Immunoreactive components of Opisthorchis viverrini and Clonorchis sinensis were analysed by enzyme-linked immunosorbent assay (ELISA), radioimmunoprecipitation and immunoblotting. Somatic extracts from these two liver flukes as well as from other related parasites, together with the metabolic products, were tested for their reactivities with sera from patients with opisthorchiasis and clonorchiasis. A significant cross-reactivity in the ELISA was noted between Opisthorchis and Clonorchis. Immunoblotting and radioimmunoprecipitation analyses showed that the 89-kD protein which was previously shown to be a predominant metabolic product of O. viverrini reacted with sera from both groups of patients. However, an antigen with a molecular weight of 16 kD, apparently a predominant somatic component, appeared to be specific for O. viverrini.

A group of monoclonal antibodies (MAb) was used to immunochemically characterize Babesia bigemina surface components. Two surface reactive MAb by an IFAT test were subsequently shown to bind to epitopes on the external surface of the parasite plasma membrane as evidenced by immunoelectron microscopy. Parasite components with relative sizes of 68, 62, 60, 58, 56, 54, 51, 49, 48, 47, 43, 36 kDa were identified with the group of MAb in at least 6 geographically different B. bigemina isolates. The antigenic components were demonstrated to be species-specific and apparently predominant. Both polyclonal antibodies (immune bovine serum) and highly diluted MAb specifically reacted with such bands producing a strong signal in Western blots.

Nmd3p from yeast is required for the export of the large (60S) ribosomal subunit from the nucleus (Ho et al., 2000). Here, we show that Nmd3p forms a stable complex with free 60S subunits. Using an epitope-tagged Nmd3p, we show that free 60S subunits can be coimmunoprecipitated with Nmd3p. The interaction was specific for 60S subunits; 40S subunits were not coimmunoprecipitated. Using this coprecipitation technique and pulse-chase labeling of ribosomal subunit proteins we showed that Nmd3p bound nascent subunits, consistent with its role in export. However, under conditions in which ribosome biogenesis was inhibited (e.g., inhibition of transcription with thiolutin, inhibition of transcription of ribosomal protein and RNA genes in a sly1-1 mutant at nonpermissive temperature, and inhibition of translation in a conditional prt1 mutant), Nmd3p remained associated with 60S subunits. In addition, Nmd3Δ120, a truncated protein that lacked a nuclear localization signal, retained 60S binding. These results suggest that Nmd3p recruits nascent 60S subunits into the pool of free 60S subunits and exchanges on 60S subunits as they recycle during translation.

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 tRNAAla 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 tRNAAla. Here we demonstrate that human anti-tRNAAla autoantibodies immunoprecipitate a synthetic polyribonucleotide containing inosine (I) and N1-methylinosine (m1I) separated by 2 nt as in the anticodon stem-loop of human tRNAAla. The shortest polyribonucleotide that can be immunoprecipitated corresponds to the pentanucleotide IpGpCpm1IpUp, which corresponds to part of the anticodon loop of human tRNAAla 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 tRNAAla stem-loop, containing the sequence dIpdGdCdm1Ip, are not antigenic. Our results show that human anti-tRNAAla 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.

Several monoclonal antibodies (Mabs) were raised against the L1 muscle stage (L1M) of Trichinella spiralis (Ts) and Trichinella pseudospiralis (Tp). Western blot analysis of various antigenic preparations established that Mabs described by different authors recognized 8 antigenic fractions (TSL1–TSL8) in crude extracts of infective larvae. The TSL1 fraction was immunodominant and present on the cuticle of different parasite stages. Mabs against Trichinella T5 (T5) and Ts were selected in order to extend the previous studies to another Trichinella phenotype. Only 35% of the selected Mabs recognized linear epitopes and 71% reacted with soluble or excretory–secretory antigens in a dot blot procedure and ELISA test. The targets of the Mabs were identified by immunoprecipitation with [35S]methionine-labelled L1M worm lysate. Mabs prepared from mice immunized with the whole parasite (T5) recognized a wider panel of antigens in different parasitic organs. Seven antigenic structures were distinguished on the cuticle and several epitopes were identified in the gut, haemolymph and stichocytes. Eleven antigenic groups were established according to their indirect immunofluorescence pattern on cross-sections of the worm. Monoclonal antibodies raised against Ts soluble antigen mainly recognized epitopes in stichocytes and on the cuticle surface. All the selected Mabs recognized T5 and Trichinella britovi (Tb) strengthening the link between these 2 species. Four Mabs were used to differentiate antigenic structures among 6 Trichinella phenotypes and to develop a new tool to follow gene flow within the Trichinella genus.

Immune resistance to infestation by an ixodid tick, Rhipicephalus appendiculatus, the vector of the African cattle disease, East Coast Fever, was induced in rabbits by either repeated tick feeding or immunization with tick extracts. In addition to resistance to tick infestation, tick extract immunization led to a reduction in the viability of eggs laid by ticks feeding on the immunized host. Resistance to infestation by ixodid ticks has previously been reported by others to have a humoral immune component. Therefore, antibodies from resistant host animals were used to detect the tick antigens they recognized as an approach to identification of the target antigen(s) for the observed immune responses on feeding ticks. In crossed immune electrophoresis two antigens were detected using sera from animals made resistant by multiple tick infestations. Sera from extract immunized animals detected these antigens and nine others. The tick antigens detected by both sets of sera in crossed immune electrophoresis were radiolabelled with [35S]amino acids. No labelled antigens were detected by Staphylococcus aureus mediated immune precipitation with sera from hosts made resistant by multiple infestations. Antibodies from extract-immunized animals identified nine protein antigens by S. aureus immunoprecipitation. The molecular weights of these antigens as assessed by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis were 180,000; 140,000; 130,000; 98,000; 92,000; 88,000; 85,000 and 82,000. The rate of synthesis of these antigens appeared to vary in relation to the tick feeding cycle.