Sea urchin larvae have an endoskeleton consisting of two calcitic spicules. We reconstructed various stages of the formation pathway of calcium carbonate from calcium ions in sea water to mineral deposition and integration into the forming spicules. Monitoring calcium uptake with the fluorescent dye calcein shows that calcium ions first penetrate the embryo and later are deposited intracellularly. Surprisingly, calcium carbonate deposits are distributed widely all over the embryo, including in the primary mesenchyme cells and in the surface epithelial cells. Using cryo-SEM, we show that the intracellular calcium carbonate deposits are contained in vesicles of diameter 0.5-1.5 μm. Using the newly developed airSEM, which allows direct correlation between fluorescence and energy dispersive spectroscopy, we confirmed the presence of solid calcium carbonate in the vesicles. This mineral phase appears as aggregates of 20-30-nm nanospheres, consistent with amorphous calcium carbonate. The aggregates finally are introduced into the spicule compartment, where they integrate into the growing spicule.biomineralization | mineralization pathway | sea urchin embryonic spicule | transient precursor mineral phase | intracellular mineral deposition
We investigated the manner in which the sea urchin larva takes up calcium from its body cavity into the primary mesenchymal cells (PMCs) that are responsible for spicule formation. We used the membrane-impermeable fluorescent dye calcein and alexa-dextran, with or without a calcium channel inhibitor, and imaged the larvae in vivo with selective-plane illumination microscopy. Both fluorescent molecules are taken up from the body cavity into the PMCs and ectoderm cells, where the two labels are predominantly colocalized in particles, whereas the calcium-binding calcein label is mainly excluded from the endoderm and is concentrated in the spicules. The presence of vesicles and vacuoles inside the PMCs that have openings through the plasma membrane directly to the body cavity was documented using high-resolution cryo-focused ion beam-SEM serial imaging. Some of the vesicles and vacuoles are interconnected to form large networks. We suggest that these vacuolar networks are involved in direct sea water uptake. We conclude that the calcium pathway from the body cavity into cells involves nonspecific endocytosis of sea water with its calcium.
Bone remodeling relies on the coordinated
functioning of osteoblasts,
bone-forming cells, and osteoclasts, bone-resorbing cells. The effects
of specific chemical and physical bone features on the osteoclast
adhesive apparatus, the sealing zone ring, and their relation to resorption
functionality are still not well-understood. We designed and implemented
a correlative imaging method that enables monitoring of the same area
of bone surface by time-lapse light microscopy, electron microscopy,
and atomic force microscopy before, during, and after exposure to
osteoclasts. We show that sealing zone rings preferentially develop
around surface protrusions, with lateral dimensions of several micrometers,
and ∼1 μm height. Direct overlay of sealing zone rings
onto resorption pits on the bone surface shows that the rings adapt
to pit morphology. The correlative procedure presented here is noninvasive
and performed under ambient conditions, without the need for sample
labeling. It can potentially be applied to study various aspects of
cell-matrix interactions.
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