Spindle checkpoint protein Bub1 is required for kinetochore localization of Mad1, Mad2, Bub3, and CENP-E, independently of its kinase activity.

The spindle checkpoint inhibits the metaphase to anaphase transition until all the chromosomes are properly attached to the mitotic spindle. We have isolated a Xenopus homologue of the spindle checkpoint component Bub1, and investigated its role in the spindle checkpoint in Xenopus egg extracts. Antibodies raised against Bub1 recognize a 150-kD phosphoprotein at both interphase and mitosis, but the molecular mass is reduced to 140 upon dephosphorylation in vitro. Bub1 is essential for the establishment and maintenance of the checkpoint and is localized to kinetochores, similar to the spindle checkpoint complex Mad1-Mad2. However, Bub1 differs from Mad1-Mad2 in that Bub1 remains on kinetochores that have attached to microtubules; the protein eventually dissociates from the kinetochore during anaphase. Immunodepletion of Bub1 abolishes the spindle checkpoint and the kinetochore binding of the checkpoint proteins Mad1, Mad2, Bub3, and CENP-E. Interestingly, reintroducing either wild-type or kinase-deficient Bub1 protein restores the checkpoint and the kinetochore localization of these proteins. Our studies demonstrate that Bub1 plays a central role in triggering the spindle checkpoint signal from the kinetochore, and that its kinase activity is not necessary for the spindle checkpoint in Xenopus egg extracts.

The adipokinetic cells in the corpus cardiacum of Locusta migratoria preferentially release young secretory granules.

The influence of flight activity on the release of secretory granules from the adipokinetic cells in the corpus cardiacum of Locusta migratoria was studied. Two labeling methods, an enzymatical and a radioactive one, were used to label young, newly synthesized secretory granules and so distinguish them from older, preexisting granules. Both methods demonstrated that the ratio between the numbers of labeled and unlabeled secretory granules was lower in flight-stimulated adipokinetic cells than in unstimulated cells. This ratio was lower in both the cell bodies and the cell processes of flight-stimulated cells. After flight there was no detectable change in the total number of secretory granules, which indicates that the synthesis of new secretory granules is not inhibited by flight activity. Rather, the tendency of flight-stimulated cells to have more trans-Golgi networks labeled with wheat-germ agglutinin-conjugated horseradish peroxidase suggests that the synthesis of new secretory granules was enhanced by flight. The results led to the conclusion that young secretory granules were preferentially released over older secretory granules.

Preferential release of newly synthesized, exportable neuropeptides by insect neuroendocrine cells and the effect of ageing of secretory granules.

The release of newly synthesized neuropeptides was studied in an in vitro system using the adipokinetic hormone (AKH)-producing cells of an insect (Locusta migratoria) as a model system. Tritiated phenylalanine incorporated into three hormonal neuropeptides, AKH I, II and III, was used to distinguish newly synthesized hormones from older, preexisting ones. After pulse-chase labeling experiments of varying duration, the secretion of AKHs by the AKH cells was stimulated. Both hormones released into the incubation medium after stimulation and non-released hormones extracted from the tissue were separated by reversed-phase high performance liquid chromatography. Their radioactivity was measured by scintillation counting of the column eluate. The ratio between the specific radioactivities of the released and the non-released neuropeptides was always greater than 1.0, which indicates that the newly synthesized peptides are preferentially released. The percentages of newly synthesized (radioactive) AKHs which are released, increased until 8 1/4 h and decreased thereafter. The results indicate that after the packaging of the prohormones into secretory granules and their processing to bioactive AKHs, some further maturation of the secretory granules is required before they can release their content. After an 8 1/4 h incubation, secretory granules with radioactive AHKs enter a non-releasable pool consisting of older secretory granules.

Cell type-specific sorting of neuropeptides: a mechanism to modulate peptide composition of large dense-core vesicles.

The CNS of Lymnaea stagnalis contains two populations of egg-laying hormone (ELH)-producing neurons that differ in size and topology. In type I neurons, all peptides located C-terminally from the cleavage site Arg-Ser-Arg-Arg180-183 are sorted into secretory large dense-core vesicles (LDCV), whereas N-terminal-located peptides accumulate in a distinct type of vesicle, the large electrondense granule (LEG). Via immunoelectron microscopy, we now show that the second population of ELH-producing neurons, type II neurons, lack LEG and incorporate all proELH-derived peptides into LDCV. This finding provides the first example of a cell type-specific sorting of neuropeptides into LDCV. Furthermore, we provide evidence that LEG are formed through a differential condensation process in the trans-Golgi network and that these bodies are ultimately degraded. Analysis of the endoprotease composition of the two types of proELH-producing neurons suggests that the formation of LEG, and consequently the retention of N-terminal peptides from the secretory pathway, requires the action of a furin-like protein.

Family of prohormone convertases in Lymnaea: characterization of two alternatively spliced furin-like transcripts and cell-specific regulation of their expression.

The majority of neuropeptides in Lymnaea stagnalis are proteolytically processed from larger precursors at sites composed of single or multiple basic amino acid residues. Previous studies have identified several putative prohormone convertases in the brain of Lymnaea. To characterize the complete family, we undertook three independent approaches: reverse-transcribed polymerase chain reaction screening, and low-stringency cDNA and genomic library screenings. The central nervous system cDNA library screening yielded two cDNAs encoding Lfurin1 and its variant form, Lfurin1-X. Both proteins show the characteristic organization of (human) furin with a putative catalytic domain, a P domain, a Cys-rich domain, a transmembrane domain, and a cytoplasmic tail. Lfurin1 and Lfurin1-X are identical, apart from a putative alternatively spliced noncatalytic luminal protein domain, which is present exclusively in Lfurin1-X. In situ hybridization revealed that the Lfur1 gene is expressed throughout the Lymnaea brain, but that the level varies considerably from one neuron to another. Quantitative analysis of the expression level of the two alternatively spliced transcripts revealed that it is neuron type-specifically regulated. This probably indicates the functional importance of noncatalytic luminal protein domains in these enzymes. In addition, our findings suggest that apart from the identified convertases LPC2, Lfurin1/Lfurin1-X, and Lfurin2, additional prohormone convertase diversity is either not present or present only at low levels in the Lymnaea brain. Alternatively, additional prohormone convertases could exist with a lower degree of sequence conservation than the other Lymnaea prohormone convertase members. From our findings, it appears that the majority of prohormone processing in Lymnaea is carried out by the three thus far identified types of Kex2-related prohormone convertases despite the large number of neuropeptide precursors and diverse multiple basic cleavage sites hydrolyzed.