def sample_refinement(pdb_filename, kT=1.0, smallmoves=3, shearmoves=5, backbone_angle_max=7, cycles=9, jobs=1, job_output='refine_output'): """ Performs fullatom structural refinement on the input <pdb_filename> by perturbing backbone torsion angles with a maximum perturbation of <backbone_angle_max> for <cycles> trials of <smallmoves> perturbations of a random residue's phi or psi and <shearmoves> perturbations of a random residue's phi and the preceding residue's psi followed by gradient based backbone torsion angle minimization and sidechain packing with an acceptance criteria scaled by <kT>. <jobs> trajectories are performed, continually exporting structures to a PyMOL instance. Output structures are named <job_output>_(job#).pdb. """ # 1. create a pose from the desired PDB file pose = Pose() pose_from_file(pose, pdb_filename) # 2. create a reference copy of the pose in fullatom starting_pose = Pose() starting_pose.assign(pose) # 3. create a standard ScoreFunction #### implement the desired ScoreFunction here scorefxn = get_fa_scorefxn() # create_score_function('standard') #### If you wish to use the ClassRelax protocol, uncomment the following #### line and comment-out the protocol setup below #refinement = protocols.relax.ClassicRelax( scorefxn ) #### Setup custom high-resolution refinement protocol #### backbone refinement protocol # 4. create a MoveMap, all backbone torsions free movemap = MoveMap() movemap.set_bb(True) # 5. create a SmallMover # a SmallMover perturbs a random (free in the MoveMap) residue's phi or psi # torsion angle for an input number of times and accepts of rejects this # change based on the Metropolis Criteria using the "rama" ScoreType and # the parameter kT # set the maximum angle to backbone_angle_max, apply it smallmoves times smallmover = protocols.simple_moves.SmallMover(movemap, kT, smallmoves) # angle_max is secondary structure dependent, however secondary structure # has not been evaulated in this protocol, thus they are all set # to the same value0 smallmover.angle_max(backbone_angle_max) # sets all at once #### use the overloaded version of the SmallMover.angle_max method if you #### want to use secondary structure biased moves #smallmover.angle_max('H', backbone_angle_max) #smallmover.angle_max('E', backbone_angle_max) #smallmover.angle_max('L', backbone_angle_max) # 6. create a ShearMover # a ShearMover is identical to a SmallMover except that the angles perturbed # are instead a random (free in the MoveMap) residue's phi and the # preceding residue's psi, this reduces the downstream structural change # set the maximum angle to backbone_angle_max, apply it shearmoves times shearmover = protocols.simple_moves.ShearMover(movemap, kT, shearmoves) # same angle_max restictions as SmallMover shearmover.angle_max(backbone_angle_max) #### use the overloaded version of the SmallMover.angle_max method if you #### want to use secondary structure biased moves #shearmover.angle_max('H', backbone_angle_max) #shearmover.angle_max('E', backbone_angle_max) #shearmover.angle_max('L', backbone_angle_max) # 7. create a MinMover, for backbone torsion minimization minmover = protocols.minimization_packing.MinMover() minmover.movemap(movemap) minmover.score_function(scorefxn) #### sidechain refinement protocol, simple packing # 8. setup a PackRotamersMover to_pack = standard_packer_task(starting_pose) to_pack.restrict_to_repacking() # prevents design, packing only to_pack.or_include_current(True) # considers the original sidechains packmover = protocols.minimization_packing.PackRotamersMover( scorefxn, to_pack) #### assess the new structure # 9. create a PyMOLMover pymover = PyMOLMover() # uncomment the line below to load structures into successive states #pymover.keep_history(True) #### the PyMOLMover slows down the protocol SIGNIFICANTLY but provides #### very informative displays #### the keep_history flag (when True) tells the PyMOLMover to store new #### structures into successive states, for a single trajectory, this #### allows you to see intermediate changes (depending on where the #### PyMOLMover is applied), when using a JobDistributor or otherwise #### displaying multiple trajectories with a single protocol, the output #### can get confusing to interpret, by changing the pose's PDBInfo.name #### the structure will load into a new PyMOL state #### try uncommenting the lines below to see different output #pymover.update_energy(True) # see the total score in color # 10. export the original structure, and scores, to PyMOL pymover.apply(pose) scorefxn(pose) pymover.send_energy(pose) # 11. setup a RepeatMover on a TrialMover of a SequenceMover (wow!) # -setup a TrialMover # a. create a SequenceMover of the previous moves #### add any other moves you desire combined_mover = SequenceMover() combined_mover.add_mover(smallmover) combined_mover.add_mover(shearmover) combined_mover.add_mover(minmover) combined_mover.add_mover(packmover) #### explore the protocol using the PyMOLMover, try viewing structures #### before they are accepted or rejected combined_mover.add_mover(pymover) # b. create a MonteCarlo object to define success/failure mc = MonteCarlo(pose, scorefxn, kT) # must reset for each trajectory! # c. create the TrialMover trial = TrialMover(combined_mover, mc) #### explore the protocol using the PyMOLMover, try viewing structures #### after acceptance/rejection, comment-out the lines below #original_trial = TrialMover(combined_mover, mc) #trial = SequenceMover() #trial.add_mover(original_trial) #trial.add_mover(pymover) #### for each trajectory, try cycles number of applications # -create the RepeatMover refinement = RepeatMover(trial, cycles) #### # 12. create a (Py)JobDistributor jd = PyJobDistributor(job_output, jobs, scorefxn) jd.native_pose = starting_pose # 13. store the score evaluations for output # printing the scores as they are produced would be difficult to read, # Rosetta produces a lot of verbose output when running scores = [0] * (jobs + 1) scores[0] = scorefxn(starting_pose) # 14. perform the refinement protocol counter = 0 # for exporting to PyMOL while not jd.job_complete: # a. set necessary variables for the new trajectory # -reload the starting pose pose.assign(starting_pose) # -change the pose's PDBInfo.name, for the PyMOLMover counter += 1 pose.pdb_info().name(job_output + '_' + str(counter)) # -reset the MonteCarlo object (sets lowest_score to that of p) mc.reset(pose) #### if you create a custom protocol, you may have additional #### variables to reset, such as kT #### if you create a custom protocol, this section will most likely #### change, many protocols exist as single Movers or can be #### chained together in a sequence (see above) so you need #### only apply the final Mover # b. apply the refinement protocol refinement.apply(pose) #### # c. output the lowest scoring decoy structure for this trajectory # -recover and output the decoy structure to a PDB file mc.recover_low(pose) jd.output_decoy(pose) # -export the final structure to PyMOL for each trajectory pose.pdb_info().name(job_output + '_' + str(counter) + '_final') pymover.apply(pose) pymover.send_energy(pose) # see the total score in color # -store the final score for this trajectory scores[counter] = scorefxn(pose) # 15. output the score evaluations print('Original Score\t:\t', scores[0]) for i in range(1, len(scores)): # print out the job scores print(job_output + '_' + str(i) + '\t:\t', scores[i]) return scores # for other protocols
def sample_single_loop_modeling(pdb_filename, loop_begin, loop_end, loop_cutpoint, frag_filename, frag_length, outer_cycles_low=2, inner_cycles_low=5, init_temp_low=2.0, final_temp_low=0.8, outer_cycles_high=5, inner_cycles_high=10, init_temp_high=2.2, final_temp_high=0.6, jobs=1, job_output='loop_output'): """ Performs simple single loop construction on the input <pdb_filename> with loop from <loop_begin> to <loop_end> with a cutpoint at <loop_cutpoint> using fragments of length <frag_length> in the file <frag_filename>. <jobs> trajectories are performed, each using a low resolution (centroid) simulated annealing with <outer_cycles> rounds and <inner_cycles> steps per round decrementing "temperature" from <init_temp> to <final_temp> geometrically. Output structures are named <job_output>_(job#).pdb. """ # 1. create a pose from the desired PDB file p = Pose() pose_from_file(p, pdb_filename) # 2. create a reference copy of the pose in fullatom starting_p = Pose() starting_p.assign(p) #### if you are constructing multiple loops simultaneously, changes will #### occur in most of the steps below # 3. create the Loop object # (note: Loop objects merely specify residues, they contain no # conformation data) my_loop = protocols.loops.Loop(loop_begin, loop_end, loop_cutpoint) #### if using multiple loops, add additional Loop objects # 4. use the Loop to set the pose FoldTree protocols.loops.set_single_loop_fold_tree(p, my_loop) #### alternate FoldTree setup, if you uncomment the lines below, #### comment-out the set_single_loop_foldtree line above (line 189) #### -create an empty FoldTree #ft = FoldTree() #### -make it a single edge the length of pose #ft.simple_tree(p.total_residue()) #### -insert a jump corresponding to the single loop region #ft.add_jump(loop_begin - 2, loop_end + 2, loop_cutpoint) #### -give the pose this FoldTree (set it to this object), this will #### erase any previous FoldTree held by the pose #p.fold_tree(ft) #### there is also a fold_tree_from_loops method in exposed which sets up #### a FoldTree but it is different from set_single_loop_foldtree in #### that is creates jumps +/- 1 residue from their corresponding loop #### endpoints and requires a third argument, the FoldTree to setup # 5. sets the cut-point residues as cut-point variants protocols.loops.add_single_cutpoint_variant(p, my_loop) # 6. create the MoveMap, allow the loop region backbone and # all chi torsions to be free movemap = MoveMap() movemap.set_bb_true_range(loop_begin, loop_end) movemap.set_chi(True) # sets all chi torsions free # 7. setup the fragment Mover # this "try--except" is used to catch improper fragment files try: fragset = core.fragment.ConstantLengthFragSet(frag_length, frag_filename) #### the ConstantLengthFragSet is overloaded, this same #### ConstantLengthFragSet can be obtained with different syntax # to obtain custom fragments, see Generating Fragment Files below except: raise IOError('Make sure frag_length matches the fragments in\n\ frag_file and that frag_file is valid') fragment_mover = protocols.simple_moves.ClassicFragmentMover( fragset, movemap) # 8. create a Mover for loop modeling using CCD (low resolution) ccd_closure = protocols.loops.loop_closure.ccd.CCDLoopClosureMover( my_loop, movemap) # 9. create ScoreFunctions # for centroid, use the default centroid ScoreFunction with chainbreak on scorefxn_low = create_score_function('cen_std') # the chainbreak ScoreType exists to penalize broken bonds # try creating a broken pose in the interpreter and use a ScoreFunction # with a chainbreak score to investigate its impact, the score is 0.0 # except when a bond is broken # this penalizes failures caused by CCD failing to close the loop scorefxn_low.set_weight(core.scoring.chainbreak, 1) # for fullatom, used for packing and scoring final output scorefxn_high = get_fa_scorefxn( ) # create_score_function_ws_patch('standard', 'score12') # 10. setup sidechain packing Mover task_pack = core.pack.task.TaskFactory.create_packer_task(starting_p) task_pack.restrict_to_repacking() # prevents design, packing only task_pack.or_include_current(True) # considers original sidechains pack = protocols.minimization_packing.PackRotamersMover( scorefxn_high, task_pack) # 11. setup the high resolution refinement # by creating a Loops object, # (note: Loops is basically a list of Loop objects), sample_loops = protocols.loops.Loops() # giving it the loop to remodel, sample_loops.add_loop(my_loop) # and creating a fullatom CCD Mover (high resolution) # this Mover is somewhat abnormal since it handles everything itself, it: # -creates its own MoveMap for the loop regions # -creates its own ScoreFunction (default to get_fa_scorefxn()) # -creates its own FoldTree for the pose based on the loops # -creates its own MonteCarlo object for monitoring the pose # -performs "simulated annealing" with 3 outer cycles and 90 inner # cycles, very similar to the protocol outlined ere # -creates its own backbone Movers (SmallMover, ShearMover) # -creates its own PackRotamersMover, it does NOT restrict repacking # to the loop regions and can alter all sidechain conformations loop_refine = LoopMover_Refine_CCD(sample_loops) # some of these parameters or objects can be set but the protocol # executed by this Mover is effectively untouchable #loop_refine.set_score_function(scorefxn_high) # in beta v2 and above loop_refine.temp_initial(init_temp_high) loop_refine.temp_final(init_temp_high) loop_refine.outer_cycles(outer_cycles_high) loop_refine.max_inner_cycles(inner_cycles_high) # 12. create centroid <--> fullatom conversion Movers to_centroid = SwitchResidueTypeSetMover('centroid') to_fullatom = SwitchResidueTypeSetMover('fa_standard') # and a Mover to recover sidechain conformations # when a protocol samples backbone torsion space in centroid, # the sidechain conformations are neglected, when it is transferred # to fullatom, we typically set the sidechain conformations to their # "original" values and perform sidechain packing, # a ReturnSidechainMover saves a pose's sidechains (in this case # staring_pose) and when applied, inserts these conformations # into the input pose recover_sidechains = protocols.simple_moves.ReturnSidechainMover( starting_p) # 13. create a reference copy of the pose in centroid # the first stage of each trajectory is in centroid # so a centroid reference is needed and the pose must start in centroid to_centroid.apply(p) starting_p_centroid = Pose() starting_p_centroid.assign(p) # 14. create the geometric "temperature" increment for simulated annealing gamma = pow((final_temp_low / init_temp_low), (1.0 / (outer_cycles_low * inner_cycles_low))) # 15. create a PyMOLMover for exporting structures to PyMOL pymov = PyMOLMover() # uncomment the line below to load structures into successive states #pymov.keep_history(True) scorefxn_high(starting_p) # for exporting the scores pymov.apply(starting_p) pymov.send_energy(starting_p) # 16. create a (Py)JobDistributor # a PyJobDistributor uses the job_output argument to name all output files # and performs the specified number (int) of jobs # a ScoreFunction is required since the PyJobDistributor output .fasc file # contains scoring information about each output PDB jd = PyJobDistributor(job_output, jobs, scorefxn_high) jd.native_pose = starting_p # 17. perform the loop modeling protocol counter = 0 # for exporting to PyMOL while not jd.job_complete: # a. set necessary variables for the new trajectory # -reload the starting pose (centroid) p.assign(starting_p_centroid) # -change the pose's PDBInfo.name, for exporting to PyMOL counter += 1 p.pdb_info().name(job_output + '_' + str(counter) + '_cen') # -reset the starting "temperature" (to init_temp) kT = init_temp_low # -create a MonteCarlo object for this trajectory # a MonteCarlo object assesses pass/fail by the Metropolis Criteria # and also records information on the lowest scoring pose mc = MonteCarlo(p, scorefxn_low, kT) # b. "randomize" the loop #### this section may change if you intend to use multiple loops or #### alter the sampling method to "randomize" the loop # -by breaking it open, for i in range(loop_begin, loop_end + 1): p.set_phi(i, -180) p.set_psi(i, 180) pymov.apply(p) # -and then inserting fragments # the number of insertions performed is somewhat arbitrary for i in range(loop_begin, loop_end + 1): fragment_mover.apply(p) pymov.apply(p) #### # low resolution loop modeling: # c. simulated annealing incrementing kT geometrically # from init_temp to final_temp #### this section may change if you intend to use multiple loops or #### alter the sampling method for low resolution modeling for i in range(1, outer_cycles_low + 1): # -start with the lowest scoring pose mc.recover_low(p) # loads mc's lowest scoring pose into p # -take several steps of in the simulated annealing by for j in range(1, inner_cycles_low + 1): # >increasing the "temperature" kT = kT * gamma mc.set_temperature(kT) # >inserting a fragment, fragment_mover.apply(p) pymov.apply(p) # >performing CCD, ccd_closure.apply(p) pymov.apply(p) # >and assessing the Metropolis Criteria mc.boltzmann(p) #### # the LoopMover_Refine_CCD makes A LOT of moves, DO NOT expect to # see useful results if you use the PyMOLMover keep_history option, the large # number of intermediates will slow processing to a halt # d. convert the best structure (lowest scoring) into fullatom by: # -recovering the best (centroid) structure (lowest scoring), mc.recover_low(p) # loads mc's lowest scoring pose into p # -switching the ResidueTypeSet to fullatom (from centroid), to_fullatom.apply(p) # -recovering the original sidechain conformations, recover_sidechains.apply(p) # -and packing the result (since the backbone conformation has changed) pack.apply(p) pymov.apply(p) p.pdb_info().name(job_output + '_' + str(counter) + '_fa') # high-resolution refinement: #### this section may change if you intend to use multiple loops or #### alter the sampling method for high resolution refinement # e. apply the LoopMover_Refine_CCD loop_refine.apply(p) # f. output the decoy (pose result from this trajectory) # include the loop RMSD (Lrsmd) # -output a PDB file using the PyJobDistributor lrms = protocols.loops.loop_rmsd(p, starting_p, sample_loops, True) jd.additional_decoy_info = ' Lrmsd: ' + str(lrms) jd.output_decoy(p) # -export the structure to PyMOL pymov.apply(p) pymov.send_energy(p)
def sample_docking(pdb_filename, partners, translation = 3.0, rotation = 8.0, jobs = 1, job_output = 'dock_output'): """ Performs protein-protein docking using the Rosetta standard DockingProtocol on the proteins in <pdb_filename> using the relative chain <partners> with an initial perturbation using <translation> Angstroms and <rotation> degrees. <jobs> trajectories are performed with output structures named <job_output>_(job#).pdb. structures are exported to a PyMOL instance. """ # 1. creates a pose from the desired PDB file pose = Pose() pose_from_file(pose, pdb_filename) # 2. setup the docking FoldTree # using this method, the jump number 1 is automatically set to be the # inter-body jump dock_jump = 1 # the exposed method setup_foldtree takes an input pose and sets its # FoldTree to have jump 1 represent the relation between the two docking # partners, the jump points are the residues closest to the centers of # geometry for each partner with a cutpoint at the end of the chain, # the second argument is a string specifying the relative chain partners # such as "A_B" of "LH_A", ONLY TWO BODY DOCKING is supported and the # partners MUST have different chain IDs and be in the same pose (the # same PDB), additional chains can be grouped with one of the partners, # the "_" character specifies which bodies are separated # the third argument...is currently unsupported but must be set (it is # supposed to specify which jumps are movable, to support multibody # docking...but Rosetta doesn't currently) # the FoldTrees setup by this method are for TWO BODY docking ONLY! protocols.docking.setup_foldtree(pose, partners, Vector1([dock_jump])) # 3. create centroid <--> fullatom conversion Movers to_centroid = SwitchResidueTypeSetMover('centroid') to_fullatom = SwitchResidueTypeSetMover('fa_standard') # and a Mover to recover sidechain conformations # when a protocol samples backbone torsion space in centroid, # the sidechain conformations are neglected, when it is transferred # to fullatom, we typically set the sidechain conformations to their # "original" values and perform sidechain packing, # a ReturnSidechainMover saves a pose's sidechains (in this case # staring_pose) and when applied, inserts these conformations # into the input pose recover_sidechains = protocols.simple_moves.ReturnSidechainMover(pose) # 4. convert to centroid to_centroid.apply(pose) # 5. create a (centroid) test pose test_pose = Pose() test_pose.assign(pose) # 6. create ScoreFunctions for centroid and fullatom docking scorefxn_low = create_score_function('interchain_cen') scorefxn_high = create_score_function('docking') # PyRosetta3: scorefxn_high_min = create_score_function_ws_patch('docking', 'docking_min') scorefxn_high_min = create_score_function('docking', 'docking_min') # 7. create Movers for producing an initial perturbation of the structure # the DockingProtocol (see below) can do this but several Movers are # used to demonstrate their syntax # these Movers randomize the orientation (rotation) of each docking partner randomize_upstream = RigidBodyRandomizeMover(pose, dock_jump, partner_upstream) randomize_downstream = RigidBodyRandomizeMover(pose, dock_jump, partner_downstream) # this Mover translates one docking partner away from the other in a random # direction a distance specified by the second argument (in Angstroms) # and rotates this partner randomly by the third argument (in degrees) dock_pert = RigidBodyPerturbMover(dock_jump, translation, rotation) # this Mover randomizes a pose's partners (rotation) spin = RigidBodySpinMover(dock_jump) # this Mover uses the axis defined by the inter-body jump (jump 1) to move # the docking partners close together slide_into_contact = protocols.docking.DockingSlideIntoContact(dock_jump) # 8. setup the MinMover # the MoveMap can set jumps (by jump number) as degrees of freedom movemap = MoveMap() movemap.set_jump(dock_jump, True) # the MinMover can minimize score based on a jump degree of freedom, this # will find the distance between the docking partners which minimizes # the score minmover = protocols.minimization_packing.MinMover() minmover.movemap(movemap) minmover.score_function(scorefxn_high_min) # 9. create a SequenceMover for the perturbation step perturb = protocols.moves.SequenceMover() perturb.add_mover(randomize_upstream) perturb.add_mover(randomize_downstream) perturb.add_mover(dock_pert) perturb.add_mover(spin) perturb.add_mover(slide_into_contact) perturb.add_mover(to_fullatom) perturb.add_mover(recover_sidechains) perturb.add_mover(minmover) # 10. setup the DockingProtocol # ...as should be obvious by now, Rosetta applications have no central # standardization, the DockingProtocol object can be created and # applied to perform Rosetta docking, many of its options and settings # can be set using the DockingProtocol setter methods # here, on instance is created with all default values and the movable jump # is manually set to jump 1 (just to be certain), the centroid docking # ScoreFunction is set and the fullatom docking ScoreFunction is set dock_prot = protocols.docking.DockingProtocol() # contains many docking functions dock_prot.set_movable_jumps(Vector1([1])) # set the jump to jump 1 dock_prot.set_lowres_scorefxn(scorefxn_low) dock_prot.set_highres_scorefxn(scorefxn_high_min) #### you can alternatively access the low and high resolution sections of #### the DockingProtocol, both are applied by the DockingProtocol but #### a novel protocol may only require centroid (DockingLowRes) or #### fullatom (DockingHighRes), uncomment the lines below and their #### application below #docking_low = DockingLowRes() #docking_low.set_movable_jumps(Vector1([1])) #docking_low.set_scorefxn(scorefxn_low) #docking_high = DockingHighRes() #docking_high.set_movable_jumps(Vector1([1])) #docking_high.set_scorefxn(scorefxn_high) # 11. setup the PyJobDistributor jd = PyJobDistributor(job_output, jobs, scorefxn_high) temp_pose = Pose() # a temporary pose to export to PyMOL temp_pose.assign(pose) to_fullatom.apply(temp_pose) # the original pose was fullatom recover_sidechains.apply(temp_pose) # with these sidechains jd.native_pose = temp_pose # for RMSD comparison # 12. setup a PyMOL_Observer (optional) # the PyMOL_Observer object owns a PyMOLMover and monitors pose objects for # structural changes, when changes are detected the new structure is # sent to PyMOL # fortunately, this allows investigation of full protocols since # intermediate changes are displayed, it also eliminates the need to # manually apply the PyMOLMover during a custom protocol # unfortunately, this can make the output difficult to interpret (since you # aren't explicitly telling it when to export) and can significantly slow # down protocols since many structures are output (PyMOL can also slow # down if too many structures are provided and a fast machine may # generate structures too quickly for PyMOL to read, the # "Buffer clean up" message # uncomment the line below to use the PyMOL_Observer ## AddPyMOLObserver(test_pose, True) # 13. perform protein-protein docking counter = 0 # for pretty output to PyMOL while not jd.job_complete: # a. set necessary variables for this trajectory # -reset the test pose to original (centroid) structure test_pose.assign(pose) # -change the pose name, for pretty output to PyMOL counter += 1 test_pose.pdb_info().name(job_output + '_' + str(counter)) # b. perturb the structure for this trajectory perturb.apply(test_pose) # c. perform docking dock_prot.apply(test_pose) #### alternate application of the DockingProtocol pieces #docking_low.apply(test_pose) #docking_high.apply(test_pose) # d. output the decoy structure to_fullatom.apply(test_pose) # ensure the output is fullatom # to PyMOL test_pose.pdb_info().name(job_output + '_' + str( counter ) + '_fa') # to a PDB file jd.output_decoy(test_pose)
# create an appropriate decoy_name using the Protocol_X.dump_dir and input_args.protocol_num decoy_name = GlycanModelProtocol.base_structs_dir + "protocol_%s_decoy" %input_args.protocol_num ########################## #### PYJOBDISTRIBUTOR #### ########################## # imports from pyrosetta import PyJobDistributor # create and use the PyJobDistributor object jd = PyJobDistributor( decoy_name, input_args.nstruct, sf ) jd.native_pose = native_pose cur_decoy_num = 1 # run the appropriate protocol print "Running Protocol %s in a PyJobDistributor..." %input_args.protocol_num while not jd.job_complete: # get a fresh pose object working_pose = native_pose.clone() # name to use specifically in PyMol GlycanModelProtocol.pmm_name = "p%s_decoy%s" %( input_args.protocol_num, cur_decoy_num ) # name to use when dumping the decoy. Should include full path working_pose.pdb_info().name( jd.current_name ) # apply the protocol working_pose.assign( GlycanModelProtocol.apply( working_pose ) ) # collect additional metric data
scorefxn_low = create_score_function("interchain_cen") dock_lowres = protocols.docking.DockingLowRes(scorefxn_low, jump_num) dock_lowres.apply(pose_low) print( CA_rmsd(pose, pose_low) ) print( calc_Lrmsd(pose, pose_low, Vector1([1])) ) # Job Distributor import tempfile output = tempfile.mkstemp()[1] jd = PyJobDistributor(output, 10, scorefxn_low) native_pose = pose_from_file("../test/data/workshops/complex.high.pdb") jd.native_pose = native_pose starting_pose = Pose() starting_pose.assign(pose_low) while (jd.job_complete == False): pose_low.assign(starting_pose) dock_lowres.apply(pose_low) jd.output_decoy(pose_low) # High-Resolution Docking scorefxn_high = create_score_function("ref2015.wts", "docking") dock_hires = protocols.docking.DockMCMProtocol() dock_hires.set_scorefxn(scorefxn_high) dock_hires.set_partners("A_B")