Antibodies to yeast phenylalanine transfer ribonucleic acid are specific for the odd nucleoside ) in the anticodon loop

Inosine and N1-methylinosine within a synthetic oligomer mimicking the anticodon loop of human tRNA(Ala) are major epitopes for anti-PL-12 myositis autoantibodies

Sera of some patients afflicted with the inflammatory disease myositis contain antibodies of the anti-PL-12 type. A fraction of these polyclonal autoantibodies specifically precipitates the fully matured human tRNA(Ala) bearing the anticodon IGC (PL-12 antigen). Earlier work (Bunn & Mathews, 1987, Science 238:116-119) had shown that the epitopes are located entirely within the anticodon stem-loop of the tRNA(Ala). Here we demonstrate that human anti-tRNA(Ala) autoantibodies immunoprecipitate a synthetic polyribonucleotide containing inosine (I) and N1-methylinosine (m1I) separated by 2 nt as in the anticodon stem-loop of human tRNA(Ala). The shortest polyribonucleotide that can be immunoprecipitated corresponds to the pentanucleotide IpGpCpm1IpUp, which corresponds to part of the anticodon loop of human tRNA(Ala) and lacks the stem-loop structure. The efficiency of immunoprecipitation was about four times greater with longer polyribonucleotides capable of forming a stem-loop structure, and was abolished by altering the relative positions of I and m1I within the synthetic polynucleotide. Synthetic oligodeoxyribonucleotide analogs of the tRNA(Ala) stem-loop, containing the sequence dIpdGdCdm1Ip, are not antigenic. Our results show that human anti-tRNA(Ala) autoantibodies selectively recognize chemical details of modified nucleotides (the 6-keto group of inosine-34 and the 6-keto group and the N1-methyl groups of N1-methylinosine-37) within an anticodon loop structure of a tRNA molecule. We also describe the chemical synthesis of the phosphoramidite derivatives corresponding to N1-methylinosine and N1-methyl-2'-deoxyinosine for use in the automatic chemical synthesis of oligonucleotides containing N1-methylinosine and N1-methyl-2'-deoxyinosine.

Autoreactive epitope defined as the anticodon region of alanine transfer RNA

Autoantibodies to aminoacyl-transfer RNA (tRNA) synthetases are common in the human autoimmune diseases polymyositis and dermatomyositis. Sera of the PL-12 specificity contain separate antibodies reacting with alanyl-tRNA synthetase and alanine tRNA (tRNAAla). The antibodies to tRNA recognize at least six distinguishable human tRNAAla species grouped into two sequence families. The antibody-reactive determinants on the tRNA were identified through ribonuclease protection and oligonucleotide binding experiments. The antibody binding site is a seven- to nine-nucleotide sequence containing the anticodon loop and requires an intact anticodon. No requirement for anticodon stem structure or sequence is observed, although the 5' portion of the stem is protected from nuclease attack. Antibodies from several patients appear to share the same specificitym, indicating that the antibodies are induced by a unique sequence feature in the immunogen.

Characterization of antibodies specific for N6-methyladenosine and for 7-methylguanosine

Antibodies specific for N6-methyladenosine (m6A) and for 7-methylguanosine (m7G) were prepared by immunization of rabbits with nucleoside conjugates of bovine serum albumin (i.e, m6A--BSA and m7G-BSA). Specificity of each antibody was assessed by inhibition of the homologous precipitin reaction with various nucleosides. These analyses revealed that the antibodies elicited in response to m6A--BSA were specific for the N6-methyl moiety of adenosine with minimal or no cross-reactivity with BSA, adenosine, and guanosine. Although a major fraction of antibodies elicited in response to m7G--BSA were specific for m7G, considerable cross-reactivity was observed with BSA. These latter antibodies were removed by affinity chromatography utilizing BSA-Sepharose adsorbent. In similar fashion, antibodies specific for m6A and m7G were isolated by immunospecific adsorption to antigen-coupled Sepharose (e.g. m6A--BSA-Sepharose), eluted, and coupled to Sepharose. The ability of these antibody-coupled adsorbents to retain specific methylated [methyl-3H]nucleosides derived from [methyl-3H]tRNA digests was assessed. Both the anti-m7G and anti-m6A antibody adsorbents quantitatively and exclusively retained 7-[3H]methylguanosine and N6-[3H]methyladenosine, respectively. The application of these adsorbents to fractionate oligonucleotides and nucleic acids is discussed.

Abundance of tRNAPhe lacking the peroxy Y-base in mouse neuroblastoma

Affinity chromatography on anti-Y (Y is a tricyclic imidazopurine to which is attached a complex four-carbon side chain) antibody immobilized to Sepharose was used to determine the proportion of rat liver tRNAPhe species containing the peroxy Y-nucleoside. Unfractionated Unfractionated mammalian tRNA was aminoacylated with labeled phenylalanine. The phenylalanyl-tRNA was then chemically acetylated to yield N-acetylphenylalanyl-tRNA. When this preparation was applied to the antibody column, between 6-10% of the radioactivity was not bound to the column, indicating a deficiency of peroxy Y-nuceloside in a minor isoaccepting tRNAPhe species. In contrast to normal tissues (including embryonic tissue), about 85% of the tRNAPhe from mouse neuroblastoma C-1300 or N-18 tumors lack the peroxy Y-base, a property which is not affected by tumor age. Rat liver labeled N-acetylphenylalanyl-tRNA preparations were resolved on Plaskon chromatography (RPC-5) into two minor peaks closely followed by a mojor component. A high proportion of the two minor tRNAPhe species was unable to bind to anti-Y antibodies. Upon mild acid treatment, the minor and major tRNAPhe species eluted simultaneously from Plaskon columns, at a much reduced salt concentration. These results would indicate that the two minor tRNAPhe species from rat liver as well as the major component contain a tricyclic imidazopurine base that differs from each other in its side chain. About 85% of the N-acetylphenylalanyl-tRNA from neuroblastoma was resolved by Plaskon chromatography as an early eluting peak. The position of this major neuroblastoma tRNAPhe species was not altered by mild acid treatment, and its elution position from the column almost coincides with that of acid-treated normal rat liver tRNAPhe. The latter results would suggest that most of the tRNAPhe chains from neuroblastoma lack the tricyclic imidazopurine of normal rat liver tRNAPhe, but are very close if not identical in primary nucleotide sequence.