Soluble Organic Matrices of the Calcitic Prismatic Shell Layers of Two Pteriomorphid Bivalves

PINNA NOBILIS AND PINCTADA MARGARITIFERA*

Yannicke DauphinDagger

From the From Laboratoire de Paléontologie, FRE 2566, Université Paris XI-Orsay, F-91405 Orsay, France

Received for publication, May 6, 2002, and in revised form, February 7, 2003

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

The calcitic prisms of the shells of two bivalves, Pinna and Pinctada, are considered simple prisms according to some morphological and mineralogical characteristics. Scanning electron microscopic and atomic force microscopic studies show that the microstructures and nanostructures of these two shells are different. Pinna prisms are monocrystalline, whereas Pinctada prisms are not. Moreover, intraprismatic membranes are present only in the Pinctada prisms. The soluble organic matrices extracted from these prisms are acidic, but their bulk compositions differ. Ultraviolet and infrared spectrometries, fluorescence, high pressure liquid chromatography, and electrophoresis show that the sugar-protein ratios and the molecular weights are different. Sulfur is mainly associated with acidic sulfated sugars, not with amino acids, and the role of acidic sulfated sugars is still underestimated. Thus, the simple prism concept is not a relevant model for the biomineralization processes in the calcitic prismatic layer of mollusk shells.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

Among more than 60 known different biominerals, calcium minerals are the most abundant. These exoskeletons (also called hard tissues or shells) have morphological, chemical, and physical properties that are never shown by the corresponding abiotic crystals. They are biocomposites (bioceramics), and organic macromolecules are their key components. Much of what is known about biominerals is deduced from the nacreous layers of mollusks, and it is believed that the organic matrix serves as a guide for crystal growth (1, 2). All of the SOM1 extracted from mollusk shells are highly acidic as shown by their amino acid contents or by ion exchange chromatography (3-5). Unfortunately, it is often said that a mollusk shell consists of an outer calcitic and an inner aragonitic layer (nacre), although this structure is rare. In fact, these shells exhibit various microstructural types, the arrangement of which strongly depends on the taxa. Currently, little data are available on the organic matrices extracted from mollusk shells.

Pinna nobilis and Pinctada margaritifera are two modern pteriomorphid bivalves with shells composed of an outer calcitic prismatic layer and an inner aragonitic nacreous layer. Their calcitic prisms offer remarkable advantages to investigate the organization of biocrystals. For example, they are large units that globally exhibit a single crystal-like organization. These prisms are built by a series of growth steps and surrounded by thick organic walls (6-10). According to Taylor et al. (11) the outer layers of Pinna and Pinctada are composed of calcitic "simple prisms." Their crystallographic c axes are normal to the layer surfaces. Illustrations of a transverse section of the prisms of Pinctada by Wise (12) are similar to those of Taylor et al. (11) and follow the simple prism concept. These calcitic layers have high S and magnesium contents (13-16). Amino acid studies of the soluble intraprismatic matrices of both genera have shown high contents of aspartic acid, glycine, alanine, and glutamic acid (17, 18). However, repeated observations have shown some differences between the two shells. In Pinctada martensi, thin sections observed in polarized light show that each prism extinguishes in several smaller blocks (8, 19). Wada (9) observed uniaxial crystals and partial irregular extinctions in horizontal sections under crossed nicols. The individual prism of Pinna exhibits a monocrystalline extinction (20, 21).

Dissolution of the crystal units releases various macromolecules into solution, and it is well known that organic components are key participants in the control processes of shape and structure in mineralized tissues (2, 3, 17, 22). Only some proteins have been isolated from the aragonitic nacreous layers of Pinctada (23) since the first evidence of the presence of organic matrices (24). Thus, before the cloning of "pure" proteins of mollusk shell layers, a better knowledge of the bulk composition of their SOM is necessary as a first step in understanding the mechanisms of layer formation. From preliminary studies of the molecular weights of the SOM extracted from the prisms, Pinna and Pinctada are different (15, 25, 26). While pursuing a long term study of calcified biominerals, the present study was undertaken to extract and compare the SOM of the calcitic prisms of Pinna and Pinctada and to relate these SOM to the simple prism concept. Unlike many studies, this work is not focused on only the protein content. The location of the organic matrices and the presence of sugars are also considered.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

Materials-- Specimens of P. margaritifera (L.) (Pteriomorpha, Pterioida, Pteriacea, Pteriidae) were collected in French Polynesia. P. nobilis L. (Pteriomorpha, Mytiloida, Pinnacea, Pinnidae) samples came from the Mediterranean Sea.

Standards-- Isoelectric focusing calibration kit (pH 2.5-6.5) was from Amersham Biosciences. Low range SDS-PAGE standards (19-107 kDa), kaleidoscope-prestained standards (6.9-202 kDa), and gel filtration standards were from Bio-Rad. Chondroitin sulfate A was purchased from Sigma. Rapid Decalcifier was from Apex Engineering Products Corporation. BSA was from Eurobio, and chymotrypsin was from Merck.

Scanning Electron Microscopy (SEM)-Atomic Force Microscope (AFM)-- The traditional method for obtaining information about the shell microstructures is scanning electron microscopy. Fractures and polished etched sections have been observed with Philips 505 and XL30 SEM. Acidic and enzymatic etchings were used to reveal the details of the microstructures of the polished sections. Samples were also studied using a Nanoscope IIIa (Digital Veeco) multi-mode scanning probe microscope operating in tapping mode. The tapping mode AFM utilizes an oscillating tip at a tip amplitude of approximately several tens of nanometers when the tip is not in contact with the surface. Because the tip is no longer in permanent contact with the sample surface during the scanning motion, sample alteration can be avoided. The resolution of tapping mode AFM is on the order of a few nanometers. Details of the etchings for SEM and AFM observations are given in the figure legends.

Extraction and Purification of the Soluble Organic Matrix-- Samples were immersed in 3% NaClO for 1 h to remove organic contaminants, rinsed with Milli-Q water, dried, and ground into powder. Powdered samples were immersed in 5 ml of Milli-Q water and then decalcified by progressive addition of 50% acetic acid so that the pH (automatically controlled with a titrimeter) is above 4. The entire extract was directly centrifuged at 21,000 × g for 15 min, which separated the supernatant (soluble) and precipitated (insoluble) fractions. The soluble fraction was desalted by exchange with Milli-Q water on a Microconcentrator (Filtron) using a 3-kDa cut-off membrane and lyophilized.

Fluorescence-UV Spectrometry-- SOM were dissolved in Milli-Q water. Fluorescence spectra were recorded on a PerkinElmer LS40 fluorescence detector equipped with a Xenon lamp and a silica flow cell. Sample spectra were corrected for background to minimize residual fluorescence effects. UV spectra were recorded on a Shimadzu UV-1601 spectrophotometer equipped with deuterium and tungsten lamps and double beam optics. The monochromator slit aperture is fixed at 2 nm. Before a sample spectrum was run, a background spectrum was measured for Milli-Q water. All spectra were recorded from 250 to 350 nm.

Infrared Spectrometry-- All spectra were recorded at a 4-cm-1 resolution with 64 scans with a strong Norton-Beer apodization on a PerkinElmer Model 1600 Fourier transform infrared spectrometer in the wave number range of 4000-450 cm-1. The spectrometer was equipped with a diffuse reflectance accessory, which permits DRIFT measurements with high sensitivity on powders. All spectra were corrected by the Kubelka-Munk function, and the bands were identified by the software. The system was purged and permanently maintained under nitrogen to reduce atmospheric CO2 and H2O absorption. A background spectrum was measured for pure KBr. The ratio of the sample spectra was automatically determined against background to minimize CO2 and H2O bands. Several spectra from the same extracted SOM and from different SOM were done with correlation coefficients higher than 95%. Only minor differences attributed to humidity are sometimes present.

HPLC-- Chromatographic analyses were performed using two TSK G5000PW and G3000PW columns connected in series (200-1 × 106 Da). They were eluted with 0.2 mM Tris, pH 7.5, at a flow rate of 1 ml/min in high sensitivity refractive index detector PE 200 (PerkinElmer Life Sciences) and thermo separation products detector 4100 and monitored at 226, 254, and 278 nm. These two detectors were connected in series so that there is a difference in the elution times.

Other analyses were done using the same TSK columns connected in series, eluted with a dissociative buffer (4 M guanidinium chloride, pH 6, at a flow rate of 0.70 ml/min), and monitored at 275 nm. SOM were also chromatographed using a Superose 12 column (APB) with a separation range from 1 to 300 kDa and exclusion limit of 2000 kDa. The Superose 12 column was eluted with 4 M guanidinium chloride, pH 6, at a flow rate of 0.70 ml/min and monitored at 275 nm. The lyophilized SOM were dissolved in the buffer overnight, and all analyses were done at ambient temperature.

Isoelectric Focusing Electrophoresis (IEF)-- Isoelectric points were determined according to Dauphin and Cuif (16, 27). One-dimensional microslab isoelectric focusing was done on homogeneous polyacrylamide gels. With the Bio-Rad Model 111 Mini IEF cell, the gel was run without electrode buffers (non-denaturing dry IEF). The lyophilized SOM were redissolved in Milli-Q water. Focusing was carried out in a stepped fashion to prevent overheating.

Two staining procedures were used: 1) Coomassie Blue-Crocein Scarlet for proteins or weakly glycosylated proteins and 2) Acridine Orange for acidic sulfated sugars. For the Coomassie Blue method, gels were placed in 27% ethanol, 10% acetic acid, 0.04% Coomassie Blue R-250, 0.5% CuSO4, and 0.05% Crocein Scarlet for 1.5 h (fixing and staining solution). The first destaining solution contained 12% ethanol, 7% acetic acid, and 0.5% CuSO4. The second destaining solution contained 25% ethanol and 7% acetic acid. For the Acridine Orange method, gels were placed in a solution of methanol (40%) and acetic acid (10%) for 30 min (fixing solution). Acridine Orange was dissolved in Milli-Q water (20 mg of Acridine Orange in 95 ml of H2O and 5 ml of methanol). Gels were placed in the solution for 30 min and then destained with Milli-Q water.

Markers-- The low pI calibration kit (APB) with pH among 2.5 and 6.5, BSA, and ribonuclease were used. They were stained with Coomassie Blue R-250.

Two-dimensional Gel Electrophoresis-- The molecular groups were separated in the first dimension by isoelectric focusing in IPG strips (Precast Immobilin DryStrip, 11 cm, pH 3-10, APB) on a Multiphor II system. The lyophilized samples were dissolved in the sample buffer (8 M urea, 0.5% Triton X-100, 40 mM dithiothreitol, Pharmalyte 3-10, bromphenol blue) and centrifuged for 10 min at 17,500 × g. This solution was applied to the Immobilin strips in a horizontal reswelling cassette overnight. The settings used for IEF were 300 V for 6.5 h and 2000 V for 11 h. The Multitemp III cooling bath was set at 20 °C.

After the focusing was complete, the second step was done according to Dauphin (28). After electrophoresis, the gels were placed in 40% methanol with 10% acetic acid for 24 h to fix the proteins and to remove the SDS. Proteins and glycoproteins were detected by silver staining (Bio-Rad silver stain kit), and sulfated acidic mucopolysaccharides were stained with Alcian Blue. Silver staining was followed by Alcian Blue.

XANES-- The work was carried out at the European Synchrotron Radiation Facility. The ID21 Scanning x-ray Microscope uses Fresnel zone plates as focusing optics to generate a submicron x-ray probe, which is used to investigate the sample with various contrast mechanisms (fluorescence, transmission, and phase contrast). An energy-dispersive high purity Ge detector (Gamma-Tech, Princeton, NJ) mounted in the horizontal plane perpendicular to the beam collects the fluorescence emission photons. This geometry minimizes the contribution of elastic scattering. Provided the sample is thin enough, a Si photodiode can be mounted downstream from the sample to exploit the transmission signal as well. An energy range between 2 and 7 keV is available, which gives access to the K-edge of sulfur at 2472 eV. The energy scan is ensured by a fixed-exit double crystal Si111 monochromator located upstream from the microscope, which offers an energy resolution necessary to resolve XANES features. This experiment required operating the x-ray microscope under vacuum to avoid the strong absorption of the sulfur emission lines by air.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

Microstructure and Nanostructures

Untreated longitudinal fractures in the outer layer of P. no- bilis do not exhibit intraprismatic structures. Only long straight parallel prisms are visible (diameter 70 µm) (Fig. 1A). Rare and faint growth lines are sometimes seen on the outer surface of the prisms in such fractures. A polished and strongly etched transverse section shows the thick organic interprismatic walls and the polygonal shape of the prisms (Fig. 1B). Polished and etched longitudinal sections show the thick interprismatic walls and transverse synchronous growth lines across the adjacent prisms (Fig. 1C). Polished, fixed, and decalcified transverse sections show intraprismatic parallel crests (Fig. 1D). The interprismatic wall is somewhat etched by enzymatic hydrolysis, which supports its organic composition, and the intraprismatic parallel crests remain visible (Fig. 1E). Thin sections observed with cross-nicols show that each prism is a monocrystal with a unique extinction pattern (Fig. 1F). However, these prisms are not compact structures. They are composed of oblique and elongated crystallites (Fig. 1, G-H), the width of which varies from 150 to 180 nm. These crystallites are subdivided into smaller rounded units with distinct boundaries in height and phase images, suggesting that they are surrounded by organic envelopes (Fig. 1I).


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Fig. 1.   Microstructures and nanostructures of the calcitic prisms of P. nobilis. A, vertical fracture in the outer layer showing the long parallel regular prismatic units. No pattern is visible on the outer surface of the prisms. B, transverse polished, fixed, and etched section showing the thick organic walls (w) (6% glutaraldehyde, 1 h; Rapid Decalcifier, 30 min). C, vertical polished and etched section showing the thick interprismatic walls (w) and the regular growth lines. D, transverse polished, fixed, and etched section showing the interprismatic wall (w) and a pattern of parallel crests. Glutaraldehyde + formic acid + Alcian Blue solution. E, inner surface showing the same pattern of parallel crests and the walls (w) (pronase in Tris buffer, pH 8, at 30 °C for 3 h). F, thin section observed in transmitted light (cross-nicols) showing the walls (w) and the monocrystalline extinction of each prismatic unit. G, vertical polished and etched section showing the aligned acicular crystallites (AFM tapping mode; 2% glutaraldehyde, 0.1% formic acid, 10 s). H, detail of the same. I, tranverse polished and etched section of the prisms showing the small crystallites surrounded by an organic thin layer (AFM image phase; 2% glutaraldehyde, 0.1% formic acid, 10 s).

Similar unetched fractures of Pinctada show another pattern. The elongated prisms are not so straight (Fig. 2A). Their surfaces seem to be corrugated, and pieces of organic sheaths cut along the growth lines are preserved (Fig. 2B). The inner structures of the prisms seem homogeneous in transverse-untreated sections, and after complete removal of the mineral portion, only the outer thick organic walls are present. However, the polished and etched transverse sections are different from those of Pinna. Enzymatic hydrolyses reveal intraprismatic sinuous lacunae (Fig. 2C). The nonspecific enzymes used and the basic pH suggested that these lacunae are the remains of intraprismatic organic membranes. The orientations of crystallites on both sides of these intraprismatic membranes within a prism are not similar (Fig. 2D). These sinuous intraprismatic lacunae are also present in fixed and etched transverse sections (Fig. 2E). In such preparations, the interprismatic walls are partially destroyed. Transverse thin sections observed with cross-nicols confirm that the prisms are composite crystals (Fig. 2F). AFM observations show that the elongated crystallites are irregularly aligned (Fig. 2, G and H). Their width is ~110 nm, whereas their length varies from 250 to 400 nm. Round units at 50-70 nm in diameter are sometimes present. As with Pinna, the crystallites seem surrounded by a thin organic layer according to the phase images (Fig. 2I).


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Fig. 2.   Microstructures and nanostructures of the calcitic prisms of P. margaritifera. A, vertical fracture in the outer layer showing the long parallel irregular prismatic units. B, detail of the same showing pieces of the outer wall stripped off along the transverse growth lines. C, polished and etched prisms showing the differential behavior of the outer walls (w) and the sinuous intraprismatic organic membranes (arrows) destroyed by proteolysis (Alcalase, 25 h, 38 °C). D, detail of the same showing the change in crystallite orientation on both sides of an intraprismatic organic membrane seen as a lacuna after proteolysis (arrow). E, transverse polished, fixed, and etched section showing the partly destroyed interprismatic wall (w) and intraprismatic sinous lacunae (arrows). Glutaraldehyde + formic acid + Alcian Blue solution. F, thin section observed in transmitted light (cross-nicols) showing the walls (w) and the composite structure (arrows) of the prismatic units. G, tranverse polished and etched section showing the crystallites, the alignment of which is not regular (AFM scan field 5 mm; 2% glutaraldehyde, 0.1% formic acid, 10 s). H, detail of the same (image phase). I, detail of the same showing elongated crystallites.

The long polygonal calcitic prisms in both Pinna and Pinctada are surrounded by a thick organic wall and exhibit growth lines in longitudinal sections. However, prismatic units of Pinna are monocrystalline, whereas those of Pinctada are not, as shown by thin sections and complex preparative processes. The enzymatic hydrolyses were done at pH >7 so that the mineral part is not strongly etched and only a small dissolution can occur. Thus, the intraprismatic sinuous lacunae in Pinctada indicate the presence of sinuous organic membranes. Besides, there is a clear difference between these sinuous intraprismatic organic membranes and the outer walls. The sinuous intraprismatic organic membranes are destroyed by acid and enzymes, whereas the outer walls are not. The ultrastructure of Pinctada is then more complex than that of Pinna, which suggests that the intraprismatic organic matrix of Pinctada is also more complex. Hence, the simple prism concept appears not to be appropriate.

Bulk Composition

The emission scan of CS exhibits a small peak at 287 nm and a main peak at 353 nm for a 257-nm excitation. Peaks are at 290 and 342 nm for BSA (Fig. 3A). Only a small peak is visible at 287 nm in Pinctada and a shoulder is visible in Pinna. The emission scan of CS shows a shoulder at 310 nm and a main peak at 353 nm for a 275-nm excitation. A peak at 342 nm is visible in the BSA spectrum. A small peak at 303 nm is present in Pinna and Pinctada SOM (Fig. 3B). CS shows a peak at 353 nm for a 287-nm excitation, whereas that of BSA is at 342 nm. Only shoulders are present in Pinna and Pinctada spectra (Fig. 3C). From UV spectra, it appears that Pinna and Pinctada SOM are not pure proteins and that these proteins have a low content of aromatic amino acids (data not shown). From fluorescence and UV spectra (data not shown), it may be inferred (1) that the SOM of Pinna and Pinctada are different (2), that these matrices are not pure proteins (3), and that their aromatic amino acid contents are very low.


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Fig. 3.   Fluorescence spectra of two standards, BSA (protein) and CS (acidic sulfated sugar), and of the SOM of Pinna and Pinctada showing that the SOM are not pure proteins. Excitation: 257 nm (A), 275 nm (B), 287 nm (C).

In infrared spectra, the amide I band is the most intense absorption band for proteins. The presence of bands arising from amino acid side chains in the region between 1800 and 1400 cm-1 (amides I and II) has been thoroughly investigated (29). It has been established that among the 20 proteinogenous amino acids, only residues arginine, asparagine, glutamine, aspartic and glutamic acids, lysine, tyrosine, histidine, and phenylalanine have intense absorption in this region. Pinna has nine bands, and Pinctada has eight bands in this part of the spectrum. The prominent band in the two matrices is the amide I band near 1653 cm-1; thus, it may be supposed that components have adopted the alpha -helical conformation (Figs. 4 and 5). However, precise interpretations of bands in the amide I region are difficult, because there is an overlap of the alpha -helical with random coil structures. The 1647 cm-1 band (amide I) may be assigned to unordered structures, this band being absent from Pinctada. Other bands show the presence of beta -turn and beta -sheet structures. The prominent amide II bands are near 1560 cm-1 (Pinna) and 1540 cm-1 (Pinctada). Strong carboxylate absorption bands are present at 1419-1420 and 1717 cm-1 in both SOM. Bands at 1717 and 1575 cm-1 are usually assigned to aspartic acid, whereas bands at 1712 and 1558 cm-1 are assigned to glutamic acid. These four bands are present in Pinctada, whereas bands corresponding to aspartate (1622 and 1678 cm-1) and glutamate (1610 and 1670 cm-1) are absent. In Pinna, bands assigned to aspartic acid (1574 and 1717 cm-1) are present, but bands related to aspartate are absent. One band is present for glutamic acid (1560 cm-1), and two bands are present for glutamate. The small band near 1245 cm-1 may imply that some molecules are sulfated (Fig. 5). Amide A bands are similar in both samples and are not specific for secondary structures.


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Fig. 4.   FTIR spectra of the SOM of Pinna and Pinctada.


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Fig. 5.   Detailed FTIR spectra of the SOM of Pinna and Pinctada showing the different bands in the amide I, amide II, and the sugar region (A) and in the amide I and II domains (B).

All of these bands are present in both proteins and sugars. Thus, it is possible that the strong amide A, I and II bands, are also due to sugars as shown by the spectra of CS (30, 31). On the other hand, bands between 1000 and 1150 cm-1, which are absent from protein spectra, are usually considered characteristic of only the sugars. Thus, in complex components, it is difficult to infer the low or high contents of sugars from the intensity of bands of only the 1000-1150-cm-1 region. In both SOM, these specific bands are weak, but this is not necessarily evidence of a low sugar content. Moreover, some molecules seem sulfated.

Molecular Masses

The HPLC chromatogram of Pinna at 226 nm in non-dissociative buffer (Tris) shows a small peak of excluded large molecules (>1 × 106 Da), a main peak at 277 kDa, and a minor peak estimated at 12 kDa (Fig. 6A). At 254 and 278 nm, the overall peaks are similar to those detected at 226 nm, but the excluded molecules are the main peak. Only the largest and smallest molecular masses are present in the refractometric chromatogram, the main peak being at 277 kDa (Fig. 7). There is a strong decrease in the intensity of the peaks from 226 to 278 nm, showing a low protein content. Refractive index detectors (or refractometers) are sensitive to a wide range of organic compounds, but they are typically used to analyze compounds that do not have strong absorbance in the UV range such as sugars. In the experimental conditions used, low quality commercial BSA shows one or two small peaks, whereas high purity globular proteins do not show peaks. CS shows a strong peak. These data may imply that the main components of the Pinna SOM are sugars or highly glycosylated proteins.


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Fig. 6.   HPLC UV profiles of Pinna (A) and Pinctada (B) showing the composite nature and the different molecular weights of the SOM. Non-dissociative buffer (Tris).


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Fig. 7.   HPLC refractometric profiles of Pinna and Pinctada showing the high content of sugars in the SOM of Pinna.

The 226-nm profile of Pinctada shows three distinct peaks of increasing intensities: one of excluded molecules, a second one at 377 kDa, and the last one at 110 kDa (Fig. 6B). As for Pinna, the 278- and 254-nm profiles are similar to each other and different from the profile at 226 nm. The main peak is at 110 kDa, the middle peak is a shoulder, and the excluded molecules are present. These three peaks are present in the refractometric profiles (Fig. 7), the excluded molecules being the most intense. It should be noted that in Figs. 6 and 7, elution times are different for the equivalent peaks in each elution profile because of the serial connection of the two detectors.

The comparison of the UV and refractometric HPLC profiles confirms the UV-fluorescence data. The SOM of Pinna and Pinctada are different. Not only are the molecular weights different, but each peak has a peculiar composition. The 226-nm profiles of Pinna and Pinctada show similar intensities, but the refractometric profile of Pinna is more intense than that of Pinctada. UV and refractometric profiles of a sample were acquired during the same elution, so that their ratios are not dependent of the quantity of SOM. According to the comparison of these profiles and the 226/278 nm ratios, Pinna seems to contain a higher proportion of sugars than Pinctada.

Components with molecular masses greater than 106 Da are present in Pinna (Fig. 8A), the main peak being at ~120 kDa. The Pinctada profile shows more peaks. A faint shoulder is indicative of excluded components (>106 Da), other peaks being at ~98 and 23 kDa (Fig. 8A). The separation range of Superose 12 chromatography in the dissociative buffer (1,000-300,000 Da) is narrower than that of the TSK columns. The Pinna profile shows an excluded peak (>300 kDa) and a broad peak at 34 kDa (Fig. 8B). The Pinctada profile is more complex with a small excluded peak, several shoulders, a main peak of apparent molecular mass of 20 kDa, and several small peaks (Fig. 8B). Clearly, there is a discrepancy in the molecular mass estimated for the molecules in the major peak of the Pinna SOM on the two different columns (120 and 34 kDa). The basis for this discrepancy is not readily apparent but may indicate some peculiarity regarding the molecules contained in this peak.


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Fig. 8.   HPLC UV profiles at 275 nm of Pinna and Pinctada in a dissociative buffer (guanidinium chloride). A, profiles showing the composite nature and the different molecular masses of the SOM. Same columns as in Fig. 6 (TSK columns). B, profiles in a Superose 12 column.

Despite the observed differences in the dissociative buffer, Pinna and Pinctada SOM are different. The comparison of the 280-nm (non-dissociative buffer) and 275-nm (dissociative buffer) profiles shows that the excluded peaks are less prominent in the dissociative buffer. There is a good correspondence of the apparent molecular masses among the three profiles of Pinctada but not in Pinna. The different behavior of the two SOM in the two buffers is consistent with the previous results. Some of the macromolecules of Pinna are poorly dissociated by guanidinium chloride, a behavior characteristic of highly glycosylated molecules. In contrast, Pinctada SOM is better dissociated and the sugar component is probably of lesser proportion.

Acidity

CS (an acidic and sulfated sugar) can be stained with Acridine Orange, but no discrete bands are present in this non-denaturing electrophoresis (Fig. 9A, center lane). Standard proteins are not stained with Acridine Orange but are stained with Coomassie Blue-Crocein Scarlet (Fig. 9A, left lane). The Pinna SOM is successfully stained with Acridine Orange, showing that the main part of the organic components consists of sulfated sugars, the pI of which is lower than 5.8 (Fig. 9A). A faint Coomassie Blue-Crocein Scarlet stain indicates that the protein components are slightly less acidic (Fig. 9A). Acidic sulfated sugars are also stained by Acridine Orange in Pinctada, but the proteins stained with Coomassie Blue-Crocein Scarlet are more acidic than those of Pinna (Fig. 9A). The two dyes used show that the SOM of Pinna and Pinctada are composed of proteins and acidic sulfated sugars. However, Pinna and Pinctada SOM are different. The protein part of Pinctada seems more acidic than that of Pinna.


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Fig. 9.   A, non-denaturing IEF of the SOM of Pinna and Pinctada. Coomassie Blue-stained standard proteins and Acridine Orange-stained CS are shown. The sugar fractions of the SOM are more acidic than the proteins. B, two-dimensional gels. Pinna and Pinctada SOM are stained with Alcian Blue and then silver. Standard proteins are silver-stained. AO, Acridine Orange; BCC, Coomassie Blue-Crocein Scarlet.

Two-dimensional Electrophoretic Separation

Pinna-- The Alcian Blue stain of the IPG strip shows a gradient from a light color (basic part) to an intense blue color at the acidic end (Fig. 9B). Thus, it may be suggested that large molecular mass components (> 300 kDa) do not penetrate into the two-dimensional gel. These acidic components are strongly stained with Alcian Blue but not with silver; thus, it may be inferred that they are sulfated sugars. A very weak silver stain is visible only in the basic part of the IPG strip (Fig. 9B). The main part of the two-dimensional gel is not stained, and only the low molecular masses-acidic pI are stained with Alcian Blue (Fig. 9B). There is a contrast between the acidic parts of the IPG strip and the two-dimensional gel. The strip is heavily Alcian Blue-stained, whereas the two-dimensional gel is faintly stained. The silver stain is faint and visible only in the acidic part of the two-dimensional gel. Despite the use of dissociative denaturant buffers containing urea, SDS, dithiothreitol, 2-mercaptoethanol, and Triton X-100, there is no discrete band or spot, and according to the stain, the main part seems composed of acidic sulfated sugars.

Pinctada-- The entire length of the IPG strip is heavily stained: the acidic part with Alcian Blue, indicative of sulfated sugars, and the basic part with silver, indicative of proteins (Fig. 9B). The main part of the two-dimensional gel is silver-stained with a good separation according to pI but with no distinct band according to molecular masses (Fig. 9B). The acidic-low molecular mass part of the gel shows some unusual patterns and is also Alcian Blue-stained. As for Pinna, it may be suggested that a part of the acidic portion of the SOM is composed of molecular masses higher than 300 kDa, and these components do not penetrate into the two-dimensional gel. The Alcian Blue-stained two-dimensional gel prior to the silver stain does not show a strong blue color (data not shown).

The striking feature of the two-dimensional gels is the absence of the spotty pattern usually seen for soft tissue proteins, despite the use of dissociative buffers. Smears are usually indicative of a high degree of glycosylation. Pinna SOM seems to be composed of acidic sulfated sugars, a part of which has molecular masses higher than 300 kDa. Pinctada SOM also shows components with molecular masses higher than 300 kDa, but this SOM contains proteins and sulfated sugars with a large pI range as shown by the IPG strip. The lower molecular weight components of the SOM also seem to be composed of proteins with a larger range of molecular weights and pI.

Sulfur Contents-- Reference spectra are in accordance with published data (32, 33). The S-K edge spectra of methionine and cysteine show a main peak at 2.473 keV (Fig. 10A). Cystine with a disulfide bond shows a double peak in the same region (Fig. 10B). A similar double peak is also present in phenyl disulfides (data not shown). The sulfated sugar, CS, shows a main peak at 2.482 keV and no peak in the S amino acid region (Fig. 10B). The spectra of the SOM extracted from Pinna and Pinctada also show a main peak at 2.482 keV, indicative of a high sulfate content based on the CS spectrum (Fig. 11A). The profile of Pinctada shows a double peak similar to that observed with CS. Pinctada shows small peaks at 2.47 keV corresponding to S amino acids according to the reference spectra, whereas the Pinna profile is flat for S amino acids. These results are consistent with the HPLC and electrophoretic data. Pinctada SOM contains more proteins than that of Pinna.


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Fig. 10.   XANES spectra. A, S amino acids. B, S amino acid with a disulfide bond and CS.


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Fig. 11.   A, XANES spectra of SOM showing the main S species is SO4 in both Pinna and Pinctada and the presence of S amino acids in Pinctada. B, in situ XANES spectra in the sinuous organic intraprismatic membranes of the prisms of Pinctada (see Fig. 2, C-F).

SEM micrographs show sinuous intraprismatic membranes in Pinctada prisms (Fig. 2, C-F, arrows) but not in Pinna (Fig. 1, D-F). In situ spectra of these sinuous intraprismatic membranes of Pinctada confirm that they are organic. A main peak at 2.48 keV and a very faint shoulder at 2.47 keV may be indicative of some S amino acids (Fig. 11B). The S amino acid region is weaker in this spectrum than that of the extracted SOM. The detailed structures of the intraprismatic membranes are unknown, but as for membranes in other microstructures in mollusk shells (i.e. the nacreous layer), they are probably composed of soluble and insoluble parts, the compositions of which are different. It is conceivable that the difference between the SOM spectrum and the in situ spectrum is due to the ratio of soluble and insoluble matrices involved in the intraprismatic membranes.

In both samples, XANES spectra show that the main sulfur species is sulfate, not S amino acids. However, the Pinctada SOM also contains some sulfur corresponding to amino acids with a small double peak, which may suggest the presence of cystine. However, the ratios of the three small peaks in the amino acid region as well as the energy of the third peak are not the same in the spectra of cystine (Fig. 10B) and Pinctada SOM (Fig. 11A).

    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

From the above results, three topics can be discussed: 1) the methods used, 2) a comparison with other calcitic prisms, and 3) the relevance of the simple prism concept.

Methods-- Because EDTA tends to form non-removable complexes with organic materials extracted from bones or shells (34-36), a moderate acidic decalcification was used (pH 4). It is sometimes said that acetic acid decalcification is a harsh process denaturing the soluble organic matrix, but the accuracy of this assessment is questionable. If the acetic acid decalcification hydrolyzes and cleaves the SOM into smaller molecules, low molecular weight peaks and bands should be present in HPLC and electrophoresis. The presence of large molecular weight species shows that the hydrolysis of the SOM during the decalcification is moderate if not absent. These results are consistent with the usual hypothesis saying that when the decalcifying solution and organic components have similar pH, the organic matrices are not altered. Previous amino acid analyses of the SOM of mollusk shells have shown that the average pI is near 4 (17, 18). Thus, it may be inferred that the decalcification used does not substantially alter the SOM. In addition, concentrated HCl has been used to extract the intraskeletal macromolecules of ascidians and no major effect was observed on the extracted macromolecules (37).

UV spectrometry and fluorescence show that the SOM studied have very low aromatic amino acid contents. Although these methods are relatively simple, they are informative and not time-consuming. Moreover, they show that the main methods used to estimate the protein contents based on the tryptophan, tyrosine, and phenylalanine absorptions are not suitable for such SOM.

There is good agreement between the results of HPLC and electrophoreses. Despite the use of dissociative buffers in both techniques, large molecular size species are observed (>103 kDa).

Comparison with Other Calcitic Prisms-- Addadi et al (38) and Albeck et al. (36) have studied the SOM extracted from the outer calcitic prisms of Atrina (Pteriomorpha, Pinnidae). Atrina and Pinna are taxonomically related. Infrared spectra of Atrina show a main peak at 1653 cm-1, strong bands at 1575 and 1417 cm-1, and weak specific sugar bands. The band at 1160-1630 cm-1 is assigned to protein amide I but also "possibly to the N-acetyl groups of polysaccharide" (36). Bands at 1255 and 1230 cm-1 may be attributed to amide III and/or sulfate (36). However, an acidic part of the matrix shows a large specific sugar band. Thus, the similarities between the infrared spectra of P. nobilis and Atrina are high despite the different decalcification processes. The prisms of Atrina also show high contents of acidic amino acids (36). S amino acids (Cys and Met) are low, but the special hydrolysis necessary to avoid destruction of these amino acids was not done by Albeck et al. (36).

The Simple Prism Concept-- Despite some similar aspects, the microstructures and nanostructures of the prisms of Pinna and Pinctada are clearly different as previously shown by optical microscope studies. Pinna prismatic units are monocrystalline, whereas those of Pinctada are not. Pinctada SEM observations showed small globular crystals (200-600 nm in diameter) surrounded by a thin granular envelope 3-5-nm thick (17). This size is similar to that of the elongated crystallites observed with AFM but is larger than that of the rounded granules. The ultrastructure of Pinna was not illustrated previously (17). Pinna and Pinctada prisms were also called megaprisms (39). They are said to be built up of small crystallites (100-300 nm in diameter) and arranged in an irregular pattern in Pinctada fucata. No radial intraprismatic membranes were observed. Again, the ultrastructure of the prismatic layer of Pinna was not illustrated previously (39).

The combination of analytical methods from simple ones such as UV and fluorescence to more focused techniques such as HPLC or XANES allows us to obtain convergent data on the SOM extracted from Pinna and Pinctada calcitic layers. First, UV and fluorescence data show strong differences between pure proteins and the SOM, which were studied. The main features of the infrared spectra are similar, but the main band in each region is different and indicative of different conformations. These spectra also show that SOM are not pure proteins; sugars and sulfate are present. However, the amount of sugars is not known and cannot be deduced, because most of the bands are present in both proteins and sugars.

UV and refractometric HPLC profiles support the conclusion that the SOM of Pinna and Pinctada are glycoproteins or glycosaminoglycans as well as their different compositions and apparent molecular weights. Both SOM have apparent molecular masses higher than 106 Da; thus, only a part of the SOM penetrates into two-dimensional gels. The different sugar content is also confirmed by the stains. It is often said that the absence of staining is because of the very acidic makeup of the SOM (40), but both Pinna and Pinctada SOM are very acidic as shown by amino acid compositions (17). The observed difference in silver staining between Pinna and Pinctada is probably because of the difference in their sugar contents. It must be noted that Alcian Blue or Acridine Orange stains are not sensitive compared with silver staining.

Non-denaturing IEF also shows strong acidity based on the position of the bands, whereas the high S contents and the differences in sugar contents are demonstrated by the stains. Both Pinna and Pinctada SOM contain up to 79% aspartic acid (17, 18), but the amino acid composition is dependent on the species. For example, aspartic acid varies from 23 to 76% in two Pinctada species, whereas glutamic acid varies from 3.6 to 18% in two Pinna species (17). XANES spectra confirm that the main sulfur species is sulfate in both SOM, but S amino acids are also present in Pinctada. Previous microprobe analyses have shown that these calcitic prisms have high S contents, typically 5650 ppm in Pinna and 3100 ppm in Pinctada (13, 14). Disulfide bonds, if present, are rare as confirmed by liquid chromatography (HPLC) and electrophoresis data. The use of dissociative denaturant-containing detergent buffers does not result in any improvement in resolution of the SOM components.2

    CONCLUSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

The techniques used do not allow us to identify the glycoproteins precisely and/or their core proteins or sugar moieties. CS is one of the most widespread sulfated sugars and is frequently observed in extracellular matrices involved in calcification processes (41-43) and in shell formation (44, 45), but the data available for Pinna and Pinctada are not sufficient to ascertain its presence in these species. The high molecular weights and sugars in Pinna suggest the presence of mucins. Mucins are high molecular weight, heavily glycosylated, and sometimes sulfated proteins and chromatograph in the void volume of most commercially available gels. They do not penetrate well into electrophoresis gels. They are stained in situ or in gels with Alcian Blue. The subunits are joined by disulfide bonds. However, the amino acid contents of mucins are different from those of Pinna and Pinctada SOM. Mucins have high threonine, serine (20%), and proline (10%) contents and low aspartic acid (4%) and glutamic acid (8%) contents.

Despite some common features, the Pinna and Pinctada SOM are not mucins. SOM extracted from the calcitic prismatic layer of Pinna is probably composed of a peptide core of repeating units decorated with carbohydrate chains. Pinctada SOM is also probably composed of a peptide core of repeating units, despite a low glycosylation level and low sulfate content.

Further studies are required to isolate and characterize the core proteins and the carbohydrate moieties of the SOM of mollusk shells and the relationships between the extrapallial fluid and the SOM. Hattan et al. (46) have shown that the major protein of extrapallial fluid of Mytilus is a glycoprotein "that is a homodimer composed of 14.3% carbohydrate." Denaturing gel electrophoresis of this protein under reducing or non-reducing conditions indicates the lack of disulfide bonds. The estimated molecular mass of the subunit is 28,350 Da, and the pI is 4.43. The major secondary structures are alpha -helix and then beta -sheet. The Mytilus shell is composed, as are Pinna and Pinctada, of an inner aragonitic layer and an outer calcitic one. However, a direct comparison between the extrapallial fluid and SOM of the calcitic layers remains difficult, because the extrapallial fluid is involved in the secretion of all of the layers of the shells and it is well known that in a single shell the SOM of the nacreous layer and of the prismatic layer are different.

High S contents, high sugar contents, and sulfate as main sulfur species are not exclusively known in calcitic minerals. Similar compositions have been described in the SOM extracted from the aragonitic skeletons of Scleractinia (28). Sulfated mucopolysaccharides are known to be closely associated with the mineralization process, and their involvement in the nucleation process of calcitic and aragonitic biominerals in vivo has been shown in various taxa (9, 34, 47-50). Moreover, from histochemical and microscopic studies, Wada (47) has shown that acidic sulfated mucopolysaccharides are not present in non-calcified organic matrices of mollusk shells.

The pioneer results of Wada (47) showing differences in the organic contents of the calcitic prisms of Pinna attenuata and P. martensii on the one hand and the presence of components similar to CS on the other hand are confirmed. Although they are present at or before the beginning of the calcification, few data are available on the structure and the composition of the thick organic walls or interprismatic sheaths. A detailed study of the organic matrices of the prismatic layer of Pinna shows that the interprismatic walls consist of soluble and insoluble fractions (31). Nevertheless, the role of each fraction in the biomineralization process is not explained. Similar data are not available for the interprismatic walls of Pinctada.

The simple prism concept is not corroborated by other microscopic observations despite a common mineralogy. In many ways, the prisms of Pinna and Pinctada are not identical. The SOM differ markedly in their structures and composition and in the molecular weights and acidities of their molecular constituents. The "similar" features of these prisms are less numerous than the "different" features. Both Pinna and Pinctada are Pteriomorpha bivalves, but they belong to distinct orders. The main microstructural differences (composite structure in Pinctada) and the major compositional differences (sugar contents) probably reflect fundamental evolutionary trends. Thus, the simple prism concept is not a relevant model for the biomineralization processes in the prismatic calcitic layer of mollusk shells.

From a methodological point of view, highly focused studies on the protein contents of biominerals are not sufficient to estimate the phylogenetic similarities of taxa on the one hand and to understand the role of the organic matrices in biomineralization processes on the other hand. The next step of this comparison is a separation of sugars and proteins followed by a separation of the constituents of each fraction. From a geological point of view, the observed distinct characteristics imply a different behavior during the fossilization processes despite a common size and mineralogy.

    ACKNOWLEDGEMENTS

The research carried out at European Synchrotron Radiation Facility (ESRF) was under contract CH721 and CH948. I thank Dr. J. Susini and Dr. M. Salomé (ID 21, ESRF, Grenoble, France) and Pr. Dr. J. Doucet (Laboratoire de l'Utilisation da Rayonnements Electromagnétiques, Université Paris XI-Orsay, Orsay, France) for their valuable advice and support. I am grateful to an anonymous reviewer for advice, which greatly enhanced the quality of this paper.

    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: Laboratoire de Paléontologie, bât. 504, Université Paris XI-Orsay, F-91405 Orsay, France. E-mail: dauphin@geol.u-psud.fr.

Published, JBC Papers in Press, February 7, 2003, DOI 10.1074/jbc.M204375200

2 Y. Dauphin, unpublished data.

    ABBREVIATIONS

The abbreviations used are: SOM, soluble organic matrix/matrices; SEM, scanning electron microscope; AFM, atomic force microscope; HPLC: high pressure liquid chromatography, FTIR, Fourier transform infrared spectrometry; IEF, isoelectric focussing electrophoresis; IPG, Precast Immobilin DryStrip; BSA: bovine serum albumin, CS, chondroitin sulfate; XANES, x-ray absorption near-edge structure.

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

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