ElrA and AUF1 differentially bind cyclin B2 mRNA.

In Xenopus embryos, maternal cyclins drive the first 12 cell divisions after which several cyclins are terminally degraded, including cyclin B2. Cyclin B2 disappearance is due to transcription-mediated mRNA deadenylation at the midblastula transition, when transcription initiates and the cell cycle lengthens. To further define the mechanism, we characterized proteins capable of binding cyclin B2 3'UTR.

Antisense knockdown of cyclin E does not affect the midblastula transition in Xenopus laevis embryos.

In Xenopus laevis embryos, cyclin E protein remains constitutively high throughout the first 12 cell cycles following fertilization until the onset of the midblastula transition (MBT) (after the 12(th) cell cycle) when it undergoes a dramatic reduction. The disappearance of cyclin E at the MBT occurs independently of active cell cycle progression, zygotic transcription, protein synthesis and the nuclear to cytoplasmic ratio. This has suggested that cyclin E is part of an autonomous maternal timer that regulates the onset of the MBT.

Purification, characterization and cloning of tensilin, the collagen-fibril binding and tissue-stiffening factor from Cucumaria frondosa dermis.

The inner dermis of the sea cucumber, Cucumaria frondosa, is a mutable collagenous tissue characterized by rapid and reversible changes in its mechanical properties regulated by one or more protein effectors that are released from neurosecretory cells. One such effector, tensilin, is a collagen-fibril binding protein, named for its ability to induce dermis stiffening. Tensilin was purified using an affinity column constructed from C.

Towards a fibrous composite with dynamically controlled stiffness: lessons from echinoderms.

Sea urchins and sea cucumbers, like other echinoderms, control the tensile properties of their connective tissues by regulating stress transfer between collagen fibrils. The collagen fibrils are spindle-shaped and up to 1 mm long with a constant aspect ratio of approx. 2000.

Collagen fibril aggregation-inhibitor from sea cucumber dermis.

Collagen fibrils from the dermis of the sea cucumber Cucumaria frondosa are aggregated in vitro by the dermal glycoprotein stiparin (Trotter et al., 1996). Under physiological ionic conditions stiparin appears to be both necessary and sufficient to cause fibrils to aggregate (Trotter et al.