1H N.M.R. spectra of some 5-substituted-3-isopropyl-6-methyl uracils

1H N.M.R. spectra of some 5-substituted-3-isopropyl-6-methyl uracils

Journal of Molecular Structure, 174 (1988)281-284 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands 281 'H N.M.R. SPECTRA OF ...

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Journal of Molecular Structure, 174 (1988)281-284 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands

281

'H N.M.R. SPECTRA OF SOME 5-SUBSTITUTED-3-ISOPROPYL-6-METHYL URACILS

B.Z.JOVANOVIC',t.D.TADIC', M.D,MUSKATIROVIC1,M.B.PESIE* and S.I.BOGDANOVIC2 1 2

Department of Organic Chemistry, Faculty of Technology and Metallurgy, University of Belgrade, P.O. Box 494, YU-11001 Belgrade, Yugoslavia Faculty of Agriculture, Department of Biochemistry,Universityof Belgrade, P.O. Box 127, YU-11081 Belgrade, Yugoslavia

ABSTRACT The IH n,m.r. spectra of some 5-substituted-3-isopropyl-6-methyl uracils were determined in deuterated dimethyl sulfoxide (d6-DMSO), The substituents are H, Cl, Br, I, NO , NH , N(CH3)*, C H , C H -NO -p and C6H4-NH2-p. It has been shown that relat?ve chemical s ift6(&s) gf4N 2-H proton of some of the examined compounds correlated linearly with Hammett u ('konstant for the substituents in position 5 of uracil ring, The correlation wvth the u constant was interpreted as providing evidence that the inductive effect of th!!substituent on chemical shift is dominating one. INTRODUCTION As it is known some 5-halo-3-alkyl-6-methyluracils are used as selective herbicides. The herbicidal activity of these compounds depends on their structure, the chemical changes during a process of their herbicidal activity and the products formed by those changes (ref. 1). In our previous investigation (ref.2-3) concerning the mechanism of thermal degradation of some 5-substituted3-alkyl-6-methyluracils, it has been shown, that by heating these compounds dealkylation of N-alkyl group takes place with the formation of the corresponding olefine and 5-substituted-6-methyluracil. The assumed mechanism includes a cyclic transition state in which heterolytic cleavageof C,-N(3) bond, as well as of the Cs-H bond takes place with the formation of the C,-CB double bond, similarly to B-syn-eliminationi.e., pyrolytic Ei elimination of esters, xanthates and amino-oxides via a six-membered cyclic transition state (ref. 4). On the basis of the obtained results it was concluded that the heterolytic cleavage of C,-N(3) bond is more advanced in transition state than heterolytic cleavage of CB-H bond. The degree of dealkylation of N-alkyl group in position 3 of uracil ring besides its structure depends on nature of the substituent in position 5 and can be attributed to its inductive effect.

0022-2860/88/$03.50 0 1988 Elsevier Science Publishers B.V.

282

The general formula of these compounds is

Where S is H, Cl, Br, I, N02, NH2, N(CH3)2, C6H5, C6H4-NO*-p and C6H4-NH2-p. In this work 'H n.m.r. spectra of above compounds are discussed in view of their structure and the effect of the substituents in position 5 on chemical shift of N(,)-H proton. EXPERIMENTAL All uracil derivatives were synthesized following the procedure already described in the literature

and identified by microanalysis, MS and 'H n.m.r

data.(ref.2-3) The 'H n.m.r. spectra of 5-substituted-3-isopropyl-6-methyl Uracils were recorded in deuterated dimethyl sulfoxide (d6-DMSO) with tetramethylsilan (TMS) as internal reference standard using Varian FT-80 A spectrophotometer. In all cases the 'H n.m.r. spectra gave satisfactory signal integration. The chemical shifts of aromatic protons of 5-(p-nitrophenyl)and 5-(p-aminophenyl)-3-isopropyl-6-Imethyl uraciland corresponding coupling constants (AA'BB' system) were consistent with the expected structures. All spectra of uracil derivatives were determined using approximatly 0.3M solution at 37+-2OC. RESULTS AND DISCUSSION The obtained results emphasize the conclusion that all uracil derivatives exist in 2,4-dioxo form. (structure I). The values of the chemical shifts of N(,)-H proton of 5-substituted-3-isopropyl-6-methyl uracils are presented in Table 1 (6 in ppm), as well as the relative chemical shifts of N(,)-H proton (As)

(relative to 3-isopropyl-6-,methyl uracilwhich has H atom in position 5 of

the ring). In the same Table are given the corresponding Hammett am constants , which as it is known represent the approximate measure of the inductive effect of the substituent.(ref.5)

283

The data from Table -H proton depends

1 confirm

the assumption

on the nature

N(1) ring. The electron-withdrawing

substituents

down field chemical

shifts

value).

electron-donating

Conversely,

a negative

to correlate

ituents with substituent

where A&stands

N(,)-H

proton,

to 5-isopropyl-6-methyl

deshild

uracil

substituents

the relative

constant

for relative

tant and where

TABLE

relative

in position

shift of 5 of uracil

giving

the

(positive

cause an upfield

A6

shift, with

A6 value.

The attempt

according

that the chemical

of the substituents

(a,) using Hammett

chemical

shift

p is the slope of obtained

to JaffC

chemical

can be considered

shifts for different

subst-

equation

(in ppm); urn-for substituent

cons-

plot (in ppm/a) gave the result which

as fair

(r=0.938,

n=8).(ref.6)

1. 'H n.m.r. chemical shifts of N&1)-H proton of 5-substituted-3-isopropyl-6-me h 1 uracils

Substituent in position

Relative chemical shift (Ab,ppm)

N(l)-H 5

(b,ppm)

"m

0

H

10.85

Cl

11.32

+0.47

0.37

Br

11.35

to.50

0.39 0.35

0

I

11.30

+0.45

NO2

11.50

to.65

0.71

NH2

10.25

-0.60

-0.16

N(CH3)2

10.60

-0.25

-0.21

'gH5 C6H4-NO*-p

10.95

to.10

0.06

11.25

to.40

C6H4-NH2-p

10.00

-0.85

The plot of relative corresponding

Hammett

The correlation possible

to assign

chemical

urn constants obtained

shifts of N is given

-H proton (1) in Fig.1.

from the data given

proportionality

constant

in Table

(A6,ppm)

vs. the

1, have made

it

(slope of the plot) with the value

p= 1.27. The exclusion cantly

of the point for NH2 substituent

the value of the proportionality

improves

the correlation

satisfactory

(r= 0.976,

The correlation ect of the substituent

coefficient

constant

does not affect

signifi-

p= 1.05, but considerably

that it classifies

the correlation

as

n = 7).

of A6 with urn constants on chemical

indicated

that the electronic

shifts of N (,)-H proton

is predominantly

eff-

284 inductive.

possible

is emphasized

This conclusion

NO2 substituent

to assume

by the fact that the value of A6 for

with a, and not with 0; constant

is correlated

the direct conjugation

though

it is

of the lone pair of electrons

on N

atom and NO2 substituent.

(1)

Ah,PPrn

I

-0.5-

I -0.2

I 0.2

I 0

Fig. 1. The plot of relative

chemical

-3-isopropyl-6-methyl

uracils

Almost

the same proportionality

could be calculated the correlation molecule

I

I

0.6

0.8

shifts of N(,)-H vs. Hammett-o, constant

(P

q

proton

of the average

5 of uracils

a,

in 5-substituted-

constants 1.14, r = 0.972,

from the data given in the literature

of 5-substituted

in position

t 0.4

n = 6)

(ref. 7) concerning

-H and N(3) -H chemical shifts in the (1) and Hammett om constant for the substituent

value N

uracils ring.

REFERENCES 1 2 3 4 5 6 7

R.Wegler, Chemie der Phlanzenschutz-und Schxdlings-bekampfungsmittel., Band II, Springer-Verlag, Berlin-Heidelberg-New York, (1970) pp.356. P.D.Tadic, M.B.PeSic and S.K.Ries, J.Agr.Food them., 19 (1971) pp.46. B.f.JovanoviC, f.D.TadiC, M.D.MuSkatiroviC and M.B.PeSi&, J.Serb.Chem.Soc., 51 (1986) pp.389. C.H.De Puy and R.W.King, Chem.Rev., 60 (1960) pp.431. J.Shorter, Correlation Analysis in Organic Chemistry: An Introduction to Linear Free-energy Relationships, Oxford University Press, (1979) pp 9. H.H.JaffP, Chem.Rev., 53 (1953) pp.191. J.P.Kokko, L.Mandell and J.H.Goldstein, J.Amer.Chem.Soc., 84 (1961) pp.1042.