(Received for publication, July 13, 1995)
From the
We exploited the mechanism underlying thrombin receptor activation to develop a novel screening method to identify peptide agonists. The thrombin receptor is activated by limited proteolysis of its amino-terminal exodomain. Thrombin cleaves this domain to unmask a new amino terminus, which then functions as a tethered peptide agonist, binding intramolecularly to the body of the receptor to trigger signaling. The thrombin receptor's amino-terminal exodomain can also donate the tethered agonist intermolecularly to activate nearby thrombin receptors. We utilized this ability by co-expressing a ``tethered ligand library,'' which displayed the thrombin receptor's amino-terminal exodomain bearing random pentapeptides in place of the native tethered ligand together with target receptors in Xenopus oocytes. Clones that conferred thrombin-dependent signaling by intermolecular ligation of the target receptor were isolated by sib selection. Agonists for the thrombin receptor itself (GFIYF) and for the formyl peptide receptor (MMWLL) were identified. Surprisingly, the latter agonist was quite active at the formyl peptide receptor even without N-formylation, and its formylated form, fMMWLL, was more potent than the classical formyl peptide receptor agonist fMLF. In addition to identifying novel peptide agonists for targets of pharmacological interest, this method might be used to discover agonists for orphan receptors. It also suggests a possible evolutionary path from peptide to protease-activated receptors.
We developed an expression cloning method for identifying novel peptide agonists based on the thrombin receptor's activation mechanism. Thrombin cleaves its receptor's amino-terminal exodomain to unmask a new amino terminus, which then functions as a tethered peptide agonist, binding intramolecularly to the body of the receptor to trigger signaling(1, 2) . The thrombin receptor's amino-terminal exodomain can also donate the tethered agonist intermolecularly to activate nearby thrombin receptors(2) . The intermolecular liganding mode is less efficient than the intramolecular mode and presumably requires greater intrinsic activity of the tethered ligand sequence itself(2) . Accordingly, we utilized the ability of the thrombin receptor's amino-terminal exodomain to donate its tethered ligand intermolecularly to search for new peptide agonists. We constructed a ``tethered ligand library,'' which displayed random pentapeptides in place of the native tethered ligand in the thrombin receptor's amino-terminal exodomain and co-expressed this library together with target receptors in Xenopus oocytes. Clones that conferred thrombin-dependent signaling by intermolecular ligation of the target receptor were isolated by sib selection. We utilized this technique to identify a clone that activated the thrombin receptor itself and a second that activated the formyl peptide receptor. Peptides mimicking the tethered ligand sequences of these clones, GFIYF for thrombin receptor agonist and MMWLL for formyl peptide receptor, were effective agonists for their respective targets. The expected and unexpected features of these agonists are discussed. The tethered ligand library method thus provided an approach for searching a diverse group of peptide sequences for agonist activity. In addition to identifying novel peptide agonists for targets of pharmacological interest, this method might be used to discover agonists for orphan receptors. The ease with which agonists were ``evolved'' in this system suggests a possible evolutionary path from peptide to protease-activated receptors.
Xenopus oocytes were harvested, microinjected with
cRNAs, and cultured as previously described(1) .
Agonist-induced responses were assessed as Ca
release(1) .
The library was constructed as follows. A
construct dubbed ATE-CD8 encoding the thrombin receptor's
amino-terminal exodomain (ATE), ()fused to the transmembrane
domain of CD8, was used to display the receptor's amino-terminal
exodomain on the cell surface(2) . Surface expression of the
encoded protein and its cleavage by thrombin was verified as the
presence and thrombin-dependent loss of an epitope placed amino to the
thrombin cleavage site(2, 3, 4) . A library
of such molecules in which the receptor's agonist peptide domain
SFLLR was replaced by random pentapeptides was constructed as follows.
ATE-CD8 was modified to introduce paired BstXI sites flanking
the agonist peptide domain so that a ``BstXI
cassette'' could later be inserted to make the
library(5, 6) . An in frame nonsense mutation was
inserted between these sites to ensure premature termination of
translation of any non-recombinant ATE-CD8 molecules occurring in the
library. The modified ATE-CD8 was inserted into pBLOG between Xenopus globin mRNA 5`- and 3`-untranslated sequence and
downstream of an SP6 RNA polymerase promoter. pBLOG was made by
subcloning a 0.9-kilobase EcoRI-PstI fragment from
pFROG (1) into the corresponding sites of pBluescript II
SK
(Stratagene) in which the BstXI site had
been destroyed. BstXI cassette inserts for the library were
generated by annealing a pool of degenerate oligonucleotides
5`-GATCCCCGG(NNK)
AACCCCAATGATAAATATGAACCATT-3`,
where N = A, C, G, or T in equimolar amounts and K = G or T in equimolar amounts with two complementary,
flanking 13 mers 5`-CCGGGGATCTAAG-3` and
5`-GTTCATATTTATC-3`(7) . The annealed oligomers were then
ligated into the new BstXI sites of the modified ATE-CD8 in
pBLOG. Escherichia coli strain DH10B were electroporated with
an aliquot of the resulting library and plated at a complexity of
4000/pool. Of 10 randomly picked clones that were
sequenced(8) , 8 indeed encoded a wild-type ATE-CD8 sequence
except for the 15 nucleotides encoding the random agonist pentapeptide;
2 had mutations probably arising during annealing or ligation. Thus,
approximately 80% of the library encoded molecules that would display
random pentapeptides at their amino termini upon cleavage by thrombin.
The library was co-expressed with target receptors in Xenopus oocytes by co-injecting cRNAs (See Fig. 2).
Figure 2:
Thrombin-induced Ca release
from oocytes co-expressing the first set of library pools and the F43A
mutant thrombin receptor. cRNA was transcribed from cDNA representing
pools of 4000 independent clones(1) . Xenopus oocytes
were co-injected with 25 ng each of library and F43A mutant thrombin
receptor cRNAs and cultured for 24 h, after which thrombin-stimulated
Ca release was assessed(1) . Results (mean
± S.D. (n = 3)) are expressed as
Ca
release in the 10 min following addition of 20 nM thrombin/baseline
Ca release in the preceding 10
min(1) . The high concentration of thrombin (20 nM)
was used in an effort to avoid selecting clones based on their
substrate properties. Oocytes expressing the library or F43A alone
showed no signaling to thrombin (not shown). Co-expression resulted in
clear-cut thrombin signaling with three of the nine pools tested. A
clone was isolated from the most active of these (pool9, arrow) by sib selection (1) .
Pools of the tethered ligand library each representing 4000 independent clones (Fig. 1) were co-expressed with a target thrombin receptor bearing the F43A loss of function mutation in its tethered ligand domain(2, 9, 10) . This receptor could be activated by free synthetic agonist peptide but, lacking its own functional tethered ligand, could not be activated by thrombin(2) . Signaling in response to thrombin in the co-expression system thus reflected intermolecular ligation of the target receptor by a member of the library. Of the first 9 pools tested, 3 clearly conferred thrombin-dependent signaling when co-expressed with the F43A receptor (Fig. 2). From the most active of these pools, a single clone that conferred signaling was isolated by sib selection.
Figure 1: Tethered ligand library design. The library utilized the thrombin receptor's amino-terminal exodomain fused to a transmembrane domain to display potential tethered agonists on the oocyte surface. The thrombin receptor's native agonist peptide SFLLR was replaced with random pentapeptide sequence (indicated by the various shapes) so that cleavage of the library by thrombin would unmask a set of potential tethered peptide agonists. When co-expressed with a target receptor in Xenopus oocytes, a member of the library bearing an appropriate tethered ligand sequence (opendiamond) intermolecularly ligands and activates the target receptor. Functionally this is seen as thrombin-triggered signaling.
The predicted amino acid sequence of this clone's tethered ligand domain was GFIYF. A synthetic peptide mimicking this domain was nearly as effective as the SFLLR peptide, which mimics the native tethered ligand sequence (Fig. 3A). Moreover, a mutant thrombin receptor in which the GFIYF sequence replaced the native SFLLR sequence signaled as effectively as wild type receptor in response to thrombin (Fig. 3B).
Figure 3:
Thrombin receptor response to the new
agonist GFIYF. A, responses to free agonist peptides.
Epitope-tagged wild-type human thrombin receptor (3, 24) was expressed in Xenopus oocytes, and
agonist-induced Ca release was assayed as in Fig. 2. The peptides tested were GFIYFNPNDK (``GFIYF . . .
,'' opensymbols) and SFLLRNPNDK (``SFLLR .
. . ,'' closedsymbols). The peptides were
extended at their carboxyl termini with native receptor sequence to
circumvent solubility problems with the pentapeptides. The added
sequence does not contribute to agonist
activity(9, 10) . Peptides were synthesized and high
pressure liquid chromatography purified as previously
described(10) . Signaling in response to GFIYF was receptor
dependent; GFIYF did not cause signaling in uninjected oocytes or in
oocytes expressing the formyl peptide receptor (not shown). B,
dose response of wild-type versus GFIYF mutant thrombin
receptor to thrombin. Xenopus oocytes were microinjected with
12.5 ng of cRNA encoding epitope-tagged wild-type thrombin receptor (opensymbols) or a mutant thrombin receptor in which
GFIYF replaced SFLLR (closedsymbols), the endogenous
tethered ligand domain. Surface expression levels were shown to be
similar for the two receptors by antibody binding as
described(3, 24) . Thrombin-induced
Ca
release was determined (Fig. 2). Like signaling to thrombin,
signaling to exogenous SFLLRN agonist peptide was also
indistinguishable in oocytes expressing the wild-type versus GFIYF mutant receptors (not shown). Data shown in A and B are the means of duplicate determinations. Standard
deviations were typically less than 20% of the means. These experiments
were replicated three times with similar
results.
The sequence of this new agonist is striking in the context of known thrombin receptor agonist peptide sequences and structure-activity relationships (Table 1). The protonated amino group at the amino-terminal of all thrombin receptor peptide agonists (the group corresponding to that created by receptor cleavage) is critical for agonist function, and small neutral residues are preferred at agonist position 1. The conserved phenylalanine at position 2 is critical for agonist function(9, 10) . Hydrophobic residues are preferred at positions 3 and 4. All of these features are captured in GFIYF. Moreover, the phenylalanine at position 5 in the GFIYF peptide is seen in the Xenopus thrombin receptor's tethered ligand sequence. Thus, tethered ligand library selection ``evolved'' an agonist that shares critical features with the known naturally occurring thrombin receptor tethered ligand sequences. A unique feature of the GFIYF agonist, however, is its lack of a basic residue. All of the known tethered ligand sequences sport an arginine at either position 3 or 5, raising the possibility that these arginines serve functions beyond receptor activation in the native receptor and its cellular context.
Can this technique be used
to find agonists for receptors that are not naturally activated by a
tethered ligand mechanism? To test this question, we co-expressed pools
representing 10,000 independent tethered ligand library clones with a
variety of potential targets: the 5HT1c(11) ,
2-adrenergic(12) , interleukin-8(13) ,
MCP-1(14) , formyl peptide(15) , or RTA (16) receptors. A pool with agonist activity for the formyl
peptide receptor was immediately identified even at this relatively low
level of complexity. We subsequently screened 11 subpools of 800
independent clones each for activity at the formyl peptide receptor.
The most active of these was serially subdivided, and a single cDNA
that conferred thrombin-dependent signaling when co-expressed with the
formyl peptide receptor was identified by sib selection. The tethered
ligand sequence in this clone was MMWLL. A synthetic peptide mimicking
this domain was nearly as active as the classical formyl peptide
receptor agonist, fMLF (formyl-Met-Leu-Phe) (Fig. 4). The
amino-terminal methionine and the hydrophobic nature of the MMWLL
sequence was consistent with published structure activity studies for
formyl peptide receptor agonists(17, 18) . However,
the level of activity shown by the MMWLL peptide was surprising given
its lack of an amino-terminal formyl group. The formyl group of fMLF is
essential for significant biological
activity(17, 19) , and unformylated MLF was indeed at
least 1000-fold less active than fMLF in this system. Addition of an N-formyl group to MMWLL yielded a 1000-fold increase in the
potency of this new agonist, and fMMWLL agonist was reproducibly more
potent than fMLF itself (Fig. 4). Thus, the amino-terminal
formyl group probably provides new interactions important for
activating the formyl peptide receptor, but MMWLL contains sufficient
information by itself to function as an agonist. These data suggest
that the formyl peptide receptor, thought to be important for mediating
chemotaxis toward N-formylated bacterial proteins, remains
competent to respond to certain unformylated peptides and may have
evolved from a pre-existing peptide receptor. Whether endogenous
unformylated peptide agonists for this receptor exist is unknown.
Figure 4:
Comparison of formyl peptide receptor
responses to the classical agonist fMLF versus the new agonist
derived from tethered ligand library. Human fMLF receptor cDNA (15) was subcloned into pFROG. Xenopus oocytes were
microinjected with 5 ng of cRNA transcribed from this construct and
then cultured for 24 h. Ca release in response to the
indicated concentration of the peptides MMWLL (closedtriangle), MLF (opentriangle), or to
their respective N-formylated forms fMMWLL (closedcircles) or fMLF (opencircles) was
then determined. Data shown represent mean ± S.D. (n = 2). This experiment was replicated
twice.
The ease with which agonists were identified using the tethered
ligand library prompts speculation regarding the evolutionary origin of
protease-activated receptors such as the thrombin receptor and
protease-activated receptor 2(20) . Of 3.2 10
possible tethered ligand sequences in the library, only 36,000
were screened to find a thrombin receptor agonist and 10,000 to find a
formyl peptide receptor agonist. From the prevalence of positive pools
in the library, we estimate that at least 1 in 10,000 tethered ligand
sequences had some agonist activity at the thrombin receptor or the
fMLF receptor. The intermolecular liganding relied upon in these
screens is much less efficient than the intramolecular liganding that
mediates activation of native protease receptors(2) . Moreover,
the tethered ligand in the intact receptor is quite tolerant of amino
acid substitutions; alanine substitution at agonist positions 3, 4, and
5 cause loss of function in the free agonist peptide but not the intact
receptor(1, 10, 21) . Because of the kinetic
advantages conferred by tethering, sequences capable of functioning as
tethered ligands may have appeared relatively frequently in the
amino-terminal exodomain of peptide receptors during their evolution.
An early protease-activated receptor may thus have arisen from a
pre-existing peptide receptor when mutation created a protease cleavage
site amino-terminal to a potential tethered ligand sequence.
In summary, the tethered ligand library method has identified new agonists for two ``peptide'' receptors. The new agonists revealed both expected and unexpected features. The tethering feature of this method provides an advantage over use of free peptides for identifying low affinity leads, and use of signaling as a readout selects for agonists over antagonists. The extent to which this technique can be applied to other G protein-coupled receptors and signaling molecules remains to be determined. Adaptation of this approach to yeast (22) or mammalian cell systems (23) that provide functional readouts for receptor activation may broaden the applicability of this technique by providing higher throughputs. In principle, the tethered ligand library provides a rapid means of establishing consensus sequences for peptide agonists to aid structure-activity studies as well as a method for identifying agonists for orphan receptors.