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A Mesoporous Pattern Created by Nature in Spicules from Thetya aurantium Sponge

Gianluca Croce ^*, Davide Viterbo ^*, Marco Milanesio ^* and Heinz Amenitsch 

^* DISTA, Università del Piemonte Orientale, Alessandria, Italy; and Institute of Biophysics and Nanosystems Research (IBN), Austrian Academy of Sciences c/o Sincrotrone Trieste, Basovizza (TS), Italy

Correspondence: Address reprint requests to Gianluca Croce, E-mail: gianluca.croce{at}mfn.unipmn.it.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

 
Siliceous or carbonate spicules provide support and defense to marine sponges. The inorganic envelope usually embodies a protein core. Our SAXS study of the siliceous spicules from the demosponge Thetya aurantium proves the very ordered structure assumed by the protein core inside the spicules. Indeed, not only the very sharp diffraction spots already found in previous studies on spicules from different sponges are confirmed, but also the 11 sharp spots in the diffraction pattern recorded after thermal treatment at 250°C can only be interpreted in terms of a natural nanocomposite mesostructure with an hexagonal lattice formed by a three-dimensional periodic arrangement of silica cages in which the protein units act as structure directing agent.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

 
Sponges are primitive marine animals and consist of organized cells supported by a skeleton of inorganic fibers known as spicules. Spicules are usually composed of calcium carbonate or of silica, and their secretion is due to specialized cells called sclerocytes (1). The two most important functions of the spicules are to provide support for the soft part of the sponges and to play a defense role. Their inorganic envelope generally contains an organic proteic axial filament (2). Proteins from siliceous spicules are called silicateins (3) (for SILICA proTEINS) and the biological formation of amorphous hydrated silica, called biosilicification, probably occurs under the control of these specialized biomolecules (4). The organic matrix is thus suggested to play a critical role in the catalysis of silica polycondensation reactions and in the structure organization (5).

Spicules may show very different and complex shapes and the molecular mechanisms leading to their formation is still rather unclear. Some of them contain an organic axial filament around which hydrated silica is deposited. The concentric arrangement of the silica is the result of a periodic secretion. Siliceous spicules are formed at the intracellular level by the deposition of hydrated silica around the protein filament. This filament, although present immediately before silicification, continues to grow during silica deposition. It is generally assumed that spicule growth is a bidirectional process: the increase in length is affected by the elongation of the filament, whereas the increase in width is determined by the apposition of the silica.

In recent years, we have carried out an extensive structural study on a number of siliceous spicules from sponges belonging to different families (6,7) using a wide variety of experimental and theoretical approaches. The most important results of these studies on the structural organization of the silicatein filament inside the spicules are: i), the very high degree of periodic regularity indicated by the very sharp diffraction spots obtained by our diffraction experiments; ii), the different arrangement and packing of the protein units in spicules from sponges of two different phylogenetic classes: in the demosponge Thetya aurantium or Geodia cydonium, a fairly dense hexagonal packing of parallel tubular protein units separated by 5.8 nm can be postulated, whereas in the hexactinellid Scolymastra joubini, a less dense hexagonal packing of spirally oriented cylindrical protein units separated by 8.4 nm is consistent with our diffraction data (6).

In this study we have concentrated our attention on siliceous spicules extracted from Tethya aurantium sponges belonging to the demosponge family, because of their rich small angle x-ray diffraction pattern (6). These spicules have an elongated shape with one sharp and one rounded tip (strogyloxeas) (8) and a length of 2–2.5 mm and a section of 15–20 µm. In previous works, we revealed the presence of bioorganic matter in the central cavities inside the inorganic envelope by electron microscopy on grinded samples and by thermogravimetric measurements (6,7). These cavities are the sites where the silicatein proteins, responsible for the spicule growth, are hosted (9). Extraction of the bioorganic matter from the silica envelope can only be performed by a rather strong treatment with HF/NH₄F solutions, which may cause relevant structural changes. To obtain some structural information on the untreated organic filaments as they are inside the spicules and to achieve a more realistic and detailed picture of their organization, small angle x-ray diffraction measurements were carried out at the SAXS beamline of the ELETTRA synchrotron radiation facility.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

 
Megasclere spicules extracted from T. aurantium sponges, collected in the coastal lagoon of Porto Cesareo (Apulian Coast), are freed from the external organic matter by immersion in hydrogen peroxide (200 vol) changed each day for two weeks. They are then rinsed in distilled water and dried at 60°C.

Diffraction experiments on these megascleres were carried out by the Austrian SAXS beamline (BL 5.2 L) (10) of the ELETTRA Synchrotron Light Laboratory (Trieste, Italy), using x-rays of wavelength = 0.1540 nm and SAXS data were collected with a two-dimensional charge-coupled device-detector (diameter 115 mm; Photonic Science, Robertsbridge, UK), positioned at 872.4 mm from the sample. For the T. aurantium spicules, the samples were still bundles of 10–15 almost parallel spicules inside a boron glass capillary, to increase the diffraction signals. Single spicules of T. aurantium were also mounted on a sample holder to perform single-fiber diffraction experiments while rotating the sample by 180°. High temperature measurements were carried out using tight bundles of parallel spicules to avoid possible disorientation of the sample caused by heating. For the in situ experiments a temperature gradient cell for x-ray scattering measurements was used. The samples were heated up to 250°C with a ramp of 1°C/min and the diffraction data were collected every 5°C after an isotherm of 5 min. The ex situ experiments were carried out heating different spicule bundles in a lab oven, where the samples were kept isothermally at 50°C, 100°C, 150°C, 200°C, and 250°C for 1 h and cooled for 30 min before the diffraction data collection. A bundle of spicules was also maintained at 250°C for 72 h and cooled for 24 h before the measurements.

In all experiments, the elongation axis of the spicule was along the horizontal x axis of the patterns. Therefore the spots along the central vertical line (y axis) are the equatorial spots, whereas the polar spots are along the horizontal x axis. The two-dimensional data were processed using the FIT2D program (11,12). Before the analysis of the SAXS data, the collected images were corrected with FIT2D for the following factors: normalization of the intensity, spatial distortion and subtraction of the instrumental errors (background noise and dark current).

	RESULTS AND DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

 
Diffraction patterns were collected from still samples composed by bundles of almost parallel spicules and from single spicules mounted on a rotating holder, as described in the Materials and Methods section. The T. aurantium bundles were also heated from room temperature to 250°C, to shed some light on the structural rearrangements accompanying the thermal decomposition of the organic material.

The diffraction pattern from a still bundle, collected at room temperature (Fig. 1 a) reveals three very sharp independent diffraction spots. The most intense spot is in the vertical (equatorial) position, whereas the other two are in nonequatorial positions. The former spot has an estimated value of d-spacing of 5.0 nm typical of spicules belonging to the demosponge family (6,7). The most striking feature of our results is the appearance of "single crystal like" diffraction spots, which are much too sharp to be ascribed to the usually rather broad diffraction effects by fibers and indicate a high degree of structural order and periodicity. Indeed, the reciprocal space image of a bundle of parallel columns with a randomly oriented periodic lattice is a set of circles and the observed diffraction spots appear at the intersections of these circles with the Ewald sphere. The high degree of structural order is confirmed by the rotation patterns from a single spicule. Indeed the sequence of patterns recorded every 1° of rotation shows the same sharp spots and arrangement found in Fig. 1 a, revealing the presence of a three-dimensional structural order. From just these three independent spots it is impossible to derive a model of the structural organization inside T. aurantium spicules.

View larger version (47K): [in this window] [in a new window]   FIGURE 1  Diffraction patterns of a bundle of T. aurantium spicules. Patterns collected (a) at room temperature and (b) at 250°C are shown.

Let us have a closer look at the relevant changes on the SAXS pattern caused by the thermal treatments on the T. aurantium spicules. The integration along the (10l) reciprocal lattice direction of the three spots common to all the patterns taken at different temperatures is shown in Fig. 2 a. These spots not only persist at all temperatures, but slightly increase in intensity and also show a small but significant change in position with a shift toward higher 2 values at higher temperatures and in Table 1 the corresponding decrease in the d-spacings is reported. The radial integration along the (00l) polar axis of all the patterns is shown in Fig. 2 b, where the appearance at higher temperatures of three new peaks at 2 = 0.8°, 1.6°, and 2.4° (d-spacings of 11.4, 5.6, and 3.7 nm) can be observed.

View larger version (11K): [in this window] [in a new window]   FIGURE 2  One-dimensional plots during heating from 25 to 250°C. The trend of (a) the one-dimensional linear integration along the (10l) reciprocal lattice and (b) of the spots along the (00l) polar axis, are shown.

View this table: [in this window] [in a new window]   TABLE 1  Bragg d-spacings for the three common diffraction spots typical of T. aurantium megasleres at 25°C and 250°C and corresponding shifts (d)

In the diffraction pattern of T. aurantium taken at 250°C 11 sharp spots are present and their d-spacings are listed in the fourth column of Table 2. Their positions are consistent with a hexagonal lattice with approximate unit cell parameters a = b = 5.9 nm, c = 11.4 nm, in which all the 11 spots can be indexed as shown in the first three columns of Table 2. After a least-square refinement based on all reflexions, the cell parameters become a = b = 5.8 nm, c = 11.2 nm and the values of the calculated spacings d_cal and the differences d = d_cal – d_obs are reported in the last two columns of Table 2.

The features of our diffraction patterns must only be indirectly related to the arrangement of the protein units, and strongly support our hypothesis that they are instead due to the presence of an ordered mesoporous siliceous system (21–24) inside the spicules, where the proteins act as templates. Indeed, the increased order observed at 250°C can actually be the consequence of two concurring effects: i), the unfolding and/or decomposition of the protein units inside the spicules causing and increase of the electron density contrast between the siliceous framework and the organic template, causing an increase of the diffraction intensities; and ii), a possible reorganization of the siliceous ordered pattern as a consequence of the condensation of free silanol groups, with an increase of the structural order and the consequent increase in the sharpness of the diffraction spots. These two effects are illustrated in the sketches of Fig. 3.

View larger version (31K): [in this window] [in a new window]   FIGURE 3  Models of the mesoporous arrangements at 25°C and at 250°C. The two sketches show our hypothesis on the ordering evolution of the mesostructure. The small circles, forming a hexagonal pattern, represent the amorphous silica walls and the ribbons schematise the templating protein units.

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

 
The relative dimensions of the thick and hard silica walls and the small central cavity, where the mesostructure with silicatein is located, make sample preparation for electron or scanning microscopy very difficult. So far all our attempts at cutting the samples have completely destroyed the structure. The small angle x-ray diffraction study of siliceous spicules proved to be a very valuable tool to elucidate the organization and disposition of the organic matter inside the amorphous silica envelope. T. aurantium strogyloxeas were chosen for this study because their diffraction patterns, especially after thermal treatment, are the richest in diffraction spots. Indeed the appearance of 11 spots in the pattern, recorded after treatment at 250°C, allowed to define unambiguously the presence of a hexagonal lattice and to derive the Miller indices of all the observed spots.

This work triggered us to deepen our study on the structure of spicules and to investigate the quaternary and tertiary structure of silicatein embedded in the mesoporous matrix. As described above, the silicatein protein cannot be extracted from the spicules without strong chemical treatments. Besides, the extracted silicatein appears as a fibrous protein, insoluble in aqueous solvents. These two problems represent an insurmountable obstacle to the study of its three-dimensional structure by NMR or x-ray crystallography. Exploiting the sequence similarity with cathepsin, we then employed the homology modeling method to build a plausible theoretical model of the three-dimensional structure of silicatein (Gianluca Croce, Davide Viterbo, Marco Giovine, and Marco Milanesio, unpublished). From this model we could estimate the volume occupied by a silicatein molecule as 196 nm³. Therefore each hexagonal cell with volume 282.6 nm³, obtained from the SAXS data, should contain only one protein molecule. Therefore the templating protein units in each cage are formed by one silicatein molecule possibly surrounded by biological fluid.

The most important outcome of this study of the T. aurantium megascleres is the very stringent proof of our hypothesis that nature has organized the organic matter in a single crystal-like hexagonal mesoporous material that can be considered one of the best grown nanostructured composite material so far synthesized or naturally formed.

Submitted on August 3, 2006; accepted for publication September 8, 2006.

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This Article Abstract Full Text (PDF) All Versions of this Article: biophysj.106.094532v1 92/1/288    most recent Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Croce, G. Articles by Amenitsch, H. Search for Related Content PubMed PubMed Citation Articles by Croce, G. Articles by Amenitsch, H.