Kahil K , Weiner S , Addadi L , Gal A .

	Figure 1. Formation of coccoliths. (A,B) SEM images of Coccolithus braarudii coccoliths. The diploid life stage forms intricate crystal morphologies (A), while the haploid stage forms simple rhombohedral crystals (B). (C–F) Cellular anatomy of Pleurochrysis carterae. (C, D) Sections in fixed cells show in (C) the various cell organelles (Chl., chloroplast; Nu., nucleus; magenta arrowheads indicate coccolith vesicles), and a high magnification image shows in (D) a coccolith vesicle (blue arrowheads indicate the crystals, yellow arrowhead indicates the organic base plate). Reprinted with permission from ref (22). Copyright 2020 Elsevier. (E) 3D rendering of a cryo-fixed cell. The inset shows the vacuole (light brown) filled with Ca–P-rich bodies (red) and coccoliths (blue). (F) 3D rendering of a live cell using confocal microscopy, showing several dense intracellular pools stained with DAPI (red); chloroplasts are in green. Reprinted with permission from ref (18). Copyright 2021 Wiley-VCH GmbH.
	Figure 2. Mineral deposition process in sea urchin larvae. (A) Light micrographs of a live larva of the sea urchin Paracentrotus lividus taken 41 h after fertilization (hpf) (top image); image at the bottom: the same larva observed under polarized light, showing the crystalline nature of the spicules. (B) SEM micrograph of an isolated spicule from Litechinus pictus larva. The spicule is pseudocolored yellow to facilitate observation. (C) Confocal fluorescence image of a 46hpf larva developed continuously in calcein-labeled seawater. Note that the spicule (S) is fully labeled. Many intracellular vesicles are also fluorescent, indicating uptake by endocytosis of seawater. (D) Cryo-FIB-SEM micrograph of a high-pressure frozen 40hpf larva. The cyan vesicle is open toward the body cavity (blastocoel), which is filled with a seawater-like solution. BF, blastocoel fluid; CM, cell membrane; N, nucleus. (E) Segmentation of cryo-FIB-SEM serial milling and block face imaging stack acquired from 40hpf high-pressure frozen larva. The segmentation shows the syncytium enveloping the spicule. A vesicle (green arrow) is depositing onto the growing spicule. Reprinted and modified with permission from (41). Copyright 2016 Elsevier. (F) Segmentation of cryo-soft X-ray tomography of a PMC taken from 36hpf larva. The colored particles are Ca-rich particles. Cytoplasm and other cellular vesicles and organelles are gray.
	Figure 3. (A) SEM image of fractured baboon tibia after removal of the organic matrix using sodium hypochlorite. Note the plate-shaped crystals organized in layers. (B) TEM image of an isolated mineralized collagen fibril extracted mechanically from turkey tendon. The banding is due to the presence of more plate-shaped crystals in the gap region of the collagen fibril as compared to the overlap region. (C) Cryo-SEM image of the fracture surface of an embryonic chicken bone showing in green the distribution of mineral (based on the BSE image of the same area). Note the presence of vesicles containing mineral particles inside the cell (arrows).
	Figure 4. Schematic illustration showing the three common processes that make up ion pathways in the biomineralization of coccolithophores, sea urchin larvae, and vertebrate bone. These pathways involve ion uptake, cellular manipulation and deposition of the mature mineral phase. The Y-axis shows the approximate calcium concentration ranges in which these three processes operate. The solid lines indicate known processes and dotted lines indicate putative ones. Question marks highlight yet uncharacterized stages in the pathway. Note the enormous calcium concentration range for mineralizing cells. Irrespective of whether the mature mineral phase is a carbonate or phosphate mineral, the ion pathways all involve calcium, carbonate and phosphate as is schematically illustrated by the blend of colors for the different ions.

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