Nicolette Levilliers

Isolation and characterization of libraries of monoclonal antibodies directed against various forms of tubulin in Paramecium

Summary— Ciliates are very good models for studying post‐translationally generated tubulin heterogeneity because they exhibit highly differentiated microtubular networks in combination with reduced genetic diversity. We have approached the analysis of tubulin heterogeneity in Paramecium through extensive isolation and characterization of monoclonal antibodies using various antigens and several immunization protocols. Eight monoclonal antibodies and 10 hybridoma supernatants were characterized by: i) immunoblotting on ciliate and pig brain tubulins as well as on peptide maps of Paramecium axonemal tubulin; ii) immunoblotting on ciliate tubulin fusion peptides generated in E coli, a procedure which allows in principle to discriminate antibodies that are directed against tubulin sequence (reactive on fusion peptides) from those directed against a post‐translational epitope (non‐reactive); and iii) immunofluorescence on Paramecium, 3T3 and PtK2 cells. Twelve antibodies labeled all microtubules in Paramecium cells and were found to be directed against tubulin primary sequences (nine of them being located in the α N‐terminal domain, one in the β C‐terminal one, and two in α and β central stretches). The remaining ones decorated only a specific subset of microtubules within the cell and were presumably directed against post‐translational modifications. Among these, three antibodies are directed against an N‐terminal acetylated epitope of α‐tubulin whereas the epitopes of three other ones (TAP 952°, AXO 58 and AXO 49°) apparently correspond to still unidentified post‐translational modifications, located in the C‐terminal domain of both α‐ and β‐tubulins. The AXO 49° specificity is similar to that of a previously described polyclonal serum raised against Paramecium axonemal tubulin [2]. The results are discussed in terms of identification and accessibility of the epitopes and immunogenicity of ciliate tubulin with reference to mammalian and ciliate tubulin sequences.

Where and when is microtubule diversity generated inParamecium? Immunological properties of microtubular networks in the interphase and dividing cells

SummaryCiliates are highly differentiated cells which display extensive deployment of microtubular systems. Because genetic diversity of tubulin is extremely reduced in these cells, microtubule diversity is mostly generated at the post-translational level either through direct modification of tubulin or through the binding of associated proteins to microtubules. We have undertaken a systematic exploration of microtubule diversity in ciliates by way of production of monoclonal antibodies. Previously we reported the biochemical characterization of these antibodies. In addition to antibodies directed against primary sequences, we obtained antibodies directed against post-translational modifications. In this paper, we report a detailed analysis of the distribution of the various epitopes on the microtubular networks ofParamecium, both in interphase cells and during division morphogenesis. Each of these antibodies decorates a subset of microtubules. Acetylation, recognized by antibodies TEU 318 and TEU 348, is detected on stable microtubules early after microtubule assembly. Epitopes recognized by two other antibodies (TAP 952 and AXO 58) are found on a subset of stable microtubules; in addition, the TAP 952 antibody is also found on labile microtubules; both epitopes are detected as soon as microtubule assembly occurs. In contrast, the epitope of the antibody, AXO 49, is associated with only a restricted subset of stable microtubules in the interphase cell, and is detected a lag-time after microtubule assembly during division morphogenesis. These data show that microtubule diversity is generated through a time-dependent sequence and according to a definite spatial pattern.

Expression of tubulin polyglycylation in Giardia lamblia.

Summry— By means of immunofluorescence, immunoelectron microscopy and immunoblotting, we show that polyglycylation, a posttranslational modification of tubulin widely spread among eukaryotes, is present in the diplomonad, Giardia lamblia, a putative ancestral cell possessing a highly developed microtubular cytoskeleton. This modification was recently discovered in the ciliated protist, Paramecium, and was not found in the Euglenozoa, a lineage considered as ancient. We used two monoclonal antibodies (mABs), TAP 952 and AXO 49, specifically recognizing mono‐ and polyglycylated tubulin isoforms, to detect this modification in Giardia extracts and to localize it in the different classes of microtubules within the cell. The α‐ and β‐tubulin subunits were recognized by the two mAbs, indicating that both tubulin subunits are glycylated, in agreement with lately reported mass spectrometry results. Noticeably, Giardia tubulin was much more reactive with AXO 49 than with TAP 952. In situ, AXO 49 intensely labeled the microtubules present in the four pairs of flagella and the median body, and lightly decorated the microtubules from the adhesive disc. In contrast, TAP 952 intensely labeled only the microtubules of the median body. The results indicate a differential expression of glycylated isoforms within various microtubular structures of Giardia lamblia. They also suggest that the complete set of enzymes required for polyglycylation is expressed in very divergent eukaryotes.

Tubulin Polyglycylation in Platyhelminthes: Diversity Among Stable Microtubule Networks and Very Late Occurrence During Spermiogenesis

The distribution of glycylated tubulin has been analyzed in different populations of stable microtubules in a digenean flatworm, Echinostoma caproni (Platyhelminthes). Two cellular types, spermatozoa and ciliated excretory cells, have been analyzed by means of immunofluorescence, immunogold, and immunoblotting techniques using two monoclonal antibodies (mAbs), AXO 49, and TAP 952, specifically directed against differently glycylated isoforms of tubulin. The presence of glycylated tubulin in the two cell types was shown. However, the differential reactivities of TAP 952 and AXO 49 mAbs with the two axoneme types suggest a difference in their glycylation level. In addition, within a single cell, the spermatozoon, cortical microtubules underlying the flagellar membrane, and axonemal microtubules were shown to comprise different tubulin isoforms, the latter ones only being labelled with one of the antiglycylated tubulin mAbs, TAP 952. Similarly, the antiacetylated (6-11B-1) and polyglutamylated (GT335) tubulin mAbs decorated the two types of axonemal microtubules, but not the cortical ones. From these data, a subcellular sorting of posttranslationally modified tubulin isoforms within spermatozoa, on the one hand, and a cellular sorting of glycylated isoforms inside the whole organism, on the other hand, is demonstrated in the flatworm E. caproni. Last, a sequential occurrence of tubulin posttranslational modifications was observed in the course of spermiogenesis. Acetylation appears first, followed shortly by glutamylation; glycylation takes place at the extreme end of spermiogenesis and, specifically, in a proximo-distal process. Thus in agreement with, and extending other studies [Bré et al., 1996], glycylation appears to close the sequence of posttranslational events occurring in axonemal microtubules during spermiogenesis.

Accessory tubules and axonemal microtubules of Apis mellifera sperm flagellum differ in their tubulin isoform content.

In the insect sperm flagellum, an extra set of nine additional microtubules, named accessory tubules, is present surrounding the axoneme. Using a sarcosyl/urea extraction, we were able to fractionate the microtubular cytoskeleton of the sperm flagellum of the insect Apis mellifera resulting in the dissociation of the axonemal microtubule protein components and the accessory tubules. This has allowed us to compare the tubulin isoform content of axonemal microtubules and accessory tubules by immunoelectron microscopy and immunoblotting using a panel of monoclonal antibodies directed against different tubulin post-translational modifications (PTMs). All the PTMs occurring in axonemal tubulin are also present in accessory tubules, which indicates the close relativeness of accessory tubules to axonemal rather than to cytoplasmic microtubules. However, our results demonstrate the presence of significant differences in the tubulin isoform content of axonemal microtubules and accessory tubules. First, the tubulin tyrosination extent of accessory tubules is far lower than that of axonemal microtubules, thus confirming at the molecular level their morphogenetic origin as outgrowths from the B-subtubule of each microtubular doublet. Second, although polyglycylation seems to occurr at the same extent in both microtubular systems, alpha-tubulin exhibits a larger amount of monoglycylated sites in axonemal microtubules than in accessory tubules. Third, a greater amount of beta-tubulin molecules is glutamylated in axonemal microtubules than in accessory tubules. Moreover, highly acidic isoforms, likely molecules with longer polyglutamate side chains, are present only in axonemal microtubules. Taken together, our data are indicative of a higher level of tubulin heterogeneity in axonemal microtubules than in accessory tubules. They also show a segregation of post-translationally modified isoforms between accessory tubules and axonemal microtubules and suggest the implication of PTMs in the functional specialization of the two microtubular systems.