2-benzyl-2-dimethylamino-4'-morpholinobutyrophenone

Administrative data

Endpoint:

in vitro gene mutation study in mammalian cells

Remarks:

Type of genotoxicity: gene mutation

Type of information:

experimental study

Adequacy of study:

key study

Study period:

2006-02-07, 2006-06-06

Reliability:

1 (reliable without restriction)

Rationale for reliability incl. deficiencies:

guideline study

Data source

Referenceopen allclose all

Materials and methods

GLP compliance:

yes (incl. QA statement)

Type of assay:

mammalian cell gene mutation assay

Test material

Method

Target gene:

Thymidine Kinase Locus

Metabolic activation:

with and without

Metabolic activation system:

S9 fraction of liver from Wistar rats (HanIbm) induced with phenobarbital and beta-naphthoflavone, mixed with a solution of co-factors.

Test concentrations with justification for top dose:

The cultures were evaluated at the following concentrations of the test item:
experiment I:
without S9 Mix: 5.0*; 10.0; 20.0; 40.0; 80.0; and 160 µg/mL
with S9 Mix: 5.0*; 10.0; 20.0; 40.0; 80.0; and 160 µg/mL

experiment II:
without S9 Mix: 1.3*; 2.5*; 5.0; 10.0; 20.0; 30.0; and 40.0 µg/mL
with S9 Mix: 5.0*; 10.0; 20.0; 40.0; 80.0; and 160 µg/mL

experiment III:
without S9 Mix: 5.0*; 10.0; 20.0; 40.0; 80.0; and 160 µg/mL

Following the expression phase of 72 hours the cultures marked with an asterisk were not continued since a minimum of only four analysable concentrations is required by the guidelines.

Vehicle / solvent:

- Vehicle used: DMSO
- Justification for choice of vehicle: The test substance is insoluble in water

Controlsopen allclose all

Details on test system and experimental conditions:

PRE-TEST:
A pre-test was performed in order to determine the concentration range of the main experiments.
1xE+7 cells were exposed to each concentration of the test item for 4 and 24 hours without and 4 hours with metabolic activation. During the 4 h treatment period the serum concentration was reduced from 15 % to 3 %. Following treatment the cells were washed and finally resuspended in 30 mL complete culture medium for a 2-day growth period. The relative suspension growth (RSG) of the treated cell cultures was calculated at the end of the growth period according to the method of Clive and Spector (Mutation Research 31, 17-29, 1975).
Test item concentrations between 5.1 and 650 µg/mL were used to evaluate toxicity in the presence (4 h treatment) and absence (4 h and 24 h treatment) of metabolic activation. Relevant toxic effects were observed at 325 µg/mL and above in the absence and at 81.3 µg/mL and above in the presence of metabolic activation (4 h treatment). Following the 24 h treatment without metabolic activation toxic effects occurred at 40.6 µg/mL and above.

MAIN TEST:
Experiment I
The treatment duration in the first experiment was 4 hours with and without metabolic activation.
Experiment II
The cells were treated with test item for 4 h with and for 24 h without metabolic activation. The experimental part without metabolic activation was terminated prior to the generation of any data on mutagenicity due to exceedingly severe toxic effects even at lower concentrations. Therefore, this experimental part was repeated as experiment IIA in a lower concentration range. The data of experiment IIA are reported as experiment II without metabolic activation.
Experiment III
This experiment was performed to verify a minor increase of the mutation frequency without metabolic activation in experiment I. Experiment III was performed in the absence of metabolic activation with a treatment time of 4 hours.

All experiments were performed in duplicate. Expression time of cells in growth medium was 48 - 72 h and selection time ranged from 10 to 15 days. The selection agent was Trifluorothymidine (TFT; 5 µg/mL). The number of replications was 2 and 2.0 cells/well in a 96-well microtiter plate were evaluated.

DETERMINATION OF CYTOTOXICITY:
Cytotoxicity was assessed using relative total growth and cloning efficiency 1= ln(number of empty wells on plates/192)/cells seeded per well.

Evaluation criteria:

EVALUATION OF RESULTS:
The test item is classified as mutagenic if there is a reproducible concentration-related increase in the mutation frequency. Such an evaluation may be considered independently of the enhancement factor for induced mutants.
A positive response is considered to be reproducible if it occurs in both parallel cultures.
However, in the evaluation of the test results the historical variability of the mutation rates in negative and solvent controls and the mutation rates of all negative and solvent controls of this study are taken into consideration.
Results of test groups are rejected if the relative total growth, the relative suspension growth, and/or cloning efficiency 1 is less than 10 % of the solvent control or the cloning efficiency 2 after the expression period is less than 20 %.
Whenever a test item is considered mutagenic according to the above mentioned criteria, the ratio of small versus large colonies is used to differentiate point mutations from clastogenic effects. If the increase of the mutation frequency is accompanied by a reproducible and dose dependent shift in the ratio of small versus large colonies, clastogenic effects are indicated.

ACCEPTABILITY CRITERIA:
A mutation assay is considered acceptable if it meets the following criteria:
All plates, from either the cloning efficiency 2 (ln(mean number of empty wells per plate / 96) / cells seeded per well) or the TFT resistance-testing portion of the experiment are analysable.
- The absolute cloning efficiency 2 of the negative and/or solvent controls is > 0.5 (50%).
- The spontaneous mutant frequency in the negative and/or solvent controls is in the range of our historical control data
- The positive controls induce significant (at least 2-fold) increases in the mutant frequencies. The cloning efficiencies and the relative total growth are greater than 10% of the concurrent vehicle control group.

Statistics:

A linear regression was performed to assess a possible dose dependent increase of mutant frequencies using SYSTAT statistics software. The number of mutant colonies obtained for the groups treated with the test item was compared to the solvent control groups. A trend is judged as significant whenever the p-value (probability value) is below 0.05. However, both, biological and statistical significance should be considered together.
The data generated at the second precipitating concentration (160 µg/mL) are not included in the statistical evaluation.

Results and discussion

Additional information on results:

TEST-SPECIFIC CONFOUNDING FACTORS:
Precipitation was seen at 80 µg/mL and above.

ADDITIONAL INFORMATION ON CYTOTOXICITY:
In the mouse lymphoma assay precipitation is problematic since the cells grow in suspension. At the end of the treatment, the cells are separated from the test item by centrifugation. A precipitate is likely to contaminate the cell-pellet at the centrifugation step. Thus, arbitrary amounts of test item are carried over to the following steps of the assay leading to non-defined exposure times of up to 48 hours to selection. Toxic or seemingly mutagenic artefacts are likely to occur under these conditions.

Any other information on results incl. tables

General Remarks

Toxicity

Relevant toxic effects, indicated by relative cloning efficiency 1 or a relative total growth of less than 50 % in both parallel cultures, were observed in the second experiment at 30 and 40 μg/mL without metabolic activation and at 160 μg/mL with metabolic activation. In the third experiment relevant toxic effects were noted in the precipitating range at 80 μg/mL and above.

In the experimental parts using 4 hour treatment, the dose range was limited by the solubility of the test item. Two precipitating concentrations were analyased. In the experimental part using continuous treatment for 24 hours without metabolic activation (experiment II), cytotoxic effects were dose limiting.

 

Mutagenicity

The data with metabolic activation do not indicate a possible mutagenic potential of the test item. Generally elevated but not dose dependent levels of the mutation frequency observed in the first culture of the first experiment with metabolic activation were based on the relatively low solvent control. Compared to the corresponding negative control no relevant increase occurred.

The data generated in the absence of metabolic activation with a treatment period of 4 hours showed an isolated increase of the mutation frequency at the maximum concentration of 160 μg/mL in the presence of precipitation.

Following 24 hours of treatment, no increase at all was noted even at severely cytotoxic concentrations in the soluble range. The increase at precipitating concentrations occurred in the second culture of the first experiment without metabolic activation and in the first culture of the third experiment. The threshold of twice the colony count of the corresponding solvent control was exceeded. No comparable increase occurred in the parallel cultures under identical conditions. Both of the increased levels of the mutation frequency are judged as biologically irrelevant precipitation artifacts.

 

Controls

In this study the range of the negative and solvent controls was from 34 up to 209 mutant colonies per 10⁶cells; the range of the groups treated with the test item was from 32 up to 538 mutant colonies per 10⁶ cells. Both solvent controls did not quite reach the historical range of solvent controls in the second experiment without metabolic activation. However, this effect was judged as biologically irrelevant fluctuation since both corresponding negative controls remained within the range of historical negative controls.

 

Statistics

A linear regression analysis (least squares) was performed to assess a possible dose dependent increase of mutant frequencies using SYSTAT® statistics software. The data generated at the second precipitating concentration of 160 μg/mL are not included in the statistical evaluation. A significant dose dependent trend of the mutation frequency indicated by a probability value of <0.05 was determined in experiment I culture I with and without metabolic activation. In experiment II such a trend was observed in both cultures without metabolic activation. However, the significant trends mentioned above were not considered biologically relevant since they either were not reproduced in the parallel culture (experiment I) or the absolute values of the mutation frequency remained within the historical range of negative and solvent controls (experiment II).

Table 2. Summary of results.

	conc. μg/mL	S9 mix	relative cloning efficiency 1	relative total growth	mutant colonies/ 106 cells	induction factor	relative cloning efficiency 1	relative total growth	mutant colonies/ 106 cells	induction factor
Column	1	2	3	4	5	6	7	8	9	10
Experiment 1/ 4 h treatment			culture I				culture II
Neg. control wtth medium		-	100.0	100.0	148		100.0	100.0	103
Solv. control with DMSO		-	100.0	100.0	165	1.0	100.0	100.0	181	1.0
Pos. Control with MMS	19.5	-	67.7	25.9	703	4.8	49.2	25.6	449	4.3
Test item	5.0	-	112.8	culture was not continued*			106.6	culture was not continued*
Test item	10.0	-	108.2	151.2	90	0.5	101.6	61.3	387	2.1
Test item	20.0	-	106.0	112.5	117	0.7	79.8	55.3	261	1.4
Test item	40.0	-	94.6	107.5	169	1.0	104.9	70.6	262	1.4
Test item	80.0 (p)	-	71.7	85.8	217	1.3	122.4	60.1	292	1.6
Test Item	160.0 (p)	-	56.8	72.5	280	1.7	81.0	44.6	538	3.0
Neg. control with medium		+	100.0	100.0	209		100.0	100.0	120
Solv. control with DMSO		+	100.0	100.0	106	1.0	100.0	100.0	66	1.0
Pos. control with CPA	4.5	+	49.9	67.8	703	3.4	57.0	69.8	336	2.8
Test item	5.0	+	100.0	culture was not continued*			73.6	culture was not continued*
Test item	10.0	+	83.9	102.1	193	1.8	63.0	156.5	43	0.7
Test item	20.0	+	87.0	84.6	230	2.2	79.0	102.7	73	1.1
Test item	40.0	+	107.0	95.3	207	2.0	84.9	146.5	37	0.6
Test item	80.0 (p)	+	82.4	67.6	251	2.4	67.6	134.9	45	0.7
Test item	160.0 (p)	+	88.6	51.2	237	2.2	75.7	52.6	80	1.2
Experiment II / 24 h treatment			culture I				culture II
Neg. control with medium		-	100.0	100.0	52		100.0	100.0	46
Solv. control with DMSO		-	100.0	100.0	34	1.0	100.0	100.0	37	1.0
POS. Control with MMS	13.0	-	35.7	29.2	756	14.6	42.8	19.1	392	8.5
Test item	1.3	-	116.4	culture was not continued*			114.4	culture was not continued*
Test item	2.5	-	93.7	culture was not continued*			102.5	culture was not continued*
Test item	5.0	-	100.0	59.0	48	1.4	87.5	67.6	51	1.4
Test item	10.0	-	95.7	48.7	69	2.0	91.3	72.8	38	1.1
Test item	20.0	-	86.4	30.3	62	1.8	79.4	59.4	35	1.0
Test item	30.0	-	40.6	27.7	65	1.9	43.4	24.2	65	1.8
Test item	40.0	-	5.8	9.0	45	1.3	9.9	9.4	38	1.0
Experiment II / 4 h treatment
Neg. control with medium		+	100.0	100.0	57		100.0	100.0	56
Solv. control with DMSO		+	100.0	100.0	64	1.0	100.0	100.0	52	1.0
Pos. control with CPA	4.5	+	19.1	33.5	385	6.7	20.3	26.7	284	5.5
Test item	5.0	+	82.4	culture was not continued*			124.8	culture was not continued*
Test item	10.0	+	100.0	141.7	32	0.5	77.0	106.6	60	1.2
Test item	20.0	+	72.0	111.2	52	0.8	74.4	98.2	54	1.0
Test item	40.0	+	73.2	89.4	51	0.8	87.8	62.2	79	1.5
Test item	80.0 (p)	+	73.2	72.6	42	0.7	97.7	93.3	48	0.9
Test item	160.0 (p)	+	36.3	37.4	46	0.7	87.8	42.8	49	0.9
Experiment III / 4 h treatment			culture I				culture II
Neg. control with medium		-	100.0	100.0	196		100.0	100.0	144
Solv. control with DMSO		-	100.0	100.0	144	1.0	100.0	100.0	154	1.0
Pos. Control with MMS	19.5	-	77.5	24.4	429	2.2	92.6	11.7	381	2.6
Test item	5.0	-	78.8	culture was not continued*			103.5	culture was not continued*
Test item	10.0	-	87.9	85.2	127	0.9	83.8	81.2	182	1.2
Test item	20.0	-	60.2	98.6	163	1.1	100.0	72.3	173	1.1
Test item	40.0	-	62.2	89.7	147	1.0	98.3	87.7	153	1.0
Test item	80.0 (p)	-	53.1	17.6	160	1.1	70.2	38.0	156	1.0
Test item	160.0 (p)	-	39.1	20.6	347	2.4	96.7	33.2	195	1.3

* culture was not continued since a minimum of four concentrations is required by the guidelines

(p) precipitation visible to the naked eye

Table 3. HISTORICAL DATA

Number of mutant colonies per 106 cells
4 h treatment
	Negative control		Positive control			Solvent control
	without S9 mix	with S9 mix	without S9 mix	with S9 mix		without S9 mix	with S9 mix
			MMS	DMNA	CPA
range:	41 - 208	41 -197	212 – 3321	203 - 847	209 – 1269	41 - 204	40 - 205
Mean value:	107	110	479	389	390	106	110
Standard deviation	37	38	281	203	170	39	35

Table 3. HISTORICAL DATA (cont.)

Number of mutant colonies per 106 cells
24 h treatment
	Negative control	Positive control	Solvent control
	without S9 mix	without S9 mix (MMS)	without S9 mix
range:	40-212	243 - 2431	40 - 202
Mean value:	109	863	107
Standard deviation	40	461	39

Applicant's summary and conclusion

Conclusions:

The test material did not invoke a mutagenic response under the conditions of the test.

Executive summary:

In this OECD 476 test with GLP certification, mouse lymphoma cells L5178Y were treated with test article at doses up to 160 µg/mL using DMSO as a vehicle. The test design consisted of two main experiments using two parallel cultures.The cells were treated with the test item for 4 h with and without metabolic activation in the first experiment. In the second experiment the duration of treatment was 4 h with and 24 h without metabolic activation.A confirmatory experiment was added to verify mutagenicity data generated in the first experiment without metabolic activation. Experiment III was solely performed in the absence of metabolic activation under experimental conditions identical to the first experiment without metabolic activation.

Precipitation of the test item and decrease in cloning efficiency was observed at doses of 80 and 160 µg/mL. A biologically irrelevant increase in mutation frequency was observed in some dishes of the first experiment. They were not reproduced in the parallel culture and considered as artifacts caused by precipitates. An increase in mutation frequency was also observed in the second experiment (without metabolic activation, 24 h). Since absolute values of the mutation frequency remained within the historical range of negative and solvent controls, this effect was considered to be biologically irrelevant. Therefore, the test article is considered to be non-mutagenic to mammalian cells in vitro.