1. Introduction

Anticalin proteins are derived from natural lipocalins via combinatorial protein design and directed evolution to recognize a variety of medically relevant target molecules, thus offering prospects for theranostic applications (Deuschle et al., 2021; Rothe & Skerra, 2018). With as low as 10% mutual amino-acid sequence identity, the natural members of the lipocalin protein family exhibit a highly conserved cup-shaped fold which is dominated by a central β-barrel made of eight antiparallel β-strands with an adjacent α-helix (Skerra, 2000). An extended ligand pocket is shaped by four structurally variable loops at the open end of the β-barrel, which leads to diverse ligand-binding activities for the natural lipocalins (Breustedt et al., 2006; Schiefner & Skerra, 2015). In connection with methods of targeted random mutagenesis and molecular selection, this molecular architecture enables the reshaping of the lipocalin binding site to tightly bind a wide range of prescribed molecular targets from small molecules through peptides to proteins (Richter et al., 2014). In fact, the mode of ligand binding by the resulting Anticalin proteins resembles the well known recognition of antigens via the six complementarity-determining regions (CDRs) of antibodies (Skerra, 2003; Achatz et al., 2022).

Colchicalin was developed against the plant poison colchicine starting from human lipocalin 2 (Lcn2; Gebauer & Skerra, 2012; Barkovskiy et al., 2019). After selection from a naïve random library and several cycles of affinity maturation, the Anticalin D6.2 (the V69M/I80T/F83L triple mutant of the initial hit D6.1) revealed a remarkably low K_d value of 120 pM. The most significant mutation during this maturation process, Val69 to Met, led to a tenfold increase in affinity, but at the expense of higher oxidation sensitivity due to the introduction of a surface-exposed methionine residue (Teh et al., 1987). Consequently, Met69 was replaced by the chemically more robust and hydrophilic glutamine side chain with a similar size. The resulting variant, D6.3, retained a picomolar affinity towards colchicine. An N-terminally truncated version of D6.3, Δ4-D6.3 (also devoid of an affinity tag), was crystallized in complex with colchicine (Barkovskiy et al., 2019). Its X-ray structural analysis confirmed the canonical molecular architecture of the lipocalin fold, with the deeply embedded ligand in the central cavity at the open end of the β-barrel. While major structural rearrangements of the variable loop region were observed in comparison to the wild-type Lcn2 scaffold (Barkovskiy et al., 2019), including a unique cis-proline bond between Phe71 and Pro72, it was unclear whether these changes were a consequence of the amino-acid exchanges that had been introduced into the loop region of the protein scaffold or were driven by complex formation with the ligand.

Whereas the antigen-binding sites of antibodies (immuno­globulins, Igs) can exist in a preformed high-affinity conformation towards their molecular target and associate with it via a rigid lock-and-key mechanism (Al Qaraghuli et al., 2021), an ability to structurally adapt to the cognate ligand has been elucidated in several instances (Al Qaraghuli et al., 2020, 2021; Stanfield & Wilson, 1994). The corresponding rearrangements extend from local changes within CDRs that directly interact with the antigen to more complex alterations in quaternary structure that affect the angle of V_H/V_L pairing and may even propagate further into the constant Ig region (Rini et al., 1992; Al Qaraghuli et al., 2020, 2021; Stanfield & Wilson, 1994).

Such spatial shifts in the hypervariable loops of the antibody in response to antigen binding can be described by two alternative mechanisms: (i) induced fit and (ii) conformational selection. In the case of induced fit, initial contact formation with the antigen is followed by conformational rearrangement of the binding site, which eventually results in tight complex formation (Stanfield & Wilson, 1994; Rini et al., 1992; Berger et al., 1999). On the other hand, conformational selection depends on the simultaneous population of both high- and low-affinity conformations of the ligand-free state of the antibody (Rini et al., 1992; Berger et al., 1999); thus, the target molecule can engage with the fraction of the antibody in the structurally more competent conformation, even though its proportion may be low. This results in a shift of the (bio)chemical equilibrium between the (at least) two different conformations according to the principle of Le Chatelier. However, in the majority of practical instances it has to be assumed that a combination of both mechanisms contributes to antigen recognition (Berger et al., 1999).

Notably, structural rearrangements in response to ligand binding have been reported for several Anticalins where X-ray structures have been elucidated for both the complex and the free state (Schönfeld et al., 2009; Kim et al., 2009; Dauner et al., 2018). In these cases a simple induced-fit mechanism was sufficient to describe the observed structural change, as an open pocket was observed in the unbound state, thus offering unhindered access by the ligand, followed by structural adaptation. Here, we report the three-dimensional structure of Colchicalin D6.2 in its ligand-free state, which unexpectedly reveals a closed binding site, indicating the need for considerable conformational rearrangement prior to complex formation with colchicine.

2. Materials and methods

3. Results

The crystal structure of Colchicalin D6.2 in the absence of its cognate ligand was solved at a resolution of 1.8 Å by molecular replacement using the previously published coordinate set of the Colchicalin–colchicine complex (Barkovskiy et al., 2019; Table 1). The refined structural model, with one protein molecule in the asymmetric unit in space group I222, comprises residues Ser5–Ile176 with continuous electron density. To compare the structure of the D6.2 apoprotein with the previously described crystal structure of Colchicalin Δ4-D6.3 in complex with colchicine (Barkovskiy et al., 2019) and to study the mechanism of ligand binding, the coordinate sets were superimposed (Figs. 1 and 2). In accordance with previous investigations of other engineered lipocalins (Richter et al., 2014; Achatz et al., 2022), the β-barrel fold remained fully preserved irrespective of the presence of colchicine, with a root-mean-square deviation (r.m.s.d.) of 0.4 Å for the 58 C^α atoms of the β-barrel that are structurally conserved across the lipocalin protein family (Skerra, 2000).

Table 1 Crystallographic data and refinement statistics Values in parentheses are for the highest resolution shell. Data collection  Space group I222  a, b, c (Å) 38.6, 75.6, 116.1  α, β, γ (°) 90.0, 90.0, 90.0  Resolution range (Å) 63.34–1.78 (1.88–1.78)  〈I/σ(I)〉 6.5 (1.8)  Rmerge (%) 6.0 (41.8)  Observed/unique reflections 175641/16656  Completeness (%) 99.6 (99.8) Refinement statistics  Rcryst/Rfree (%) 20.1/25.9  No. of protein atoms 1404  No. of water molecules 61  Average B factor (Å2)   Protein 45.4   Solvent 39.1  Ramachandran analysis†   Core (%) 86.5   Allowed (%) 12.8   Generously allowed (%) 0.0   Disallowed (%) 0.7 †Calculated with PROCHECK (Laskowski et al., 1993).

Figure 1 Comparison of Colchicalin in the presence or absence of the ligand colchicine. (a) Amino-acid sequence alignment of Colchicalin D6.2, crystallized in this study without ligand, with the previously crystallized Colchicalin Δ4-D6.3 in complex with colchicine (Barkovskiy et al., 2019) as well as wild-type Lcn2. Positions Ile97, Lys98 and Ser99 on loop #3, which do not directly contact the ligand, exhibit the largest deviation between the apo and complexed states of Colchicalin and are marked in blue. (b) Overall architecture of the previously described Colchicalin Δ4-D6.3 in complex with colchicine (orange). (c) Overall architecture of Colchicalin D6.2 in its apo state. The marked conformational rearrangement of loop #3 is evident (loops colored magenta and cyan, respectively). (d) Spatial deviation between Cα positions in the crystal structure of apo Colchicalin versus the Colchicalin–colchicine complex after superposition via the 58 conserved Cα atoms in the lipocalin fold (Skerra, 2000). The structurally variable loop regions 1–4 are indicated. Note the high values for loop #3. (e, f) B-factor plots for the two Colchicalin crystal structures. The average B-factor values are shown separately for the main-chain atoms (solid lines) and side-chain atoms (broken lines) of each residue in the apoprotein (e) and the Colchicalin–colchicine complex (f).

Figure 2 X-ray crystallographic analysis of Colchicalin in the apo form compared with its complex with colchicine. (a) Superposition of Colchicalin D6.2 in the apo state (loops in cyan) with Colchicalin Δ4-D6.3 in complex with colchicine (PDB entry 5nkn; loops in violet). (b) Binding mechanism for colchicine. In the apo state the side chains of Ile97 in loop #3 and of Phe71 in loop #2 point into the ligand pocket (cyan). In the complex, the drastic rearrangement of loop #3 in combination with the (upward/outward) side-chain flip of Phe71 enables the tight fit of colchicine within the ligand pocket. Of note, the cis-peptide bond between Phe71 and Pro72 in loop #2 is present in both structures. (c) Side-chain conformations of Met69 in the apo structure in comparison with Gln69 in the structure of the ligand complex. The carboxamide group of glutamine forms an additional hydrogen bond to the main-chain O atom of Ala52 (red dashed line). (d) A concerted change in side-chain conformations upon colchicine binding. In the complex, the side chains of Met51 at the C-terminal end of loop #1 and Met73 in loop #2 (violet) are directed towards the bound colchicine, whereas in the apo state they point away from the binding site. It seems that the inward movement of the Phe71 side chain in the apoprotein drags along the neighboring residue Met73 in loop #2, whose bulky side chain laterally pushes aside that of Met51 in loop #1.

However, a much higher overall r.m.s.d. of 2.1 Å was calculated upon pairwise superposition of all 172 C^α atoms (Ser5–Ile176), which was mainly due to the markedly different conformations of the four loops that form the binding site (Fig. 1d). The size of the ligand pocket in the apoprotein is 17 × 17 Å (measured between the C^α atoms of the residue pairs Gly40/Pro101 and Phe71/Arg130, respectively) compared with dimensions of 15 × 20 Å in the complex between Colchicalin and colchicine. The side-chain conformation of Met69 in D6.2 on the surface of the β-barrel, the only differing amino acid between the structures (apart from the four N-terminally deleted residues in Δ4-D6.3 and the unresolved start methionine residue in D6.2), is very similar to that of its counterpart glutamine in the complex of Δ4-D6.3 with colchicine. In the latter structure an additional hydrogen bond can be seen between the side chain of Gln69 and the backbone O atom of Ala52 (Fig. 2c).

Regarding the complex formation with colchicine, structural effects on the ligand pocket of the engineered lipocalin are evident for the side chains of Met51, Phe71 and Met73 (Table 2). These are directed away from the binding site in the apo state, whereas in the complex they point towards the bound colchicine (Fig. 2d). This concerted side-chain re­orientation is accompanied by conformational changes in all four structurally variable loops at the entrance to the ligand pocket. For example, in the apo state loop #1 is slightly bent towards the binding pocket, with a maximum deviation of 3.5 Å at Ile49 (C^α atom). Notable structural deviations are also seen for loop #4, the N-terminal part of which, up to Gln128, is bent outwards by up to 3.7 Å, whereas the following segment is directed inwards by up to 3.6 Å at Arg130 (C^α atom). Interestingly, while the side chain of Phe71 is buried in the pocket of the apoprotein and swings out in the ligand complex, the cis-peptide configuration of the peptide bond to the following residue, Pro72, in loop #2 remains preserved between both states.

Table 2 Structural alterations in apo Colchicalin upon binding colchicine Residue Cα deviation† (Å) Region Val33 0.4 β-Strand A Val36 0.3 β-Strand A Gly40 1.4 Loop #1 Phe41 2.7 Loop #1 Met51 2.3 Loop #1 Thr54 0.3 β-Strand B Tyr56 0.7 β-Strand B Val66 0.5 β-Strand C Phe68 0.3 β-Strand C Met/Gln69 0.2 β-Strand C Lys70 1.8 Loop #2 Phe71 1.7 Loop #2 Met73 2.2 Loop #2 Met79 0.4 β-Strand D Asp81 0.6 β-Strand D Leu94 0.2 β-Strand E Gly102 4.8 Loop #3 Thr104 1.4 Loop #3 Trp106 0.1 β-Strand F Phe123 0.2 β-Strand G Arg130 3.6 Loop #4 Asp132 0.3 Loop #4 Phe134 0.2 β-Strand H Thr136 0.3 β-Strand H Tyr138 0.4 β-Strand H †Distances between Cα atoms in the apoprotein (PDB entry 6z6z) and Colchicalin in complex with colchicine (PDB entry 5nkn) for those residues which form contacts to the bound ligand after superposition of both crystal structures via the 58 conserved Cα positions in the lipocalin fold (Skerra, 2000).

Remarkably, the largest deviation occurs at Gly95–Ser105 in loop #3, which is bent inwards in the apo­protein by up to 11.1 Å at the C^α atom of Lys98 (which is not in contact with the bound ligand) in both states after superposition via the set of 58 conserved C^α atoms (see Figs. 1b and 2b). As a result, the side chain of Ile97 occupies the ligand pocket together with the Phe71 side chain in its altered conformation as described above. While Phe71 rests in a position that is otherwise filled by the trimethoxyphenylene moiety (ring A), Ile97 replaces the aminocyclohexyl ring (B) of the bound colchicine in the complex. Conversely, loop #3 is bent outwards in the colchicine complex, thus providing space for the ligand. Calculation of the ligand-pocket volumes using CASTp (Tian et al., 2018) led to 343 ų for the Colchicalin–colchicine complex (after removal of the ligand) compared with a much smaller value of 63 ų for the apo state, which clearly demonstrates the functional effect of the change in loop conformation.

The fact that loop #3 gives rise to this kind of steric hindrance for colchicine binding in the present crystal structure suggests the presence of at least one additional conformation with an accessible binding pocket in the apo state of Colchicalin, presumably in a low proportion in solution, in order to provide a mechanism for complex formation with colchicine. Interestingly, a three-dimensional structure prediction based on the amino-acid sequence of Colchicalin using the AlphaFold2.0 system (Jumper et al., 2021) did not provide any indication of alternative loop conformations in this engineered lipocalin. In both cases, all five most highly ranked models resembled the loop conformations of the wild-type Lcn2 protein, the crystal structure of which differs considerably from Colchicalin both in the apo and the holo state in all loops except for loop #1 (Achatz et al., 2022).

A potential influence of crystal packing on the conformation of loop #3 in the structure of the apo state can be excluded as the entire loop resides in a solvent-filled channel within the crystal. Nevertheless, the backbone is well defined in the electron density and the entire loop shows low B factors (Fig. 1e). On the other hand, residues 97–103 at the tip of the loop are poorly defined in the crystal structure of the Colchicalin–colchicine complex, which is reflected by high local B factors (Fig. 1f) and could indicate multiple populated conformational states in this region. However, without doubt Ile97 points away from the binding pocket, which is fully occupied with the ligand in the complex.

Of note, during refinement of the crystal structure additional 2F_o − F_c electron density with a spherical shape appeared near loop #3 of apo Colchicalin. Considering that the precipitant solution contained 200 mM CaCl₂, a Ca²⁺ ion was modeled at this position (B factor 25.3 Ų), leading to an octahedral coordination sphere involving Gly95 (main-chain carbonyl), Asn96 (side-chain carboxamide), Glu100 (side-chain carboxylate) and Thr104 (main-chain carbonyl) as well as two water molecules. However, a pentagonal bipyramidal coordination is preferred in natural calcium-binding sites and often more than one side-chain carboxylate groups are found as ligands (sometimes in a bidentate fashion; Kirberger et al., 2008). Still, the question arose whether binding of the calcium ion in the crystallized protein may play a role in the new conformation of loop #3.

In fact, such a metal-induced conformational change should strongly influence the affinity towards colchicine as loop #3 harbors several ligand-contacting residues: Glu100, Pro101, Gly102 and Tyr103 (Fig. 3). Thus, we measured the colchicine-binding activity of the D6.2-His₆ protein by fluorescence titration in the presence or absence of 200 mM CaCl₂. As a result (Fig. 3b), there was no detectable effect on the K_d value for colchicine, even at such a high concentration of calcium. Therefore, coordination of the calcium ion is most likely to be an accidental consequence of crystal packing (which occurs in space group I222 for apo Colchicalin compared with P4₁22 for the Colchicalin–colchicine complex) and is functionally irrelevant.

Figure 3 The role of a bound Ca2+ ion in the crystal structure of ligand-free Colchicalin. (a) A Ca2+-binding site with octahedral coordination in the crystal structure of the apoprotein. The four residues that contact the metal ion, two side chains and two main-chain carbonyl O atoms, as well as two coordinating water molecules, are depicted as sticks or small spheres. The 2Fo − Fc electron density around the Ca2+ ion is shown contoured at 5σ. (b) Fluorescence titration of Colchicalin D6.2 with colchicine in the presence or absence of 200 mM CaCl2 reveals no significant influence on the ligand affinity.

4. Discussion

Prior to this study, evidence for structural adaptation of an engineered lipocalin loop region to the bound target has only been observed in a few cases when investigating X-ray structures of both ligand-free Anticalins and their complexes (Kim et al., 2009; Dauner et al., 2018; Schönfeld et al., 2009). For instance, comparison of the unbound Anticalin Tb7.14 (PDB entry 3dtq) with the closely related mutant Tb7N9 in complex with Y³⁺-DTPA (PDB entry 3dsz) revealed only minor shifts of loops #2, #3 and #4, with the largest deviation of 1.3 Å seen for Gly102 in loop #3. Loop #1 displayed considerable backbone plasticity but was not involved in ligand contacts (Kim et al., 2009). In another structural analysis, a comparison between Petrocalin with the bound ligand petrobactin and the ligand-free lipocalin (PDB entries 6gqz and 6gr0, respectively) indicated larger rearrangements within the loop region. Loop #2 moved 4.3 Å and loop #3 moved 2.0 Å towards the bound ligand (measured at the C^α atoms of Glu74 and Ser99 of chain A, respectively), thus providing evidence for an induced fit upon complex formation (Dauner et al., 2018). Finally, in the case of the Anticalin PRS-050, which binds the protein target CTLA-4, significant conformational rearrangements of loops #2, #3 and #4 were measured as result of complex formation (PDB entries 3bx7 and 3bx8, respectively). In fact, a pronounced induced fit was observed for loops #3 and #4, which changed their conformations from disordered to ordered in the corresponding X-ray structures (Schönfeld et al., 2009).

Compared with these previous examples, the movement of loop #3 by ∼11 Å in the Colchicalin structure as a result of ligand binding is by far the largest structural change. Remarkably, the binding site is occupied by Ile97, together with Phe71 in loop #2, in the apo state and loop #3 has to move outwards from the ligand pocket in order for colchicine to find its place. Hence, an `induced fit' in the conventional sense, where a target complex is initially formed and then triggers conformational changes, cannot apply. Instead, it is more plausible to assume that both observed conformations of loop #3 exist in the apo state, with the open conformation probably less occupied but still sufficiently available for complex formation with colchicine, which is accompanied by a shift in the equilibrium (Fig. 4). This kind of mechanism would be in accordance with the concept of `conformational selection' (Berger et al., 1999). Whether loop #3 may exhibit additional conformations in solution, or even might be fully mobile, remains to be studied, for example using NMR analysis.

Figure 4 Schematic illustration of the principle of conformational selection upon the binding of colchicine to Colchicalin. Prior to complex formation, Colchicalin exists in solution in at least two states, one with an open and one with an occluded ligand pocket, and only the open state can accommodate colchicine.

It has previously been recognized that the binding mode of both natural and engineered lipocalins to their target molecules resembles the interaction between antigens and immunoglobulins (Skerra, 2003). In the case of antibodies, six hypervariable loops (also known as complementarity-determining regions, CDRs) are mounted on a conserved β-sandwich framework and govern the specific and tight complex formation with the antigen. This molecular architecture is comparable to the lipocalins, where the four structurally variable loops that form the cup-shaped binding site are supported by a rigid β-barrel.

For antibodies, two distinct modes of target binding have been observed: (i) a rigid lock-and-key interaction and (ii) varying degrees of conformational rearrangement upon complex formation. As mentioned further above, in principle two mechanisms of spatial adaptation have been recognized: (i) induced fit, in which conformational alteration follows ligand binding, and (ii) conformational selection, which is based on a pre-existing mixture of conformational states (Rini et al., 1992; Berger et al., 1999).

To date, studies of engineered lipocalins have provided evidence for induced fit upon ligand binding, including significant backbone rearrangements of the loop region towards the bound target molecule that were accompanied by shifts and rotations of individual amino-acid side chains (Schönfeld et al., 2009; Kim et al., 2009; Dauner et al., 2018). In the present study, we observed the largest shift to date of a structurally variable loop (loop #3) associated with ligand binding in the case of an Anticalin selected against colchicine. Together with a side-chain flip of Phe71 by about 120°, and a few less drastic side-chain alterations, this movement, starting from the apo state, creates a perfectly complementary pocket to the tricyclic colchicine ligand, whereas the β-barrel scaffold remains structurally unchanged. Conversely, due to the peculiar conformations of loop #3 and Phe71 in the unbound state, colchicine is sterically hindered from forming an initial complex with Colchicalin.

Therefore, it is reasonable to assume that the open conformation must also exist in the absence of the ligand, possibly with a scarce population, such that the binding site is fundamentally accessible. Hence, the mechanism of conformational selection appears to describe the mode of binding for this Anticalin more accurately (Fig. 4). While it cannot be fully excluded that the structure of the binding site in either the apo or the holo state of Colchicalin, as evident from the X-ray analyses, is influenced by the crystal environment (such as the bound calcium ion from the precipitant solution or direct/indirect packing contacts with a neighboring molecule), the manner in which the side chains of Phe71 and Ile97 occupy the same pocket in the apo state where the ligand colchicine is bound in the complex is compelling.

Taken together with the previous studies mentioned above, the case of the Colchicalin–colchicine pair with its distinct protein conformations in the presence and absence of the ligand provides another example that nicely illustrates the structural and functional analogy between (engineered) lipocalins and antibodies with regard to the mechanisms of ligand/antigen recognition.