Glassin, a histidine-rich protein from the siliceous skeletal system of the marine sponge
            <i>Euplectella</i>
            , directs silica polycondensation

Shimizu, Katsuhiko; Amano, Taro; Bari, Md. Rezaul; Weaver, James C.; Arima, Jiro; Mori, Nobuhiro

doi:10.1073/pnas.1506968112

Cited by 64 publications

(59 citation statements)

References 37 publications

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“…We also rejected the proteins that lacked signal peptide as a silicifying protein must be secreted outside the silica cell membrane in order for silicification to take place in the paramural space. Proteins were further screened for the presence of internal repeat units as found in several silica precipitating proteins (Kröger et al ., 1999; Kauss et al ., 2003; Shimizu et al ., 2015), abundance of histidine, glutamic acid (Shimizu et al ., 2015), lysine (Kröger et al ., 1999; Kauss et al ., 2003) or serine, glycine-rich motifs, and frequency of proline-lysine and proline-glutamic acid residues (Harrison, 1996). Based on our selection criteria, we identified a protein in sorghum (Sb01g025970) that had seven repeat units rich in lysine, similar to silaffins from Cylindrotheca fusiformis , a diatom species (Kröger et al ., 1999); histidine-aspartic acid rich regions similar to glassin from a marine sponge, Euplectella (Shimizu et al ., 2015), and several proline residues as in a proline-rich protein (PRP1) from cucumber (Kauss et al ., 2003).…”

Section: Resultsmentioning

confidence: 99%

“…Silicification is widespread among living beings from unicellular microbes to highly evolved multicellular organisms (Perry, 2003). Several bio-silica associated proteins have been reported, for example, silaffins (Kröger et al ., 1999; Poulsen & Kröger, 2004), silacidins (Wenzl et al ., 2008) and silicanin-1 (Kotzsch et al ., 2017) from diatoms; and silicateins (Shimizu et al ., 1998) and glassin (Shimizu et al ., 2015) from sponges. Among plants, a short peptide derived from an inducible proline-rich protein precipitates silica in vitro .…”

Section: Introductionmentioning

confidence: 99%

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Siliplant1 (Slp1) protein precipitates silica in sorghum silica cells

Kumar

Adiram-Filiba²,

Blum

et al. 2019

Preprint

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28• Silicon is absorbed by plant roots as silicic acid. The acid moves with the transpiration 29 stream to the shoot, and mineralizes as silica. In grasses, leaf epidermal cells called 30 silica cells deposit silica in most of their volume by unknown mechanism. 31• Using bioinformatics tools, we identified a previously uncharacterized protein in 32 sorghum (Sorghum bicolor), which we named Siliplant1 (Slp1). Silica precipitation 33 activity in vitro, expression profile, and activity in precipitating biosilica in vivo were 34 characterized. 35• Slp1 is a basic protein with seven repeat units rich in proline, lysine, and glutamic acid. 36 A short peptide, repeating five times in the protein precipitated silica in vitro at a 37 biologically relevant silicic acid concentration. Raman and NMR spectroscopies 38 showed that the peptide attached the silica through lysine amine groups, forming a 39 mineral-peptide open structure. We found Slp1 expression in immature leaf and 40 inflorescence tissues. In the immature leaf active silicification zone, Slp1 was localized 41 to the cytoplasm or near cell boundaries of silica cells. It was packed in vesicles and 42 secreted to the paramural space. Transient overexpression of Slp1 in sorghum resulted 43 in ectopic silica deposition in all leaf epidermal cell types. 44 • Our results show that Slp1 precipitates silica in sorghum silica cells. 45 46 47

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Siliplant1 (Slp1) protein precipitates silica in sorghum silica cells

Kumar

Adiram-Filiba²,

Blum

et al. 2019

Preprint

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“…It should be noted that under this hypothesis, Si transport has ancient and deep origins and may be ancestral in eukaryotes; however, biosilicification is not. From molecular comparisons of silica polymerization mechanisms, it does appear that biosilicification has arisen independently in multiple different lineages (Sumper and Kroger 2004; Matsunaga et al 2007; Gong et al 2010; Shimizu et al 2015; Durak et al 2016). …”

Section: Discussionmentioning

confidence: 99%

The Evolution of Silicon Transport in Eukaryotes

et al. 2016

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Biosilicification (the formation of biological structures from silica) occurs in diverse eukaryotic lineages, plays a major role in global biogeochemical cycles, and has significant biotechnological applications. Silicon (Si) uptake is crucial for biosilicification, yet the evolutionary history of the transporters involved remains poorly known. Recent evidence suggests that the SIT family of Si transporters, initially identified in diatoms, may be widely distributed, with an extended family of related transporters (SIT-Ls) present in some nonsilicified organisms. Here, we identify SITs and SIT-Ls in a range of eukaryotes, including major silicified lineages (radiolarians and chrysophytes) and also bacterial SIT-Ls. Our evidence suggests that the symmetrical 10-transmembrane-domain SIT structure has independently evolved multiple times via duplication and fusion of 5-transmembrane-domain SIT-Ls. We also identify a second gene family, similar to the active Si transporter Lsi2, that is broadly distributed amongst siliceous and nonsiliceous eukaryotes. Our analyses resolve a distinct group of Lsi2-like genes, including plant and diatom Si-responsive genes, and sequences unique to siliceous sponges and choanoflagellates. The SIT/SIT-L and Lsi2 transporter families likely contribute to biosilicification in diverse lineages, indicating an ancient role for Si transport in eukaryotes. We propose that these Si transporters may have arisen initially to prevent Si toxicity in the high Si Precambrian oceans, with subsequent biologically induced reductions in Si concentrations of Phanerozoic seas leading to widespread losses of SIT, SIT-L, and Lsi2-like genes in diverse lineages. Thus, the origin and diversification of two independent Si transporter families both drove and were driven by ancient ocean Si levels.

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“…The accession number FR748156). Our attempt to isolate silicatein from the silica skeleton of the E. aspergillum and E. curvistellata was unsuccessful, but instead we discovered glassin as a protein directing acceleration of silica polycondensation (Shimizu et al 2015). Sequences encoding silicatein have not identified from the transcriptome analysis of Aphrocallistes vastus by Riesgo et al (2015).…”

Section: Introductionmentioning

confidence: 97%

Exploration of Genes Associated with Sponge Silicon Biomineralization in the Whole Genome Sequence of the Hexactinellid Euplectella curvistellata

et al. 2018

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Silicatein is the first protein isolated from the silicon biominerals and characterized as constituent of the axial filament in the silica spicules of the demosponge Tethya aurantia, by significant sequence similarity with cathepsin L, an animal lysosomal protease, and as a catalyst of silica polycondensation at neutral pH and room temperature. This protein was then identified in a wide range of the class Demospongiae and in some species of the class Hexactinellida. Our attempt to isolate silicatein from the silica skeleton of Euplectella was unsuccessful, but instead we discovered glassin, a protein directing acceleration of silica polycondensation and sharing no significant relationship with any proteins including silicatein. The present study aims to verify the existence of silicatein by exploring the whole genome DNA sequence database of E. curvistellata with the sequence similarity search. Although we identified the sequences of glassin, cathepsin L and chitin synthetase, an enzyme synthesizing chitin, which has already been found in the silicon biominer

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Glassin, a histidine-rich protein from the siliceous skeletal system of the marine sponge Euplectella , directs silica polycondensation

Cited by 64 publications

References 37 publications

Siliplant1 (Slp1) protein precipitates silica in sorghum silica cells

Siliplant1 (Slp1) protein precipitates silica in sorghum silica cells

The Evolution of Silicon Transport in Eukaryotes

Exploration of Genes Associated with Sponge Silicon Biomineralization in the Whole Genome Sequence of the Hexactinellid Euplectella curvistellata

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