3-phenylpropyl acetate

Administrative data

Key value for chemical safety assessment

Genetic toxicity in vitro

Description of key information

3-Phenylpropyl acetate is not likely to be a gene mutant in vitro.

Link to relevant study records

Reference

Endpoint:

in vitro gene mutation study in bacteria

Type of information:

(Q)SAR

Adequacy of study:

weight of evidence

Reliability:

2 (reliable with restrictions)

Rationale for reliability incl. deficiencies:

results derived from a valid (Q)SAR model and falling into its applicability domain, with limited documentation / justification

Justification for type of information:

The supporting QMRF report has been attached

Qualifier:

according to guideline

Guideline:

other: Prediction is done using QSAR Toolbox version 3.4

Principles of method if other than guideline:

Prediction is done using QSAR Toolbox version 3.4

GLP compliance:

no

Type of assay:

bacterial reverse mutation assay

Specific details on test material used for the study:

- Name of test material: 3-Phenylpropyl acetate- Molecular formula: C11H14O2- Molecular weight: 178.23 g/mol- Smiles notation:c1(CCCOC(C)=O)ccccc1- Substance type: Organic- Physical state: No data

Target gene:

Histidine

Species / strain / cell type:

S. typhimurium TA 100

Details on mammalian cell type (if applicable):

Not applicable

Additional strain / cell type characteristics:

not specified

Cytokinesis block (if used):

not specified

Metabolic activation:

with

Metabolic activation system:

S9 metabolic activation system

Test concentrations with justification for top dose:

not specified

Vehicle / solvent:

not specified

Untreated negative controls:

not specified

Negative solvent / vehicle controls:

not specified

True negative controls:

not specified

Positive controls:

not specified

Positive control substance:

not specified

Remarks:

not specified

Details on test system and experimental conditions:

not specified

Rationale for test conditions:

not specified

Evaluation criteria:

The plates were noted for a dose dependent increase in the number of revertants

Statistics:

not specified

Species / strain:

S. typhimurium TA 100

Metabolic activation:

with

Genotoxicity:

negative

Cytotoxicity / choice of top concentrations:

not specified

Vehicle controls validity:

not specified

Untreated negative controls validity:

not specified

Positive controls validity:

not specified

The prediction was based on dataset comprised from the following descriptors: "Gene mutation"
Estimation method: Takes highest mode value from the 6 nearest neighbours
Domain  logical expression:Result: In Domain

((((((("a" or "b" or "c" or "d" or "e") and("f" and(not "g")) ) and("h" and(not "i")) ) and "j") and("k" and(not "l")) ) and "m") and("n" and "o") )

Domain logical expression index: "a"

Referential boundary:The target chemical should be classified as Esters (Acute toxicity) by US-EPA New Chemical Categories

Domain logical expression index: "b"

Referential boundary:The target chemical should be classified as Acetoxy AND Aryl AND Carboxylic acid ester by Organic Functional groups

Domain logical expression index: "c"

Referential boundary:The target chemical should be classified as Aryl AND Carboxylic acid ester by Organic Functional groups (nested)

Domain logical expression index: "d"

Referential boundary:The target chemical should be classified as Aliphatic Carbon [CH] AND Aliphatic Carbon [-CH2-] AND Aliphatic Carbon [-CH3] AND Aromatic Carbon [C] AND Carbonyl, aliphatic attach [-C(=O)-] AND Ester, aliphatic attach [-C(=O)O] AND Miscellaneous sulfide (=S) or oxide (=O) AND Olefinic carbon [=CH- or =C<] by Organic functional groups (US EPA)

Domain logical expression index: "e"

Referential boundary:The target chemical should be classified as Aromatic compound AND Carbonic acid derivative AND Carboxylic acid derivative AND Carboxylic acid ester by Organic functional groups, Norbert Haider (checkmol)

Domain logical expression index: "f"

Referential boundary:The target chemical should be classified as AN2 AND AN2 >> Shiff base formation after aldehyde release AND AN2 >> Shiff base formation after aldehyde release >> Specific Acetate Esters AND SN1 AND SN1 >> Nucleophilic attack after carbenium ion formation AND SN1 >> Nucleophilic attack after carbenium ion formation >> Specific Acetate Esters AND SN2 AND SN2 >> Acylation AND SN2 >> Acylation >> Specific Acetate Esters AND SN2 >> Nucleophilic substitution at sp3 Carbon atom AND SN2 >> Nucleophilic substitution at sp3 Carbon atom >> Specific Acetate Esters by DNA binding by OASIS v.1.4

Domain logical expression index: "g"

Referential boundary:The target chemical should be classified as AN2 >>  Michael-type addition, quinoid structures OR AN2 >>  Michael-type addition, quinoid structures >> Flavonoids OR AN2 >>  Michael-type addition, quinoid structures >> Quinone methides OR AN2 >>  Michael-type addition, quinoid structures >> Quinones and Trihydroxybenzenes OR AN2 >> Carbamoylation after isocyanate formation OR AN2 >> Carbamoylation after isocyanate formation >> N-Hydroxylamines OR AN2 >> Michael-type addition on alpha, beta-unsaturated carbonyl compounds OR AN2 >> Michael-type addition on alpha, beta-unsaturated carbonyl compounds >> Four- and Five-Membered Lactones OR AN2 >> Michael-type conjugate addition to activated alkene derivatives OR AN2 >> Michael-type conjugate addition to activated alkene derivatives >> Alpha-Beta Conjugated Alkene Derivatives with Geminal Electron-Withdrawing Groups OR AN2 >> Schiff base formation OR AN2 >> Schiff base formation >> Polarized Haloalkene Derivatives OR AN2 >> Schiff base formation by aldehyde formed after metabolic activation OR AN2 >> Schiff base formation by aldehyde formed after metabolic activation >> Geminal Polyhaloalkane Derivatives OR AN2 >> Shiff base formation for aldehydes OR AN2 >> Shiff base formation for aldehydes >> Haloalkane Derivatives with Labile Halogen OR AN2 >> Thioacylation via nucleophilic addition after cysteine-mediated thioketene formation OR AN2 >> Thioacylation via nucleophilic addition after cysteine-mediated thioketene formation >> Haloalkenes with Electron-Withdrawing Groups OR AN2 >> Thioacylation via nucleophilic addition after cysteine-mediated thioketene formation >> Polarized Haloalkene Derivatives OR No alert found OR Non-covalent interaction OR Non-covalent interaction >> DNA intercalation OR Non-covalent interaction >> DNA intercalation >> Acridone, Thioxanthone, Xanthone and Phenazine Derivatives OR Non-covalent interaction >> DNA intercalation >> Bleomycin and Structurally Related Compounds OR Non-covalent interaction >> DNA intercalation >> Coumarins OR Non-covalent interaction >> DNA intercalation >> DNA Intercalators with Carboxamide and Aminoalkylamine Side Chain OR Non-covalent interaction >> DNA intercalation >> Fused-Ring Nitroaromatics OR Non-covalent interaction >> DNA intercalation >> Organic Azides OR Non-covalent interaction >> DNA intercalation >> Polycyclic Aromatic Hydrocarbon and Naphthalenediimide Derivatives OR Non-covalent interaction >> DNA intercalation >> Quinones and Trihydroxybenzenes OR Non-specific OR Non-specific >> Incorporation into DNA/RNA, due to structural analogy with  nucleoside bases    OR Non-specific >> Incorporation into DNA/RNA, due to structural analogy with  nucleoside bases    >> Specific Imine and Thione Derivatives OR Radical OR Radical >> Generation of ROS by glutathione depletion (indirect) OR Radical >> Generation of ROS by glutathione depletion (indirect) >> Haloalkanes Containing Heteroatom OR Radical >> Radical mechanism by ROS formation OR Radical >> Radical mechanism by ROS formation >> Organic Azides OR Radical >> Radical mechanism via ROS formation (indirect) OR Radical >> Radical mechanism via ROS formation (indirect) >> Acridone, Thioxanthone, Xanthone and Phenazine Derivatives OR Radical >> Radical mechanism via ROS formation (indirect) >> Bleomycin and Structurally Related Compounds OR Radical >> Radical mechanism via ROS formation (indirect) >> Coumarins OR Radical >> Radical mechanism via ROS formation (indirect) >> Flavonoids OR Radical >> Radical mechanism via ROS formation (indirect) >> Fused-Ring Nitroaromatics OR Radical >> Radical mechanism via ROS formation (indirect) >> Geminal Polyhaloalkane Derivatives OR Radical >> Radical mechanism via ROS formation (indirect) >> N-Hydroxylamines OR Radical >> Radical mechanism via ROS formation (indirect) >> Nitroaniline Derivatives OR Radical >> Radical mechanism via ROS formation (indirect) >> p-Aminobiphenyl Analogs OR Radical >> Radical mechanism via ROS formation (indirect) >> p-Substituted Mononitrobenzenes OR Radical >> Radical mechanism via ROS formation (indirect) >> Quinones and Trihydroxybenzenes OR Radical >> Radical mechanism via ROS formation (indirect) >> Single-Ring Substituted Primary Aromatic Amines OR Radical >> Radical mechanism via ROS formation (indirect) >> Specific Imine and Thione Derivatives OR Radical >> ROS formation after GSH depletion OR Radical >> ROS formation after GSH depletion >> Quinone methides OR SN1 >> Alkylation after metabolically formed carbenium ion species OR SN1 >> Alkylation after metabolically formed carbenium ion species >> Polycyclic Aromatic Hydrocarbon and Naphthalenediimide Derivatives OR SN1 >> Nucleophilic attack after carbenium ion formation >> N-Nitroso Compounds OR SN1 >> Nucleophilic attack after carbenium ion formation >> Pyrrolizidine Derivatives OR SN1 >> Nucleophilic attack after nitrene formation OR SN1 >> Nucleophilic attack after nitrene formation >> Organic Azides OR SN1 >> Nucleophilic attack after nitrenium ion formation OR SN1 >> Nucleophilic attack after nitrenium ion formation >> N-Hydroxylamines OR SN1 >> Nucleophilic attack after nitrenium ion formation >> p-Aminobiphenyl Analogs OR SN1 >> Nucleophilic attack after nitrenium ion formation >> Single-Ring Substituted Primary Aromatic Amines OR SN1 >> Nucleophilic attack after nitrosonium cation formation OR SN1 >> Nucleophilic attack after nitrosonium cation formation >> N-Nitroso Compounds OR SN1 >> Nucleophilic attack after reduction and nitrenium ion formation OR SN1 >> Nucleophilic attack after reduction and nitrenium ion formation >> Fused-Ring Nitroaromatics OR SN1 >> Nucleophilic attack after reduction and nitrenium ion formation >> Nitroaniline Derivatives OR SN1 >> Nucleophilic attack after reduction and nitrenium ion formation >> p-Substituted Mononitrobenzenes OR SN1 >> Nucleophilic substitution on diazonium ion OR SN1 >> Nucleophilic substitution on diazonium ion >> Specific Imine and Thione Derivatives OR SN1 >> SN1 reaction at nitrogen-atom bound to a good leaving group or on  nitrenium ion OR SN1 >> SN1 reaction at nitrogen-atom bound to a good leaving group or on  nitrenium ion >> N-Acyloxy(Alkoxy) Arenamides OR SN2 >> Acylation >> N-Hydroxylamines OR SN2 >> Acylation involving a leaving group  OR SN2 >> Acylation involving a leaving group  >> Haloalkane Derivatives with Labile Halogen OR SN2 >> Acylation involving a leaving group after metabolic activation OR SN2 >> Acylation involving a leaving group after metabolic activation >> Geminal Polyhaloalkane Derivatives OR SN2 >> Alkylation OR SN2 >> Alkylation >> Alkylphosphates, Alkylthiophosphates and Alkylphosphonates OR SN2 >> Alkylation, direct acting epoxides and related OR SN2 >> Alkylation, direct acting epoxides and related >> Epoxides and Aziridines OR SN2 >> Alkylation, direct acting epoxides and related after cyclization OR SN2 >> Alkylation, direct acting epoxides and related after cyclization >> Nitrogen and Sulfur Mustards OR SN2 >> Alkylation, direct acting epoxides and related after P450-mediated metabolic activation OR SN2 >> Alkylation, direct acting epoxides and related after P450-mediated metabolic activation >> Haloalkenes with Electron-Withdrawing Groups OR SN2 >> Alkylation, direct acting epoxides and related after P450-mediated metabolic activation >> Polarized Haloalkene Derivatives OR SN2 >> Alkylation, direct acting epoxides and related after P450-mediated metabolic activation >> Polycyclic Aromatic Hydrocarbon and Naphthalenediimide Derivatives OR SN2 >> Alkylation, nucleophilic substitution at sp3-carbon atom OR SN2 >> Alkylation, nucleophilic substitution at sp3-carbon atom >> Haloalkane Derivatives with Labile Halogen OR SN2 >> Alkylation, nucleophilic substitution at sp3-carbon atom >> Haloalkanes Containing Heteroatom OR SN2 >> Alkylation, ring opening SN2 reaction OR SN2 >> Alkylation, ring opening SN2 reaction >> Four- and Five-Membered Lactones OR SN2 >> Direct acting epoxides formed after metabolic activation OR SN2 >> Direct acting epoxides formed after metabolic activation >> Coumarins OR SN2 >> Direct acting epoxides formed after metabolic activation >> Quinoline Derivatives OR SN2 >> DNA alkylation OR SN2 >> DNA alkylation >> Vicinal Dihaloalkanes OR SN2 >> Internal SN2 reaction with aziridinium and/or cyclic sulfonium ion formation (enzymatic) OR SN2 >> Internal SN2 reaction with aziridinium and/or cyclic sulfonium ion formation (enzymatic) >> Vicinal Dihaloalkanes OR SN2 >> Nucleophilic substitution at sp3 Carbon atom >> Haloalkanes Containing Heteroatom OR SN2 >> Nucleophilic substitution at sp3 carbon atom after thiol (glutathione) conjugation OR SN2 >> Nucleophilic substitution at sp3 carbon atom after thiol (glutathione) conjugation >> Geminal Polyhaloalkane Derivatives OR SN2 >> SN2 at an activated carbon atom OR SN2 >> SN2 at an activated carbon atom >> Quinoline Derivatives OR SN2 >> SN2 at sp3 and activated sp2 carbon atom OR SN2 >> SN2 at sp3 and activated sp2 carbon atom >> Polarized Haloalkene Derivatives OR SN2 >> SN2 reaction at nitrogen-atom bound to a good leaving group OR SN2 >> SN2 reaction at nitrogen-atom bound to a good leaving group >> N-Acetoxyamines OR SN2 >> SN2 reaction at nitrogen-atom bound to a good leaving group or nitrenium ion OR SN2 >> SN2 reaction at nitrogen-atom bound to a good leaving group or nitrenium ion >> N-Acyloxy(Alkoxy) Arenamides by DNA binding by OASIS v.1.4

Domain logical expression index: "h"

Referential boundary:The target chemical should be classified as Non binder, without OH or NH2 group by Estrogen Receptor Binding

Domain logical expression index: "i"

Referential boundary:The target chemical should be classified as Non binder, MW>500 OR Non binder, non cyclic structure OR Strong binder, OH group by Estrogen Receptor Binding

Domain logical expression index: "j"

Referential boundary:The target chemical should be classified as No superfragment by Superfragments ONLY

Domain logical expression index: "k"

Referential boundary:The target chemical should be classified as Group 14 - Carbon C AND Group 16 - Oxygen O by Chemical elements

Domain logical expression index: "l"

Referential boundary:The target chemical should be classified as Group 15 - Nitrogen N by Chemical elements

Domain logical expression index: "m"

Similarity boundary:Target: CC(=O)OCCCc1ccccc1
Threshold=40%,
Dice(Atom centered fragments)
Atom type; Count H attached; Hybridization

Domain logical expression index: "n"

Parametric boundary:The target chemical should have a value of log Kow which is >= 1.13

Domain logical expression index: "o"

Parametric boundary:The target chemical should have a value of log Kow which is <= 3.99

Conclusions:

3-Phenylpropyl acetate is predicted to be not mutagenic to the Salmonella typhimurium strain TA100 in the presence of S9 activation system and hence is not likely to classify as a gene mutant in vitro.

Executive summary:

Gene mutation was predicted for 3 -Phenylpropyl acetate using SSS QSAR prediction database, 2016. The study assumed the use of Salmonella typhimurium strain TA100 with S9 activation system. 3-Phenylpropyl acetate is predicted to be not mutagenic to the Salmonella typhimurium strain TA100 in the presence of S9 activation system and hence is not likely to classify as a gene mutant in vitro.

Endpoint conclusion

Endpoint conclusion:

no adverse effect observed (negative)

Additional information

Additional information from genetic toxicity in vitro:

Gene mutation in vitro:

Prediction model based estimation and data from read across chemical have been summarized below to determine the mutagenic nature of the 3 - Phenylpropyl acetate:

Gene mutation was predicted for 3 -Phenylpropyl acetate (CAS no 122 -72 -5) using SSS QSAR prediction database, 2016. The study assumed the use of Salmonella typhimurium strain TA100 with S9 activation system. 3-Phenylpropyl acetate is predicted to be not mutagenic to the Salmonella typhimurium strain TA100 in the presence of S9 activation system and hence is not likely to classify as a gene mutant in vitro.

Gene mutation was predicted for 3 -Phenylpropyl acetate (CAS no 122 -72 -5) using SSS QSAR prediction database, 2016. The study assumed the use of Salmonella typhimurium strain TA1535 without S9 activation system. 3-Phenylpropyl acetate is predicted to be not mutagenic to the Salmonella typhimurium strain TA1535 in the absence of S9 activation system and hence is not likely to classify as a gene mutant in vitro.

In a gene toxicity test by Sustainability Support Services (2015), Chinese Hamster Ovary (CHO) cells were exposed to Methyl phenylacetate (RA CAS no 101 -41 -7) in the concentration of 0, 0.5, 1.0, 2.5 or 5.0 mM both with and without metabolic activation for 3 hours. The results showed that there was no evidence of cytotoxicity after treatment. Independently of tested Methyl phenylacetate concentration, the results showed no evidence of gene toxicity. Therefore, it is considered that Methyl phenylacetate in the concentration of 0, 0.5, 1.0, 2.5 or 5.0 mM does not cause genetic mutation(s) when CHO cells are exposed to the test chemical in the presence or absence of metabolic activation.

In a study performed by Mortelmans et al (1986), Benzyl Acetate (RA CAS no 140 -11 -4) was examined for its ability to cause mutagenic changes when tested in five strains of the bacteria Salmonella typhimurium, specifically, TA 1535, TA 1537, TA97, TA 98 and TA 100 through the preincubation assay method.Preliminary dose range finding study was performed initially to set the doses for the main study. The test was conducted both in the presence and absence of metabolic activation using male rat and hamster liver derived S-9 mix at dose levels of 0, 33, 100, 333, 1000, 3333 or 10000 ug/plate. The test was repeated and atleast three plates were used at each dose level. Benzyl Acetate did not induce mutation in the Salmonella typhimurium strain TA98, TA100, TA1535 or TA1537 both in the presence and absence of S9 metabolic activation system and hence is not likely to be mutagenic under the conditions of this study.

In a study conducted by Florin et al. (1980), Benzyl Acetate (RA CAS no 140 -11 -4) was investigated for its ability to induce mutagenic activity when tested in an in vitro reverse mutagenicity test using four strains of the bacteria Salmonella typhimurium, specifically TA 98, TA 100, TA 1535 and TA 1537. Spot test was performed for the chemical at dose levels of 0.03, 0.3, 3 and 30 µmol/plate. The study was conducted both in the presence and absence of metabolic activation using S9 mix from Aroclor 1254 or methylcholanthrene induced rats. Benzyl acetate is not mutagenic in the bacterium Salmonella typhimurium LT-2 strains TA 98, TA 100, TA1535 and TA37 with and without S9 metabolic activation system and hence is not likely to classify as gene mutant in vitro.

Based on the weight of evidence data summarized, 3- Phenylpropyl acetate is not likely to classify as a gene mutant in vitro.

Justification for selection of genetic toxicity endpoint

Data is from K2 prediction database

Justification for classification or non-classification

Based on the weight of evidence data summarized, 3 -Phenylpropyl acetate is not likely to classify as a gene mutant in vitro.