Morphogenesis of the giant sperm axoneme in Asphondylia ruebsaameni Kertesz (Diptera, Cecidomyiidae)

The formation of the sperm giant axoneme of the gall-midge fly Asphondylia ruebsaameni is described here. The axoneme consists of a great number of microtubular doublets (up to 2,500) arranged in a double spiral wrapping around an axial cluster of mitochondria. Each microtubular doublet is provided with an outer arm only. In the early spermatid the occurrence of a large system of curved multi-layered filamentous material associated with membranous cisternae has been observed in the perinuclear region. Such a system extends throughout the cytoplasm to contact the plasma membrane. The filamentous material appears to act as a nucleating centre for the assembly of the microtubular doublets, which initially have a submembranous location and later are distributed in the interior of the cell. After their assembly, microtubular doublets are associated pairwise and are arranged in a single microtubular row with a zig-zag configuration. This configuration changes during spermiogenesis as a consequence both of a rotation of the microtubular doublet pairs and a compaction of the axonemal complex due to the elimination of the excess cytoplasm. As a result of this process, a double parallel spiral of microtubular doublets is formed.     

Differential distribution of glutamylated tubulin isoforms along the sea urchin sperm axoneme

Tubulin belongs to a highly conserved multigenic family, in which several gene products usually coexist in the same tissue or the same cell. Moreover, seven classes of post-translational modifications of these gene products lead to an amazing diversity of tubulin polypeptide chains, within the same cell type, whose physiological function remains elusive. Such diversity has been found in a very stable microtubular organelle, the sea urchin sperm flagellum, where some tubulin isoforms have been directly implicated in motility, whereas others may play a more structural role. In particular, polyglutamylated tubulin has been shown to be crucial for motility (Gagnon et al., 1996: J Cell Sci 109:1545 p). Here, we show with the GT335 antibody that polyglutamylated tubulin is distributed according to a decreasing gradient along the sea urchin sperm axoneme, since a semi-quantitative measurement of immunofluorescence intensity reveals that in its proximal half, the axoneme is sixfold more labeled than in its distal half. This gradient along the length of the axoneme is confirmed by immunogold labeling procedures which, in addition, demonstrate a uniform distribution of polyglutamylated tubulin among peripheral doublets and a lesser content in the central pair within a same section. Moreover, our data obtained with B3, an antibody that recognizes both mono- and poly-glutamylated tubulin, suggest that the number of glutamate residues in the lateral poly-glutamyl chain of tubulin varies along the whole length of the axoneme. These novel results coupled with those published earlier may be important to understand the role of polyglutamylation in flagellar motility.     

Glutamylated tubulin: diversity of expression and distribution of isoforms

Glutamylation of alpha and beta tubulin isotypes is a major posttranslational modification giving rise to diversified isoforms occurring mainly in neurotubules, centrioles, and axonemes. Monoglutamylated tubulin isoforms can be differentially recognized by two mAbs, B3 and GT335, which both recognize either polyglutamylated isoforms. In the present study, immunoelectron microscopy and immunofluorescence analyses were performed with these two mAbs to determine the expression and distribution of glutamylated tubulin isoforms in selected biological models whose tubulin isotypes are characterized. In mouse spermatozoa, microtubules of the flagellum contain polyglutamylated isoforms except in the tip where only monoglutamylated isoforms are detected. In spermatids, only a subset of manchette microtubules contain monoglutamylated tubulin isoforms. Cytoplasmic microtubules of Sertoli cells are monoglutamylated. Mitotic and meiotic spindles of germ cells are monoglutamylated whereas the HeLa cell mitotic spindle is polyglutamylated. Three models of axonemes are demonstrated as a function of the degree and extent of tubulin glutamylation. In lung ciliated cells, axonemes are uniformly polyglutamylated. In sea urchin sperm and Chlamydomonas, flagellar microtubules are polyglutamylated in their proximal part and monoglutamylated in their distal part. In Paramecium, cilia are bi- or monoglutamylated only at their base. In all cells, centrioles or basal bodies are polyglutamylated. These new data emphasize the importance of glutamylation in all types of microtubules and strengthen the hypothesis of its role in the regulation of the intracellular traffic and flagellar motility.     

Size and fecundity in the Jamaican gall-midge Asphondylia boerhaaviae

ABSTRACT. 1. The gall-midge Asphondylia boerhaaviae Möhn galls weeds belonging to the Nyctaginaceae in Jamaica and other parts of the Caribbean. The species breeds throughout the year with a generation length of < 1 month.
2. In adult females, plots of wing length on hind tibial length, of maximum potential fecundity (m.p.f.) on wing length, and of m.p.f. on ovariole number, suggested the presence of a small morph, which the use of discriminant function analysis and other investigations confirmed. There was also good evidence of two size morphs in adult males.
3. Both body size and ovariole number had significant effects on m.p.f. but these effects were different in the two morphs. While the food plants had significant influences on size and fecundity, these were relatively small. The m.p.f. of the small morph was 125.8±11.1 eggs, and of the large morph 318.7±8.3 (95% cl).
4. Laboratory experiments on the flight performance of newly-emerged midges indicated that the small morph was not dispersive and that about 80% of the large morph was dispersive. No differences in size, wing length or fecundity could be found between the two behavioural types of the large morph.
5. The nature of the polymorphism is unusual, particularly since the dispersive individuals potentially have similar (or greater) fecundity than the non-dispersive ones.
6. Estimates of achieved fecundity (eggs actually laid, rather than m.p.f.) were 67.8±9.6 (field, minimum) and 138.9±30.4 (laboratory), the latter estimate being based on large-morph females.     

Sperm axoneme of two rows of doublets reversely oriented in the gall-midge Lestremia (Diptera, Cecidomyiidae)

The spermatozoon of Lestremia lacks an acrosome and has a giant centriole that gives origin to a giant axoneme with about 150 doublets. The axonemal doublets, disposed in two opposite rows oriented antiparallel, have A doublets with two dynein arms and a B tubule filled with dense proteinaceous material. Mitochondria fuse in two derivatives and show cristae and a longitudinal crystallized axis. The probable origin of the giant axoneme is hypothesized and the more prolonged motility of Lestremia sperm in comparison with that of other gall midges is related to the presence of a more precise axonemal organization. The spermatological results agree with the systematic position of Lestremiinae at the base of the evolutionary trend of the family Cecidomyiidae.     

Comparative immunogold analysis of tubulin isoforms in the mouse sperm flagellum: Unique distribution of glutamylated tubulin

The distribution of different tubulin isoforms in the mouse sperm flagellum was studied using four site-directed antibodies to tubulin: DM1A and DM1B general anti α and β-tubulin, 6-11B-1 anti-acetylated α-tubulin, and GT335 anti-glutamylated α and β-tubulin. Quantitative immunogold analyses were performed on five regions of the flagellum: the middle piece, three successive regions of the principal piece, and the terminal piece. A uniform labeling was observed with DM1A and DM1B along the entire flagellum both for peripheral doublets and the central pair. Similar results were obtained with 6-11B-1 directed to acetylated α-tubulin, an N-terminal-modified tubulin isoform. In contrast, the labeling for glutamylated α and β-tubulin, C-terminal modified isoforms, was not uniform. The highest intensity was found in the middle piece and the terminal piece. The labeling which decreased significantly both for peripheral doublets and central pair along the principal piece was considered as a loss of glutamylated tubulin accessibility. From the middle piece to the end of the principal piece, this labeling was predominant in doublets 1-5-6, corresponding to the plane of the flagellar wave. However, the labeling for doublets 2-3-4-7-8-9 was heterogeneous, showing an increasing asymmetry. These results suggest that in the mammalian sperm cell model, the glutamylated tubulin might be involved in a functional heterogeneity among peripheral doublets of the flagellum. © 1996 Wiley-Liss, Inc.     

Ultrastructural analysis of the aberrant axoneme morphogenesis in thrips (Thysanoptera, Insecta)

Thrips spermiogenesis is characterized by unusual features in the differentiating spermatid cells. Three centrioles from which three individual short flagella are initially assembled, make the early spermatid a tri-flagellated cell. Successively, during spermatid maturation, the three basal bodies maintain a position close to the most anterior end of the elongating nucleus, so that the three axonemes are progressively incorporated in the spermatid cytoplasm, where they run in parallel to the main nuclear axis. Finally, the three axonemes amalgamate to form a microtubular bundle. The process starts with the formation of rifts at three specific points in each axonemal circumference, corresponding to sites 1,3,7 and leads to the formation of 9 microtubular rows of different length, i.e. 3 "dyads", 3 "triads" and 3 "tetrads". In the spermatozoon, the nucleus, the mitochondrion and the bundle of microtubules are arranged in a helicoidal pattern. The elongation of the spermatozoon is allowed by the deep anchorage of the spermatid to the cyst cell through a dense mass of material which, at the end of spermiogenesis, becomes a long anterior cylindrical structure. This bizarre "axoneme" does not show any trace of progressive movement but it is able to beat. According to the presence of dynein arms, sliding can take place only within each row and not between the rows. The possible molecular basis underlying the peculiar instability of thrips axonemes is discussed in light of the present knowledge on the organization of the axoneme in mutant organisms carrying alterations of the tubulin molecule.     

Ultrastructural patterns of the flagellar axoneme in the non-motile part of the mole-cricket sperm

The mole-cricket spermatozoon (Gryllotalpa gryllotalpa) has a motile anterior tail region and an immotile posterior region. The posterior portion appears stiff and its microtubular doublets and central singlet microtubules are swollen, apparently due to an excess of material within them. In particular, doublet number 6 is of an unusually large size. The general organization of the axoneme is also modified by a loss of dynein arms and spokes in the posterior portion. When studied by a fixation technique that involves tannic acid to outline the protein molecules and PA-TCH-Ag method for staining polysaccharides it could be seen that the microtubular doublets and accessory microtubules contain rounded globules surrounded by polysaccharides. The arrangement of protofilaments within the microtubular walls is visible both in the anterior tail region with normal doublets and in the posterior region with degenerated doublets.     

Kinetic analysis of axoneme and dynein ATPase from sea urchin sperm

The behavior of the ATPase of axoneme (detergent-treated flagellum) and dynein from sea urchin sperm was investigated. The activation of the ATPase by divalent cations was attributed to formation of a complex of ATP and the divalent cation; the metal-ATP complex is an effective substrate. However, free ATP is a modifier of the ATPase. Free ATP markedly changes the affinity of the metal-ATP complex to the enzymes. Calcium-activated ATPase activity of axoneme decreased at high concentration of CaCl₂, but that of dynein did not decrease.     

Connecting bridges between axoneme and other components in the sperm tail of some insects

Spermatozoa from three insect groups were examined by electron microscopy and found to have bridges that connect some of the axonemal doublets with either the two mitochondrial derivatives or, in the phasmids, the so-called laminated bodies. Within Hemiptera Heteroptera the bridges extend from doublet Nos. 1 and 5, within chrysopid neuropterans from doublet Nos. 2 and 5, and in the phasmids from axonemal doublet Nos. 2 and 4. Bridges were looked for in spermatozoa from several other insect groups but not found. The bridges in the chrysopids are regularly curved rather than straight. While bridges in heteropterans and chrysopids were seen in spermatozoa fixed with “standard fixatives,” those in the phasmids were distinctly resolved only in spermatozoa that had been fixed with a tannic acidcontaining fixative. In spite of these differences, it is conceivable that the bridges in these three insect taxa are all derived from similar, faint, bridge-like connections that sometimes can be seen to extend from all or many doublets toward the axonemal sheath of the early insect spermatid. These bridges or bridge-like structures might have a morphogenic function in that they may specify the location of the mitochondria later to become mitochondrial derivatives or, in the phasmids, of the laminated bodies.     

Immunocytochemical study of tubulin in the 9+‘1’ sperm axoneme of a monogenean (Platyhelminthes), Pseudodactylogyrus sp.

The spermatozoon of the monopisthocotylean monogenean Pseudodactylogyrus sp. (a gill parasite of eels) has a single axoneme showing a 9+‘1’ pattern, a nucleus and a mitochondrion, but has no cortical microtubules. This species thus provides a very simple model for the study of tubulin in the 9+‘1’ axonemes of the Platyhelminthes, in contrast with digenean sperm which have a more complex spermatozoon with two such axonemes and cortical microtubules. Indirect immunofluorescence labelling of tubulin shows that the elongating spermatids, initially lying in all directions in the early stages, are arranged as parallel elements in further stages. The number of spermatids in an isogenic group could also be precisely counted and equals 32. Nuclear labelling with fluorescent dyes shows that the nuclei, first located in the common mass of the spermatids, later elongate and migrate into the growing spermatids, and that the nucleus is located in the central part of the mature spermatozoon, with the two extremities devoid of nucleus. Labelling with antibodies directed against acetylated, tyrosinated, and polyglutamylated tubulin gave positive results, thus indicating that these post-translational modifications of tubulin are present in the axoneme of spermatids and spermatozoa of monopisthocotylean monogeneans.     

Androgen-induced up-regulation of tubulin isoforms in neuroblastoma cells

Androgens regulate the physiology of motor neurones both during development and in adult life. In particular, androgens increase the rate of axonal regeneration after axotomy, an effect correlated with the up-regulation of tubulin. In order to determine whether this was the result of a direct hormone action on neurones, we examined the effect of testosterone on microtubular proteins in human neuroblastoma SH-SY5Y cells. Treatment of proliferating SH-SY5Y cells with testosterone resulted in an up-regulation of alpha- and beta-tubulin. By contrast, no change in tubulin was observed either in cells differentiated into a neuronal phenotype by retinoic acid or in adrenal SW13 cells. We also show that an up-regulation of the ubiquitous beta(II)-tubulin and of the neurone-specific beta(III)-tubulin isoforms contributes to the overall increase in tubulin in response to androgen treatment. The increase in tubulin levels following testosterone treatment was abolished by co-incubation with antiandrogens, indicating that this effect is mediated through a classical mechanism of steroid action. The two microtubule-associated proteins, tau and MAP2b, remained unchanged following testosterone exposure. Thus, these results demonstrate that tubulin is a direct neuronal target of androgen regulation and suggest that dysregulation of tubulin expression may contribute to the pathogenesis of some motor neuronopathies.     

Unusual distribution of tubulin isoforms in the snail Lymnaea stagnalis

Immunocytochemistry and Western blotting techniques demonstrated that the nervous system and foot of the pond snail Lymnaea stagnalis are rich sources of tubulin, which can be extracted and assembled in vitro in the presence of taxol. Various broad-spectrum antibodies raised against -tubulin and -tubulin yielded qualitatively similar results. One monoclonal antibody to trypanosome -tubulin, however, labelled -tubulin more strongly on both probed sections and Western blots. Cytochemistry and immunoblotting revealed that tyrosinated tubulin constitutes a large proportion of total -tubulin in locomotor cilia of the foot and in axons of the nervous system. Detyrosinated tubulin also appeared to be abundant in the foot cilia but only a very faint band of detyrosinated tubulin was found on protein blots extracted from the central ganglia, and staining was barely detectable in central ganglia or peripheral nerves. Similarly, acetylated tubulin appeared to be abundant in foot cilia, but Western blotting indicated only low levels of acetylated tubulin in the nervous system. Immunocytochemistry indicated that, while most neurons possessed little or no acetylated tubulin, a small number of axons contained significant amounts of this isoform. Thus, while a large amount of tubulin was expected in the nervous system and locomotor cilia of L. stagnalis, the observed distribution of isoforms was unanticipated. Specifically, neurons of other organisms have generally been reported to contain substantial amounts of both detyrosinated -tubulin and acetylated -tubulin. Our results indicate that such findings cannot be generalized across all species. L. stagnalis, with its well studied nervous system and unusual distribution of tubulin isoforms, may prove to be particularly useful for studying the roles of tubulin isoforms in microtubule function and cell activity.     

Erythrocyte microtubule assembly in vitro. Determination of the effects of erythrocyte tau, tubulin isoforms, and tubulin oligomers on erythrocyte tubulin assembly, and comparison with brain microtubule assembly

Two tubulin variants, isolated from chicken brain and erythrocytes and known to have different peptide maps and electrophoretic properties, are demonstrated to exhibit different assembly properties in vitro: 1) erythrocyte tubulin assembles with greater efficiency (lower critical concentration, greater elongation rate) but exhibits a lower nucleation rate than brain tubulin, and 2) erythrocyte tubulin readily forms oligomers whose presence significantly retards the rate of elongation, suggesting that tubulin oligomers may also be important for determining the rate of assembly and the length of microtubules in erythrocytes. Erythrocyte tubulin isolated by cycles of in vitro assembly-disassembly is also demonstrated to contain a 67-kDa tau factor that greatly enhances microtubule nucleation but has little effect on elongation rates or critical concentration. Immunofluorescence microscopy with tau antibody indicates that tau is specifically associated with marginal band microtubules, suggesting that it may be important for determining microtubule function in vivo.     

Motile organelles: the importance of specific tubulin isoforms

The requirements for building flagellar axonemes and centrioles are beginning to be uncovered. The carboxyl terminus of a specific beta tubulin isoform plays an important role in forming the '9 + 2' structure of the axoneme; delta tubulin plays an essential role in forming the triplet microtubules of centrioles and basal bodies.     

Inhibition of axoneme and dynein ATPase from sea urchin sperm by free ATP

Sea urchin sperm flagellar ATPase (EC 3.6.1.3) has magnesium-ATP as an effective substrate and is inhibited by free ATP. The inhibition is prevented by high concentration of KCl or NaCl. 0.4 M KCl extracts 48% of ATPase activity from axoneme. The 0.4 M KCl extract and 0.4 M KCl-treated axoneme are also inhibited by free ATP and this inhibition is reversed by KCl. Dynein purified twice by sucrose density gradient centrifugation is alsof inhibited by free ATP; this inhibition is also reversed by KCl.