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Mol Cell Biol, January 1998, p. 450-458, Vol. 18, No. 1
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Regulation of Sex-Specific Selection of
fruitless 5' Splice Sites by transformer
and transformer-2
Volker
Heinrichs,*
Lisa C.
Ryner, and
Bruce S.
Baker
Department of Biological Sciences, Stanford
University, Stanford, California 94305-5020
Received 29 August 1997/Returned for modification 14 October
1997/Accepted 24 October 1997
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ABSTRACT |
In Drosophila melanogaster, the fruitless
(fru) gene controls essentially all aspects of male
courtship behavior. It does this through sex-specific alternative
splicing of the fru pre-mRNA, leading to the production of
male-specific fru mRNAs capable of expressing male-specific
fru proteins. Sex-specific fru splicing involves the choice between alternative 5' splice sites, one used exclusively in males and the other used only in females. Here we report
that the Drosophila sex determination genes
transformer (tra) and transformer-2
(tra-2) switch fru splicing from the
male-specific pattern to the female-specific pattern through activation
of the female-specific fru 5' splice site. Activation of
female-specific fru splicing requires
cis-acting tra and tra-2 repeat
elements that are part of an exonic splicing enhancer located
immediately upstream of the female-specific fru 5' splice
site and are recognized by the TRA and TRA-2 proteins in vitro. This
fru splicing enhancer is sufficient to promote the
activation by tra and tra-2 of both a 5' splice
site and the female-specific doublesex (dsx) 3'
splice site, suggesting that the mechanisms of 5' splice site
activation and 3' splice site activation may be similar.
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INTRODUCTION |
Alternative pre-mRNA processing is
widely used as a regulatory mechanism for the control of gene
expression in higher eukaryotes. Developmentally regulated pre-mRNA
processing can give rise to gene expression patterns that are specific
with regard to tissue, developmental stage, and sex.
In Drosophila melanogaster, the fruitless
(fru) gene regulates essentially all aspects of male
courtship behavior, including sexual orientation (33, 54).
It does this by functioning in about 0.5% of the neurons in the
central nervous system (CNS). fru is part of the hierarchy
of Drosophila sex determination genes (5), where
it controls one of the two branches identified downstream of the genes
transformer (tra) and transformer-2
(tra-2) (63). The other branch controls all known
aspects of somatic sexual differentiation outside the CNS, as well as
certain aspects of sexual differentiation within the CNS, and is
regulated by the doublesex (dsx) gene
(13). Fundamental to the sex-specific functions of
fru, transcripts from the distal fru promoter
undergo sex-specific alternative splicing (54). In males, a
male-specific 5' splice site (5' SS) is used that is located 1,590 nucleotides (nt) upstream of the female-specific 5' SS used in females.
Both 5' SS are spliced to a common 3' splice site (3' SS) over 70 kb
downstream. Male-specific and female-specific fru cDNAs
contain a common coding region downstream of the common 3' SS. In
males, usage of the distal male-specific 5' SS extends the open reading
frame in the 5' direction such that an additional 101 amino acids are
present at the N terminus.
Females mutant for either tra or tra-2 exhibit
male-specific fru splicing and male courtship behavior
(54), indicating that tra and tra-2
are required either directly or indirectly for female-specific fru splicing. tra and tra-2 are known
to activate directly the female-specific dsx 3' SS by
binding to cis-acting tra and tra-2 (tra/tra-2) repeat elements, (T/A)C(T/A)(T/A)C(A/G)ATCAACA
(27, 30, 53). While tra-2 is expressed in both
sexes (2, 25), tra, which is expressed only in
females (11), is one of the few cell-specific splicing
regulators known to date. In dsx, the tra/tra-2
repeat elements are present in six copies which are part of an exonic
splicing enhancer located 300 nt downstream of the female-specific
dsx 3' SS (13, 48). Three copies of the
tra/tra-2 repeat elements are also present upstream of the female-specific 5' SS in fru (33, 54), suggesting
that regulation of fru splicing by tra/tra-2 may
occur directly. However, it is not known whether the
tra/tra-2 repeat elements in fru are required for
the regulation of fru sex-specific splicing.
tra and tra-2 contain protein domains known to be
involved in regulated and general splicing. tra-2 contains a
RRM-type RNA binding domain flanked by two SR domains, regions rich in
serine and arginine residues, while tra contains a single SR
domain. RRM-type RNA binding domains have been shown to be essential
for the recognition of pre-mRNAs by a variety of RNA processing factors (12). SR domains have been implicated in protein-protein
interactions between splicing factors (37, 68) and also in
the intracellular localization of splicing factors to nuclear speckles
(41), regions of the nucleus enriched in splicing factors.
Other RNA processing factors containing RRM-type RNA binding domains
and/or SR domains include the splicing factors of the SR protein
family, general splicing factors which can also affect splice site
choices (4, 15, 16, 18, 21, 23, 36, 39, 52, 55, 67, 72, 73),
and the splicing factors U1-70K (64) and U2AF
(74) involved in the general recognition of splice sites.
Recent studies have implicated additional proteins in splicing
regulation by tra/tra-2. The TRA-2 protein has been reported to interact with the TRA protein (3, 32), the
Drosophila SR protein RBP1 (29), human SR
proteins (68), and the human U2AF35 protein
(68). The Drosophila SR protein RBP1 participates
in the activation of the female-specific dsx 3' SS together
with tra/tra-2 by specifically binding to the dsx
pre-mRNA in the proximity of the female-specific dsx 3' SS
(28, 43). Mutations in the gene of another
Drosophila SR protein, B52, inhibit female-specific dsx splicing, suggesting indirect or direct involvement of
B52 in dsx splicing regulation (50). Unlike TRA,
SR proteins appear to be ubiquitous, although there are differences in
the relative abundance of members of this family in various tissues
(71). Two other tissue-specific splicing factors, the
soma-specific PSI protein in Drosophila (57) and
a human neuron-specific 75-kDa protein (46), have been
reported to regulate splicing of their target genes together with
particular hnRNP proteins. These findings indicate that in several
systems, tissue-specific splicing regulation involves both
tissue-specific regulators and target-specific contributions from
ubiquitous factors.
Recently, several mammalian tra-2 homologs have been
identified (6, 17, 44, 56). At least one human
tra-2 homolog can functionally replace tra-2 in
Drosophila (17), suggesting that the mechanisms
governing splice site selection by tra/tra-2 in
Drosophila may also be significant in humans. The mechanism by which sex-specific fru splicing is regulated, is
currently unknown. A priori, tra/tra-2 could induce
female-specific fru splicing by either blocking the
male-specific 5' SS or activating the female-specific 5' SS. In
fru, the tra/tra-2 repeat elements are located
between the two sex-specific 5' SSs, 38 nt upstream of the
female-specific 5' SS and 1,352 nt downstream of the male-specific 5'
SS (54). Thus, the close proximity of the
tra/tra-2 repeat elements to the female-specific
fru 5' SS would suggest that the likely mechanism of
fru regulation is 5' SS activation. In the case of
dsx, instead of affecting 5' SS selection, tra
and tra-2 activate the female-specific dsx 3' SS
(27, 30, 53). Furthermore, the activation model would
predict that in fru the tra/tra-2 repeat elements
function as an upstream splicing enhancer, while in dsx their role is that of a downstream splicing enhancer. Unlike
transcriptional enhancers, splicing enhancers can be position
dependent. For example, shortening the distance of the
tra/tra-2 repeat elements to the female-specific
dsx 3' SS inhibits dsx splicing regulation by tra/tra-2 (65). Indeed, while other downstream
splicing enhancers, generally containing multiple repeats of the
sequence motif GAR, where R is a purine, have been identified in exons
of vertebrate genes (14, 19, 24, 31, 40, 51, 62, 66, 69,
70), and several of these purine-rich downstream splicing
enhancers are recognized by SR proteins (40, 51, 60, 61), to
our knowledge no upstream splicing enhancer has been reported to date. Hence, an involvement of tra/tra-2 and of the
tra/tra-2 repeat elements in the selection of fru
5' SSs would indicate a novel regulatory mechanism.
In order to determine whether tra/tra-2 regulate
fru sex-specific splicing by acting through the
tra/tra-2 repeat elements and, if they do, to determine the
regulatory mechanism and its relationship to the mechanism of
dsx splicing regulation, we developed a fru
splicing assay system. Here we report that tra and
tra-2 regulate fru sex-specific splicing in
transfected Drosophila cells. Our data show that
tra/tra-2 induce female-specific fru splicing by
activating the female-specific fru 5' SS.
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MATERIALS AND METHODS |
Plasmid constructs.
To make the fru minigene
construct fruM+Fwt, a 1.5-kb NotI-EcoRI fragment
from the class 1 fru cDNA (54), including the male-specific 5' SS, was ligated to a 0.645-kb genomic EcoRI
fragment from phage 1H (54) spanning the
tra/tra-2 repeat elements and the female-specific 5' SS and
cloned into pSK+ (Stratagene). A 1.2-kb genomic PstI
fragment from cosmid HXI (54) including the common 3'
SS was placed downstream. A 2.5-kb BamHI fragment including
the actin 5C promoter (53) was placed upstream and a
0.5-kB NotI fragment encompassing the
tra-2 polyadenylation site (53) was placed
downstream of the fru sequences, respectively. Constructs fruM+Fmut, fruM+F
B-M, and fruFwt are derivatives of construct fruM+Fwt. In construct fruM+Fmut, the sequence of the tra/tra-2 repeat elements was changed from TCAATCAACA
to GGCAGCTTAC. In construct fruM+FB-M, a 1-kb
BbsI-MscI fragment located between the
male-specific fru 5' SS and the repeat elements was deleted. Construct fruFwt lacks the NotI-EcoRI fragment of
construct fruM+Fwt, which contains the male-specific fru 5'
SS. fruM+REwt and fruM+REmut are derivatives of construct fruM+FB-M.
Both the 0.645-kb genomic EcoRI fragment and all
fru sequences 4 bp upstream of the male-specific 5' SS were
deleted, and PCR fragments encompassing the wild-type (wt)
fru repeat elements and the mutated fru repeat
elements, respectively, were inserted upstream of the male-specific 5'
SS instead. The fru PCR primers used were
5'-TCCCCCGGGGAATTCGAGGACGTGTGA-3' and
5'-TAACCCGGGCGCCAGTTGGTGGGGAT-3'. Construct fruM+REds is a derivative of construct fruM+Fwt lacking the female-specific 5' SS in
which the 0.645-kb genomic EcoRI fragment was replaced by a
PCR fragment containing the wt fru repeat elements.
Construct dsxF+dsxRE contains genomic dsx sequences
including the 114-bp intron between nt 2066 and 3048f
(13). Construct dsxF+fruRE is a derivative of construct
dsxF+dsxRE in which the dsx repeat region between nt
2741f and 3048f (13) was deleted and
a PCR fragment containing the wt fru repeat region was
inserted instead. The tra, tra-2, rbp1
and B52 expression constructs are as described previously (28,
53).
The following probes were used. For constructs fruM+Fwt, fruM+FREmut,
and fruM+FB-M, a 179-bp BsaHI-BbsI fragment
spanning the male-specific fru 5' SS was placed upstream of
the 0.645-kb genomic EcoRI fragment. For construct fruFwt,
the 0.645-kb genomic EcoRI fragment was used. For construct
fruM+REds, the 179-bp BsaHI-BbsI fragment was
used. For constructs fruM+REwt and fruM+REmut, EcoRI fragments spanning the inserted repeat regions and the male-specific fru 5' SS were used. For constructs dsxF+dsxRE and
dsxF+fruRE, a dsx genomic fragment spanning nt 2066 to
2711f, including the 114-bp intron (13), was
used as a probe.
Transfections and RNase protections.
Transfections and RNase
protections were performed essentially as described previously
(28, 53). If not indicated otherwise, 10 µg of the
minigene constructs and 30 to 100 ng of the cDNA expression constructs
were transfected. Quantitations of RNase protection products were done
by densitometry and were corrected for the different numbers of labeled
residues in the protection products.
RT-PCR experiments.
Reverse transcription (RT)-PCR
experiments on RNA isolated from transfected SL2 cells were carried out
using the primers m and c as described previously (54).
Male-specific fru splicing gave rise to a 164-bp PCR product
as expected. Upon cotransfection with tra/tra-2, a PCR
product 1,754 bp long was detected, as expected for female-specific
fru splicing. Several PCR products 350 to 1,600 bp long were
also detected, possibly indicating cryptic splicing.
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RESULTS |
Regulation of fru sex-specific splicing by
tra and tra-2 in transfected
Drosophila cells.
To study the regulation of
fru sex-specific splicing, we began by establishing a
fru splicing assay system in transfected Drosophila Schneider (SL2) cells. As is characteristic for
male somatic tissue, Schneider cells express endogenously a functional tra-2 transcript, but no functional tra
transcript (53). We constructed a fru minigene
fruM+Fwt, driven by an actin promoter, which contains the
fru genomic region spanning the male-specific 5' SS, the
tra/tra-2 repeat elements, and the female-specific 5' SS,
fused to the downstream common 3' SS (see Fig. 2C). In this construct,
the fru intron flanked by the female-specific 5' SS and the
common 3' SS, over 70 kb long (Fig. 1),
was shortened to 1.3 kb. Construct fruM+Fwt includes 300 bp of intron
sequence downstream of the female-specific 5' SS and 1,000 bp of intron sequence upstream of the common 3' SS, respectively. Transient transfections into Drosophila Schneider (SL2) cells were
carried out, and fru splicing products were detected by an
RNase protection assay.
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FIG. 1.
Patterns of fru and dsx
sex-specific splicing. Schematic drawings of fruitless
(fru) and doublesex (dsx) splicing
patterns are shown. Only part of the fru gene is depicted.
Exons (boxes), introns (thin horizontal lines), and splices (thick
lines) are indicated. Female-specific splicing patterns are indicated
above and male-specific splicing patterns are indicated below each
gene. Male- (M) and female (F)-specific exon segments and common exons
(C) are indicated. The tra/tra-2 repeat elements are
indicated by thick dashes, and distances of the tra/tra-2
repeat elements to the sex-specific splice sites are given.
Female-specific (AUGF) and male-specific (AUGM)
translational start codons as well as female-specific (AAF)
and male-specific (AAM) polyadenylation sites are shown.
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The male-specific
fru 5' SS and the female-specific
fru 5' SS are 1,590 nt apart. To visualize usage of the male
and female
5' SSs simultaneously, the probe used contains two fragments
synthesized
in one piece which hybridize across the female 5' SS and
the male
5' SS, respectively (Fig.
2C). Usage of the female and male 5'
SSs are expected to generate the specific RNase protection products
F
and M, respectively (Fig.
1C). In addition, protection product
MF will
be generated from transcripts spliced in the female pattern,
from
unspliced RNA, and also in cases in which there is usage
of a cryptic
5' SS located between the female and male 5' SSs.
No endogenous
fru transcript was detected in SL2 cells, as shown
in Fig.
2A, lane 1. We observed that in the
absence of cotransfected
tra/tra-2 expression constructs,
the
fru minigene fruM+Fwt is
spliced mainly in the male
pattern (Fig.
2A, lane 2) with a molar
ratio of male (M) to female (F)
protection products (M/F) of 6.
The protection products were
quantitated by densitometry, and
quantitations were corrected for the
different numbers of labeled
residues in the protection products. No
unspliced fruM+Fwt RNA
was detected (not shown). A low ratio of
protection product F
to protection product MF (F/MF = 0.17) in the
absence of cotransfected
tra/tra-2 (Fig.
2A, lane 2)
probably reflects the presence of
cryptic splicing products (Fig.
1C),
as also indicated by RT-PCR
experiments (data not shown; see Materials
and Methods).
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FIG. 2.
Regulation of fru sex-specific splicing in
transfected Schneider cells. (A) The fru minigene construct
fruM+Fwt was transfected together with various combinations of cDNA
expression constructs encoding tra, tra-2,
rbp1, and B52 as indicated (28, 53) into
Schneider cells, and fru splicing was analyzed by RNase
protection assays. The presence (+) or absence ( ) of construct
fruM+Fwt and of the tra, tra-2, rbp1,
and B52 expression constructs in the transfection experiments is
indicated above each lane. Splicing products are identified to the
right of the autoradiograph. Lane M contains pSK+ DNA cut with
HpaII and used as a nucleotide length marker. The positions
of size markers (in nucleotides) are shown to the left of the
autoradiographs in panels A and B. (B) The amount of cotransfected
tra and tra-2 expression constructs was titrated
down to 0.3% (0.1 ng) of the amount transfected in panel A. (C)
Depiction of construct fruM+Fwt. Exons are represented by boxes, and
the intron is represented by a thin horizontal line. The positions of
the male-specific and female-specific 5' SSs are indicated, and
male-specific (M) and female-specific (F) exon segments are identified.
The three dashes upstream of the female-specific 5' SS represent the
tra/tra-2 repeat elements. The antisense RNase protection
probes are indicated directly below the map by horizontal bars. RNase
protection products (prod.) derived from male-specific and
female-specific fru splicing are given at the bottom of the
panel, and the expected product lengths are given in parentheses. The
distance between the male-specific and female-specific fru
5' SSs is 1,590 nt. The intron is 1,300 nt long. Note that the RNase
protection probes and the protection products are not drawn to scale.
Protection product MF can be obtained as a consequence of female
splicing or use of cryptic 5' splice sites or from unspliced
pre-mRNA.
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To test for regulation of
fru sex-specific splicing by
tra and
tra-2, we cotransfected
tra
and
tra-2 expression constructs.
Significantly, when both
tra and
tra-2 expression constructs were
cotransfected together with the
fru minigene, a shift to
purely
female-specific 5' SS usage occurs (Fig.
2A, lane 5), as
indicated
by an increase in spliced female product F, by the absence of
detectable product M, and by a ratio of protection product F to
protection product MF (F/MF) of 1.1. Switching from the male-specific
5' SS to the female-specific 5' SS by
tra/tra-2 was also
confirmed
by RT-PCR assay (data not shown; see Materials and Methods)
and
depends on the concentrations of the
tra/tra-2
expression constructs
(compare Fig.
2B, lane 1, and Fig.
2A, lane 5).
In Fig.
2B, lane
1, the ratio of product M to product F is 1.38 and the
ratio of
product F to product MF is 0.19. Expression of
tra
alone (Fig.
2A, lane 3) or
tra-2 (Fig.
2A, lane 4) induces
only a slight shift
to female-specific
fru splicing, as
indicated by a ratio of protection
product F to protection product MF
(F/MF) of 0.28. Thus, transfection
of both
tra and
tra-2 is required to switch
fru splicing
precisely
and efficiently from the male-specific 5' SS to the
female-specific
5' SS in cultured Schneider cells. These results in our
assay
system are consistent with results obtained in
Drosophila, where
female flies require both
tra
and
tra-2 for female-specific
fru splicing
(
54).
We also cotransfected the
Drosophila SR protein RBP1 in our
fru splicing assay. Expression of RBP1 in transfected
Schneider
cells was shown to induce female-specific
dsx
splicing (
28).
We found that transfection of RBP1 can also
induce some female-specific
fru splicing (Fig.
2A, lane 6),
suggesting that RBP1 may also
play a role in the regulation of
fru splicing. A potential RBP1
target site (ATCCCCA)
(
28) is present 12 nt upstream of the
female-specific
fru 5' SS. As a control, transfection of the
Drosophila SR protein B52 (
16,
52) did not affect
fru splicing (Fig.
2A, lane 7).
The tra/tra-2 repeat elements are required for
fru splicing regulation by tra/tra-2.
To
determine whether the tra/tra-2 repeat elements are
essential for regulation of fru splicing by tra
and tra-2, we tested a construct, fruM+FREmut, in which the
sequence of the conserved part of the tra/tra-2 repeat
elements was changed from TCAATCAACA to GGCAGCTTAC.
The probe used is the same as in Fig. 2, and since it contains wt
tra/tra-2 repeat elements, generates short loop-outs when
hybridized to the mutant tra/tra-2 repeat elements in
fruM+FREmut, resulting in a shortened female-specific RNase
protection product (Fig. 3A, lanes 1 and
2). Inefficient cutting of these short loop-outs by RNase A also
generates a larger protection product derived from spliced female
product which is marked by an asterisk (Fig. 3A). We observed that in
construct fruM+FREmut, switching to female fru splicing by
tra and tra-2 was almost completely blocked, as indicated by the presence of significant amounts of male splicing product M in the presence of cotransfected tra and
tra-2 (Fig. 3A, lane 2). In contrast, deletion of a 1-kb
fragment between the repeat elements and the male-specific 5' SS, as in
construct fruM+FB-M (Fig. 3B), did not affect regulation of
fru splicing by tra and tra-2 (Fig.
3A, lanes 3 and 4). These findings show that the tra/tra-2
repeat elements are required for regulation of fru splicing
by tra and tra-2, suggesting that tra
and tra-2 promote female-specific fru splicing by
acting through these elements.
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FIG. 3.
cis-acting elements required for regulation
of fru splicing by tra/tra-2. (A) Constructs
carrying mutations within the tra/tra-2 repeat elements
(construct fruM+FREmut) or a deletion of sequences between the
male-specific fru 5' SS and the tra/tra-2 repeat
sequences (construct fruM+FB-M) were transfected in the absence ()
or presence (+) of cotransfected tra/tra-2 as indicated
above the RNase protection assay autoradiograph. RNase protection
products are indicated to the right of the autoradiograph and are as
described in the legend to Fig. 2C. An additional RNase protection
product (RE mut.) is derived from female-specific splicing of construct
fruM+REmut. An incompletely cleaved protection product derived from
female-specific splicing of construct fruF+MRE mut is indicated by an
asterisk. The positions of size markers (in nucleotides) are shown to
the left of the autoradiograph. Lane M contains pSK+ DNA cut with
HpaII. (B) Illustration of constructs fruM+FREmut and
fruM+FB-M. fruM+FREmut contains mutated tra/tra-2
repeat elements indicated by asterisks. In fruM+FB-M, a 1-kb
BbsI-MscI fragment indicated by a broken-line box
was deleted. The probe used in these experiments is as described in the
legend to Fig. 2.
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Evidence for activation of the female-specific fru 5'
SS as the mechanism of fru splicing regulation.
To
determine whether tra and tra-2 induce
female-specific fru splicing by blocking the male-specific
5' SS or by activating the female-specific 5' SS, we tested constructs
that contain upstream of the common 3' SS (i) either the male-specific
5' SS, including the tra/tra-2 repeats (construct fruM+REds
[Fig. 4C]), or (ii) the female-specific
5' SS, including the tra/tra-2 repeats (construct fruFwt
[Fig. 4C]). The tra/tra-2 repeat elements were included at
the authentic position relative to the splice sites, 1,352 nt
downstream of the male-specific 5' SS and 38 nt upstream of the
female-specific 5' SS, respectively. We did observe activation of the
isolated female-specific 5' SS by tra/tra-2, as indicated by
the disappearance of unspliced RNA upon cotransfection with tra/tra-2 (Fig. 4A, lanes 1 and 2). A shorter exposure of
the same gel (Fig. 4A, lanes 3 and 4) also shows an increase in spliced female product by tra/tra-2 (Fig. 4A, lane 4), suggesting
that the effect observed in Fig. 4A, lane 2, is not due to instability of unspliced pre-mRNA. While spliced female product is seen to increase
in Fig. 4A, lane 4, the background bands below the spliced female
product in Fig. 4A, lanes 3 and 4, remain constant, suggesting equal
loading of RNA. Usage of the isolated female-specific 5' SS in the
absence of cotransfected tra and tra-2 (Fig. 4A,
lane 1) is probably due to the lack of the competing male-specific fru 5' SS, since the deletion of sequences located between
the male-specific fru 5' SS and the fru repeat
region, as in construct fruM+FB-M (Fig. 3B), does not affect
fru splicing. Similarly, the isolated female-specific
dsx 3' SS is also used in the absence of cotransfected
tra/tra-2, as shown previously (53) and as also
reproduced in this study (see Fig. 6). In contrast, the male-specific fru 5' SS was found to be unaffected by cotransfection with
tra/tra-2 (Fig. 4B, lanes 1 and 2). Taken together, these
results suggest that tra/tra-2 induce female-specific
fru splicing by activating the female-specific
fru 5' SS, as also suggested by the proximity of the
tra/tra-2 repeat elements to the female-specific 5' SS. Thus, in fru, the tra/tra-2 repeat region
functions as an upstream splicing enhancer.
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FIG. 4.
Testing the activation and the blockage model of
fru regulation. (A) Construct fruFwt containing the
female-specific fru 5' SS and the tra/tra-2
repeat elements was transfected in the absence () or presence (+) of
cotransfected tra/tra-2 as indicated above the RNase
protection assay autoradiograph. Lanes 3 and 4 show a shorter exposure
of lanes 1 and 2, respectively. Lane M contains pSK+ DNA cut with
HpaII. The positions of size markers (in nucleotides) are
shown to the left of the autoradiographs in panels A and B. (B)
Construct fruM+REds containing the male-specific fru 5' SS
and the tra/tra-2 repeat elements was transfected in the
absence () or presence (+) of cotransfected tra/tra-2 as
indicated above the RNase protection assay autoradiograph. RNase
protection products derived from spliced and unspliced pre-mRNAs of
constructs fruFwt and fruM+REds are indicated to the right of the
autoradiograph. (C) Illustration of constructs fruFwt and fruM+REds.
fruFwt contains the female-specific fru 5' SS, and fruM+REds
contains the male-specific fru 5' SS. The
tra/tra-2 repeat elements were included at the correct
distance upstream of the female-specific 5' SS and downstream of the
male-specific 5' SS, respectively. The deletion of the female-specific
fru 5' SS in construct in fruM+REds is indicated by
parentheses. The probes used in the RNase protection experiments are
represented by horizontal bars below each construct. RNase protection
products corresponding to spliced and unspliced pre-mRNAs are shown
below each construct.
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The fru repeat region is sufficient to promote the
activation of a 5' SS.
We next wanted to address the question of
whether the tra/tra-2 repeat region in fru is
sufficient to promote the activation of a 5' SS by
tra/tra-2. Since we showed that the male-specific fru 5'SS is normally unaffected by tra/tra-2
(Fig. 4), we inserted a 300-bp fragment of fru containing
the tra/tra-2 repeats 4 nt upstream of the male-specific
fru 5' SS (construct fruM+REwt [Fig. 5B]). Interestingly, spliced male
product was detected upon cotransfection with tra/tra-2
(Fig. 5A, lane 2), suggesting activation of the male-specific
fru 5' SS by tra/tra-2 in this hybrid construct. For a control, when the same fragment carrying mutations within the
tra/tra-2 repeat elements was inserted 4 nt upstream of the male-specific fru 5' SS, as in construct fruM+REmut (Fig.
5B), no spliced male product in the presence of tra/tra-2
was detected. Two separate probes, complementary to the constructs
fruM+REwt and fruM+REmut, respectively, were used in these experiments. Thus, the tra/tra-2 repeat elements are essential to promote
the activation of a heterologous 5' SS by tra/tra-2. Lack of
usage of the male-specific 5' SS in the constructs fruM+REwt and
fruM+REmut in the absence of cotransfected tra/tra-2 (Fig.
5A, lanes 1 and 3) was found to be due to the deletion of a stretch of
sequence upstream of the male-specific 5' SS in these constructs. The
insertion of the fru repeat region in either orientation
does not affect the usage of the male-specific fru 5' SS in
the absence of cotransfected tra/tra-2 (data not shown).
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 5.
Activation of a heterologous 5' SS by
tra/tra-2. (A) Construct fruM+REwt containing wt
tra/tra-2 repeat elements upstream of the male-specific
fru 5' SS and construct fruM+REmut containing mutant
tra/tra-2 repeat elements upstream of the male-specific
fru 5' SS were transfected in the absence () or presence
(+) of cotransfected tra/tra-2 as indicated above the RNase
protection assay autoradiograph. RNase protection products derived from
spliced and unspliced pre-mRNAs are indicated to the right of the
autoradiograph and are as described in the legend to Fig. 5B. Lane M
contains pSK+ DNA cut with HpaII. The positions of size
markers (in nucleotides) are shown to the left of the autoradiograph.
(B) Illustration of constructs fruM+REwt and fruM+REmut. The wt
fru repeat region is indicated by three dashes, and the
mutated fru repeat region is indicated by three asterisks.
The repeat mutations in construct fruM+REmut are as in construct
fruM+FREmut. For each construct, a specific RNase protection probe
hybridizing across the splice sites was generated and is indicated by a
horizontal bar below the constructs. RNase protection products
corresponding to spliced and unspliced pre-mRNAs are shown below the
constructs.
|
|
The fru repeat region and the dsx repeat
region are functionally interchangeable.
Our study shows that in
fru, the tra/tra-2 repeat region functions as an
upstream splicing enhancer required for the activation of the
female-specific fru 5' SS by tra/tra-2. In
contrast, tra/tra-2 activate the female-specific
dsx 3' SS by recognizing tra/tra-2 repeat
elements present downstream of this 3' SS (27, 30, 53). To
address the question of whether the tra/tra-2 repeat regions
in fru and dsx are functionally interchangeable,
we inserted the tra/tra-2 repeat region from fru
downstream of the female-specific dsx 3' SS (Fig.
6B). For the activation of the
female-specific dsx 3' SS by tra/tra-2 to occur,
the dsx repeat region has to be positioned at a distance of
300 bp downstream of this 3' SS (65). To ensure positioning
of the fru repeat region at this precise location, we placed
the fru repeat region downstream of a dsx PCR
fragment ending immediately upstream of the dsx repeat region, generating construct dsxF+fruRE (Fig. 6B), which lacks the
competing downstream male-specific dsx 3' SS (compare
diagram with that in Fig. 1). For a control, splicing of a construct
dsxF+dsxRE (Fig. 6B) containing the dsx repeat region was
tested. As shown previously, due to default usage of the isolated
female-specific dsx 3' SS, activation of the female-specific
dsx 3' splice site by tra/tra-2 is indicated by a
decrease in unspliced RNA in a construct lacking the male-specific
dsx 3' SS (53) and is also demonstrated here
(Fig. 6A, lanes 1 and 2). We found that the fru repeat
region promotes the activation of the female-specific dsx 3'
SS by tra/tra-2 almost as efficiently (Fig. 6A, lanes 3 and
4) as the dsx repeat region (Fig. 6A, lanes 1 and 2),
demonstrating that the fru and dsx repeat regions
can be functionally interchangeable in terms of dsx
regulation.
View larger version (17K):
[in this window]
[in a new window]
|
FIG. 6.
The fru and dsx repeat regions are
functionally interchangeable. (A) Construct dsxF+dsxRE containing the
dsx repeat region downstream of the female-specific
dsx 3' SS and construct dsxF+fruRE containing the
fru repeat region downstream of the female-specific
dsx 3' SS were transfected in the absence () or presence
(+) of cotransfected tra/tra-2 as indicated above the RNase
protection assay autoradiograph. RNase protection products derived from
spliced and unspliced pre-mRNAs are indicated to the right of the
autoradiograph and are as shown in panel B. The slightly lower mobility
of the protection product F derived from construct dsxF+fruRE (lanes 3 and 4) compared to that of product F derived from construct dsxF+dsxRE
(lanes 1 and 2) is due to a short stretch of polylinker present in
construct dsxF+fruRE and in the probe, but not in construct dsxF+dsxRE.
Lane M contains pSK+ DNA cut with HpaII. The positions of
size markers (in nucleotides) are indicated to the left of the
autoradiograph. (B) Illustration of constructs dsxF+dsxRE and
dsxF+fruRE. The fru repeat region is indicated by three
dashes, and the dsx repeat region is indicated by six
dashes. The common (C) and the female (F) dsx exon are indicated
(compare diagram with that in Fig. 1). The probe used in the RNase
protection experiments is represented by a horizontal bar below the
constructs. RNase protection products corresponding to spliced and
unspliced pre-mRNAs are shown at the bottom of the panel.
|
|
| |
DISCUSSION |
Here we report that tra and tra-2 induce
female-specific fru splicing by activating the
female-specific fru 5' SS. Our results also suggest that
tra and tra-2 regulate fru splicing
directly, since we show that fru splicing regulation
requires the tra/tra-2 repeat elements recognized by
tra and tra-2. Hence, the tra and tra-2 genes are functioning directly upstream of the
fru gene. Although our results explain how female-specific
fru splicing is achieved, it remains to be determined how
male flies ensure exclusively male fru splicing. Several
scenarios are conceivable. The female-specific fru 5' SS
could be a weak 5' SS, causing default usage of the male-specific
fru 5' SS in males when tra is not expressed.
This model is analogous to the situation in dsx, where the
regulated female-specific dsx 3' SS is a weak 3' SS due to a
purine-rich polypyrimidine tract (13). Both the sequences of
the female (TCG/GTAAGT) and male (TAG/GTAAGC) fru 5' SSs
match the Drosophila 5' SS consensus sequence MAG/GTRAGT
(47) in 7 of 9 nt. However, the precise sequence context of
the 9-nt consensus sequence of the 5' SS has been proposed to affect 5'
SS usage (1). Alternatively, yet unidentified
trans-acting factors could either block the female-specific
fru 5' SS or activate the male-specific fru 5' SS
in male flies. Our observation that the deletion of sequences upstream
of the male-specific fru 5' SS inhibits male fru
splicing could indicate that a mechanism for activating the male-specific fru 5' SS exists.
Activation of the proximal female-specific fru 5' SS by
tra and tra-2 represents a previously unknown
functional property of tra/tra-2. Although increasing the
concentration of the human SR protein ASF/SF2 induces the usage of
proximal 5' SSs (22, 38), the mechanism of action of ASF/SF2
appears to be fundamentally different from what we know about the
mechanism that leads to the usage of a proximal 5' SS in
fru. ASF/SF2 has been shown to have a general affinity to 5'
SSs (77) and stabilizes the recognition of 5' SSs by U1
small nuclear ribonucleoprotein particle (snRNP) (20, 59).
Increasing the affinity of U1 snRNP to all 5' SS in a pre-mRNA molecule
has been proposed to lead to the preferential usage of the 5' SS
closest to a 3' SS (20). Splicing to a distal 5' SS in the
human caldesmon gene is promoted by a purine-rich downstream splicing
enhancer, although the regulatory factor(s) involved is not known
(31). In contrast, tra/tra-2 specifically select
a 5' SS for activation depending on the presence of the upstream
tra/tra-2 repeat elements.
Involvement of tra/tra-2 in both 5' SS activation in
fru and 3' SS activation in dsx shows that
tra and tra-2 are multifunctional splicing
regulators. tra-2 (but not tra) is also involved
in regulating splicing of the tra-2 pre-mRNA (45)
and the exuperantia pre-mRNA (26) in the male
germ line, although it is not known whether these tra-2
functions involve tra/tra-2 repeat elements. Other examples
of multifunctional splicing factors have been described both in
Drosophila and in humans. The Drosophila Sxl
protein regulates splicing of the Sxl (9),
tra (11, 49, 58), and msl-2 (7,
34, 75) pre-mRNAs and affects msl-2 translation
(8, 35). The human U1 snRNP-specific protein A is also
involved in pre-mRNA polyadenylation (10, 42). Functional
activity of the fru repeat region in promoting
dsx 3' SS activation by tra/tra-2 suggests that
the mechanisms of 5' SS activation and 3' SS activation are
surprisingly similar. 5' SSs and 3' SSs are defined by distinct
sequence motifs and are specifically recognized early in spliceosome
assembly by general splicing factors. While 5' SSs are recognized by U1
snRNP (76) and by the SR protein ASF/SF2 (77), U2
snRNPs and U2AF bind to the 3' ends of introns (74). SR
proteins have also been shown to engage in protein-protein interactions
both with U1 snRNPs and with U2AF (37, 68). Since tra and tra-2 can interact with U2AF and with SR
proteins (29, 68), it is conceivable that by binding to
tra/tra-2 repeat elements, tra/tra-2 can
stabilize the recognition of both a specific 5' SS and a 3' SS by
general splicing factors. Thus, activation of a 5' SS versus a 3' SS by
tra/tra-2 could depend solely on the interactions of
tra/tra-2 with general splicing factors recognizing 5' SSs
on the one hand and 3' SSs on the other. Alternatively, additional
regulatory factors specific to fru 5' SS activation and/or
dsx 3' SS activation could be involved. There is evidence that the regulation of dsx splicing involves
dsx-specific features. The position of the dsx
repeat region 300 nt downstream of the female-specific dsx
3' SS is conserved between D. melanogaster and
Drosophila virilis (12a) and is essential for
dsx regulation by tra/tra-2 (65). In
contrast, purine-rich downstream splicing enhancers appear to be
generally found significantly closer to the upstream intron, at
distances ranging from 3 to 117 nt (24, 40, 51, 66), and
placing a purine-rich splicing enhancer beyond 293 nt downstream of the
3' SS inhibits splice site activation (40). Furthermore,
activation of the female-specific dsx 3' SS involves the
Drosophila SR protein RBP1 which recognizes evolutionarily conserved RNA target sequences present within the unusual purine-rich polypyrimidine tract of the female-specific dsx 3' SS and
within the dsx repeat region (28). Further
experiments are needed to identify possible additional players in
fru and dsx splicing regulation and to define the
molecular interactions involved.
| |
ACKNOWLEDGMENT |
This work was supported by grants from the National Institutes of
Health to B.S.B.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biological Sciences, Stanford University, 371 Serra Mall, Stanford, CA 94305-5020. Phone: (650) 723-0898. Fax: (650) 723-6035. E-mail: vheinric{at}cmgm.stanford.edu.
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Mol Cell Biol, January 1998, p. 450-458, Vol. 18, No. 1
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
