Carbon-13 nmr spectra of the tRNA “wobble” nucleosides 5-carboxymethyl-, 5-carbomethoxymethyl-, and 5-carbamoylmethyluridine

THE !'Q>!)IFI~:r) NUCLEOSIDLE FHO?l THE 11 W0BBL.s POSITIOlY )) OF WNAs. A.?faZkiewics', 3. Sochacka , A.F. Sayed Ahmed and S. Yassin' Institute of 3rganic 'Chemistry , 'I'echnical :Jniversity go-924 c&i , Lwirki 36, Poland Abstract:: he synthesis of 5-carboxymethyl.a:ninomethyluridifie isolated fro

## Abstract Carbon‐13 NMR chemical shifts and carbon‐proton coupling constants for nine 4‐substituted and six 5‐substituted pyrimidines are reported. The carbon chemical shifts are correlated with π‐electron densities. Carbon‐proton coupling constants fail to correlate with substituent electronegat

## Abstract On the basis of the data obtained from ^13^C NMR spectra of 8,2′‐S‐cycloadenosine 3′,5′‐cyclic phosphate and other nucleoside 3′,5′‐cyclic phosphate analogues, it is suggested that the published assignments of the C‐3′ and C‐4′ signals in nucleoside 3′,5′‐cyclic phosphates should be rev

## Abstract ^13^C NMR signals were assigned for 18 methyl 5β‐cholenoates with a double bond in ring A, B, C or D (Δ^2^, Δ^3^, Δ^5^, Δ^6^, Δ^7^, Δ^8(14)^, Δ^9(11)^, Δ^11^ or Δ^14^). The double bond substituent effects on the ^13^C NMR chemical shifts of the parent 5β‐cholanoates were clarified.