I-BRD9

Insight into Selective Mechanism of class of I-BRD9 Inhibitors toward BRD9 Based on Molecular Dynamics Simulations
Jing Su1, Xinguo Liu1*, Shaolong Zhang1, Fangfang Yan1, Qinggang Zhang1 and Jianzhong Chen 1*

1School of Physics and Electronics, Shandong Normal University, Jinan, 250358, China;

2School of Science, Shandong Jiaotong University, Jinan, 250357, China

*Corresponding Author Information: Xinguo Liu ([email protected]), Jianzhong Chen ([email protected], [email protected]).

This article has been accepted for publication and undergone full peer review but has not been through the copyediting, typesetting, pagination and proofreading process, which may lead to differences between this version and the Version of Record. Please cite this article as doi: 10.1111/cbdd.13398

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ABSTRACT

Recently, bromodomain containing protein 9 (BRD9), 7 (BRD7) and 4 (BRD4) have been potential target of anti-cancer drug design. Molecular dynamic (MD) simulations followed by molecular mechanics Poisson-Boltzmann surface area (MM-PBSA) calculation were performed to study the selective mechanism of I-BRD9 inhibitor H1B and its derivatives N1D, TVU and 5V2 toward BRD9 and BRD4. The rank of our calculated binding free energies agrees with that of the experimental data. The results show that binding free energy of H1B to BRD7 is slightly lower than that of H1B to BRD9, and all four inhibitors bind more tightly to BRD9 than to BRD4. Decomposition of binding free energies into individual residues implies that Ile164 and Asn211 in BRD7 and Ile53 and Asn100 in BRD9 play significant role in selectivity of H1B toward BRD7 and BRD9. Besides, several key residues Phe44, Ile53, Asn100, Thr104 in BRD9 and Pro82, Lys91, Asn140, Asp144 in BRD4 that are located in the ZA-loop and BC-loop provide significant contributions to binding selectivity of inhibitors to BRD9 and BRD4. This study is expected to provide important theoretical guidance for rational designs of highly selective inhibitors targeting BRD9 and BRD4.
KEYWORDS: Molecular dynamics simulations, Molecular mechanics, Bromodomain-containing protein, Selectivity, MM-PBSA

1 | INTRODUCTION

Post-translational modification of chromatin is an important composition of epigenetic code. Regulating of nucleosome positioning along DNA by chromatin remodeling complexes is required for variety of process such as chromatin organization, transcriptional regulation and DNA repair[1-8]. Recently, some studies begin to focus on one of four mammalian chromatin remodeling complexes, namely the mammalian switch/sucrose nonfermentable (SWI/SNF) complex[9,10]. Mutations in components of SWI/SNF complexes alter activity of the complexes and play an important role in tumor formation[11,12]. Remodeling and modifying complexes can mediate specific protein–protein and protein–nucleic acid interactions, which is critical for appropriate regulation of chromatin.
Bromodomain containing proteins (BRDs) are closely related with various epigenetic regulatory functions. Among BRDs, bromodomain containing protein 9 (BRD9) is a specific protein and has displayed different physiological functions in multiple tissues. Compared to the other BRD containing proteins such as bromodomain and extra terminal (BET) family members[13-17], especially BRD4(1), little is known about the role of separate residues in molecular structure of BRD9. Recent studies pointed out that BRD9 is a core subunit of SWI/SNF complexes and plays a part role in leukemia growth[12,18]. This protein is required for the proliferation of acute myeloid leukemia (AML) cells[19]. In non-small cell lung cancer (NSCLC) tumber samples, BRD9 has been identified as part of a group of copy number variant genes, which suggests that chromosome imbalance in BRD9 may be associated with tumorigenesis[20]. A similar analysis of cervical cancer samples also found abnormalities in
BRD9 protein[21]. The above evidences indicate that BRD9 plays an important role in regulation

of human transcription and diseases. Although some works have reported different selective inhibitors of BRD9, specific role of separate residues in bindings of inhibitors to BRD9 is not still clear. In addition, bromodomain containing protein 7 (BRD7) is a paralog protein of BRD9 and belongs to a subunit of poly-bromo-associated BAF SWI/SNF complexes[22]. BRD9 and BRD7 are involved in oncology growth and have been potential drug targets[23]. Based on importance of these two proteins, some related works have focused on insight into binding modes of inhibitors to BRD9 and BRD7. For example, Martin et al. identified two potent chemical probes BI-7273 and BI-9564 that is useful for further studying BRD9 function in both in vitro and in vivo settings and their work also revealed key residues involving
inhibitor-protein interaction, among which BI-9564 displays >30-fold selectivity toward BRD9 over BRD7[18]. Theodoulou et al. identified a potent compound I-BRD9 through structure-based design and this inhibitors shows > 200-fold selectivity toward BRD7 relative to BRD9[24].
Therefore, it is of significance to further probe interaction mechanism of inhibitors with residues in BRD9, BRD7 and BRD4 at atomic level for design of more efficient anticancer drugs targeting BRDs.
Bromodomains are highly conserved protein modules, including approximately 110 amino acids[13,25-27]. The topology structures of the conserved domains in BRD9, BRD7 and BRD4 consist of four alpha-helices (αZ, αA, αB and αC) and two flexible loop regions (ZA-loop and BC-loop). This topology forms basis of the acetyl-lysine (Kac) binding pocket[28]. The binding sites of inhibitors to BRD9 and BRD4 are shown in Figure 1a-b. To measure structural similarity of BRD9, BRD7 and BRD4, the superimposed structures of these three proteins are

displayed in Figure 1c. It can be seen that the structures of BRD7 and BRD9 are very similar and their main structural differences mainly stem from the ZA-Loop.
By now, three BRD9 inhibitors LP99[29], ketone “compound 28”[23] and I-BRD9 [24] have been reported. LP99 is the first inhibitor and its structure is designed using a methylquinolinone scaffold[29], ketone “compound 28” is derived from a keto-indolizine BAZ2A/B chemical probe[23,30], and I-BRD9, a potent cell-active selective binder to BRD9, is developed based on a thienopyridone scaffold. The class of I-BRD9 inhibitors has been well proposed in the work of Theodoulou et al (2016), and molecular structure of I-BRD9 (H1B) is shown in Figure 1d. To probe binding modes of inhibitors to BRDs, we carried out detailed insight into binding selectivity of I-BRD9 toward BRD9 and BRD7. Meanwhile, three derivations N1D, TVU and 5V2 of I-BRD9 were selected to clarify their selective mechanism toward BRD9 and BRD4 by using molecular dynamic (MD) simulation[31-38] and binding free energy calculations[39-44]. Nine complexes composed of these four inhibitors and three proteins are H1B-BRD9/BRD7/BRD4, N1D-BRD9/BRD4, TVU-BRD9/BRD4 and 5V2-BRD9/BRD4. The reason why we select these three derivations is based on the following facts: (1) 5V2 has similar structure to H1B, (2) selectivity of N1D toward BRD9 and BRD4 is quite different in experiments, (3) TVU has similar binding ability to BRD9 and BRD4. The structures of these inhibitors are displayed in Figure 1d. We expect that this study can provide theoretical guidance for designs of potent inhibitors targeting BRDs.

2 | COMPUTATION DETAILS

2.1 | System Setups

The structures of BRD9 coupled with inhibitors H1B, N1D, TVU and 5V2, separately corresponding to 4UIW, 4UIT, 4UIU and 4UIV[24], were obtained from protein data bank (PDB), while the ones of BRD4 complexed with inhibitors N1D, TVU and 5V2 were taken from 4UIZ, 4UIX and 4UIY , respectively[24]. However, due to lack of crystal structures of BRD7 and BRD4 complexed with H1B, autoDock 4.2 software was applied to dock H1B into binding pocket of BRD7 and BRD4[45]. The initial structures of BRD7 and BRD4 were taken from PDB ID:2I7K (BRD7)[28] and PDB ID:2OSS (BRD4)[14]. These two structures were minimized to eliminate bad contacts. During docking, the grid box in (x, y, z) direction was set to (60, 60, 60) Å and the spacing value is 0.375 Å. The inhibitor–protein docking was performed using the Lamarckian genetic algorithm (LGA), and the parameters were set to the default values of the software. The docked conformations were clustered using a tolerance of 2 Å root-mean-square deviations and evaluated for the final best docking structure according to the binding free energy. The above nine structures were used as the initial models of MD simulations. All crystal water molecules were retained in the initial models. The missing hydrogen atoms were added to the system by using the Leap module of Amber16[46]. The AM1 method in Antechamber module was employed to perform bond-charge correction (BCC) calculations and the BCC charges were assigned to atoms of inhibitors[47]. The force field

parameters of H1B, N1D, TVU and 5V2 were generated by using general amber force field (GAFF)[48], while the parameters of proteins and water molecules were derived from the standard Amber force field ff99SB[49]. An appropriate number of counterions were added to maintain the neutral charge state of each system. Then each system is placed in a truncated octahedron box of TIP3P water molecules, and the distance between the edges of the water box and the closest atom of solutes was at least 12.0 Å[50].

2.2 | MD Simulations

All MD simulations were carried out by using the PMEMD module in Amber16[46]. In order to remove bad contacts between complexes and solvent molecules, energy minimizations were performed in two stages. A harmonic constraint of a strength of 100 kcal/mol· Å−2 is exerted on these nine complexes to minimize counterions and water molecules. Then, all atoms were freely relaxed by eliminating the restriction. The systems were minimized by steepest descent minimization of 2500 steps followed by conjugate gradient minimization of 2500 steps. The Particle Mesh Ewald (PME) method was used to treat the long-range electrostatic interactions in a periodic boundary condition[51,52]. All the covalent bonds involving hydrogen atoms were constrained using the SHAKE algorithm[53]. The time step for MD simulations was set to 2 fs, with a direct-space and nonbonded cutoff of 9 Å. The temperature was controlled by using the Langevin thermostat with a collision frequency of 2.0 ps−1[54]. The systems were heated from 0 to 300 K in 500 ps and subsequently an equilibrium simulation of 500 ps at 300 K was

executed. At last, 150 ns MD simulations without any restriction were run on these nine systems at a constant pressure of 1 atm, and the atomic coordinates were recorded every 2 ps.

2.3 | Calculations of Binding Free Energies
To evaluate binding ability of inhibitors to BRD9, BRD7 and BRD4, binding free energies ( G ) of inhibitors to BRDs were calculated by using MM-PBSA method based on 200

snapshots extracted from the last 50 ns of MD trajectories at intervals of 250 ps[55-60]. Due to expensive computational time of normal mode analysis, 50 snapshots extracted from the previous 200 snapshots at an interval of 4 snapshots were used to calculate the entropy[61]. For BRD family, the prediction given by MM/PBSA is more consistent with the experimental value compared to molecular mechanics generalized Born surface area (MM/GBSA) method[62,63]
which was supported by the previous researches[64-66]. Thus, we adopted MM/PBSA method to compute binding free energies of inhibitors to BRD9, BRD7 and BRD4. For every snapshot, free energies of each molecular species (complex, receptor and inhibitor) were computed using the following equation:

G  Gcomplex  (Gprotein  Ginhibitor )

(1)

where

Gcomplex ,

Gprotein

and

Ginhibitor

are free energies of complex, receptor and inhibitor,

respectively. Binding free energies ( G ) is evaluated by a sum of the changes in gas phase binding energies ( EMM ), solvation free energies ( Gsolv ) and entropy ( TS ):

G  EMM  Gsolv  TS

(2)

in which

EMM

is further divided into van der Walls ( Evdw ) and electrostatic energies

(  E ele ). Solvation free energy ( Gsolv ) is further decomposed into polar ( Gpol) and non-polar ( Gnonpol ) components. Binding free energies ( G ) can be represented by the
following equation:

G  Eele Evdw Gpol Gnonpol TS

(3)

where the first two terms (  E ele and  E vdw ) are usually computed by using molecular mechanics. The term ( Gpol) can be obtained by solving the Poisson-Boltzmann equation.

Gnonpol

can be computed by the following empirical equation:

Gnonpol   SASA 

(4)

where the values of and  are set as 0.00542 kcal/mol·Å-2 and 0.92 kcal/mol, respectively. The atom radii were set according to the radii in the prmtop files. The dielectric constant for the solute and solvent are set to 1.0 and 80.0, respectively. For the last term, the entropy (  TS ) was calculated by using classical statistical thermodynamics and normal mode analysis.

3 | RESULTS AND DISCUSSION

3.1 | Equilibrium of Dynamics Simulation

In order to assess dynamics stability of nine complexes, structural properties were monitored through the entire MD simulation of each complex. Root-mean-square deviations (RMSDs) of

backbone atoms in BRD9, BRD7 and BRD4 relative to their starting structures were computed to evaluate stability of nine complexes during MD simulations by using Cpptraj module in Amber16[67], and the information of RMSDs was plotted in Figure S1. It can be observed that RMSD values of each system tend to converge after 30 ns of MD simulations and the averaged RMSD values of all systems are less than 2.25 Å, indicating that the systems are stable and equilibrated. To understand structural flexibility of a certain residue around its average position, root-mean-square fluctuations (RMSFs) of Cα atoms were calculated along the equilibrated MD trajectories of nine complexes (Figure S2). One can observe that RMSFs of four α helices of BRD9, BRD7 and BRD4 are lower than 1.0 Å, indicating that these second structures are rigid. Besides, the residues with high fluctuation are those located in the ZA-loop (residues 38-66 in BRD9, 149-177 in BRD7 and 76-106 in BRD4), the BC-loop (residues 95-106 in BRD9,
206-217 in BRD7 and 135-146 in BRD4), the turn regions and the N-terminal of BRDs. Due to the presence of H1B, the flexibility of the ZA-Loop in BRD7 is stronger than that in BRD9. But the flexibility of residues 160-175 in BRD7 is weaker than that of the corresponding residues 87-102 in BRD4. TVU produces stronger restriction on the mobility of the regions located in the residues 35-55 in BRD9 and residues 73-93 in BRD4. For N1D, the residues 38-42 and
47-56 are the most flexible regions on the ZA-Loop of BRD9. But in the case of the ZA-Loop of BRD4, the flexibility of the corresponding residues 78-82 is obviously inhibited by the N1D binding, while that of residues 87-96 is enhanced by the presence of N1D. On the contrary, the flexibility of residues 47-56 in the ZA-Loop of BRD9 complexed with 5V2 is stronger than that of residues 87-96 in the ZA-Loop of BRD4. Especially under bindings of N1D, TVU and 5V2, the overall flexibility of the BC-Loop in BRD9 is slightly greater than that of BRD4. The above

analysis implies that selectivity of inhibitors toward BRD9, BRD7 and BRD4 may be determined by the key residues located in the regions of the ZA-loop and BC-loop.

3.2 | Binding Free Energy Analysis

To evaluate the difference in binding ability of inhibitors to BRD9, BRD7 and BRD4,

MM-PBSA method was used to calculate binding free energies, which was divided into several separate contribution terms (gas phase energy, solvation energy and entropy contribution).
Table 1 shows binding free energies, separate components of free energies and experimental binding affinities. Binding free energies of H1B to BRD7, BRD9 and BRD4 are -16.51, -17.54 and -11.92 kcal/mol, respectively. The experimental values of H1B to BRD9/BRD4 are -10.03 and -7.28 kcal/mol. The work from Theodoulou et al. proved that I-BRD9 has >200-fold selectivity toward BRD7 VS BRD9[24], which basically agrees with our current calculation.
Moreover, the study of Martin et al. showed that another BI-9564 also has >30-fold selectivity for BRD9 over BRD7[18]. These results show possibility of developing high selective inhibitors toward BRD7 and BRD9. Binding free energies of N1D, TVU and 5V2 to BRD9 are -17.29,
-20.38 and -19.00 kcal/mol, respectively, while that of N1D, TVU and 5V2 to BRD4 are -11.76,

-18.78 and -12.24 kcal/mol, separately. One can observe that the rank of our calculated binding free energies using MM-PBSA method is in accordance with that of experimental values.
Binding free energies of H1B, N1D, TVU and 5V2 to BRD9 are separately increased by 5.62,

5.53, 1.60 and 6.76 kcal/mol compared to that of these inhibitors to BRD4. This result suggests that all four inhibitors have stronger binding ability to BRD9 than to BRD4, especially H1B, NID and 5V2. Among the individual components, the favorable electrostatic interaction is
opposed by the unfavorable polar solvation energy to form an unfavorable force ( Gele  pol )
impairing associations of inhibitors with proteins. The van der Walls interaction ( Evdw ) and the non-polar solvation ( Gnonpol ) term contribute favorable force to inhibitor bindings, but the
former is much stronger than the latter. The entropy changes (  TS ) caused by the changes of motion freedom also weaken bindings of inhibitors to BRDs.

We compared some independent binding free energy components between inhibitor-protein complexes so as to explore mechanism of driving selective binding of class of I-BRD9 inhibitors to BRD9, BRD7 and BRD4 (Figure 2 and Table 1). One can see that in bindings of H1B to BRD7 and BRD9, the difference in the sum of electrostatic term and polar solvation energy term is neglected, which suggests that polar interaction of H1B with BRD9 and BRD7 is not a main force to drive selectivity of H1B toward BRD9 and BRD7. In this paper, we will
only study selective mechanism of H1B toward BRD7 and BRD9. The unfavorable polar interactions ( Gele pol ) of H1B, N1D and 5V2 with BRD9 are respectively decreased by 4.87,
0.48 and 5.50 kcal/mol compared to BRD4, which suggests that the decrease in the polar interactions strengthens bindings of H1B, N1D and 5V2 to BRD9, especially for H1B and 5V2. However, the polar interaction of TVU with BRD9 is increased by 0.89 kcal/mol relative to BRD4, which weakens binding of TVU to BRD9. The van der Waals interactions of H1B, N1D, TVU and 5V2 with BRD9 are strengthened by 6.36, 6.82, 5.36 and 1.29 kcal/mol compared to that of these four inhibitors with BRD4, respectively. This result suggests that van der Waals

interactions strengthen bindings of the current four inhibitors to BRD9 relative to BRD4. In addition, the entropy effect (  TS ) is decreased by 0.99 kcal/mol by binding of 5V2 to BRD9 relative to BRD4, which enhances association of 5V2 with BRD9. The nonpolar interactions do
not produce obvious changes between three proteins, which indicate that the nonpolar interaction is not a main factor affecting selective bindings of inhibitors to BRD9 and BRD4.

3.3 | Binding of H1B to BRD9 versus BRD7

In order to further obtain the details involving the underlying selective mechanisms of H1B toward BRD9 and BRD7, binding free energies were decomposed into contributions of per residues (Figure 3a). It is noted that ten residues generate important contributions to bindings of H1B to BRD7 and BRD9. In order to gain deeper understanding of selective mechanism, binding mode and geometric information of inhibitors relative to key residues were depicted in Figure 4, Figure S3 and Figure S4 by using the lowest energy structures extracted from MD trajectories. The information of hydrogen bonds can be obtained by utilizing Cpptraj program in Amber 16 and the results were shown in Table 2. As shown in Figure 4 a1-b1, the benzene ring of Phe155 in BRD7 forms the CH-π interaction with the trifluoromethyl of H1B and this residue also forms the CH-O interaction with H1B[68], but Phe44 in BRD9 only forms the CH-O interaction with H1B (Figure S3 A1-B1). Phe155 and Phe44 separately contribute interaction energies of -1.17 and -0.67 kcal/mol to the H1B-BRD7 and H1B-BRD9 bindings. Phe156 in BRD7 and Phe45 in BRD9 also form the CH-π interactions with inhibitor H1B, which respectively contribute interaction energies of -0.94 and -0.53 kcal/mol to the H1B-BRD7 and

H1B-BRD9 associations. Val160 in BRD7 and Val49 in BRD9 produce the CH-π interactions with the hydrophobic ring of H1B by separately given energy contributions of -1.04 and -1.54 kcal/mol. Ile164 in BRD7 only forms a CH-π interaction and an extremely unstable hydrogen bond with H1B and the total energy is -1.72 kcal/mol (Table 2 and Figure 3a). However, Ile53 in BRD9 not only forms two CH-π interactions with H1B, but also forms a stable hydrogen bond, which provides the total energy contribution of -3.35 kcal/mol for the H1B-BRD9 binding. The methyl of residue Ala165 in BRD7 and Ala54 in BRD9 form the CH-π interactions in the H1B-BRD7 and H1B-BRD9 complexes and the energy contributions of these two residues is -0.97 and -0.69 kcal/mol, respectively. From Figure 4a1-b1, the benzene ring of Tyr210 in BRD7 produces hydrophobic interaction of -0.79 kcal/mol with BRD7, while Tyr99 in BRD9 does not form the interaction. According to Figure 3a, the interaction energy of H1B with Asn211 in BRD7 and Asn100 in BRD9 are -5.09 and -2.25 kcal/mol, respectively. Asn211 forms two highly stable hydrogen bonds with H1B, while Asn100 only forms one highly stable hydrogen bond with H1B (Table 2 and Figure S4 A1-B1). Lys212 in BRD7 and Arg101 in BRD9 produce a hydrogen bonding interaction with H1B and their energy contribution are
-1.74 and -1.86 kcal/mol, respectively. The hydrophobic interactions formed by Thr215 in BRD7 and Thr104 in BRD9 with H1B is -1.04 and -0.62 kcal/mol. Structurally, Tyr217 of BRD7 and Tyr106 of BRD9 generate two stacked π-π interactions with the benzene ring of H1B, which respectively contributes interaction energy of -2.35 and -2.91 kcal/mol to association of H1B with BRD7 and BRD9.

3.4 | Binding of N1D to BRD9 versus BRD4

According to Figure 3, the force driving bindings of N1D to BRD9 and BRD4 mainly origins from residues Phe44/Pro82, Val49/Val87, Ile53/Lys91, Ala54/Leu92, –/Leu94, Tyr99/Tyr139, Asn100/Asn140, Arg101/Lys141, Thr104/Asp144 and Tyr106/Ile146 in BRD9/BRD4. Besides, the corresponding residues of BRD9 and BRD4 were acquired from the superimposed structures (Figure 1c) by using Pymol[69]. These residues are located in the BC-loop and ZA-loop of BRD9 and BRD4.
As shown in Figure 3a, ten residues provide strong contributions to N1D-BRD9 and BRD4 bindings. Phe44/Pro82 in BRD9/BRD4 contributes -1.51 and -0.88 kcal/mol to bindings of N1D to BRD9 and BRD4, respectively. One can see from Table 3, the side-chain van der Waals

energy

Svdw of Phe44-N1D is -1.90 kcal/mol, while the one of Pro82-N1D is only -0.97

kcal/mol, indicating that binding of N1D to Phe44 and Pro82 may be caused by van der Walls interactions of side chain atoms (Figure 4a1 and b1). From Figure S3A1 and B1, Phe44 of BRD9 and Pro82 of BRD4 structurally form the weak CH-O interactions with N1D. Moreover, the benzene ring of Phe44 also produces the T-shaped π-π interaction with that of N1D, while the hydrophobic ring of Pro82 forms a weak π-π interaction with the benzene ring of N1D (Figure 4a1 and b1). Totally, the interaction of N1D with Phe44 in BRD9 is much stronger than that of N1D with Pro82 in BRD4. The interactions of N1D with Val49 of BRD9 and Val87 of BRD4 are -1.67 and -1.46 kcal/mol (Figure 3a), respectively, which structurally agrees with the CH-π interactions of the hydrophobic ring in N1D with the alkyl of Val49 and Val87. Although these two residues do not play a significant role in binding selectivity of N1D toward BRD9 and BRD4, but they enhance stability of two complexes. The methyl of Ile53 in BRD9 generates the CH-π interaction of -1.33 kcal/mol with the benzene ring of N1D, but Lys91 in BRD4 does not

form strong interaction with N1D, which shows that binding difference of Ile53 and Lys91 to N1D plays significant role in selective binding of N1D to BRD9 and BRD4. According to Figure 3a, the energy contribution of Leu92 of BRD4 to the N1D binding is 0.80 kcal/mol stronger than that of Ala54 of BRD9. From Table 3, the van der Waals interaction of the side chain in Leu92 with N1D is -1.68 kcal/mol, while that of the side chain in Ala54 only -0.60 kcal/mol. The cause leading to this result may owe to the side chain of Leu92 longer than that of Ala54 (Figure 4a1 and b1). Because of the vacancy of corresponding position residue in BRD9, there is a natural advantage of Leu94 in BRD4 to produce the CH-π interactions with the hydrophobic ring of N1D, which contributes an energy contribution of -1.81 kcal/mol to the N1D-BRD4 binding. From Figure 3a, although the benzene ring of Tyr99 in BRD9 and Tyr139 in BRD4 generate strong hydrophobic interaction with N1D, due to small binding difference of N1D to these two residues, thus these two residues do not play role in selectivity of N1D toward BRD9 and BRD4. The interaction of N1D with Asn100 in BRD9 is -1.94 kcal/mol, while that of N1D with Asn140 in BRD4 is only -0.96 kcal/mol, which shows that Asn100 and Asn140 provide significant contribution for selectivity of N1D toward BRD9 and BRD4. According to Table 3, the electrostatic interaction is the main factor driving obvious selectivity of N1D on these two residues. Structurally, Asn100 in BRD9 not only forms a hydrogen bonding interaction with N1D (Figure S4 A1 and Table2), but also produces two CH-O interactions with N1D. However, there is only one hydrogen bonding interaction between Asn140 in BRD4 and N1D (Figure S4 B1). The inhibitor N1D also shows strong selectivity in binding to Arg101 of BRD9 and Lys141 of BRD4 (Figure 3a). The electrostatic interaction is a main force inducing obvious binding difference of N1D to Arg101 and Lys141. Arg101 in BRD9 forms a hydrogen

bond with N1D with an energy contribution of -1.35 kcal/mol. But Lys141 in BRD4 doesn’t generate beneficial interaction with N1D (Table 3). According to Figure 3a, the methyl of Thr104 in BRD9 produces the CH-CH interaction of -0.67 kcal/mol with the alkyl of N1D, while Asp144 in BRD4 forms a positive repulsive interaction of 1.30 kcal/mol with N1D. As seen in Figure 4, a negative charge carried by two carbonyl oxygen atoms of Asp144 generates unfavorable repulsive interaction with the oxygen atom of N1D, which heavily impairs binding of N1D to BRD4. The obvious difference in van der Waals interactions of N1D with Tyr106 of BRD9 and Ile146 of BRD4 is partial cause leading to selectivity of N1D toward these two residues. In Figure 4, the benzene ring of Tyr106 in BRD9 not only forms the CH-π interaction with the alkyl of inhibitor N1D, but also produces two π-π stacked interactions with the hydrophobic rings of N1D, which totally provides the energy contribution of -2.47 kcal/mol to the N1D-BRD9 binding. The energy contribution of Ile146 in the BRD4-N1D complex is -2.18 kcal/mol, which mainly comes from the CH-π interactions of the alkyl of Ile146 with two hydrophobic rings of N1D, respectively. Based on the above analysis, Phe44/Pro82, Ile53/Lys91, Ala54/Leu92, –/Leu94, Asn100/Asn140, Arg101/Lys141, Thr104/Asp144 and Tyr106/Ile146 in BRD9/BRD4 located in the ZA-loop and BC-loop play significant roles in selective binding of N1D toward BRD9 and BRD4, which also agrees well with the previous studies[70-72].

3.5 | Binding of TVU to BRD9 versus BRD4

As shown in Figure 3b, although Val49/Val87, Tyr99/Tyr139, Asn100/Asn140, Arg101/Lys141 and Tyr106/Ile146 in BRD9/BRD4 can produce strong interactions with TVU, binding difference of TVU to these residues are very small, thus these residues do not play an important part in selectivity of TVU toward BRD9 and BRD4. On the contrary, Phe44/Pro82, Ile53/Lys91, Ala54/Leu92, –/Leu94 and Thr104/Asp144 are responsible for main contributions to selectivity of TVU toward BRD9 and BRD4. Similar to the binding of N1D to Phe44 of BRD9 and Pro82 of BRD4, the contribution of van der Walls energy is the main force for binding of TVU to Phe44 and Pro82. Compared to strong contribution of Ile53 to the
TVU-BRD9 binding, Lys91 in BRD4 does not generate interaction with TVU. The energy contributions of Leu92 to the TVU-BRD4 binding and Ala54 to the association of TVU with BRD9 are -2.04 and -1.03 kcal/mol, respectively, which structurally agrees with the CH-π interactions between the alkyls of these two residues and the hydrophobic rings of TVU (Figure 4a2 and b2). From Table 3, van der Waals interactions of side chain in Ala54 and Leu92 with TVU is main force driving the selective bindings of TVU toward BRD9 and BRD4. The negative charge of Asp144 in BRD4 forms an unfavorable electrostatic repulsive interaction with the oxygen atom of TVU, which weakens binding of TVU to BRD4. However, the methyl of Thr104 in BRD9 generates the favorable CH-CH interaction with the alkyl of TVU, which strengthens binding of TVU to BRD9. Thus, Asp144/Thr104 in BRD4/BRD9 play an important role in selectivity of TVU toward BRD4 and BRD9.

3.6 | Binding of 5V2 to BRD9 versus BRD4

According to Figure 3, Phe44/Pro82, Val49/Val87, Ile53/Lys91, Ala54/Leu92, –/Leu94, Tyr99/Tyr139, Asn100/Asn140, Arg101/Lys141, Thr104/Asp144 and Tyr106/Ile146 in BRD9/BRD4 generates obvious difference in the 5V2-residue interactions, which shows that these residues play significant role in selectivity of 5V2 on BRD9 and BRD4. As shown in Figure S3 A3 and Figure 4A3, the CH-O and T-shaped π-π interactions of TVU with Phe44 in BRD9 are not observed, while Pro82 in BRD4 forms the CH-O and π-π interactions with TVU. Unlike N1D and TVU, 5V2 shows binding difference between Val49 in BRD9 and Val87 in BRD4. According to Figure 4a3 and b3, there is two CH-π interactions formed between the alkyl of residue Val49 and hydrophobic ring of 5V2, and the energy contribution of this residue is -1.62 kcal/mol. But Val87 in BRD4 only forms a CH-π interaction with 5V2 and the energy is
-0.60 kcal/mol. Compared to N1D and TVU, 5V2 produces a weak interaction with Ile53 in BRD9, and that of 5V2 with Lys91 is almost zero. As shown in Table 3, the van der Waals interaction of the side chain in Leu92 with 5V2 also is the main force driving selective binding of 5V2 toward BRD9. As seen from Figure 3c, Leu94 in BRD4 produces strong interaction with 5V2, but in the corresponding position in BRD9, no residue favorably interacts with 5V2. From Table 3, the main force driving selectivity of 5V2 toward to BRD9 and BRD4 partially comes from the polar interactions of 5V2 with Asn100 in BRD9 and Asn140 in BRD4. Asn100 in BRD9 and Asn140 in BRD4 form two hydrogen bonds with 5V2 (Table 2, Figure S4 A3 and B3). In addition, Asn100 forms three CH-O interactions with 5V2, while Asn140 only forms a CH-O interaction with 5V2 (Figure S3 A3 and B3). Totally, Asn100 and Asn140 contribute the interaction energies of -4.56 and -2.53 kcal/mol to the 5V2-BRD9 and 5V2-BRD4 bindings, respectively. According to Table 2, although Arg101 in BRD9 and Lys141 in BRD4 form

hydrogen bonding interactions with 5V2, but stability of the hydrogen bond between 5V2 and Lys141 is weaker than that between 5V2 and Arg101. As shown in Figure 3c, Asp144 in BRD4 generates an unfavorable interaction of 1.40 kcal/mol with 5V2 and this interaction mostly origins from the electrostatics repulsive interaction of the negative charge in Asp144 with the oxygen atom of 5V2, while Thr104 in BRD9 contributes a favorable CH-CH interaction of
-0.88 kcal/mol to the 5V2-BRD9 binding. Similar to N1D, the van der Waals interaction of the side chain in Tyr106 in BRD9 with the hydrophobic ring of 5V2 is much stronger than that of the side chain in Ile146 with 5V2 (Table2 and Figure 4 a3 and b3), which plays a main role in selectivity of 5V2 on BRD9 and BRD4.

3.7 | Binding Difference of Four Inhibitors to BRD9

In addition, binding difference of four inhibitors to BRD9 is also been probed. Based on the difference of molecular structure between H1B, N1D, TVU and 5V2, it is observed from Figure S3 A1-A3 that the hydrophobic rings in H1B, TVU and 5V2 are easier to form the CH-O interactions with the oxygen atom of Asn100 than that of N1D. From Figure S4 A1-A3, the nitrogen atom in H1B, TVU and 5V2 forms a stable hydrogen bond with the oxygen atom of Asn100, but the nitrogen atom in the hydrophobic ring in N1D does not form hydrogen bond with Asn100. From Figure 4a4, the trifluoromethyl group of 5V2 interacts with the benzene ring of Phe47 through a CH-π contact. Meanwhile, the benzene ring of 5V2 also forms a π-π interaction with Phe47, and the total energy contribution of Phe47 is -1.41 kcal/mol in the
5V2-BRD9 complex. Compared with N1D and TVU, the fluorine atoms in H1B and 5V2 can

form hydrogen bonds with the oxygen atom of Tyr106 in BRD9, but these hydrogen bonds are unstable. Thus, the substitution of fluorine atoms has little effect on bindings of class of I-BRD9 inhibitors to BRD9. In addition, it is observed that H1B has more methyl than 5V2, but its binding ability to BRD9 is weaker than that of 5V2. In Figure 4a1, the methyl of H1B forms a CH-π interaction with Phe45 and the energy is -1.41 kcal/mol. Due to this interaction, the position of H1B at BRD9 changed compared with 5V2, especially the distances of H1B and 5V2 away from Asn100, Phe47 and Tyr99 (Figure 5). The distance between Asn100 and H1B forming two hydrogen bonds is larger than that between Asn100 and 5V2. Therefore, the energy contribution of Asn100 to the 5V2-BRD9 binding is 2.31 kcal/mol higher than that with H1B. The distance between the hydrophobic ring of H1B and the benzene ring of Tyr99 is significantly greater than the distance between 5V2 and Tyr99. Therefore, the CH-π interaction of H1B with Tyr99 disappears compared to that of 5V2 of Tyr99 (Figure 5d). Similarly, due to the increase of distance between the benzene ring of Phe47 and H1B, Phe47 lost the van der Waals interactions with H1B, so the interaction energy of Phe47 with H1B is decreased by 1.40 kcal/mol compared with that with 5V2 (Figure 5c).

4 | CONCLUSION

Based on calculation of binding free energies, four inhibitors produce stronger binding ability to BRD9 than to BRD4, and binding ability of H1B to BRD9 is slightly higher than to BRD7. In addition, the difference in the van der Waals interactions and the entropy is the main force responsible for selectivity of TVU on BRD9 and BRD4, certainly this difference also

provides partial contribution to the selectivity of N1D toward BRD9 and BRD4. Decomposition of binding free energies into separate residues proved that residues Ile164 and Asn211 from BRD7 and Ile53 and Asn100 from BRD9 contribute significant force to selectivity of H1B toward BRD7 and BRD9. Thus, in future drug designs targeting BRD7 and BRD9 more attentions should be paid to hydrogen bonding interactions of (Asn211, Asn100) in (BRD7, BRD9) with inhibitors. In addition, several key residues Phe44, Ile53, Asn100, Thr104 in BRD9 and Pro82, Lys91, Asn140, Asp144 in BRD4 that are located in the ZA-loop and BC-loop provide significant contributions to binding selectivity of inhibitors to BRD9 and BRD4.
Therefore, these residues in the ZA-loop and ZB-loop can be used as potential target of drug designs inhibiting activity of BRD9 and BRD4.

DISCLOSURE STATEMEDT

No potential conflict of interest was reported by the author.

ACKNOWLEDGMENTS

This work is supported by the National Natural Science Foundation of China (11274205, 11274206 and 11504206), and major development projects of Shandong Jiaotong University.

Figure legends

FIGURE 1 (a) The binding site of BRD9, (b) The binding site of BRD4, (c) The superimposed structures of the apo BRD9 (gray), BRD7(pink) and BRD4 (green), (d) The molecular structures of inhibitors H1B(I-BRD9), 5V2, TVU and N1D.
FIGURE 2 Comparisons of binding free energy components (a)

H1B-BRD7/BRD9/BRD4, (b) N1D-BRD9/BRD4, (c) TVU-BRD9/BRD4 and (d)

5V2-BRD9/BRD4.

FIGURE 3 Comparisons between

Ginhibitorresidue , (a) H1B-BRD7/BRD9, (b)

N1D-BRD9/BRD4, (c) TVU-BRD9/BRD4 and (d) 5V2-BRD9/BRD4.

FIGURE 4 Geometric positions of inhibitors relative to key residues of proteins involving strong interaction, (a) H1B-BRD7/BRD9, (b) N1D-BRD9/BRD4, (c) TVU-BRD9/BRD4 and (d) 5V2-BRD9/BRD4.
FIGURE 5 Frequency distribution histogram of distance forming hydrogen bonding and polar interactions: (a) frequency distribution of distance between HD21 in residue Asn100 and O33 in H1B/O30 in 5V2, (b) frequency distribution of distance between H14 in H1B/H12 in 5V2 and OD1 in residue Asn100, (c) frequency distribution of distance between the benzene ring of H1B/5V2 and residue Phe47, (d) frequency distribution of distance between the hydrophobic ring of H1B/5V2 and the benzene of residue Tyr99.

Figure legends for Supporting Information

FIGURE S1 Root-mean-square deviation (RMSD) of backbone atoms in BRD7, BRD9 and BRD4 relative to the corresponding crystal structures as function of simulations time: (A) H1B-protein, (B) N1D-protein, (C) TVU-protein, (D)
5V2-protein.

FIGURE S2 Root-mean-square fluctuations (RMSFs) of Cα atoms of BRD9 and BRD4:

(A) inhibitor-NRD7, (B) inhibitor-BRD9, (C) inhibitor-BRD4.

FIGURE S3 The CH-O interactions formed between three inhibitors and key residues of proteins, (A) H1B-BRD9/BRD7, (B) N1D-BRD9/BRD4, (C) TVU-BRD9/BRD4 and
(D) 5V2-BRD9/BRD4.

FIGURE S4 Hydrogen bonds formed between three inhibitors and key residues of proteins, (A) H1B-BRD9/BRD7, (B) N1D-BRD9/BRD4, (C) TVU-BRD9/BRD4 and
(D) 5V2-BRD9/BRD4.

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TABLE 1 Binding free energy calculations of inhibitors to BRD9 and BRD4.a

BRD7 BRD9 BRD4 BRD9 BRD4 BRD9 BRD4 BRD9 BRD4

-H1B
-H1B
-H1B
-N1D -N1D -TVU -TVU -5V2 -5V2
Terms Mean Mean Mean Mean Mean Mean Mean Mean Mean

(σb ) (σb ) (σb ) (σb ) (σb ) (σb ) (σb ) (σb ) (σb )
Gele -7.94 -22.90 -59.62 -29.54 -19.74 -40.90 -40.92 -11.05 -66.37
(8.36) (8.58) (9.42) (10.62) (7.96) (4.81) (6.51) (7.77) (7.78)
Gvdw
-45.16
-48.42
-42.06
-48.20
-41.38
-49.88
-44.52
-43.58
-42.29

(2.87)
(3.24)
(3.25)
(4.06)
(3.44)
(3.12) (3.03)
(3.37)
(2.94)
Gpol
21.04
35.97
77.56
47.64
38.32
55.27
54.40
22.79
83.61
(6.70) (6.48) (8.66) (9.25) (7.85) (4.43) (5.49) (6.99) (7.38)
Gnonpol
-5.81
-6.03
-5.59
-5.91
-5.49
-5.98
-5.81
-5.44
-5.46
(0.20) (0.10) (0.27) (0.24) (0.27) (0.14) (0.16) (8.18) (0.12)
c
Gele pol
13.10
13.07
17.94
18.10
18.58
14.37
13.48
11.74
17.24
(2.75) (3.47) (4.09) (3.43) (3.41) (3.02) (3.36) (3.14) (2.96)
 TS
21.37
23.84
17.79
18.72
16.54
21.11
18.07
18.28
19.27
(5.59) (6.35) (5.54) (6.21) (3.64) (5.58) (6.43) (5.08) (6.75)

d
Gbind
-16.51
-17.54
-11.92
-17.29
-11.76
-20.38
-18.78
-19.00
-12.24
e
Gexp
-10.03
-7.28
-9.21
-6.46
-10.85
-10.03
-10.72
-7.69

a All values are given in kcal/mol.

b Standard errors.

c
ele pol

 Gele

 G

pol

d
bind

 Eele

 G

pol

 Evdw

 Gnopol

 TS

e The experimental binding free energies calculated according to the IC50 by G

 RT ln IC50 .

TABLE 2 Hydrogen bonds in each complex.a

BRDs Hydrogen bonds Occup/% Dist/ Å Ang/°
Accptor Donor H1B N1D TVU 5V2
BRD7 Lig O33 Asn211 HD21-ND2 99.31 2.96 157.52
Lig O48 Lys212 H-N 97.95 2.98 159.11
Asn211 OD1 Lig H14-N37 95.80 2.91 157.65
Ile164 O Lig H13-N35 19.61 2.89 154.18
BRD9 Lig O33 Asn100 HD21-ND2 99.43 2.89 160.17
Lig O48 Arg101 H-N 95.90 2.99 158.33
Asn100 OD1 Lig H14-N37 48.29 2.93 155.74
Ile53 O Lig H13-N35 68.44 2.86 154.10
Lig O29 Asn100 HD21-ND2 99.85 2.87 164.70
Lig O58 Arg101 H-N 48.20 2.97 155.43
Lig O2 Asn100 HD21-ND2 99.97 2.85 158.78
Lig O5 Arg101 H-N 98.78 2.95 157.16
Asn100 OD1 Lig H10-N1 59.57 3.29 155.89
Lig O30 Asn100 HD21-ND2 66.94 3.09 156.95
Lig O46 Arg101 H-N 97.88 2.96 157.07
Asn100 OD1 Lig H12-N34 99.18 2.89 156.77
BRD4 Lig O29 Asn140 HD21-ND2 98.89 2.89 160.31
Lig O2 Asn140 HD21-ND2 99.85 2.90 156.93
Lig O4 Lys141 H-N 99.46 2.90 159.83
Asn140 OD1 Lig H10-N1 71.29 3.27 156.83
Lig O30 Asn140 HD21-ND2 99.41 2.90 160.61
Lig O45 Lys141 H-N 47.78 3.00 161.41
Lig O46 Lys141 H-N 15.41 2.94 159.93
Asn140 OD1 Lig H12-N34 14.71 2.91 156.57
a The hydrogen bonds are determined by the acceptor…donor atom distance of less than 3.5 Å and acceptor…H-donor angle of greater than 120°.

TABLE 3 Energy contributions of separate residues to the bindings of inhibitors to BRD9 and BRD4.a

Residue N1D TVU 5V2
Svdw Bvdw Tele Tsolv Svdw Bvdw Tele Tsolv Svdw Bvdw Tele Tsolv
9/Phe44 -1.90 -1.10 -1.71 3.20 -1.81 -1.32 -1.73 3.26 -0.57 -1.09 -1.00 2.52
4/Pro82 -0.97 -1.32 -1.13 2.54 -1.08 -1.27 -1.41 3.02 -1.13 -1.39 -1.96 3.52
9/Val49 -1.42 -0.32 -0.14 0.20 -1.45 -0.45 -0.06 0.34 -1.45 -0.30 0.95 -0.83
4/Val87 -1.14 -0.47 -0.16 0.31 -1.30 -0.36 -0.05 0.18 -0.54 -0.28 0.08 0.14
9/Ile53 -1.54 -0.67 0.80 0.04 -1.76 -0.63 0.81 0.09 -0.40 -0.13 -0.82 0.94
4/Lys91 -0.05 -0.04 0.43 -0.33 -0.08 -0.05 0.62 -0.49 -0.10 -0.11 11.91 -11.63
9/Ala54 -0.60 -0.65 0.13 -0.02 -0.53 -0.52 0.01 0.01 -0.19 -0.15 1.15 -1.08
4/Leu92 -1.68 -0.14 0.23 -0.35 -1.81 -0.22 0.41 -0.42 -1.64 -0.17 -0.08 0.09
9/– — — — — — — — — — — — —
4/Leu94 -1.59 -0.10 -0.08 -0.04 -1.42 -0.09 0.02 -0.12 -1.06 -0.07 0.24 -0.30
9/Tyr99 -1.98 -0.40 -0.83 2.02 -1.90 -0.49 -1.26 2.74 -1.84 -0.57 -2.42 4.25
4/Tyr139 -1.90 -0.32 -0.95 1.94 -1.57 -0.34 -0.67 1.71 -1.71 -0.34 -1.92 2.90
9/Asn100 -0.33 -0.54 -7.04 5.97 -0.73 -0.40 -10.00 7.13 -0.63 -0.62 -11.44 8.13
4/Asn140 -0.56 -0.33 -5.51 5.44 -1.08 -0.52 -9.89 7.43 -0.98 -0.61 -8.55 7.62
9/Arg101 -0.81 -0.17 -3.75 3.38 -1.00 -0.08 -6.14 5.27 -1.02 -0.07 8.75 -9.56
4/Lys141 -0.29 -0.13 -1.66 1.99 -0.81 0.15 -7.30 6.16 -0.74 -0.20 9.37 -9.68
9/Thr104 -0.57 -0.09 -0.22 0.21 -0.59 -0.11 -0.22 0.20 -0.67 -0.10 0.33 -0.43
4/Asp144 -0.26 -0.04 -0.03 1.64 -0.82 -0.10 -0.45 3.03 -0.93 -0.10 -19.09 21.52
9/Tyr106 -4.01 -0.27 -0.37 2.18 -4.14 -0.32 0.35 1.22 -4.07 -0.26 1.23 0.43
4/Ile146 -1.76 -0.15 -0.06 -0.20 -2.31 -0.23 -0.02 -0.29 -1.87 -0.15 0.98 -1.26
a All values are given in kcal/mol. S : the van der Waals energies of the side chains in residue, B : the van der Waals energies
vdw vdw
of the backbone atoms, Tele : the electrostatic energies of residue, Tsolv : the solvation energies of residues.

FIGURE 1 (a) The binding site of BRD9, (b) The binding site of BRD4, (c) The superimposed structures of the apo BRD9 (gray), BRD7(pink) and BRD4 (green), (d) The molecular structures of inhibitors H1B(I-BRD9), 5V2, TVU and N1D.

FIGURE 2 Comparisons of binding free energy components (a)
H1B-BRD7/BRD9/BRD4, (b) N1D-BRD9/BRD4, (c) TVU-BRD9/BRD4 and (d)
5V2-BRD9/BRD4.

FIGURE 3 Comparisons between

Ginhibitorresidue , (a) H1B-BRD7/BRD9, (b)

N1D-BRD9/BRD4, (c) TVU-BRD9/BRD4 and (d) 5V2-BRD9/BRD4.

FIGURE 4 Geometric positions of inhibitors relative to key residues of proteins involving strong interaction, (a) H1B-BRD7/BRD9, (b) N1D-BRD9/BRD4, (c) TVU-BRD9/BRD4 and (d) 5V2-BRD9/BRD4.

FIGURE 5 Frequency distribution histogram of distance forming hydrogen bonding and polar interactions: (a) frequency distribution of distance between HD21 in residue Asn100 and O33 in H1B/O30 in 5V2, (b) frequency distribution of distance between H14 in H1B/H12 in 5V2 and OD1 in residue Asn100, (c) frequency distribution of distance between the benzene ring of H1B/5V2 and residue Phe47, (d) frequency distribution of distance between the hydrophobic ring of H1B/5V2 and the benzene of residue Tyr99.