Mutation of a putative sperm membrane protein in Caenorhabditis elegans prevents sperm differentiation but not its associated meiotic divisions.

Spermatogenesis in the nematode Caenorhabditis elegans uses unusual organelles, called the fibrous body-membranous organelle (FB-MO) complexes, to prepackage and deliver macromolecules to spermatids during cytokinesis that accompanies the second meiotic division. Mutations in the spe-4 (spermatogenesis-defective) gene disrupt these organelles and prevent cytokinesis during spermatogenesis, but do not prevent completion of the meiotic nuclear divisions that normally accompany spermatid formation. We report an ultrastructural analysis of spe-4 mutant sperm where the normally close association of the FB's with the MO's and the double layered membrane surrounding the FB's are both defective. The internal membrane structure of the MO's is also disrupted in spe-4 mutant sperm. Although sperm morphogenesis in spe-4 mutants arrests prior to the formation of spermatids, meiosis can apparently be completed so that haploid nuclei reside in an arrested spermatocyte. We have cloned the spe-4 gene in order to understand its role during spermatogenesis and the molecular basis of how mutation of this gene disrupts this process. The spe-4 gene encodes an approximately 1.5-kb mRNA that is expressed during spermatogenesis, and the sequence of this gene suggests that it encodes an integral membrane protein. These data suggest that mutation of an integral membrane protein within FB-MO complexes disrupts morphogenesis and prevents formation of spermatids but does not affect completion of the meiotic nuclear divisions in C. elegans sperm.

Chlamydomonas alpha-tubulin is posttranslationally modified in the flagella during flagellar assembly.

The principal alpha-tubulin within Chlamydomonas reinhardtii flagellar axonemes differs from the major alpha-tubulin in the cell body. We show that these two isoelectric variants of alpha-tubulin are related to one another since posttranslational modification of the cell body precursor form converts it to the axonemal form. During flagellar assembly, precursor alpha-tubulin enters the flagella and is posttranslationally modified within the flagellar matrix fraction prior to or at the time of its addition to the growing axonemal microtubules. Experiments designed to identify the nature of this posttranslational modification have also been conducted. When flagella are induced to assemble in the absence of de novo protein synthesis, tritiated acetate can be used to posttranslationally label alpha-tubulin in vivo and, under these conditions, no other flagellar polypeptides exhibit detectable labeling.

Reversal of the posttranslational modification on Chlamydomonas flagellar alpha-tubulin occurs during flagellar resorption.

We previously have shown that a posttranslational modification of alpha-tubulin takes place in the flagellum during Chlamydomonas flagellar assembly (L'Hernault, S. W., and J. L. Rosenbaum, 1983, J. Cell Biol., 97:258-263). In this report, we show that the posttranslationally modified alpha-3 tubulin is changed back to its unmodified alpha-1 precursor form during the microtubular disassembly that takes place during flagellar resorption. These data indicate that the addition and removal of a posttranslational modification on alpha-tubulin might be a control step in the assembly and disassembly of flagella.

Alpha-tubulin acetylase activity in isolated Chlamydomonas flagella.

We have previously shown that the alpha-tubulin of Chlamydomonas flagella is synthesized as a precursor which is modified by acetylation in the flagellum during flagellar assembly. In this report, we show the presence of an alpha-tubulin acetylase activity in isolated Chlamydomonas flagella that is highly specific for alpha-tubulin of both mammalian brain and Chlamydomonas.

Myosin VI is required for asymmetric segregation of cellular components during C. elegans spermatogenesis.

BACKGROUND: The asymmetric division of cells and unequal allocation of cell contents is essential for correct development. This process of active segregation is poorly understood but in many instances has been shown to depend on the cytoskeleton. Motor proteins moving along actin filaments and microtubules are logical candidates to provide the motive force for asymmetric sorting of cell contents. The role of myosins in such processes has been suggested, but few examples of their involvement are known. RESULTS: Analysis of a Caenorhabditis elegans class VI myosin deletion mutant reveals a role for this motor protein in the segregation of cell components during spermatogenesis. Mutant spermatocytes cannot efficiently deliver mitochondria and endoplasmic reticulum/Golgi-derived fibrous-body membranous organelle complexes to budding spermatids, and fail to remove actin filaments and microtubules from the spermatids. The segregation defects are not due to a global sorting failure as nuclear inheritance is unaffected. CONCLUSIONS: C. elegans myosin VI has an important role in the unequal partitioning of both organelles and cytoskeletal components, a novel role for this class of motor protein.

The Caenorhabditis elegans spe-5 gene is required for morphogenesis of a sperm-specific organelle and is associated with an inherent cold-sensitive phenotype.

The nonrandom segregation of organelles to the appropriate compartment during asymmetric cellular division is observed in many developing systems. Caenorhabditis elegans spermatogenesis is an excellent system to address this issue genetically. The proper progression of spermatogenesis requires specialized intracellular organelles, the fibrous body-membranous organelle complexes (FB-MOs). The FB-MOs play a critical role in cytoplasmic partitioning during the asymmetric cellular division associated with sperm meiosis II. Here we show that spe-5 mutants contain defective, vacuolated FB-MOs and usually arrest spermatogenesis at the spermatocyte stage. Occasionally, spe-5 mutants containing defective FB-MOs will form spermatids that are capable of differentiating into functional spermatozoa. These spe-5 spermatids exhibit an incomplete penetrance for tubulin mis-segregation during the second meiotic division. In addition to morphological and FB-MO segregation defects, all six spe-5 mutants are cold-sensitive, exhibiting a more penetrant sterile phenotype at 16 degrees than 25 degrees. This cold sensitivity could be an inherent property of FB-MO morphogenesis.

Developmental genetics of chromosome I spermatogenesis-defective mutants in the nematode Caenorhabditis elegans.

Mutations affecting Caenorhabditis elegans spermatogenesis can be used to dissect the processes of meiosis and spermatozoan morphological maturation. We have obtained 23 new chromosome I mutations that affect spermatogenesis (spe mutations). These mutations, together with six previously described mutations, identify 11 complementation groups, of which six are defined by multiple alleles. These spe mutations are all recessive and cause normally self-fertile hermaphrodites to produce unfertilized oocytes that can be fertilized by wild-type male sperm. Five chromosome I mutation/deficiency heterozygotes have similar phenotypes to the homozygote showing that the probable null phenotype of these genes is defective sperm. Spermatogenesis is disrupted at different steps by mutations in these genes. The maturation of 1 degree spermatocytes is disrupted by mutations in spe-4 and spe-5. Spermatids from spe-8 and spe-12 mutants develop into normal spermatozoa in males, but not in hermaphrodites. fer-6 spermatids are abnormal, and fer-1 spermatids look normal but subsequently become abnormal spermatozoa. Mutations in five genes (fer-7, spe-9, spe-11, spe-13 and spe-15) allow formation of normal looking motile spermatozoa that appear to be defective in either sperm-spermathecal or sperm-oocyte interactions.

Additional sequence complexity in the muscle gene, unc-22, and its encoded protein, twitchin, of Caenorhabditis elegans.

Null mutations of the Caenorhabditis elegans unc-22 gene cause a pronounced body surface twitch associated with impaired movement and disruption of muscle structure. Partial sequence analysis of unc-22 has previously revealed that its encoded polypeptide, named twitchin, consists of a single protein kinase domain and multiple copies of both an immunoglobulin-like domain and a fibronectin type III-like domain. This paper reports additional DNA sequence information that has revealed the transcription start of unc-22, the N terminus of twitchin, and an explanation for the weak phenotype of a transposon insertion allele. These new data indicate that the unc-22 gene is 18 kb larger than previously reported and has a transcription unit of 38,308 bp. These data add 791 amino acids to the twitchin N terminus for a complete polypeptide size of 6,839 amino acids and a predicted molecular weight of 753,494. This new polypeptide sequence includes four additional copies of the above-mentioned immunoglobulin-like domains and also includes a glycine-rich sequence that might form a flexible hinge. The additional coding sequence reveals that the insertion of the Tc1 transposon, in the unc-22 allele, st139, should disrupt twitchin structure because it is located in an exon. However, cDNA sequencing has revealed that several cryptic splice donors and acceptors adjacent to the Tc1 insertion site are used to splice the transposon out of unc-22(st139) mRNA. One of these splicing events produces a near wild-type mRNA that deletes only six amino acids from twitchin, and this might explain the unusually mild phenotype associated with this mutation.

Genetic and molecular characterization of the Caenorhabditis elegans spermatogenesis-defective gene spe-17.

Two self-sterile mutations that define the spermatogenesis-defective gene spe-17 have been analyzed. These mutations affect unc-22 and fail to complement each other for both Unc-22 and spermatogenesis defects. Both of these mutations are deficiencies (hcDf1 and hDf13) that affect more than one transcription unit. Genomic DNA adjacent to and including the region deleted by the smaller deficiency (hcDf1) has been sequenced and four mRNAs (including unc-22) have been localized to this sequenced region. The three non unc-22 mRNAs are shown to be sex-specific: a 1.2-kb mRNA that can be detected in sperm-free hermaphrodites and 1.2- and 0.56-kb mRNAs found in males. hDf13 deletes at least 55 kb of chromosome IV, including all of unc-22, both male-specific mRNAs and at least part of the female-specific mRNA. hcDf1, which is approximately 15.6 kb, deletes only the 5' end of unc-22 and the gene that encodes the 0.56-kb male-specific mRNA. The common defect that apparently accounts for the defective sperm in hcDf1 and hDf13 homozygotes is deletion of the spe-17 gene, which encodes the 0.56-kb mRNA. Strains carrying two copies of either deletion are self-fertile when they are transgenic for any of four extrachromosomal array that include spe-17. We have sequenced two spe-17 cDNAs, and the deduced 142 amino acid protein sequence is highly charged and rich in serine and threonine, but shows no significant homology to any previously determined protein sequence.

Sperm competition in the absence of fertilization in Caenorhabditis elegans.

Hermaphrodite self-fertilization is the primary mode of reproduction in the nematode Caenorhabditis elegans. However, when a hermaphrodite is crossed with a male, nearly all of the oocytes are fertilized by male-derived sperm. This sperm precedence during reproduction is due to the competitive superiority of male-derived sperm and results in a functional suppression of hermaphrodite self-fertility. In this study, mutant males that inseminate fertilization-defective sperm were used to reveal that sperm competition within a hermaphrodite does not require successful fertilization. However, sperm competition does require normal sperm motility. Additionally, sperm competition is not an absolute process because oocytes not fertilized by male-derived sperm can sometimes be fertilized by hermaphrodite-derived sperm. These results indicate that outcrossed progeny result from a wild-type cross because male-derived sperm are competitively superior and hermaphrodite-derived sperm become unavailable to oocytes. The sperm competition assays described in this study will be useful in further classifying the large number of currently identified mutations that alter sperm function and development in C. elegans.

dpy-18 encodes an alpha-subunit of prolyl-4-hydroxylase in caenorhabditis elegans.

Collagen is an extracellular matrix (ECM) component encoded by a large multigene family in multicellular animals. Procollagen is post-translationally modified by prolyl-4-hydroxylase (EC 1.14.11.2) before secretion and participation in ECM formation. Therefore, collagen processing and regulation can be studied by examining this required interaction of prolyl-4-hydroxylase with procollagen. High-resolution polymorphism mapping was used to place the Caenorhabditis elegans dpy-18 gene on the physical map, and we show that it encodes a prolyl-4-hydroxylase alpha catalytic subunit. The Dpy phenotype of dpy-18(e364) amber mutants is more severe when this mutation is in trans to the noncomplementing deficiency tDf7, while the dpy-18(e499) deletion mutant exhibits the same phenotype as dpy-18(e499)/tDf7. Furthermore, dpy-18 RNA interference (RNAi) in wild-type worms results in Dpy progeny, while dpy-18 (RNAi) in dpy-18(e499) mutants does not alter the Dpy phenotype of their progeny. These observations suggest that the dpy-18 null phenotype is Dpy. A dpy-18::gfp promoter fusion construct is expressed throughout the hypodermis within the cells that abundantly produce the cuticle collagens, as well as in certain head and posterior neurons. While prolyl-4-hydroxylase has been studied extensively by biochemical techniques, this is the first report of a mutationally defined prolyl-4-hydroxylase in any animal.

The C. elegans spe-9 gene encodes a sperm transmembrane protein that contains EGF-like repeats and is required for fertilization.

In the nematode worm C. elegans, individuals with mutations in the spe-9 gene produce spermatozoa with wild-type morphology and motility that cannot fertilize oocytes even after contact between gametes. Therefore, disruption of spe-9 function affects either gamete recognition, adhesion, signaling, and/or fusion. The spe-9 gene encodes a sperm transmembrane protein with an extracellular domain that contains ten epidermal growth factor-like repeats. A common feature of proteins that include epidermal growth factor-like motifs is their involvement in extracellular functions such as adhesive and ligand-receptor interactions. Additionally, the overall structure of the predicted SPE-9 protein is similar to that of ligands for the Notch/LIN-12/GLP-1 family of transmembrane receptors. These results suggest that SPE-9 functions in the specialized cell-cell interactions required for fertilization.

A novel chloride channel localizes to Caenorhabditis elegans spermatids and chloride channel blockers induce spermatid differentiation.

Caenorhabditis elegans spermatogenesis is especially suited for studies of nonrandom cytoplasmic segregation during cellular differentiation. Spermatocytes separate from an anuclear cytoplasmic core and undergo two sequential divisions. During the second division, intracellular organelles segregate specifically to spermatids as they bud from an anuclear residual body. We have applied patch-clamp techniques in order to investigate membrane protein distribution during these asymmetric divisions. We show that membrane components, as assayed by voltage-dependent ion channel activity, follow a specific distribution pattern during sperm development. Several voltage-sensitive ion channel activities are observed in spermatocytes and residual bodies, but only a single-channel type can be detected in spermatids, indicating that other channel activities are excluded from or inactivated within these cells as they form. The channel that is observed in spermatids is an inward-rectifying chloride channel (Clir), as indicated by its sensitivity to chloride channel inhibitors and Cl-dependent shifts in its conductance. Treatment of spermatids with Cl channel blockers induce their differentiation into spermatozoa, suggesting that Clir plays a role during this developmental step. These studies are the first application of patch-clamp electrophysiology to C. elegans development.

Analyses of reproductive interactions that occur after heterospecific matings within the genus Caenorhabditis.

Formation of zygotes in internally fertilizing organisms requires a number of successful interactions between oocytes and sperm within a receptive female reproductive tract. These interactions are usually assumed to be species-specific. For most species, it is either not possible to inseminate females with sperm from a different species or not possible to observe the consequences of such an insemination because the female is opaque. Nematodes of the genus Caenorhabditis are optically transparent and prior work indicates copulation between individuals of two different species is possible. We have used a series of vital stains and other cytological methods to analyze sperm after cross-species mating. We present here a series of analyses of the postcopulatory, prefertilization interactions among three Caenorhabditis species and find that reproductive biology is conserved, to varying degrees, among all three species. This approach allows investigation into which in vivo interactions between sperm and both oocytes and the somatic gonad have been maintained during the reproductive isolation that accompanies speciation.

Chlamydomonas alpha-tubulin is posttranslationally modified by acetylation on the epsilon-amino group of a lysine.

Previous work has shown that the principal alpha-tubulin within Chlamydomonas reinhardtii flagellar axonemes differs from the major alpha-tubulin in the cell body. These two variants of alpha-tubulin are related to one another since posttranslational modification of the cell body form converts it to the axonemal form. When flagella are induced to assemble in the absence of de novo protein synthesis, tritiated acetate can be used to posttranslationally label alpha-tubulin in vivo, and under these conditions, no other flagellar polypeptides exhibit detectable labeling [L'Hernault, S. W., & Rosenbaum, J. L. (1983) J. Cell Biol. 97, 258-263]. In the present report, this labeling method has been used to provide material for chemical analysis of the tritiated moiety that is posttranslationally added to flagellar alpha-tubulin. This radioactivity was volatile after acid hydrolysis, suggesting that the posttranslational modification is the addition of neither an amino acid nor carbohydrate. Treatment of posttranslationally 3H-labeled alpha-tubulin with hydrazine yields radioactive acetylhydrazine, indicating that the moiety involved in posttranslational modification is an acetyl group. Analysis of complete proteolytic digests by thin-layer chromatography has revealed that this acetyl group is located on the epsilon-amino group of a flagellar alpha-tubulin lysine residue.

The mechanism of ran import into the nucleus by nuclear transport factor 2.

The small GTPase Ran is essential for virtually all nucleocytoplasmic transport events. It is hypothesized that Ran drives vectorial transport of macromolecules into and out of the nucleus via the establishment of a Ran gradient between the cytoplasm and nucleoplasm. Although Ran shuttles between the nucleus and cytoplasm, it is concentrated in the nucleus at steady state. We show that nuclear transport factor 2 (NTF2) is required to concentrate Ran in the nucleus in the budding yeast, Saccharomyces cerevisiae. To analyze the mechanism of Ran import into the nucleus by NTF2, we use mutants in a variety of nuclear transport factors along with biochemical analyses of NTF2 complexes. We find that Ran remains concentrated in the nucleus when importin-mediated protein import is disrupted and demonstrate that NTF2 does not form a stable complex with the transport receptor, importin-beta. Consistent with a critical role for NTF2 in establishing and maintaining the Ran gradient, we show that NTF2 is required for early embryogenesis in Caenorhabditis elegans. Our data distinguish between two possible mechanisms for Ran import by NTF2 and demonstrate that Ran import is independent from importin-beta-mediated protein import.

The presenilin protein family member SPE-4 localizes to an ER/Golgi derived organelle and is required for proper cytoplasmic partitioning during Caenorhabditis elegans spermatogenesis.

During Caenorhabditis elegans spermatogenesis, asymmetric partitioning of cellular components principally occurs via ER/Golgi-derived organelles, named fibrous body-membranous organelles. In C. elegans spe-4 mutants, morphogenesis of fibrous body-membranous organelle complexes is defective and spermatogenesis arrests at an unusual cellular stage with four haploid nuclei within a common cytoplasm. The spe-4 encoded integral membrane protein is a diverged member of the presenilin family implicated in early onset Alzheimer's disease. Specific antisera were used to show that SPE-4 resides within the fibrous body-membranous organelles membranes during wild-type spermatogenesis. Several spe-4 recessive mutants were examined for SPE-4 immunoreactivity and a deletion mutant lacks detectable SPE-4 while either of two missense mutants synthesize and localize immunoreactive SPE-4 within their fibrous body-membranous organelles. One of these missense mutations is located within a motif that is common to all presenilins. spe-4 mutants were also examined for other partitioning defects and tubulin was found to accumulate in unusual deposits close to the plasma membrane. These results suggest that wild-type SPE-4 is required for proper localization of macromolecules that are subject to asymmetric partitioning during spermatogenesis.