| Id |
Subject |
Object |
Predicate |
Lexical cue |
| T102 |
0-7 |
Sentence |
denotes |
Results |
| T103 |
9-28 |
Sentence |
denotes |
Structural Dynamics |
| T104 |
29-262 |
Sentence |
denotes |
To compute the RMSD of systems, the rotational and translational movements were removed by first fitting the Cα atoms of the RBD to the crystal structure and then computing the RMSD with respect to the Cα atoms of RBD in each system. |
| T105 |
263-352 |
Sentence |
denotes |
Figure 3 shows the RMSD plot in the RBD of SARS-COV, nCOV-2019, and some of its variants. |
| T106 |
353-473 |
Sentence |
denotes |
Comparison of the RMSD of SARS and nCOV-2019 RBD shows that SARS-COV has a larger RMSD throughout the 500 ns simulation. |
| T107 |
474-643 |
Sentence |
denotes |
In nCOV-2019, the RMSD is very stable with a value of about 1.5 Å, whereas in SARS-COV, the RMSD increases up to ∼4 Å after 100 ns and then fluctuates between 3 and 4 Å. |
| T108 |
644-749 |
Sentence |
denotes |
The change in RMSD of SARS is partially related to the motion in the C-terminal which is a flexible loop. |
| T109 |
750-831 |
Sentence |
denotes |
Figure 3 Cα RMSD plots for nCOV-2019 and SARS-COV and a few nCOV-2019 mutations. |
| T110 |
832-912 |
Sentence |
denotes |
The RMSD plots for the nCOV-2019 mutants show similar behaviors to nCOV-2019-wt. |
| T111 |
913-1054 |
Sentence |
denotes |
In most of the variants, the RMSD is very stable during the 300 ns simulation which shows the great tolerance of the interface for mutations. |
| T112 |
1055-1106 |
Sentence |
denotes |
However, a few mutations showed some RMSD variance. |
| T113 |
1107-1194 |
Sentence |
denotes |
In mutation Y489A, the RMSD increases from 1.37 ± 0.21 Å to1.88 ± 0.16 Å after 2000 ns. |
| T114 |
1195-1307 |
Sentence |
denotes |
Mutation Y505A resulted in an increase in RMSD up to 100 ns to a value to 1.98 ± 0.20 Å and decreased afterward. |
| T115 |
1308-1395 |
Sentence |
denotes |
The RMSD for mutation N487A shows an increasing behavior with a value of 2.10 ± 0.23 Å. |
| T116 |
1396-1461 |
Sentence |
denotes |
Mutations N439K, V483A, and V483F showed a stable RMSD of ∼1.5 Å. |
| T117 |
1462-1538 |
Sentence |
denotes |
For mutations T478I, G476S, S494P, and A475V, the RMSD increases up to ∼2 Å. |
| T118 |
1539-1641 |
Sentence |
denotes |
These variations in the backbone RMSD show the involvement of these residues in the complex stability. |
| T119 |
1642-1696 |
Sentence |
denotes |
RMSD plots for other mutations are shown in Figure S1. |
| T120 |
1697-1898 |
Sentence |
denotes |
Since the extended loop (residues 449 to 510 shown in Figure 1B from α4 to α5) of the RBD makes all contacts with ACE2, the RMSD was computed by also fitting to the Cα atoms of this region (Figure S2). |
| T121 |
1899-2069 |
Sentence |
denotes |
The extended loop in nCOV-2019 is very stable with less deviation (RMSD = 0.86 ± 0.017 Å) from the crystal structure compared to SARS-COV having an RMSD of 2.79 ± 0.05 Å. |
| T122 |
2070-2145 |
Sentence |
denotes |
Few of the mutants show an increase in the loop RMSD during the simulation. |
| T123 |
2146-2293 |
Sentence |
denotes |
In mutants N487A and Y449A the loop RMSD jumps to a value of about 1.95 ± 0.12 Å and 1.94 ± 0.24 Å, respectively, after about 200 ns of simulation. |
| T124 |
2294-2414 |
Sentence |
denotes |
Mutants G447A and E484A show a loop RMSD values of 2.22 ± 0.03 Å and 1.96 ± 0.02 Å during the last 100 ns of simulation. |
| T125 |
2415-2501 |
Sentence |
denotes |
Other mutants showed a stable extended loop (observed in loop RMSD) during simulation. |
| T126 |
2502-2602 |
Sentence |
denotes |
The stability of extended loop for mutant systems confirms the high tolerance of this region of RBD. |
| T127 |
2603-2739 |
Sentence |
denotes |
To characterize the dynamic behavior for each amino acid in the RBD, we analyzed the root mean square fluctuation (RMSF) of all systems. |
| T128 |
2740-2883 |
Sentence |
denotes |
The RMSF plots for nCOV-2019, SARS-COV, and four other mutations are shown in Figure 4. nCOV-2019 shows less fluctuations compared to SARS-COV. |
| T129 |
2884-3026 |
Sentence |
denotes |
L3 in nCOV-2019 corresponding to residues 476 to 487 (shown in red in Figure 4) has smaller RMSF (1.5 Å) than SARS-COV L3 residues 463 to 474. |
| T130 |
3027-3109 |
Sentence |
denotes |
L1 in both nCOV-2019 and SARS-COV (green) has small fluctuation (less than 1.5 Å). |
| T131 |
3110-3205 |
Sentence |
denotes |
Moreover, the C-terminal residues of SARS-COV show high fluctuation (Figure 4 shown in orange). |
| T132 |
3206-3252 |
Sentence |
denotes |
Few mutants show higher fluctuation in the L1. |
| T133 |
3253-3350 |
Sentence |
denotes |
Mutants Y505A and S494A had a RMSF of 2.5 Å and mutation N487A had a RMSF of about 4 Å in the L1. |
| T134 |
3351-3407 |
Sentence |
denotes |
Mutation Y449A has a higher RMSF of about 3 Å in the L3. |
| T135 |
3408-3489 |
Sentence |
denotes |
Mutants G496A, E484A, and G447A show a high fluctuation of about 4.5 Å in the L3. |
| T136 |
3490-3539 |
Sentence |
denotes |
The RMSF of other variants is shown in Figure S3. |
| T137 |
3540-3620 |
Sentence |
denotes |
Figure 4 RMSF plots for nCOV-2019-wt, SARS-COV, Y505A, N487A, G496A, and E484A. |
| T138 |
3621-3727 |
Sentence |
denotes |
The red shaded region shows the fluctuation in L1 and the green shaded region shows the fluctuation in L3. |
| T139 |
3728-3805 |
Sentence |
denotes |
The orange shaded region in SARS-COV shows the fluctuation in the C-terminal. |
| T140 |
3806-3879 |
Sentence |
denotes |
For comparison, the RMSF of nCOV-2019-wt is shown as cyan in other plots. |
| T141 |
3881-3893 |
Sentence |
denotes |
PCA and aFEL |
| T142 |
3894-3994 |
Sentence |
denotes |
To identify the dominant motions in the nCOV-2019, SARS-COV, and all the mutants, PCA was performed. |
| T143 |
3995-4200 |
Sentence |
denotes |
Most of the combined motions were captured by the first ten eigenvectors generated from the last 400 ns for SARS-COV, nCOV-2019, and extended mutant systems and the last 200 ns for other nCOV-2019 mutants. |
| T144 |
4201-4315 |
Sentence |
denotes |
The percentage of the motions captured by the first three eigenvectors was 51% for nCOV-2019 and 68% for SARS-COV. |
| T145 |
4316-4409 |
Sentence |
denotes |
In all mutations, more than 50% of the motions were captured by the first three eigenvectors. |
| T146 |
4410-4570 |
Sentence |
denotes |
The first few PC’s describe the highest motions in a protein which are related to a functional motion such as binding or unbinding of protein from the receptor. |
| T147 |
4571-4770 |
Sentence |
denotes |
The first three eigenvectors were used to calculate the aFEL using the last 400 ns of simulation for nCOV-2019 and SARS-COV as shown in Figure 5, which displays the variance in conformational motion. |
| T148 |
4771-4869 |
Sentence |
denotes |
SARS-COV showed two distinct low free energy states shown as blue separated by a metastable state. |
| T149 |
4870-4971 |
Sentence |
denotes |
There is a clear separation between the two regions by a free energy barrier of about 6–7.5 kcal/mol. |
| T150 |
4972-5087 |
Sentence |
denotes |
These two states correspond to the loop motions in the L3 as well as the motion in C-terminal residues of SARS-COV. |
| T151 |
5088-5236 |
Sentence |
denotes |
The L3 motion in nCOV-2019 is stabilized by the H-bond between N487 on RBD and Y83 on ACE2 as well as a π-stacking interaction between F486 and Y83. |
| T152 |
5237-5433 |
Sentence |
denotes |
It is evident that the nCOV-2019 RBD is more stable than SASR-COV RBD and exists in one conformation whereas the SARS-COV interface fluctuates and the aFEL is separated into two different regions. |
| T153 |
5434-5655 |
Sentence |
denotes |
The first two eigenvectors were used to calculate and plot the aFEL as a function of first two principal components using the last 200 ns of the simulation for mutant systems. aFEL for other systems is shown in Figure S4. |
| T154 |
5656-5815 |
Sentence |
denotes |
Figure 5 Mapping of the principal components of the RBD for the aFEL from the last 400 ns of simulations for SARS-COV (top row) and nCOV-2019-wt (bottom row). |
| T155 |
5816-5874 |
Sentence |
denotes |
The color bar is relative to the lowest free energy state. |
| T156 |
5875-6153 |
Sentence |
denotes |
In each system, the first eigenvector was used to construct the porcupine plots to visualize the most dominant movements (Figure S5). nCOV-2019 showed a small motion in L3 and the core region and the extended loop region are very rigid showing small cones in the porcupine plot. |
| T157 |
6154-6259 |
Sentence |
denotes |
The core structure of the RBD remains dormant as the cones are blue in most of the regions (Figure S5-A). |
| T158 |
6260-6329 |
Sentence |
denotes |
In SARS-COV, the C-terminal region shows large motions (Figure S5-B). |
| T159 |
6330-6387 |
Sentence |
denotes |
Mutation N487A showed a large motion in L1 (Figure S5-C). |
| T160 |
6388-6466 |
Sentence |
denotes |
Mutations Y449A, G447A, and E484A demonstrate large motions in L3 (Figure S5). |
| T161 |
6467-6576 |
Sentence |
denotes |
Overall, these plots show the involvement of these residues in the dynamic stability of the RBD/ACE2 complex. |
| T162 |
6578-6582 |
Sentence |
denotes |
DCCM |
| T163 |
6583-6829 |
Sentence |
denotes |
The correlated motions of RBD atoms were also analyzed with the DCCM based on the Cα atoms of RBD from the last 400 ns of simulation for nCOV-2019, SARS-COV, and extended mutant systems and the last 200 ns for the other mutant systems (Figure 6). |
| T164 |
6830-7029 |
Sentence |
denotes |
The DCCM for nCOV-2019 showed a correlation between residues 490–505 (containing α5, L4 and β5 regions) and residues 440–455 (containing α4, L1 and β5 regions) shown in the red rectangle in Figure 6. |
| T165 |
7030-7117 |
Sentence |
denotes |
This correlation showed the coordination of these regions for binding ACE2 effectively. |
| T166 |
7118-7236 |
Sentence |
denotes |
Another important correlation that appears in the DCCM of nCOV-2019 is between residues 473–481 with residues 482–491. |
| T167 |
7237-7338 |
Sentence |
denotes |
These residues are in L3 and β6 regions and their correlation in nCOV-2019 is stronger than SARS-COV. |
| T168 |
7339-7450 |
Sentence |
denotes |
This is due to the presence of the β6 strand in nCOV-2019, whereas in SARS-COV these residues all belong to L3. |
| T169 |
7451-7640 |
Sentence |
denotes |
This indicates that L3 in nCOV-2019 has evolved from SARS-COV to adopt a new secondary structure, which causes strong correlation and makes the loop act as a recognition region for binding. |
| T170 |
7641-7704 |
Sentence |
denotes |
The correlation in L3 is shown as a blue rectangle in Figure 6. |
| T171 |
7705-7801 |
Sentence |
denotes |
Some of the mutations disrupted the patterns of correlation and anticorrelation in nCOV-2019-wt. |
| T172 |
7802-7890 |
Sentence |
denotes |
Mutation N487A showed a stronger correlation in L3 and β6 strand than the wild-type RBD. |
| T173 |
7891-7962 |
Sentence |
denotes |
In mutation E484A, correlation in L3 is stronger than the nCOV-2019-wt. |
| T174 |
7963-8009 |
Sentence |
denotes |
DCCM for other mutants are shown in Figure S6. |
| T175 |
8010-8181 |
Sentence |
denotes |
It is worth mentioning that mutation F486A disrupts the DCCM of nCOV-2019 by introducing strong correlations in the core region of RBD as well as the extended loop region. |
| T176 |
8182-8331 |
Sentence |
denotes |
Residue F486 resides in L3 and plays a crucial role in stabilizing the recognition loop by making a π-stacking interaction with residue Y83A on ACE2. |
| T177 |
8332-8423 |
Sentence |
denotes |
Figure 6 DCCM for nCOV-2019, SARS-COV, and mutants with residue numbers of the RBD domain. |
| T178 |
8424-8513 |
Sentence |
denotes |
Red boxes show the correlation between α5, L4, and β5 regions and α4, L1, and β5 regions. |
| T179 |
8514-8567 |
Sentence |
denotes |
Blue boxes show the correlation in L3 and β6 regions. |
| T180 |
8569-8590 |
Sentence |
denotes |
Binding Free Energies |
| T181 |
8591-9095 |
Sentence |
denotes |
The binding energetics between ACE2 and the RBD of SARS-COV, nCOV-2019, and all its mutant complexes were investigated by the MMPBSA method.48 The binding energy was partitioned into its individual components including: electrostatic, van der Waals, polar solvation, and SASA to identify important factors affecting the interface of RBD and ACE2 in all complexes. nCOV-2019 has a total binding energy of −50.22 ± 1.93 kcal/mol, whereas SARS-COV has a much higher binding energy of −18.79 ± 1.53 kcal/mol. |
| T182 |
9096-9338 |
Sentence |
denotes |
Decomposition of binding energy to its components show that the most striking difference between nCOV-2019 and SARS-COV is the electrostatic contribution which is −746.69 ± 2.66 kcal/mol for nCOV-2019 and −600.14 ± 7.65 kcal/mol for SARS-COV. |
| T183 |
9339-9643 |
Sentence |
denotes |
This high electrostatic contribution is compensated by a large polar solvation free energy which is 797.30 ± 3.12kcal/mol for nCOV-2019 and 659.61 ± 8.98 kcal/mol for SARS-COV. nCOV-2019 also possess a higher van der Waals (vdw) contribution (−89.93 ± 0.46 kcal/mol than SARS-COV (−70.07 ± 1.22 kcal/mol. |
| T184 |
9644-9763 |
Sentence |
denotes |
Furthermore, the SASA contribution to binding for SARS-COV was −8.30 ± 0.15 kcal/mol and −10.58 kcal/mol for nCOV-2019. |
| T185 |
9764-9895 |
Sentence |
denotes |
Both hydrophobic and electrostatic interactions play major roles in the higher affinity of nCOV-2019 RBD than SARS-COV RBD to ACE2. |
| T186 |
9896-10152 |
Sentence |
denotes |
The binding free energies for nCOV-2019 and SARS-COV were decomposed into a per-residue based binding energy to find the residues that contribute strongly to the binding and are responsible for higher binding affinity of nCOV-2019 than SARS-COV (Figure 7). |
| T187 |
10153-10272 |
Sentence |
denotes |
Most of the residues in the RBM of nCOV-2019 had more favorable contribution to the total binding energy than SARS-COV. |
| T188 |
10273-10423 |
Sentence |
denotes |
Residues Q498, Y505, N501, Q493, and K417 in nCOV-2019 RBM contributed more than 5 kcal/mol to binding affinity and are crucial for complex formation. |
| T189 |
10424-10513 |
Sentence |
denotes |
A few residues such as E484 and S494 contributed unfavorably to the total binding energy. |
| T190 |
10514-10634 |
Sentence |
denotes |
Among all the interface residues K417 had the highest contribution to the total binding energy (−12.34 ± 0.23 kcal/mol). |
| T191 |
10635-10805 |
Sentence |
denotes |
The corresponding residue in SARS-COV is V404 only had a −0.02 ± 0.01 kcal/mol contribution, which points to the importance of this residue for nCOV-2019 binding to ACE2. |
| T192 |
10806-10964 |
Sentence |
denotes |
Residue Q498 contributed −6.72 ± 0.18 kcal/mol and its corresponding residue in SARS-COV is a Y484 that contributed to total binding by −1.83 ± 0.06 kcal/mol. |
| T193 |
10965-11144 |
Sentence |
denotes |
Other important residues Y505 and N501 have more negative contribution to total binding energy than their counterparts in SARS-COV residues Y491 and T487, respectively (Figure 7). |
| T194 |
11145-11365 |
Sentence |
denotes |
Residue D480 in SARS-COV contributed positively to binding energy by 6.2 ± 0.15 kcal/mol and the corresponding residue in nCOV-2019 which is a S494 residue lowered this positive contribution to only 1.17 ± 0.06 kcal/mol. |
| T195 |
11366-11774 |
Sentence |
denotes |
Mutation D480A/G appeared to be a dominant mutation in SARS-COV in 2002–2003.51 This mutation was reported to escape neutralization by antibody 80R.52 To investigate the effect of this point mutation on binding of SARS-COV RBD to ACE2 we performed an additional simulation and calculated the binding affinity for this mutant in SARS-COV RBD with the same approach for other mutation in this study (Figure 8). |
| T196 |
11775-11906 |
Sentence |
denotes |
D480A mutation showed a binding affinity of 23.46 ± 3.07 kcal/mol which is about 5 kcal/mol higher than the wild-type SARS-COV RBD. |
| T197 |
11907-12114 |
Sentence |
denotes |
In SARS-COV, residue R426 had the highest contribution to the total binding energy (−6.27 ± 0.22 kcal/mol although the corresponding residue in nCOV-2019 is N439 with a contribution of −0.32 ± 0.02 kcal/mol. |
| T198 |
12115-12260 |
Sentence |
denotes |
These important mutations on RBM of nCOV-2019 from SARS-COV caused RBD of nCOV-2019 to bind ACE2 with much stronger (about 30 kcal/mol) affinity. |
| T199 |
12261-12350 |
Sentence |
denotes |
Figure 7 Binding energy decomposition per residue for the RBM of nCOV-2019 and SARS-COV. |
| T200 |
12351-12423 |
Sentence |
denotes |
Figure 8 Total free binding energy of SARS-COV, nCOV-2019, and mutants. |
| T201 |
12424-12473 |
Sentence |
denotes |
Natural mutants are shown with X at the bar base. |
| T202 |
12474-12580 |
Sentence |
denotes |
Binding free energy decomposition to its individual components for all mutants is represented in Table S2. |
| T203 |
12581-12767 |
Sentence |
denotes |
In all complexes, a large positive polar solvation free energy disfavors the binding and complex formation, which is compensated by a large negative electrostatic free energy of binding. |
| T204 |
12768-12807 |
Sentence |
denotes |
All variants had similar SASA energies. |
| T205 |
12808-12921 |
Sentence |
denotes |
The vdw free energy of binding ranged from −84.68 ± 0.68 kcal/mol for Q493A to −103.85 ± 0.66 kcal/mol for Y489A. |
| T206 |
12922-13159 |
Sentence |
denotes |
Mutant K417A had the lowest electrostatic contribution to binding −415.67 ± 5.07 kcal/mol and mutants N439K and E484A had the highest electrostatic binding contribution of −989.80 ± 5.6 kcal/mol and −941.20 ± 3.95 kcal/mol, respectively. |
| T207 |
13160-13322 |
Sentence |
denotes |
Most alanine substitutions exhibited similar or lower total binding affinities to nCOV-2019, however a few mutants had higher binding affinity than the wild type. |
| T208 |
13323-13453 |
Sentence |
denotes |
Mutant Y489A had a total binding energy of −61.78 ± 2.59 kcal/mol which was about 11 kcal/mol lower than wild type binding energy. |
| T209 |
13454-13551 |
Sentence |
denotes |
Mutants G446A, G447A, and T478I also demonstrated higher total binding affinities than nCOV-2019. |
| T210 |
13552-13637 |
Sentence |
denotes |
Other alanine substitutions had similar or lower total binding energy than nCOV-2019. |
| T211 |
13638-13753 |
Sentence |
denotes |
Mutant G502A has the lowest binding affinity among all the mutants with a binding energy of −24.31 ± 2.98 kcal/mol. |
| T212 |
13754-13899 |
Sentence |
denotes |
Mutant systems K417A, L455A, T500A, and N501A are the other mutants with total binding affinities significantly lower than the wild type complex. |
| T213 |
13900-14008 |
Sentence |
denotes |
The electrostatic component of binding contributes the most to the low binding affinities for these mutants. |
| T214 |
14009-14135 |
Sentence |
denotes |
The contribution of RBM residues to binding with ACE2 for nCOV-2019 was mapped to the RBD structure and is shown in Figure 9B. |
| T215 |
14136-14281 |
Sentence |
denotes |
Figure 9 (A) H bonds between RBD of nCOV-2019 and SARS-COV. (B) Mapping contribution of interface residues to structure in the RBD of nCOV-2019. |
| T216 |
14282-14323 |
Sentence |
denotes |
The RBD is purple and the ACE2 is yellow. |
| T217 |
14324-14501 |
Sentence |
denotes |
The RBD in contact with AC2 is rendered in a surface format with more red being a favorable contribution to binding (more negative) and blue unfavorable contribution (positive). |
| T218 |
14502-14614 |
Sentence |
denotes |
Most natural mutants exhibited similar binding affinities compared to wild-type nCOV-2019 with a few exceptions. |
| T219 |
14615-14786 |
Sentence |
denotes |
Mutation T478I which is one of the most frequent mutations based on the GISAID database has a binding affinity which is about 6 kcal/mol higher than that of the wild-type. |
| T220 |
14787-14871 |
Sentence |
denotes |
S494P and A475V showed a slightly lower binding affinity than the wild-type complex. |
| T221 |
14872-14945 |
Sentence |
denotes |
Other natural mutants showed binding affinities similar to wild-type RBD. |
| T222 |
14946-15145 |
Sentence |
denotes |
N439K demonstrated a high electrostatic energy which is compensated by large polar solvation energy and this mutant has a total binding energy of −48.27 ± 3.07 kcal/mol which is similar to nCOV-2019. |
| T223 |
15147-15207 |
Sentence |
denotes |
Hydrogen Bond, Salt-Bridge, and Hydrophobic Contact Analysis |
| T224 |
15208-15512 |
Sentence |
denotes |
Important hydrogen bonds (H-bonds) and salt bridges between nCOV-2019 RBD or SARS-COV RBD and ACE2 for the last 400 ns of trajectory are shown in Table 1. nCOV-2019 RBD makes 10 H-bonds/1 salt bridge with ACE2, whereas SARS-COV makes only 5 H-bonds/1 salt bridge with ACE2 with more than 30% persistence. |
| T225 |
15513-15618 |
Sentence |
denotes |
Table 1 H-Bonds and Salt-Bridges between nCOV-2019 and ACE2 and SARS-COV and ACE2 that Persist for >30%a |
| T226 |
15619-15679 |
Sentence |
denotes |
# nCOV-2019 ACE2 % occupancy SARS-COV ACE2 % occupancy |
| T227 |
15680-15712 |
Sentence |
denotes |
1 G502 K353 89 Y436 D38 96 |
| T228 |
15713-15748 |
Sentence |
denotes |
2 Q493 E35 83 R426 E329 87 |
| T229 |
15749-15781 |
Sentence |
denotes |
3 N487 Y83 80 T486 D355 83 |
| T230 |
15782-15814 |
Sentence |
denotes |
4 Q498 D38 73 G488 K353 80 |
| T231 |
15815-15849 |
Sentence |
denotes |
5 K417 D30 55 N479 K31 52 |
| T232 |
15850-15882 |
Sentence |
denotes |
6 T500 D355 53 Y440 H34 47 |
| T233 |
15883-15908 |
Sentence |
denotes |
7 Y505 E37 52 |
| T234 |
15909-15935 |
Sentence |
denotes |
8 Q498 K353 49 |
| T235 |
15936-15961 |
Sentence |
denotes |
9 Y449 D38 45 |
| T236 |
15962-15989 |
Sentence |
denotes |
10 G496 K353 37 |
| T237 |
15990-16016 |
Sentence |
denotes |
11 Q493 K31 32 |
| T238 |
16017-16049 |
Sentence |
denotes |
a Salt bridge is shown as bold. |
| T239 |
16050-16164 |
Sentence |
denotes |
The evolution of the coronavirus from SARS-COV to nCOV-2019 has reshaped the interfacial hydrogen bonds with ACE2. |
| T240 |
16165-16233 |
Sentence |
denotes |
G502 in nCOV-2019 has a persistent H-bond with residue K353 on ACE2. |
| T241 |
16234-16315 |
Sentence |
denotes |
This residue was G488 in SARS-COV, which also makes the H-bond with K353 on ACE2. |
| T242 |
16316-16392 |
Sentence |
denotes |
Q493 in nCOV-2019 makes H-bond with E35 and another H-bond with K31 on ACE2. |
| T243 |
16393-16476 |
Sentence |
denotes |
This residue was an N479 in SARS-COV, which only makes one H-bond with K31 on ACE2. |
| T244 |
16477-16570 |
Sentence |
denotes |
An important mutation from SARS-COV to nCOV-2019 is residue Q498, which was Y484 in SARS-COV. |
| T245 |
16571-16681 |
Sentence |
denotes |
Q498 makes two H-bonds with residues D38 and K353 on ACE2, whereas Y484 in SARS-COV does not make any H-bonds. |
| T246 |
16682-16826 |
Sentence |
denotes |
Importantly, a salt bridge between K417 and D30 in the nCOV-2019/ACE2 complex contributes to the total binding energy by −12.34 ± 0.23 kcal/mol. |
| T247 |
16827-16937 |
Sentence |
denotes |
This residue is V404 in SARS-COV which is not able to make any salt-bridge and does not make H-bond with ACE2. |
| T248 |
16938-17083 |
Sentence |
denotes |
Gao et al.27 used a FEP approach and showed that mutation V404 to K417 lowers the binding energy of nCOV-2019 RBD to ACE2 by −2.2 ± 0.9 kcal/mol. |
| T249 |
17084-17175 |
Sentence |
denotes |
A salt bridge between R426 on RBD and E329 on ACE2 stabilizes the complex in SARS-COV/ACE2. |
| T250 |
17176-17269 |
Sentence |
denotes |
This residue is N439 in nCOV-2019 which is unable to make salt-bridge with ACE2 residue E329. |
| T251 |
17270-17441 |
Sentence |
denotes |
One of the most observed mutations in nCOV-2019 according to the GISAID database is N439K which recovers some of the electrostatic interactions with ACE2 at this position. |
| T252 |
17442-17516 |
Sentence |
denotes |
Y436 in SARS-COV and Y449 in nCOV-2019 both make H-bonds with D38 on ACE2. |
| T253 |
17517-17643 |
Sentence |
denotes |
The unchanged T486 in SARS-COV corresponds to T500 in nCOV-2019, both of which make consistent H-bonds with ACE2 residue D355. |
| T254 |
17644-17746 |
Sentence |
denotes |
Hydrophobic interactions also play an important role in stabilizing the RBD/ACE2 complex in nCOV-2019. |
| T255 |
17747-17867 |
Sentence |
denotes |
An important interaction between nCOV-2019 RBD and ACE2 is the π-stacking interaction between F486 (RBD) and Y83 (ACE2). |
| T256 |
17868-17970 |
Sentence |
denotes |
This interaction helps in stabilizing L3 in nCOV-2019 compared to SARS-COV where this residue is L472. |
| T257 |
17971-18117 |
Sentence |
denotes |
It was observed by Gao et al.26 that mutation L472 to F486 in nCOV-2019 results in a net change in the binding free energy of −1.2 ± 0.2 kcal/mol. |
| T258 |
18118-18257 |
Sentence |
denotes |
Other interfacial residues in nCOV-2019 RBD that participate in the hydrophobic interaction with ACE2 are L455, F456, Y473, A475, and Y489. |
| T259 |
18258-18347 |
Sentence |
denotes |
It is interesting to note that all these residues except Y489 have mutated from SARS-COV. |
| T260 |
18348-18600 |
Sentence |
denotes |
Spinello and co-workers30 performed long-timescale (1μs) simulation of nCOV-2019/ACE2 and SARS-COV ACE2 and found that L3 in nCOV-2019 is more stable due to presence of the β6 strand and existence of two H-bonds in L3 (H-bonds G485-C488 and Q474-G476). |
| T261 |
18601-18776 |
Sentence |
denotes |
Importantly, an amino acid insertion in L3 makes this loop longer than L3 in SARS-COV and enables it to act like a recognition loop and make more persistent H-bonds with ACE2. |
| T262 |
18777-18937 |
Sentence |
denotes |
L455 in nCOV-2019 RBD is important for hydrophobic interaction with ACE2 and mutation L455A lowers the vdw contribution of binding affinity by about 5 kcal/mol. |
| T263 |
18938-19011 |
Sentence |
denotes |
The H-bonds between RBD of nCOV-2019 and SARS-COV are shown in Figure 9A. |
| T264 |
19012-19135 |
Sentence |
denotes |
The structural details discussed here are in agreement with other structural studies of the nCOV-2019 RBD/ACE2 complex.4,53 |
| T265 |
19136-19275 |
Sentence |
denotes |
H-bond analysis was also performed for the mutant systems and the results for H-bonds with more than 40% consistency are shown in Table S3. |
| T266 |
19276-19383 |
Sentence |
denotes |
Few of the alanine substitutions increase the number of interfacial H-bonds between nCOV-2019 RBD and ACE2. |
| T267 |
19384-19486 |
Sentence |
denotes |
Interestingly, the ala-substitution at Y489A increased the number of H-bonds in the wild-type complex. |
| T268 |
19487-19663 |
Sentence |
denotes |
Mutation in some of the residues having consistent H-bonds in the wild type complex such as Q498A and Q493A, stunningly maintain the number of H-bonds in the wild-type complex. |
| T269 |
19664-19831 |
Sentence |
denotes |
This indicates that the plasticity in the network of H-bonds in RBM of nCOV-2019 can reshape the network and strengthen other H-bonds upon mutation in these locations. |
| T270 |
19832-19913 |
Sentence |
denotes |
However, few mutations decrease the number of H-bonds from the wild-type complex. |
| T271 |
19914-20033 |
Sentence |
denotes |
Alanine substitution at residue G502 has a significant effect on the network of H-bonds between nCOV-2019 and SARS-COV. |
| T272 |
20034-20125 |
Sentence |
denotes |
This residue locates at the end of L4 loop near two other important residues Q498 and T500. |
| T273 |
20126-20177 |
Sentence |
denotes |
This mutation breaks the H-bonds at these residues. |
| T274 |
20178-20278 |
Sentence |
denotes |
Mutation K417A decreases the number of H-bonds to only 5 where the H-bond at residue Q498 is broken. |
| T275 |
20279-20413 |
Sentence |
denotes |
This indicates the delicate nature of the H-bond from residue Q498 which can easily be broken upon ala-substitution at other residues. |
| T276 |
20414-20509 |
Sentence |
denotes |
Furthermore, mutation N487 also decreases the number of H-bonds by breaking the H-bond at Q498. |
