The hexactinellids are a diverse group of predominantly deep sea sponges that synthesize elaborate fibrous skeletal systems of amorphous hydrated silica. As a representative example, members of the genus Euplectella have proved to be useful model systems for investigating structure-function relationships in these hierarchically ordered siliceous network-like composites. Despite recent advances in understanding the mechanistic origins of damage tolerance in these complex skeletal systems, the details of their synthesis have remained largely unexplored. Here, we describe a previously unidentified protein, named "glassin," the main constituent in the water-soluble fraction of the demineralized skeletal elements of Euplectella. When combined with silicic acid solutions, glassin rapidly accelerates silica polycondensation over a pH range of 6-8. Glassin is characterized by high histidine content, and cDNA sequence analysis reveals that glassin shares no significant similarity with any other known proteins. The deduced amino acid sequence reveals that glassin consists of two similar histidine-rich domains and a connecting domain. Each of the histidine-rich domains is composed of three segments: an amino-terminal histidine and aspartic acid-rich sequence, a proline-rich sequence in the middle, and a histidine and threonine-rich sequence at the carboxyl terminus. Histidine always forms HX or HHX repeats, in which most of X positions are occupied by glycine, aspartic acid, or threonine. Recombinant glassin reproduces the silica precipitation activity observed in the native proteins. The highly modular composition of glassin, composed of imidazole, acidic, and hydroxyl residues, favors silica polycondensation and provides insights into the molecular mechanisms of skeletal formation in hexactinellid sponges.T he hexactinellids are a circumglobal group of predominantly deep sea sponges. Exhibiting a diverse array of morphologies, the skeletal systems of hexactinellids, which are composed of amorphous hydrated silica (the other silica-forming sponge class is the Demospongiae), range in structural complexity from loose aggregations of individual skeletal elements (spicules) to complex, hierarchically ordered lattices. Hexactinellids have evolved the ability to colonize either rocky substrates or soft sediments and exhibit remarkable skeletal modifications to accomplish these feats (1). For example, the sediment-dwelling hexactinellids produce bundles of long fibrillar anchor spicules that form robust holdfast structures. These anchor spicules exhibit surprising flexibility and damage tolerance and have served as useful model systems for investigating high performance silica-based organic-inorganic biological composites (2-4). In one representative genus, Euplectella (Fig. 1), the constituent spicules are assembled into a highly regular cylindrical lattice that exhibits multiple levels of structural hierarchy spanning from the nanoscale to the macroscale. The lattice is composed of two interpenetrating grid-like networks of no...
The gene encoding 4-N-trimethylaminobutyraldehyde dehydrogenase (TMABaldehyde-DH) from Pseudomonas sp. 13CM, responsible for the conversion of 4-N-trimethylaminobutyraldehyde (TMABaldehyde) to γ-butyrobetaine in the carnitine biosynthesis pathway, isolated by shotgun cloning and expressed in Escherichia coli DH5α. The recombinant TMABaldehyde-DH was purified 19.5 fold to apparent homogeneity by hydrophobic and affinity chromatography and biochemically characterized. The enzyme was found to be a trimer with identical 52 kDa subunits. The isoelectric point was found to be 4.5. Optimum pH and temperature were found respectively as pH 9.5 and 40 °C. The Km values for TMABaldehyde, 4-dimethylaminobutyraldehyde, and NAD+ were respectively, 0.31, 0.62, and 1.16 mM. The molecular and catalytic properties differed from those of TMABaldehyde-DH I, which was discovered initially in Pseudomonas sp. 13CM. The new enzyme, designated TMABaldehyde-DH II, structural gene was inserted into an expression vector pET24b (+) and over-expressed in E. coli BL21 (DE3) under the control of a T7 promoter. The recombinant TMABaldehyde-DH from Pseudomonas sp. 13CM can now be obtained in large quantity necessary for further biochemical characterization and applications.
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