNP A1 residues 260 and 289 (Fig. 1). To more clearly
identify which residues within this region might contribute to NLS
and/or NES function and to Trn binding, we performed alanine-scanning
mutagenesis by sequential insertion of clusters of four alanines
between residues 265 and 292 of the M9 sequence in the context of the
previously described yeast two-hybrid plasmid pGBT9/M9 (Fig. 1) (15).
The pGBT9/M9 plasmid encodes the Gal4 DNA-binding domain linked to residues 256-320 of hnRNP A1. These M9 mutants were then analyzed for
their ability to interact with the M9-binding domain of human Trn using
the yeast two-hybrid assay as described previously (15). The G274A
mutant of M9, which fails to interact with Trn (15), served as a
negative control.

View larger version (19K):
[in this window]
[in a new window]
|
Fig. 1.
Structure and biological activity of M9
mutants. Alanine-scanning mutants were constructed in the context
of pGBT9/M9, which expresses the Gal4 DNA-binding domain linked to
residues 256-320 of hnRNP A1. The resultant M9 mutants were then
tested for biological activity in the yeast two-hybrid assay and as
recombinant fusion proteins consisting of GST linked to this same
region of hnRNP A1. The sequences at the bottom give the M9 NLS as
defined by Weighardt et al. (12) (upper row) and
the M9 NLS/NES as defined by Michael et al. (10)
(lower row). The indicated clustered alanine-scanning
mutants were constructed and tested for Trn binding by yeast two-hybrid
assay, with activity given on the right as percent of wild-type M9
binding as measured by lacZ induction in the Y190 yeast
indicator strain averaged over several experiments. M9 NLS and NES
function was determined as described under "Results" and is given
as ++, comparable to the wild type (WT); +, partially active
and , inactive.
|
|
As shown in Fig. 1, mutant M9-
2, which bears alanines at residues
273-276, was not able to detectably interact with Trn, a result that
was expected in light of the inactivity of the G274A missense mutant.
In contrast, all other mutants retained at least weak Trn-binding
ability. The least active of these latter mutants was M9-
1, which
retained only ~2% of the activity of the wild type. However, mutants
M9-D0 and M9-D3 were also significantly inhibited in their ability to
bind Trn, retaining ~26 and ~7% of wild-type activity,
respectively. In contrast, mutants M9-D4, M9-D5, and M9-D6 retained
wild-type levels of Trn-binding activity. Western blot analysis of
these yeast transformants showed that the wild-type and mutant forms of
these Gal4/M9 fusion proteins were all expressed at comparable levels
(Fig. 2). Overall, these data therefore
suggest that the Trn-binding domain of hnRNP A1 is localized to between
residues 265 and 280, with the most critical residues located between
positions 269 and 276. To more fully confirm this hypothesis, we
generated several M9 deletion mutants in the context of the
Gal4/M9-(256-320) fusion protein and investigated whether these
retained Trn-binding activity in the two-hybrid assay. As shown in
Table I, hnRNP A1 residues 256-284 or
256-280 retained high levels of Trn binding, whereas the 256-272
deletion mutant was, as expected, inactive. Although the M9 deletion
mutant retaining hnRNP A1 residues 264-284, a total of only 21 amino acids, also retained strong Trn-binding activity, the 264-280 mutant
did show a significant drop in Trn binding, retaining only ~8% of
the activity of sequence 256-320 (Table I). All M9 deletion mutants
were again expressed at comparable levels in yeast cells, as determined
by Western blot analysis using an anti-Gal4 antiserum (Fig. 2). These
deletion data therefore confirm the alanine-scanning analysis shown in
Fig. 1 and map the core Trn-binding sequence of hnRNP A1 to between
residues 264 and 280.

View larger version (60K):
[in this window]
[in a new window]
|
Fig. 2.
Quantitation of the expression level of
Gal4/M9 fusion proteins in yeast. The yeast strain Y190 was
transformed with plasmids expressing the indicated wild-type
(WT) or mutant forms of the Gal4/M9-(256-320) fusion
protein. Western blot analysis of selected transformants was performed
using an anti-Gal4 polyclonal antiserum as described previously
(16).
|
|
View this table:
[in this window]
[in a new window]
|
Table I
Transportin binding activity of M9 deletion mutants
The Y190 yeast indicator strain was transformed with plasmids encoding
the VP16/Trn-(582-890) fusion protein and Gal4 DNA-binding domain
fusion proteins that included the indicated hnRNP A1 residues. Induced
-galactosidase activities were determined as described in the legend
to Fig. 1 and are given as a percentage of the level seen with the Gal4
fusion protein containing hnRNP A1 residues 256-320.
|
|
Nuclear Import Activity of M9 Mutants--
As noted above, Trn has
been shown to mediate the nuclear import of substrates bearing the M9
NLS/NES, and M9 mutants that fail to bind Trn, such as G274A, also fail
to import (13, 15). To examine the NLS activity of the M9 mutants given
in Fig. 1, we purified recombinant proteins consisting of GST linked to
wild-type or mutant forms of M9 (hnRNP A1 residues 256-320). These
were then mixed with a rabbit IgG tracer protein and microinjected into
the cytoplasm of HeLa cells, a process that takes 8-10 min at room
temperature for each sample. After microinjection, cultures were fed
fresh 37 °C culture medium, incubated at 37 °C for 1 or 30 min,
and then fixed and stained with anti-GST and anti-rabbit IgG antibodies
as described previously (15).
As shown in Fig. 3 (C and
D), the wild-type M9 sequence proved to be a highly
effective NLS sequence in that essentially all of the wild-type GST/M9
protein was localized to the nucleus within 1 min of completion of
microinjection. In contrast, the GST/D2 fusion failed to detectably
accumulate in the nucleus even by 30 min after microinjection (Fig. 3,
M and N), as is indeed expected based on the
inability of the M9-D2 mutant to bind Trn (Fig. 1). Interestingly, the
M9-D1 and M9-D3 mutants both showed significant nuclear accumulation by
30 min after microinjection (Fig. 3, E, F,
I, and J). However, these mutant M9 sequences are
clearly a substantially less effective NLS than the wild-type M9
sequence, as judged by the weak nuclear accumulation seen at 1 min
after injection (Fig. 3, G, H, K, and
L). It is therefore apparent that the markedly reduced
affinity for Trn displayed by the M9-D1 and M9-D3 mutants (Fig. 1) is
nevertheless sufficient to mediate nuclear import, albeit with reduced
efficiency. The other M9 mutants, i.e. M9-D0, M9-D4, M9-D5,
and M9-D6 (Fig. 1), were all found to mediate nuclear entry with an
efficiency comparable to that seen with the wild-type GST/M9 fusion
protein, consistent with their ability to bind Trn effectively in
vivo (Fig. 1 and data not shown).

View larger version (84K):
[in this window]
[in a new window]
|
Fig. 3.
Analysis of M9 NLS activity. Purified
recombinant wild-type and mutant GST/M9 proteins were mixed with a
rabbit IgG tracer and then microinjected into the cytoplasm of HeLa
cells. After a 1- or 30-min incubation at 37 °C, cells were fixed,
and the subcellular localization of the injected GST/M9 and IgG
proteins was determined by immunofluorescence. The data shown are for
the wild-type (WT) M9 sequence and for the M9- 1, M9- 2,
and M9- 3 mutants described in Fig. 1.
|
|
Nuclear Export Activity of Mutant M9 Sequences--
We next wished
to investigate whether the mutations described in Fig. 1 would affect
the NES activity of the M9 sequence. Because M9 is a more effective NLS
than NES, protein substrates bearing the M9 sequence appear to localize
to the cell nucleus at steady state even though they have been shown to
continuously shuttle between the nucleus and cytoplasm (22). To measure
NES activity, we have therefore developed an assay for protein
nucleocytoplasmic shuttling that depends upon the microinjection of
recombinant proteins into a single nucleus in a cell containing two or
more nuclei. Such cells normally exist at a low level in a culture of
HeLa cells, but their prevalence can be increased by overnight culture
in serum-free medium followed by 4-6 h of culture in medium containing serum.
Such an experiment, in which binuclear cells were injected with
wild-type or mutant GST/M9 proteins together with an IgG tracer, is
shown in Fig. 4. After 20 min of
incubation at 37 °C, much of the microinjected wild-type GST/M9
protein migrated from the injected nucleus, identified by the IgG
tracer, to the uninjected nucleus (Fig. 4, A and
B). Similarly, both the GST/D1 and GST/D3 proteins were also
able to migrate to the other nucleus, although this process appeared
less efficient and also led to a low but detectable level of
cytoplasmic protein accumulation (Fig. 4, E and
K). Finally, the GST/D2 mutant, which failed to import into the cell nucleus (Fig. 3), also failed to exit the injected nucleus (Fig. 4H). All the other M9 mutants described in Fig. 1,
i.e. M9-D0, M9-
4, M9-
5, and M9-
6, all demonstrated
efficient nucleocytoplasmic shuttling and therefore clearly retain NES
activity (data not shown).

View larger version (59K):
[in this window]
[in a new window]
|
Fig. 4.
NES activity of M9 mutants. HeLa cells
containing two nuclei were injected into one nucleus with a recombinant
wild-type or mutant GST/M9 fusion protein mixed with an IgG tracer.
After 20 min of incubation at 37 °C, cells were fixed and subjected
to double-label immunofluorescence. Because M9 is both an NES and an
NLS (10), nucleocytoplasmic shuttling results in a redistribution of
functional M9 fusion proteins to the uninjected nucleus (second
row), whereas the IgG tracer remains confined to the injected
nucleus (first row).
|
|
Selection of Novel Functional M9 Sequences--
Although the M9
mutants delineated in Fig. 1 failed to segregate M9 NLS and NES
activity, these mutants are clearly too crude to prove this point
clearly. As an alternative approach, we therefore decided to totally
randomize each of the four amino acid segments defined by mutants
M9-D0, M9-
1, M9-
2, and M9-
3 and then select for retention of
the ability to bind Trn effectively using the two-hybrid assay in
yeast. This approach, which we have previously used to define the
sequence requirements for leucine-rich NES function (17), should fully
define the sequence requirements for Trn binding in vivo and
also generate a large pool of variant M9 sequences that should retain
NLS activity. However, if M9 NES function is dependent on an
interaction with an unknown nuclear export receptor distinct from Trn,
then this extensive pool of M9 sequence variants should allow
segregation of M9 NLS function from M9 NES activity.
The M9 sequence present in pGBT9/M9 was therefore randomized in four
4-amino acid segments, and each library was analyzed for Trn binding in
the yeast two-hybrid context by screening for expression of the
his3 selectable marker. M9 variants that permitted yeast
colony growth under selective conditions were then recovered and
retransformed to confirm that the observed his3 expression was indeed mediated by an interaction with Trn. These secondary transformants were also analyzed for level of expression of a second
indicator gene, lacZ, as a measure of the affinity of the interaction of Trn with the various recovered M9 derivatives.
Based on a comparison of the number of yeast transformants observed on
his3-selective versus nonselective plates, we
observed that
20% of the R0 library transformants,
25% of the R1
library transformants, and
40% of the R3 library transformants were
able to mediate an interaction with Trn sufficient to support growth under conditions selective for his3 expression. Multiple
colonies from each library were picked and analyzed for Trn dependence, level of activation of the lacZ indicator gene, and
sequence. In Fig. 5, we present 12 randomized sequences from the R0, R1, and R3 M9 libraries that all
displayed essentially wild-type levels of Trn binding, as judged from a
comparable induction of lacZ expression.

View larger version (34K):
[in this window]
[in a new window]
|
Fig. 5.
Identity of random M9 sequence variants
selected for Trn binding. The M9 sequence was randomized in four
clusters of 4 amino acids coincident with hnRNP A1 residues 265-268,
269-272, 273-276, and 277-280 to give libraries R0, R1, R2, and R3,
respectively. These libraries were then tested for Trn binding by
two-hybrid analysis. Active M9 variants were sequenced, and their amino
acid sequences are given in uppercase letters. In addition,
two additional libraries were generated that randomized residues
273-275 and 274-276, respectively. The sequences of the recovered M9
variants from these two smaller libraries are given in the R2
column, with the invariant residues indicated in lowercase
letters. Sequences recovered more than once are indicated by
numbers in parentheses. All sequences gave levels
of Trn interaction comparable to the wild type (WT) as
determined by the level of lacZ induction observed in yeast
indicator cells, with the following exceptions: *, 20-50% of
wild-type M9; and , 5-20% of wild-type M9. Residues that displayed
evident selection are indicated by arrows, whereas sequences
subsequently tested for NLS and NES activity are indicated in
boldface. All such M9 variants displayed levels of NES and
NLS function comparable to the wild type (see Fig. 7 for representative
data).
|
|
Unlike the R0, R1, and R3 libraries, the R2 library, which randomized
residues (positions 273-276) that blocked Trn binding when mutated to
alanine (Fig. 1), resulted in only a very small number of yeast
colonies upon selection for his3 expression. Although several of these were picked, only one (R2-1) proved to be a real Trn
interactor, whereas the remaining positives all contained frameshift
mutations that generated autonomous transcription activation domains
(data not shown). To generate additional information as to sequence
requirements in this critical region of M9, we therefore generated two
additional libraries in which only 3 amino acids at a time were
randomized, i.e. 273FGP275 or
274GPM276. These two libraries allowed ~1 and
~2%, respectively, of the yeast transformants to generate colonies
under his3-selective conditions. The amino acid sequences of
17 of these transformants are given in Fig. 5. Four transformants were
predicted to encode the wild-type M9 amino acid sequence, but had
different underlying nucleotide sequences. Unlike the R0, R1, and R3
libraries, for the R2 region, we recovered several sequences multiple
times upon randomization and also noted that a number of such recovered
sequences appeared to have a lower affinity for Trn, as suggested by
lower levels of induced lacZ indicator gene expression in
the yeast indicator cells.
Analysis of the recovered protein sequences showed complete
conservation at only one position, i.e. serine 271. However,
this serine is clearly not absolutely essential for either Trn binding or M9 function, as mutation to alanine, in M9-D1, permitted a low level
of both Trn binding and NLS/NES activity (Figs. 1, 3, and 4). Other
residues that appeared non-random in the selected sequences included
position 266, which was always Tyr, Trp, or Phe; position 269, which
was invariably a small hydrophilic residue; position 273, which was
generally hydrophobic; position 274, which was glycine in all but two
transformants; position 275, which was always either proline or lysine;
position 276, which always contained a large hydrophobic residue; and
position 277, which was generally either lysine or arginine. No other
positions in M9 displayed a clear sequence requirement for Trn binding
(Fig. 5). The consensus sequence for efficient Trn binding by M9
suggested by these data is given in Fig.
6.

View larger version (9K):
[in this window]
[in a new window]
|
Fig. 6.
Consensus Trn interaction motif. A
consensus Trn protein-binding motif, derived from the data shown in
Fig. 4, is given and aligned with the wild-type M9 Trn-binding sequence
(residues 266-277 of hnRNP A1). J, hydrophilic amino acid;
Z, hydrophobic amino acid; X, any residue.
|
|
Having identified a range of M9 sequences that permitted Trn binding
in vivo, we next investigated whether these sequences would
also permit M9 NLS and NES function. The M9 sequences highlighted in
Fig. 5 were therefore prepared as GST fusion proteins, and their NLS
and NES activity was assayed as shown in Figs. 3 and 4. To briefly
summarize this work, all these randomized sequences were found to
mediate nuclear protein import and export with an efficiency comparable
to the wild type. Results from representative assays showing nuclear
shuttling by the R1-9 mutant of M9 (i.e. M9 bearing sequence
9 from the R1 pool shown in Fig. 5) as well as by the R2-11, R2-12, and
R3-10 mutants of M9 are given in Fig. 7.

View larger version (39K):
[in this window]
[in a new window]
|
Fig. 7.
Nucleocytoplasmic shuttling activity of M9
variants. Randomized M9 sequence variants that had been selected
for binding to Trn in vivo were tested for NLS and NES
activity by nuclear microinjection as described in the legend to Fig.
4. All such variants were active. R1-9 is the ninth sequence variant in
the R1 library, as given in Fig. 4, i.e. substitution of
DMSG for residues 269QSSN272 in M9. The 11.4.11 mutant substitutes residues 269-280 of M9, as described under
"Results."
|
|
To take this analysis a step further, we next generated two M9 variants
containing combinations of the selected randomized sequences given in
Fig. 5. In particular, these two mutants, termed 11.4.11 and 8.4.10, respectively, substituted the R1-11, R2-4, and R3-11 sequences
(i.e. 269EESAFGKMFQKY280) or the
R1-8, R2-4, and R3-10 sequences (i.e.
269RYTFFGKMTSYR280) in place of wild-type
sequence 269-280 present in M9. Both of these very extensive M9
variants displayed close to wild-type Trn binding in yeast cells, and
both also gave good NLS and NES activity when assayed by microinjection
in HeLa cells (Fig. 7, I and J; and data not shown).
Effect of RanGTP on the M9-Trn Interaction--
Although the
mutational analysis presented in Fig. 1 and the randomization/selection
for Trn binding given in Fig. 5 between them varied every single amino
acid between residues 265 and 292 in the hnRNP A1 M9 NLS/NES, they
never the less failed to identify any mutants that segregated the NLS
activity of M9 from its NES activity. This analysis therefore raises
the possibility that Trn is, in fact, not only the import but also the
export factor for M9. If this were the case, one would predict that the
M9-Trn interaction should be stable in the presence of RanGTP, which is
found at high levels in the cell nucleus (1, 4). However, as shown in
Fig. 8, addition of RanGTP resulted in
the release of Trn from an M9 column when tested in vitro,
although RanGDP had no such effect. Nevertheless, it remains possible
that this release is an in vitro artifact that would not
occur under in vivo conditions.

View larger version (78K):
[in this window]
[in a new window]
|
Fig. 8.
RanGTP releases M9·Trn complexes in
vitro. Wild-type full-length 35S-labeled
Trn was synthesized in an in vitro translation reaction and
then bound to recombinant GST/M9. M9·Trn complexes were then
collected on glutathione-Sepharose beads and incubated with recombinant
Ran bound to GTP or GDP. The Q69L mutant of Ran was used here, as it is
GTPase-deficient even in the presence of RanGAP (20). After washing,
proteins that remained bound to the beads were eluted and detected by
gel analysis.
|
|
To test whether Ran binding and M9 binding to Trn are indeed mutually
incompatible in the nuclear environment, we used the yeast two-hybrid
assay, which measures nuclear protein-protein interactions,
i.e. interactions that occur in the presence of endogenous
RanGTP. As noted above, human Trn residues 582-890 interact strongly
with Gal4/M9 in the two-hybrid setting (15), and this result is
reproduced in Table II. However,
VP16/Trn-(582-890) does not interact with Gal4/Ran, a result that is
expected given that the Trn Ran-binding domain, as for other
Imp-
-related proteins, is expected to map to the amino-terminal
region (23). More important, expression of a VP16 fusion protein
containing full-length Trn (amino acids 1-890) gave rise to a readily
detectable interaction with Gal4/Ran (which is presumably in the form
of RanGTP), although no interaction with Gal4/M9 was detected.
Therefore, as in the in vitro situation (Fig. 8), binding of
full-length Trn to RanGTP and to M9 represent mutually exclusive
interactions in the yeast nucleus in vivo.
View this table:
[in this window]
[in a new window]
|
Table II
Binding of transportin to M9 and Ran is mutually exclusive in vivo
The Y190 yeast indicator strain was transformed with plasmids encoding
the indicated fusions to the Gal4 DNA-binding domain or the VP16
transcription activation domain, and induced -galactosidase activity
was determined as described (15).
|
|
A final possibility that we considered is that the export factor for
the M9 NES would be a variant form of Trn. Such a protein has, in fact,
been reported and termed transportin 2 (Trn2) (18). Although little is
known about the role of Trn2 in vivo, Trn2 was reported to
be unable to interact with hnRNP A1 and other hnRNPs in
vitro. However, if Trn2 is an M9-specific NES receptor, then hnRNP
A1 binding would be expected to also require RanGTP binding to Trn2, a
possibility that was not tested. In Table II, we have investigated
whether full-length Trn2 (amino acids 1-894) would be able to bind M9
in the yeast cell nucleus. In fact, even though the VP16/Trn2-(1-894)
fusion protein gave readily detectable levels of binding to Gal4/Ran,
no M9 binding was detected. We therefore conclude that Trn2 is unlikely
to be the export receptor for the M9 NES.
 |
DISCUSSION |
The goal of this work was 2-fold. First, we wished to define the
sequences in M9 required for interaction with the Trn nuclear import
receptor and hence for M9 NLS function. Second, we wished to test
whether the reported NES activity of M9 could be segregated from its
NLS activity. As described in detail in the Introduction, such a
segregation is predicted by the hypothesis that nuclear RanGTP serves
to dissociate NLS-import factor complexes, yet to stabilize NES-export
factor complexes (1-3). These dual aims were addressed by first
delineating the sequences in the M9 domain important for Trn binding by
alanine-scanning and deletion mutagenesis (Fig. 1 and Table I) followed
by randomization of these sequences, together with selection for
retention of Trn binding, in order to exhaustively identify residues
that contribute to the M9-Trn interaction (Figs. 5 and 6).
The mutational data presented in Fig. 1 and Table I demonstrate that
the M9 residues that contribute to Trn binding are located between
positions 264 and 280 of hnRNP A1, with the most critical residues
located between positions 269 and 276. The randomization/selection data
presented in Fig. 5 demonstrate that no single residue in M9, with the
possible exception of serine 271, is absolutely critical for efficient
Trn binding. However, serine 271 is dispensable for at least modest Trn
binding based on the mutational data presented in Fig. 1. Taken
together, these data demonstrate that no single residue located in the
hnRNP A1 M9 domain is essential for Trn binding in vivo and
instead suggest that this protein-protein interaction results from the
combined activity of multiple residues in M9, as defined by the
consensus Trn-binding site given in Fig. 6. Nevertheless, it is also
apparent that certain residues make particularly important
contributions to this interaction. In addition to serine 271, these
appear to include glycine 274 and the slightly more variable residues
located at positions 275 and 276. Although residues 266, 269, 273, and
277 also make contributions to the M9-Trn interaction, as documented by
the selection shown in Fig. 5, these residues appear to be less tightly conserved.
As predicted, M9 mutants and variants that retained Trn-binding
activity, including all the M9 variants given in Fig. 5 that were
tested, retained NLS activity. The Trn-binding consensus sequence given
in Fig. 6 therefore also defines the consensus sequence for M9 NLS
function. Mutants of M9 that were significantly attenuated for Trn
binding, such as M9-D1 and M9-D3 (Fig. 1), also retained detectable NLS
activity, although this was clearly reduced with respect to the
wild-type M9 sequence (Fig. 3). Unexpectedly, all M9 mutants and
variants that retained Trn-binding activity also displayed readily
detectable NES function, including the "composite" M9 mutants
11.4.11 and 8.4.10, which were extensively mutated between hnRNP A1
residues 269 and 280 (Figs. 5 and 7). In contrast, mutants that had
lost all Trn-binding activity, such as M9-D2 and G274A, also had lost
all NES activity (Figs. 1 and 4). Therefore, these data provide strong
evidence in favor of the hypothesis that Trn binding is predictive of
not only M9 NLS but also NES activity in vivo.
Could transportin be not only the import but also the export receptor
for hnRNP A1? Based on several findings, this appears unlikely. As
shown in Fig. 8 and also reported recently by others (5, 18), preformed
M9·Trn complexes are efficiently dissociated in vitro by
RanGTP, but not by RanGDP. As RanGTP is present at high levels in the
cell nucleus (1-4), this finding is most consistent with the
hypothesis that M9·Trn complexes are dissociated in the nucleus after
import from the cytoplasm. These in vitro data were further
validated in vivo by the finding that full-length Trn is
unable to interact with M9 in the yeast two-hybrid assay, which measures nuclear protein-protein interactions, even though it efficiently interacts with Ran (which is presumably in the RanGTP form), whereas deletion of the amino-terminal Ran-binding domain of Trn
blocks Ran binding, but activates in vivo M9 binding (Table II). Therefore, both in vitro and in the nucleus in
vivo, RanGTP binding and M9 binding by Trn are mutually exclusive.
Recent immunoprecipitation studies also suggest that Trn is unlikely to
bind to hnRNP A1 assembled into nuclear hnRNP complexes in
vivo in that precipitation of such complexes using an
hnRNPC-specific antibody failed to coprecipitate Trn (18).
Interestingly, these studies also demonstrated that the M9 domain of
hnRNP A1 was not accessible to an M9-specific monoclonal antibody when
hnRNP A1 was assembled into nuclear hnRNP complexes, even though M9
appears not to be bound to Trn. These studies therefore raise the
possibility that M9 is bound in the nucleus by a nuclear export factor
distinct from Trn.
The data presently available therefore provide us with a paradox. On
the one hand, the extensive mutational analysis presented in this
report demonstrates that Trn binding is predictive of M9 NES function.
On the other hand, several lines of data suggest that Trn is not the M9
NES receptor. Could an isoform of Trn or a closely related protein be
the M9 NES receptor? Only one such closely related protein is known,
i.e. the Trn2 protein (18). However, at least by two-hybrid
analysis, full-length Trn2 does not appear able to interact with M9 in
the yeast cell nucleus, although Trn2 does bind Ran effectively (Table
II). This result therefore appears inconsistent with the hypothesis
that Trn2 mediates M9 NES function. Alternately, it is possible that
the sequence determinants for Trn binding by M9 actually define not so
much a linear protein recognition sequence as a particular protein structure. If so, this might explain why a similar consensus sequence could mediate an interaction with both Trn and a perhaps only distantly
related M9 NES receptor. As the identity and target sequences for
nuclear export and import factors are rapidly being defined, it should
only be a matter of time before this conundrum is resolved.
 |
ACKNOWLEDGEMENT |
We thank Gideon Dreyfuss for the Trn2 cDNA.
 |
FOOTNOTES |
*
This work was supported by the Howard Hughes Medical
Institute.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
¶
To whom correspondence should be addressed. Tel.:
919-684-3369; Fax: 919-681-8979; E-mail: Culle002{at}mc.duke.edu.
 |
ABBREVIATIONS |
The abbreviations used are:
Imp-
, importin
/karyopherin
1;
NLS, nuclear localization signal;
NES, nuclear
export signal;
hnRNP, heterogeneous nuclear ribonucleoprotein;
Trn, transportin;
GST, glutathione S-transferase.
 |
REFERENCES |
-
Izaurralde, E.,
and Adam, S.
(1998)
RNA
4,
351-364[Abstract/Free Full Text]
-
Mattaj, I. W.,
and Englmeier, L.
(1998)
Annu. Rev. Biochem.
67,
265-306[CrossRef][Medline]
[Order article via Infotrieve]
-
Weis, K.
(1998)
Trends Biochem. Sci.
23,
185-189[CrossRef][Medline]
[Order article via Infotrieve]
-
Koepp, D. M.,
and Silver, P. A.
(1996)
Cell
87,
1-4[Medline]
[Order article via Infotrieve]
-
Izaurralde, E.,
Kutay, U.,
von Kobbe, C.,
Mattaj, I. W.,
and Görlich, D.
(1997)
EMBO J.
16,
6535-6547[Abstract/Free Full Text]
-
Rexach, M.,
and Blobel, G.
(1995)
Cell
83,
683-692[Medline]
[Order article via Infotrieve]
-
Görlich, D.,
Pante, N.,
Kutay, U.,
Aebi, U.,
and Bischoff, F. R.
(1996)
EMBO J.
15,
5584-5594[Abstract]
-
Kutay, U.,
Bischoff, F. R.,
Kostka, S.,
Kraft, R.,
and Görlich, D.
(1997)
Cell
90,
1061-1071[Medline]
[Order article via Infotrieve]
-
Fornerod, M.,
Ohno, M.,
Yoshida, M.,
and Mattaj, I. W.
(1997)
Cell
90,
1051-1060[Medline]
[Order article via Infotrieve]
-
Michael, W. M.,
Choi, M.,
and Dreyfuss, G.
(1995)
Cell
83,
415-422[Medline]
[Order article via Infotrieve]
-
Siomi, H.,
and Dreyfuss, G.
(1995)
J. Cell Biol.
129,
551-560[Abstract]
-
Weighardt, F.,
Biamonti, G.,
and Riva, S.
(1995)
J. Cell Sci.
108,
545-555[Abstract/Free Full Text]
-
Pollard, V. W.,
Michael, W. M.,
Nakielny, S.,
Siomi, M. C.,
Wang, F.,
and Dreyfuss, G.
(1996)
Cell
86,
985-994[Medline]
[Order article via Infotrieve]
-
Bonifaci, N.,
Moroianu, J.,
Radu, A.,
and Blobel, G.
(1997)
Proc. Natl. Acad. Sci. U. S. A.
94,
5055-5060[Abstract/Free Full Text]
-
Fridell, R. A.,
Truant, R.,
Thorne, L.,
Benson, R. E.,
and Cullen, B. R.
(1997)
J. Cell Sci.
110,
1325-1331[Abstract/Free Full Text]
-
Blair, W. S.,
and Cullen, B. R.
(1997)
Mol. Cell. Biol.
17,
2888-2896[Abstract]
-
Bogerd, H. P.,
Fridell, R. A.,
Benson, R. E.,
Hua, J.,
and Cullen, B. R.
(1996)
Mol. Cell. Biol.
16,
4207-4214[Abstract]
-
Siomi, M. C.,
Eder, P. S.,
Kataoka, N.,
Wan, L.,
Liu, Q.,
and Dreyfuss, G.
(1997)
J. Cell Biol.
138,
1181-1192[Abstract/Free Full Text]
-
Truant, R.,
Fridell, R. A.,
Benson, R. E.,
Bogerd, H.,
and Cullen, B. R.
(1998)
Mol. Cell. Biol.
18,
1449-1458[Abstract/Free Full Text]
-
Bischoff, F. R.,
Klebe, C.,
Kretschmer, J.,
Wittinghofer, A.,
and Ponstingl, H.
(1994)
Proc. Natl. Acad. Sci. U. S. A.
91,
2587-2591[Abstract]
-
Harper, J. W.,
Adami, G. R.,
Wei, N.,
Keyomarsi, K.,
and Elledge, S. J.
(1993)
Cell
75,
805-816[Medline]
[Order article via Infotrieve]
-
Piñol-Roma, S.,
and Dreyfuss, G.
(1992)
Nature
355,
730-732[CrossRef][Medline]
[Order article via Infotrieve]
-
Görlich, D.,
Dabrowski, M.,
Bischoff, F. R.,
Kutay, U.,
Bork, P.,
Hartmann, E.,
Prehn, S.,
and Izaurralde, E.
(1997)
J. Cell Biol.
138,
65-80[Abstract/Free Full Text]
Copyright © 1999 by The American Society for Biochemistry and Molecular Biology, Inc.