This study demonstrates that low oxygen (O2) levels induce the embryonic protein Nodal. This finding is significant, as low O2 levels characterize the microenvironments associated with both early development and tumor progression, and Nodal has been shown to promote tumorigenicity and to govern stem cell fate.
We utilized the transgenic adenocarcinoma mouse prostate (TRAMP) model to study the formation of abnormal mitosis in malignant tumors of the prostate. The results presented here are focused on centrosome and centriole abnormalities and the implications for abnormal cell divisions, genomic instability, and apoptosis. Centrosomes are microtubule organizing organelles which assemble bipolar spindles in normal cells but can organize mono-, tri-, and multipolar mitoses in tumor cells, as shown here with histology and electron microscopy in TRAMP neoplastic tissue. These abnormalities will cause unequal distribution of chromosomes and can initiate imbalanced cell cycles in which checkpoints for cell cycle control are lost. Neoplastic tissue of the TRAMP model is also characterized by numerous apoptotic cells. This may be the result of multipolar mitoses related to aberrant centrosome formations. Our results also reveal that centrosomes at the poles in mitotic cancer cells contain more than the regular perpendicular pair of centrioles which indicates abnormal distribution of centrioles during separation to the mitotic poles. Abnormalities in the centriole-centrosome complex are also seen during interphase where the complex is either closely associated with the nucleus or loosely dispersed in the cytoplasm. An increase in centriole numbers is observed during interphase, which may be the result of increased centriole duplication. Alternatively, these centrioles may be derived from basal bodies that have accumulated in the cell's cytoplasm, after the loss of cell borders. The supernumerary centrioles may participate in the formation of abnormal mitoses during cell division. These results demonstrate multiple abnormalities in the centrosome-centriole complex during prostate cancer that result in abnormal mitoses and may lead to increases in genomic instability and/or apoptosis.
The mitotic inhibitor, chloral hydrate, induces ciliary loss in the early embryo phase of Lytechinus pictus. It causes a breakdown of cilia at the junction of the cilium and the basal body known as the basal plate. This leaves the plasma membrane temporarily unsealed. The basal apparatus accessory structures, consisting of the basal body, basal foot, basal foot cap, striated side arm, and striated rootlet, are either misaligned or disintegrated by treatment with chloral hydrate. Furthermore, microtubules which are associated with the basal apparatus are disassembled. Mitochondria accumulate at the base of cilia - underneath the plasma membrane - and show alterations in their structural organization. The accumulation of mitochondria is observed in 40% of all electron micrograph sections while 60% show the areas mostly devoid of mitochondria. The microvilli surrounding a cilium and striated rootlet remain intact in the presence of chloral hydrate. These results suggest that deciliation in early sea urchin embryos by chloral hydrate is caused by combined effects on the ciliary membrane and on microtubules in the cilia. Furthermore, it is suggested that chloral hydrate can serve as a tool to explore the cytoskeletal mechanisms that are involved in cilia motility in the developing sea urchin embryo.
Calcium loss and muscle atrophy are two of the main metabolic changes experienced by astronauts and crew members during exposure to microgravity in space. Calcium and cytoskeletal events were investigated within sea urchin embryos which were cultured in space under both microgravity and 1 g conditions. Embryos were fixed at time-points ranging from 3 h to 8 days after fertilization. Investigative emphasis was placed upon: (1) sperm-induced calcium-dependent exocytosis and cortical granule secretion, (2) membrane fusion of cortical granule and plasma membranes; (3) microfilament polymerization and microvilli elongation; and (5) embryonic development into morula, blastula, gastrula, and pluteus stages. For embryos cultured under microgravity conditions, the processes of cortical granule discharge, fusion of cortical granule membranes with the plasma membrane, elongation of microvilli and elevation of the fertilization coat were reduced in comparison with embryos cultured at 1 g in space and under normal conditions on Earth. Also, 4% of all cells undergoing division in microgravity showed abnormalities in the centrosome-centriole complex. These abnormalities were not observed within the 1 g flight and ground control specimens, indicating that significant alterations in sea urchin development processes occur under microgravity conditions.
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