Elizabeth C. Raff

The testis-specific β-tubulin subunit in drosophila melanogaster has multiple functions in spermatogenesis

We have isolated four recessive male sterile mutations in the structural gene for the testis-specific Drosophila beta 2-tubulin. Each of these mutations encodes a variant beta 2-tubulin subunit synthesized at normal levels, but which is subsequently unstable and rapidly degraded within the testis. In such testes, the normal alpha tubulins are also synthesized at normal levels and then degraded. Thus in mutant males the testis tubulin pool is drastically reduced relative to wild-type. In males homozygous for any of the recessive beta 2-tubulin mutations, the early mitotic divisions, which are completed before the time of synthesis of beta 2-tubulin, are normal. Thereafter, however, all microtubule-mediated events subsequent to the expression of the altered subunit are defective: meiosis, nuclear shaping and assembly of the axoneme all fail to occur. We thus conclude that the beta 2-tubulin subunit that forms the Drosophila sperm axoneme is not functionally restricted but serves multiple functions in spermatogenesis, including the assembly of both singlet and doublet tubules.

Kinesin Heavy Chain Is Essential for Viability and Neuromuscular Functions in Drosophila, but Mutants Show No Defects in Mitosis

The in vivo function of the microtubule motor protein kinesin was examined in Drosophila using genetics and immunolocalization. Kinesin heavy chain mutations (khc) cause abnormal behavior and lethality. Mutant larvae exhibit loss of mobility and tactile responsiveness in the most posterior segments, followed by general paralysis and death during larval or pupal development. Adults homozygous for a temperature-sensitive allele also exhibit a loss in mobility and sensory responses. The data indicate that kinesin function is essential and suggest that kinesin has an important role in the neuromuscular system, perhaps as a motor for axonal transport. The possibility of more general cellular functions remains open, but observation of embryogenesis and morphogenesis in khc mutants suggests that mitosis and the cell cycle can proceed in spite of impaired kinesin function. Immunolocalization suggests that kinesin may have some general cellular functions but that it is not a major component of mitotic spindles.

Drosophila KAP Interacts with the Kinesin II Motor Subunit KLP64D to Assemble Chordotonal Sensory Cilia, but Not Sperm Tails

BACKGROUND Kinesin II-mediated anterograde intraflagellar transport (IFT) is essential for the assembly and maintenance of flagella and cilia in various cell types. Kinesin associated protein (KAP) is identified as the non-motor accessory subunit of Kinesin II, but its role in the corresponding motor function is not understood. RESULTS We show that mutations in the Drosophila KAP (DmKap) gene could eliminate the sensory cilia as well as the sound-evoked potentials of Johnstons organ (JO) neurons. Ultrastructure analysis of these mutants revealed that the ciliary axonemes are absent. Mutations in Klp64D, which codes for a Kinesin II motor subunit in Drosophila, show similar ciliary defects. All these defects are rescued by exclusive expression of DmKAP and KLP64D/KIF3A in the JO neurons of respective mutants. Furthermore, reduced copy number of the DmKap gene was found to enhance the defects of hypomorphic Klp64D alleles. Unexpectedly, however, both the DmKap and the Klp64D mutant adults produce vigorously motile sperm with normal axonemes. CONCLUSIONS KAP plays an essential role in Kinesin II function, which is required for the axoneme growth and maintenance of the cilia in Drosophila type I sensory neurons. However, the flagellar assembly in Drosophila spermatids does not require Kinesin II and is independent of IFT.

Mutation in a testis-specific β-tubulin in Drosophila: Analysis of its effects on meiosis and map location of the gene

The structural gene for a testis-specific beta--tubulin subunit in Drosophila melanogaster was mapped genetically and cytogenetically by means of a dominant male sterile mutation, B2tD, in which a variant form of the testis beta--tubulin is expressed. The B2t locus is at 48.5 map units on the third chromosome genetic map, and in bands 85D4-7 on the salivary chromosome map. The mutation B2tD causes disruption of microtubule function in all stages of spermatogenesis, beginning with meiosis. The effects of gene dosage of B2tD on meiosis were examined in detail cytologically at the light microscope level. In testes of flies in which the variant tubulin subunit is expressed, abnormal meiotic spindle formation, improper chromosome movement and failure to undergo cytokinesis occur. The extent of these defects in microtubule function depends on the dosage of the B2tD mutation, being most severe in males homozygous for the mutation, intermediate in males heterozygous for the mutation, and least marked in males heterozygous for B2tD and a tandem duplication of the region of the genome containing the B2t locus. Chromosomal events unrelated to microtubule function, such as replication and condensation, occur normally. Results obtained during mapping of the B2t locus strongly suggest a haplo-insufficient site at or closely linked to this locus.

The Control of Microtubule Assembly in Vivo

Publisher Summary This chapter discusses the control of microtubule assembly in vivo. Microtubule assembly depends on the formation or activation of microtubule-organizing centers or structures, the primary cellular signals for which are largely unknown. A variety of microtubule-organizing centers has been observed; the most ubiquitous consists of amorphous electron-dense material, sometimes exhibiting a fibrous or granular substructure, of uncertain biochemical composition. There are some indications that one component of these centers may be tubulin itself, but it is not clear if this material has a general or typical composition. In different cell types or at different times this material may give rise either directly to microtubules or to more elaborate microtubule-containing organelles, particularly centrioles. Centrioles (after some morphological modifications and in some cases after physical relocation to the cell surface) may function as basal bodies and give rise directly to the microtubules of the flagella or cilia axoneme, thus themselves constituting a microtubule-organizing structure.

Embryo fossilization is a biological process mediated by microbial biofilms.

Fossilized embryos with extraordinary cellular preservation appear in the Late Neoproterozoic and Cambrian, coincident with the appearance of animal body fossils. It has been hypothesized that microbial processes are responsible for preservation and mineralization of organic tissues. However, the actions of microbes in preservation of embryos have not been demonstrated experimentally. Here, we show that bacterial biofilms assemble rapidly in dead marine embryos and form remarkable pseudomorphs in which the bacterial biofilm replaces and exquisitely models details of cellular organization and structure. The experimental model was the decay of cleavage stage embryos similar in size and morphology to fossil embryos. The data show that embryo preservation takes place in 3 distinct steps: (i) blockage of autolysis by reducing or anaerobic conditions, (ii) rapid formation of microbial biofilms that consume the embryo but form a replica that retains cell organization and morphology, and (iii) bacterially catalyzed mineralization. Major bacterial taxa in embryo decay biofilms were identified by using 16S rDNA sequencing. Decay processes were similar in different taphonomic conditions, but the composition of bacterial populations depended on specific conditions. Experimental taphonomy generates preservation states similar to those in fossil embryos. The data show how fossilization of soft tissues in sediments can be mediated by bacterial replacement and mineralization, providing a foundation for experimentally creating biofilms from defined microbial species to model fossilization as a biological process.

ADAPTIVE EVOLUTION OF BINDIN IN THE GENUS HELIOCIDARIS IS CORRELATED WITH THE SHIFT TO DIRECT DEVELOPMENT

Abstract Sea urchins are widely used to study both fertilization and development. In this study we combine the two fields to examine the evolution of reproductive isolation in the genus Heliocidaris. Heliocidaris tuberculata develops indirectly via a feeding larva, whereas the only other species in the genus, H. erythrogramma, has evolved direct development through a nonfeeding larva. We estimated the time of divergence between H. erythrogramma and H. tuberculata from mitochondrial DNA divergence, quantified levels of gametic compatibility between the two species in cross‐fertilization assays, and examined the mode of evolution of the sperm protein bindin by sequencing multiple alleles of the two species. Bindin is the major component of the sea urchin sperm acrosomal vesicle, and is involved in sperm‐egg attachment and fusion. Based on our analyses, we conclude that: the two species of Heliocidaris diverged less than five million years ago, indicating that direct development can evolve rapidly in sea urchins; since their divergence, the two species have become gametically incompatible; Heliocidaris bindin has evolved under positive selection; and this positive selection is concentrated on the branch leading to H. erythrogramma. Three hypotheses can explain the observed pattern of selection on bindin: (1) it is a correlated response to the evolution of direct development in H. erythrogramma; (2) it is the result of an intraspecific process acting in H. erythrogramma but not in H. tuberculata; or (3) it is the product of reinforcement on the species that invests more energy into each egg to avoid hybridization.

Regulation of tubulin gene expression during embryogenesis in drosophila melanogaster

Four different tubulins have been identified that are expressed during embryogenesis in Drosophila melanogaster. Two alpha-tubulin subunits (alpha 1 and alpha 2) and one beta-tubulin subunit (beta 1) are expressed throughout embryonic development. A second beta-tubulin subunit (beta 3) is expressed only for a short period in mid-embryonic development. Synthesis of beta 3-tubulin in vitro in a rabbit reticulocyte translation system is directed by RNA extracted from embryos only at the stage when the protein is expressed. Thus we conclude that the mRNA encoding beta 3-tubulin is transcribed only during the brief period of beta 3-tubulin synthesis. The expression of beta 3-tubulin is accompanied by a coordinate transient increase in the level of synthesis of the embryonic alpha-tubulins, thereby maintaining an approximately equimolar synthesis of alpha- and beta-tubulin subunits throughout embryogenesis.

Conserved axoneme symmetry altered by a component β-tubulin

Abstract Ninefold microtubule symmetry of the eukaryotic basal body and motile axoneme has been long established [1–3]. In Drosophila , these organelles contain distinct but similar β -tubulin isoforms [4–10]: basal bodies contain only β 1-tubulin, and only β 2-tubulin is used for assembly of sperm axonemes. A single α -tubulin functions throughout spermatogenesis [11,12]. Thus, differences in organelle assembly reside in β -tubulin. We tested the ability of β 1 to function in axonemes and found that β 1 alone could not generate axonemes. Small sequence differences between the two isoforms therefore mediate large differences in assembly capacity, even though these two related organelles have a common evolutionarily ancient architecture. In males with equal β 1 and β 2, β 1 was co-incorporated at equimolar ratio into functional sperm axonemes. When β 1 exceeded β 2, however, axonemes with 10 doublets were produced, an alteration unprecedented in natural phylogeny. Addition of the tenth doublet occurred by a novel mechanism, bypassing the basal body. It has been assumed that the instructions for axoneme morphogenesis reside primarily in the basal body, which normally serves as the axonemal template. Our data reveal that β -tubulin requirements for basal bodies and axonemes are distinct, and that key information for axoneme architecture resides in the axonemal β -tubulin.

Site and timing of synthesis of tubulin and other proteins during oogenesis in Drosophila melanogaster

Abstract Protein synthetic patterns during oogenesis in Drosophila melanogaster were examined; in particular the site, time, and rate of tubulin synthesis and accumulation during oogenesis were determined. Ovarian proteins were labeled with [ 35 S]methionine in vivo or in organ culure in vitro , and the proteins synthesized in egg chambers of specific developmental stages displayed by two-dimensional gel electrophoresis. A dissection technique was devised to examine proteins synthesized in each of the three cell types present in stage 10B egg chambers. The majority of proteins which were resolved by two-dimensional gel electrophoresis, including tubulin and actin, were synthesized throughout oogenesis and, at least to some extent, in each of the stage 10B cell types. Protein synthesis specific to developmental stage and/or cell type was also observed; for example, two nonchorion proteins were synthesized only in follicle cells and primarily at stage 10. A sensitive and specific radioimmune assay was developed in order to quantitate tubulin accumulation. Synthesis of several α-tubulin subunits and one β-tubulin subunit was observed. The tubulin content per egg chamber increased from 3 ng in stage 9 to 17 ng in stage 14, a period of about 13 hr. An accumulation rate of 1 ng/hr suggests that tubulin mRNA can account for about 4% of the total, nonmitochondrial, poly(A) + RNA of the egg. Analysis of separated cell types at stage 10B revealed that both the follicle and nurse cells synthesize and accumulate appreciable amounts of tubulin. The stage 10B oocyte contains relatively little tubulin but actively synthesizes it. These two complementary analyses demonstrate that the tubulin present in the egg is synthesized within the oocyte-nurse cell syncytium, first in the nurse cells and later in the oocyte.