def test_complex_with_single_polymer():
a = Species('A')
b = Species('B')
p = OrderedPolymerSpecies([a, b, a])
#This should just produce a ComplexSpecies around the PolymerSpecies
c2 = Complex([p, Species("S")])
assert c2 == ComplexSpecies([p, Species("S")], called_from_complex=True)
#If the Polymer is in a Conformation, it cannot be Complexed.
pc = PolymerConformation(polymer=p)
assert str(pc.polymers[0]) == str(p)
assert pc.polymers[0].parent == pc
assert p.parent is None
with pytest.raises(ValueError):
c2 = Complex([pc.polymers[0], Species("S")])
#A monomer form the polymer can still be complexed, however
c2 = Complex([pc.polymers[0][0], Species("S")])
assert isinstance(c2.parent, PolymerConformation)
assert c2.parent != pc
assert len(c2.parent.complexes) == 1
assert len(c2.parent.polymers) == 1
assert str(c2) == str(
ComplexSpecies([pc.polymers[0][0], Species("S")],
called_from_complex=True))
def test_contains(self):
s1 = Species(name='s1', material_type="m1")
s2 = Species(name='s2', material_type="m2")
s3 = Species("s3")
c1 = ComplexSpecies([s1, s2, s1], called_from_complex=True)
c2 = ComplexSpecies([c1, s3], called_from_complex=True)
self.assertTrue(s1 in c1)
self.assertTrue(s2 in c1)
self.assertFalse(c1 in c1)
self.assertTrue(s1 in c2)
self.assertTrue(s2 in c2)
self.assertTrue(c1 in c2)
self.assertTrue(s3 in c2)
#contains checks the direction, position, and parent as well.
p = OrderedPolymerSpecies([s1, [s2, "reverse"]])
p2 = OrderedPolymerSpecies([s2, [s2, "reverse"]])
c3 = ComplexSpecies([p[0], p[1]], called_from_complex=True)
assert not s1 in c3
assert not s2 in c3
assert p[0] in c3
assert p[1] in c3
assert not p2[1] in c3
assert p[0] not in c1
def test_complex_with_multiple_polymers():
a = Species('A')
b = Species('B')
p = OrderedPolymerSpecies([a, b, a])
pc0 = PolymerConformation(polymer=p)
p2 = OrderedPolymerSpecies([b, a, b])
pc2 = PolymerConformation(polymer=p2)
#Bind one two monomers from one polymer
#Polymers must be placed into a Conformation before being bound together
with pytest.raises(TypeError):
c = Complex([Species("S"), p[0], p[2]])
c = Complex([Species("S"), pc0.polymers[0][0], pc0.polymers[0][2]])
#Correct parent
assert c.parent == PolymerConformation(
[ComplexSpecies([Species("S"), p[0], p[2]], called_from_complex=True)])
#correct complex returned
assert str(c) == str(
ComplexSpecies([Species("S"), p[0], p[2]], called_from_complex=True))
#Ordered Case
oc = Complex([Species("S"), pc0.polymers[0][0], pc0.polymers[0][2]],
ordered=True)
#Correct parent
assert oc.parent == PolymerConformation([
OrderedComplexSpecies([Species("S"), p[0], p[2]],
called_from_complex=True)
])
#correct complex returned
assert str(oc) == str(
OrderedComplexSpecies([Species("S"), p[0], p[2]],
called_from_complex=True))
#Two polymers which bind together
#Polymers must be placed into a Conformation before being bound together
with pytest.raises(TypeError):
c2 = Complex([Species("S"), p[0], p2[1]])
c2 = Complex([Species("S"), pc0.polymers[0][0], pc2.polymers[0][1]])
assert c2.parent == PolymerConformation([
ComplexSpecies([Species("S"), p[0], p2[1]], called_from_complex=True)
])
assert str(c2) == str(
ComplexSpecies([Species("S"), p[0], p2[1]], called_from_complex=True))
#Two polymers already bound together in a Conformation interacting at a new location
l1 = c2.parent.polymers[0][1]
l2 = c2.parent.polymers[1][0]
c3 = Complex([l1, l2], ordered=True)
assert c3.parent == PolymerConformation([
ComplexSpecies([Species("S"), p[0], p2[1]], called_from_complex=True),
OrderedComplexSpecies([p[1], p2[0]], called_from_complex=True)
])
assert str(c3) == str(
OrderedComplexSpecies([p[1], p2[0]], called_from_complex=True))
def test_species_equality(self):
s1 = Species(name='s1', material_type="m1")
s2 = Species(name='s2', material_type="m2")
c1 = ComplexSpecies([s1, s2])
c2 = ComplexSpecies([s2, s1])
# Check equality of differently ordered complexes
self.assertEqual(c1, c2)
oc1 = OrderedComplexSpecies([s2, s1])
oc2 = OrderedComplexSpecies([s1, s2])
self.assertFalse(oc1 == oc2)
def test_species_equality(self):
s1 = Species(name='s1', material_type="m1")
s2 = Species(name='s2', material_type="m2")
c1 = ComplexSpecies([s1, s2], called_from_complex=True)
c2 = ComplexSpecies([s2, s1], called_from_complex=True)
# Check equality of differently ordered complexes
self.assertEqual(c1, c2)
oc1 = OrderedComplexSpecies([s2, s1], called_from_complex=True)
oc2 = OrderedComplexSpecies([s1, s2], called_from_complex=True)
self.assertFalse(oc1 == oc2)
#check of __contains__
self.assertTrue(s1 in c1)
def test_contains_species_monomer(self):
"""Checks if the ComplexSpecies has a monomer (Species) inside of it,
but without checking Species.parent or Species.position. In effect, a
less stringent version of __contains__. This is useful for checking
complexes containing monomers from Polymers."""
s1 = Species(name='s1', material_type="m1")
s2 = Species(name='s2', material_type="m2")
p = OrderedPolymerSpecies([s1, [s2, "reverse"]])
p2 = OrderedPolymerSpecies([[s2, "reverse"], s1])
c2 = ComplexSpecies([p[0], p[1]], called_from_complex=True)
#Contains parent doesn't matter
assert c2.contains_species_monomer(s1)
assert c2.contains_species_monomer(p[0])
assert c2.contains_species_monomer(p2[0])
#position doesn't matter
assert c2.contains_species_monomer(p2[1])
#Direction does matter (by default)
assert not c2.contains_species_monomer(s2)
#Direction does matter (with keyword)
print("*****")
print(s2 is p2[0], s2, p2[0])
def test_complex_no_polymer():
a = Species('A')
b = Species('B')
#Create a ComplexSpecies
c = Complex([a, b])
assert (c == ComplexSpecies([a, b], called_from_complex=True))
#Ordered Complex
truth = OrderedComplexSpecies([a, Complex([b, a]), a])
testcomplx = Complex([a, Complex([b, a]), a], ordered=True)
assert (truth == testcomplx)
def test_species_initialization(self):
s1 = Species(name='s1')
s2 = Species(name='s2', material_type="m2")
# Check invalidity of ComplexSpecies with fewer than 2 component
with self.assertRaisesRegexp(ValueError,'chemical_reaction_network.complex requires '
'2 or more species in its constructor'):
ComplexSpecies([s1])
# Check invalidity of OrderedComplexSpecies with fewer than 2 component
with self.assertRaisesRegexp(ValueError, 'chemical_reaction_network.complex requires 2 '
'or more species in its constructor.'):
OrderedComplexSpecies([s1])
# Check invalidity of multimers with fewer than 2 component
with self.assertRaisesRegexp(ValueError, 'chemical_reaction_network.complex requires 2 '
'or more species in its constructor'):
Multimer(s1, 1)
# Check the naming conventions
oc1 = OrderedComplexSpecies([s2, s1])
c1 = ComplexSpecies([s2, s1])
m1 = Multimer(s1, 2)
c3 = ComplexSpecies([s1, s1])
# Check validity of ComplexSpecies, Multimers and OrderedComplexSpecies with strings instead of species
self.assertEqual(OrderedComplexSpecies([s2, "s1"]), oc1)
self.assertEqual(ComplexSpecies([s2, "s1"]), c1)
self.assertEqual(Multimer("s1", 2), m1)
# ComplexSpecies should sort the species added alphabetically by representation
self.assertEqual(repr(c1), "complex_"+repr(s2)+"_"+repr(s1))
# OrderedComplexSpecies do not sort their internal species
self.assertEqual(repr(oc1), "ordered_complex_"+repr(s2)+"_"+repr(s1))
# Multimers are just complexes with multiplicity
self.assertEqual(repr(m1), "complex_2x_"+repr(s1))
self.assertEqual(repr(c3), repr(m1))
def test_update_species(self):
from biocrnpyler import CombinatorialPromoter, Protein, Species, Combinatorial_Cooperative_Binding, \
DNAassembly,Transcription_MM, Translation_MM, Multimer, ComplexSpecies
#make a complicated promoter
newprom = CombinatorialPromoter("testprom",["treg1",Species("treg2",material_type="rna")],\
tx_capable_list = [["treg1","treg2"]],cooperativity={"testprom_treg2":1},leak=True)
newdna = DNAassembly("testDNA", promoter=newprom)
newdna.update_mechanisms(mechanisms={
"transcription": Transcription_MM(),
"translation": Translation_MM()
})
newdna.update_parameters(
parameters={
"cooperativity": 2,
"kb": 100,
"ku": 10,
"ktx": .05,
"ktl": .2,
"kdeg": 2
})
newprom_spec = newprom.update_species()
sp_treg1 = Species("treg1", material_type="protein")
sp_treg2 = Species("treg2", material_type="rna")
#mu_treg2 = Multimer(sp_treg2,2)
sp_dna = Species("testDNA", material_type="dna")
sp_rnap = Species("RNAP", material_type="protein")
sp_rna = Species("testDNA", material_type="rna")
cp_dna_rnap = ComplexSpecies([sp_dna, sp_rnap])
cp_dna_treg1 = ComplexSpecies([sp_dna, sp_treg1, sp_treg1])
cp_dna_treg2 = ComplexSpecies([sp_dna, sp_treg2])
cp_dna_treg1_rnap = ComplexSpecies([cp_dna_treg1, sp_rnap])
cp_dna_treg2_rnap = ComplexSpecies([cp_dna_treg2, sp_rnap])
cp_dna_treg1_treg2 = ComplexSpecies(
[sp_dna, sp_treg1, sp_treg1, sp_treg2])
cp_dna_treg1_treg2_rnap = ComplexSpecies([cp_dna_treg1_treg2, sp_rnap])
knownspecies = [sp_dna,sp_rnap,sp_rna,cp_dna_rnap,cp_dna_treg1,\
cp_dna_treg2,cp_dna_treg1_treg2,cp_dna_treg1_rnap, \
cp_dna_treg2_rnap,cp_dna_treg1_treg2_rnap]
#these are the species that should come out
test_set = set([str(a) for a in newprom_spec])
mistake_found = False
#we should have the correct length of species
self.assertTrue(len(test_set) == len(knownspecies))
for known_spec in knownspecies:
#go through and check each species if it's in the set generated by the promoter
if (str(known_spec) not in test_set):
print("couldn't find " + str(known_spec))
mistake_found = True
break
self.assertTrue(not mistake_found)
def test_species_initialization(self):
s1 = Species(name='s1')
s2 = Species(name='s2', material_type="m2")
# Check invalidity of ComplexSpecies with fewer than 2 component
with self.assertRaisesRegex(
ValueError, 'chemical_reaction_network.complex requires '
'2 or more species in its constructor'):
ComplexSpecies([s1], called_from_complex=True)
# Check invalidity of OrderedComplexSpecies with fewer than 2 component
with self.assertRaisesRegex(
ValueError, 'chemical_reaction_network.complex requires 2 '
'or more species in its constructor.'):
OrderedComplexSpecies([s1], called_from_complex=True)
# Check invalidity of multimers with fewer than 2 component
with self.assertRaisesRegex(
ValueError, 'chemical_reaction_network.complex requires 2 '
'or more species in its constructor'):
Multimer(s1, 1, called_from_complex=True)
# Check the naming conventions
oc1 = OrderedComplexSpecies([s2, s1], called_from_complex=True)
c1 = ComplexSpecies([s2, s1], called_from_complex=True)
m1 = Multimer(s1, 2, called_from_complex=True)
c3 = ComplexSpecies([s1, s1], called_from_complex=True)
# Check invalidity of ComplexSpecies, Multimers and OrderedComplexSpecies with strings instead of species
with self.assertRaisesRegex(
TypeError,
'recieved a non-species as a member of the list species'):
self.assertEqual(OrderedComplexSpecies([s2, "s1"]), oc1)
self.assertEqual(ComplexSpecies([s2, "s1"]), c1)
self.assertEqual(Multimer("s1", 2), m1)
# ComplexSpecies should sort the species added alphabetically by representation
#an extra underscore is added at the end of the representation to deal with embedded complexes.
self.assertEqual(repr(c1),
"complex_" + repr(s2) + "_" + repr(s1) + "_")
# OrderedComplexSpecies do not sort their internal species
self.assertEqual(repr(oc1),
"ordered_complex_" + repr(s2) + "_" + repr(s1) + "_")
# Multimers are just complexes with multiplicity
self.assertEqual(repr(m1), "complex_" + repr(s1) + "_2x_")
self.assertEqual(repr(c3), repr(m1))
# Nested list creation of ComplexSpecies
c1 = ComplexSpecies([s1, [s2, s1]], called_from_complex=True)
c2 = ComplexSpecies([s1, s2, s1], called_from_complex=True)
self.assertEqual(c1, c2)
c1 = OrderedComplexSpecies([s1, [s2, s1]], called_from_complex=True)
c2 = OrderedComplexSpecies([s1, s2, s1], called_from_complex=True)
c3 = OrderedComplexSpecies([s1, [s1, s2]], called_from_complex=True)
self.assertEqual(c1, c2)
self.assertFalse(c1 == c3)
def test_update_reactions(self):
"""this function tests the CombinatorialPromoter for the ability to make
reactions with the proper inputs and outputs."""
from biocrnpyler import CombinatorialPromoter, Protein, Species, Combinatorial_Cooperative_Binding, \
DNAassembly,Transcription_MM, Translation_MM, ComplexSpecies, Multimer
#make a relatively simple combinatorial promoter
newprom = CombinatorialPromoter("testprom", ["treg1", "treg2"],
tx_capable_list=[["treg2", "treg1"]],
leak=True)
#you have to put it into an assembly
newdna = DNAassembly("testDNA", promoter=newprom)
#adding mechanisms because there is no mixture. I believe this is what the mixture does
newdna.update_mechanisms(mechanisms={
"transcription": Transcription_MM(),
"translation": Translation_MM()
})
newdna.update_parameters(parameters={"cooperativity":2,"kb":100, "ku":10, "ktx":.05, ("testprom_leak","ktx"):.01,\
("testprom_leak","ku"):50,("testprom_treg1_treg2_RNAP","ku"):5})
#you have to do update_species first
newprom_spec = newprom.update_species()
#now the test... does it produce the right reactions??
newprom_rxns = newprom.update_reactions()
#here i am generating the species manually
sp_dna = Species("testDNA", material_type="dna")
sp_rna = Species("testDNA", material_type="rna")
sp_treg1 = Species("treg1", material_type="protein")
sp_treg2 = Species("treg2", material_type="protein")
sp_rnap = Species("RNAP", material_type="protein")
#now the complexes
sp_dna_treg1 = ComplexSpecies([sp_dna, sp_treg1, sp_treg1])
sp_dna_treg2 = ComplexSpecies([sp_dna, sp_treg2, sp_treg2])
sp_dna_treg1_treg2 = ComplexSpecies(
[sp_dna, sp_treg2, sp_treg2, sp_treg1, sp_treg1])
sp_dna_rnap = ComplexSpecies([sp_dna, sp_rnap])
sp_dna_treg1_rnap = ComplexSpecies([sp_dna_treg1, sp_rnap])
sp_dna_treg2_rnap = ComplexSpecies([sp_dna_treg2, sp_rnap])
sp_dna_treg1_treg2_rnap = ComplexSpecies([sp_dna_treg1_treg2, sp_rnap])
#print('\n\n'.join([str(a) for a in newprom_rxns]))
#now, we generate the reaction input outputs manually
r0 = [set([sp_rnap, sp_dna]),
set([sp_dna_rnap]), 100, 50] #RNAP binding to DNA
r1 = [set([sp_dna_rnap]),
set([sp_dna, sp_rna, sp_rnap]), .01, 0] #leaky transcription
r2 = [set([sp_dna, sp_treg1]),
set([sp_dna_treg1]), 100, 10] #treg1 binding
r3 = [set([sp_dna_treg1, sp_rnap]),
set([sp_dna_treg1_rnap]), 100,
50] #rnap binding to treg1 bound dna
r4 = [
set([sp_dna_treg1_rnap]),
set([sp_dna_treg1, sp_rnap, sp_rna]), .01, 0
] #leaky tx from single regulator
r5 = [
set([sp_dna_treg2_rnap]),
set([sp_dna_treg2, sp_rnap, sp_rna]), .01, 0
] #leaky tx from single regulator
r6 = [
set([sp_dna_treg1_treg2_rnap]),
set([sp_dna_treg1_treg2, sp_rnap, sp_rna]), .05, 0
] #ktx for regular tx
r7 = [set([sp_dna_treg2, sp_rnap]),
set([sp_dna_treg2_rnap]), 100,
50] #rnap binding to treg2 bound dna
r8 = [set([sp_dna, sp_treg2]),
set([sp_dna_treg2]), 100, 10] #treg2 binding
r9 = [
set([sp_dna_treg1, sp_treg2]),
set([sp_dna_treg1_treg2]), 100, 10
] #treg2 binding to dna that already has treg1
r10 = [
set([sp_dna_treg2, sp_treg1]),
set([sp_dna_treg1_treg2]), 100, 10
] #treg1 binding to dna that already has treg2
r11 = [
set([sp_dna_treg1_treg2, sp_rnap]),
set([sp_dna_treg1_treg2_rnap]), 100, 5
] #rnap binding to full complex
truthlist = [r0, r1, r2, r3, r4, r5, r6, r7, r8, r9, r10, r11]
#print('\n\n'.join([str(a) for a in newprom_rxns]))
for rxn in newprom_rxns:
in_outs = [set(rxn.inputs), set(rxn.outputs)]
correctPick = False
for rset in truthlist:
#go through all the reactions and make sure that
#they have the correct inputs, outputs, and constants.
if (rset[0] == in_outs[0] and rset[1] == in_outs[1]):
self.assertTrue(rxn.k == rset[2])
self.assertTrue(rxn.k_r == rset[3])
correctPick = True
break
self.assertTrue(correctPick)
#12 reactions must be generated
self.assertTrue(len(newprom_rxns) == len(truthlist))
#TODO: tests below this are questionable
#then we should also test what happens if you say that nothing can transcribe:
newprom2 = CombinatorialPromoter("testprom",
["treg1"]) #,tx_capable_list = [])
newdna2 = DNAassembly("testDNA", promoter=newprom2)
#adding mechanisms because there is no mixture. I believe this is what the mixture does
newdna2.update_mechanisms(mechanisms={
"transcription": Transcription_MM(),
"translation": Translation_MM()
})
newdna2.update_parameters(parameters={
"cooperativity": 2,
"kb": 100,
"ku": 10,
"ktx": .05
})
with self.assertWarns(UserWarning):
#TODO fix this with a warning detection system that actually checks for the proper warning
newprom_rxns = newprom2.update_reactions()
