Bovine high molecular weight amelogenin proteins

Purification of Developing Enamel Matrix Proteins Using Preparative SDS-PAGE

In this chapter we discuss the potential of preparative SDS-PAGE for use in purifying native developing enamel matrix proteins. We believe that the methodology has the potential to provide the relatively large-scale single-step purification of any enamel protein that can be resolved as a single band during analytical SDS-PAGE. Of course, a single band on analytical SDS-PAGE does not guarantee absolute purity as the band may be comprised of two or more proteins migrating at the same apparent molecular weight on the gel. Where absolute purity is required, the methodology can be used in conjunction with other techniques such as ion-exchange chromatography or reverse-phase chromatography. We do not see preparative SDS-PAGE replacing chromatographic methodologies but believe that it can provide another powerful tool to add to the battery of purification techniques already available to researchers in the field.

Comparison of three methods for enamel protein extraction in different developmental phases of rat lower incisors

Protein extraction methods [urea, trichloroacetic acid (TCA), and acetic acid] were compared for protein recovery from rat incisor developing enamel in the S phase (intermediate/late secretion), M1 phase (early maturation), M2 phase (intermediate maturation), and M3 phase (final maturation). We compared the protein recoveries with the percentage of enamel matrix dry weight burnt off by incineration. Our results indicate that TCA and urea were equally efficient for the extraction of S-stage proteins (85% and 90% recovery, respectively), while urea was the best for M1-stage proteins (92% recovery), and TCA the best for M2-stage (99% recovery) and M3-stage (60% recovery) proteins. The other methods yielded less than 30% recovery in comparison to incineration for M2 and M3 stages. The fact that urea extraction works well in the S and M1 stages and not thereafter is probably related to the changes in the proteins during enamel development and the amount of mineral that needs to be dissolved. TCA is the single method that effectively recovered proteins from all developmental stages of the rat incisor enamel.

Expression of cytokeratin 14 in ameloblast-lineage cells of the developing tooth of rat, both in vivo and in vitro

In the search for a cell marker useful for studying tooth development, immunohistochemical studies using antibodies against cytokeratin 14 (K14), c-Met/hepatocyte growth factor receptor and amelogenin were carried out in the developing tooth of the newborn rat and in primary cultured cells of the ameloblast lineage, including inner enamel epithelium cells, preameloblasts and ameloblasts, prepared from the mandibular incisors of postnatal 7-day-old rats. The appearance of K14 was cell- and differentiation-stage specific, i.e. there was a weak expression signal within inner enamel epithelial cells that were in the proliferating stage, and there were strong signals within preameloblasts and ameloblasts that were in the post-proliferating and amelogenesis stages, respectively. In the culture system, c-Met appeared in all cells, whereas K14 and amelogenin appeared mainly in clustered cells that were considered to be in the post-proliferating stage. K14 was detected earlier than amelogenin, and it was also confirmed by immunofluorostaining that c-Met, K14 and amelogenin were coexpressed in ameloblasts. These findings indicate that K14 is a good new marker for ameloblast-lineage cells during rat tooth development both in vivo and in vitro.

Production of a monoclonal antibody against human amelogenin

The extracellular organic matrix of developing human enamel is composed of two major classes of proteins, the hydrophobic amelogenins and the acidic enamelins. In order to identify, purify, and characterize the amelogenins from this complex mixture of proteins, and to study their ultrastructural localization and their pathways of synthesis, secretion, and degradation, specific and sensitive probes are needed. In the present paper the production of a monoclonal antibody against human amelogenin employing an intrasplenic primary immunization protocol is described. The monoclonal antibody produced is IgM and recognizes major human amelogenin protein bands in Western immunoblot assays. It also recognizes amelogenin protein bands from other species, specifically bovine and porcine. Indirect immunohistochemical studies showed the monoclonal antibody to react specifically with the extracellular matrix of human developing enamel. It did not react with the underlying dentin layer.

Characterization of amelogenin mRNA from secretory- and maturation-stage rat incisor enamel

Amelogenins are extracellular matrix proteins expressed at the secretory and the maturation stages of enamel formation. To characterize amelogenin transcripts from these two stages, rat incisor enamel-organ mRNA was hybridized to a mouse amelogenin cDNA. Northern analysis of the mRNA showed four amelogenin transcripts at the secretory stage. Two of these were larger than previously described, and would code for high molecular-weight amelogenins (> 40 kDa). These transcripts were similar in size to at least three bovine amelogenin mRNAs. At the maturation stage, one transcript slightly smaller than the major amelogenin transcript from the secretory stage was apparent. These differences may indicate a selective splicing of amelogenin mRNA in the maturation stage as compared to the secretory stage of enamel development.

Common epitopes of mammalian amelogenins at the C-terminus and possible functional roles of the corresponding domain in enamel mineralization

The present studies were undertaken to investigate the presence of common epitopes of mammalian amelogenins at the C-terminus and the possible functional importance of the conserved C-terminal domain in enamel mineralization during mammalian amelogenesis. Enamel proteins, including the intact amelogenins and their degraded polypeptides, were isolated from the secretory enamel of pig, cow, rat, and rabbit incisors. Rabbit and rat antipeptide sera, as well as rat anti-25 kD and 20 kD pig amelogenin sera, were used to identify the amelogenins among the isolated matrix proteins of each of the animal species. The antipeptide sera were developed previously (Aoba et al. [19]) using as immunogens the two synthetic peptides, C13 and C25, which correspond to the last 12 (plus Cys for KLH-conjugation) and 25 amino acid residues of pig intact amelogenin, respectively. Reactivity of the enamel proteins with each antiserum was examined by Western blot analysis. The results of immunoblotting showed that a few enamel matrix proteins in each of the mammalian species were recognized by the anti-C13 serum, specifically, pig amelogenin at 25 kD (and trace components at 27, 22, and 18 kD), cow amelogenin at 28 kD (trace components at 26, 22, 19, and 14 kD), rat amelogenins at 28 and 26 kD (and a trace component at 20 kD), and rabbit amelogenins at 24 and 21 kD (and a trace at 13 kD). The anti-C25 serum reacted additionally with pig amelogenin at 23 kD, cow amelogenin at 27 kD (a major matrix constituent), and rabbit protein at 19 kD.(ABSTRACT TRUNCATED AT 250 WORDS)

Anti-peptide antibodies reactive with epitopic domains of porcine amelogenins at the C-terminus

This was an immunological investigation of the processing of porcine amelogenins in situ. Rabbit and rat anti-peptide sera reacted specifically with the hydrophilic segment of the intact amelogenins at the C-terminus. The immunogens used were the synthetic peptides: (a) C13 composed of PATDKTKREEVDC and (b) C25 composed of MQSLLPDLPLEAWPATDKTKREEVD. These peptides correspond to the C-terminal 12- and 25-residue segments of porcine amelogenin, respectively. Cystine was introduced at the C-terminus of C12 for KLH-binding (C13). Western blot analysis disclosed that: (i) both rabbit and rat anti-C13 sera reacted selectively with the 25-kDa porcine amelogenin and three other minor components (27, 22 and 18 kDa); (ii) anti-C25 peptide sera, additionally, reacted with the 23-kDa amelogenins (a degradation derivative of the 25-kDa protein, lacking the 12-residue segment at the C-terminus) and as trace components, 20-, 16- and 14-kDa moieties. Importantly, all the proteins reactive with the anti-C13 serum were concentrated in the outer secretory enamel adjacent to the ameloblasts, decreasing significantly in the underlying inner secretory enamel. Immunohistochemical studies applying the anti-peptide sera to the developing tooth germs of a minipig also confirmed the localization of reactivity in the outer secretory region. Neither anti-peptide serum reacted with porcine non-amelogenins, serum proteins nor dentine matrix proteins at the dilutions tested. however, it was found that both the anti-C13 and C25 sera reacted with human keratin.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of the leucine-rich amelogenin peptide (LRAP) as the translation product of an alternatively spliced transcript

The polymerase chain reaction was used to amplify bovine tooth amelogenin cDNA, resulting in several products which were separated by agarose gel electrophoresis. Sequence determination of one of the products revealed that it encoded an amino acid sequence identical to that of a small leucine-rich amelogenin polypeptide (LRAP) previously characterized by protein sequencing. Comparison of the nucleotide sequence of this cDNA with that determined for the cloned bovine amelogenine gene strongly suggested that the LRAP transcript resulted from alternative splicing of the primary transcript of this gene, thus explaining the origin of the puzzling LRAP sequence. Analysis of the structure of LRAP suggests that the polypeptide might exhibit interesting properties relative to hydroxy apatite crystal formation.

Immunohistochemical demonstration of amelogenin penetration toward the dental pulp in the early stages of ameloblast development in rat molar tooth germs

In order to examine the synthesis and secretion of enamel protein by ameloblasts in their early stages of development, immunohistochemical localization was carried out at light and electron microscopic levels using a monoclonal antibody produced in a preliminary experiment. Materials used were tooth germs of mandibular first molars of rats at 0-5 days after birth. Immunoblot analysis after two-dimensional electrophoresis revealed that antigen molecules recognized by the monoclonal antibody were amelogenins of 26-28 kDa (pI, 6.6-7.0). An immunohistochemical examination using this monoclonal antibody demonstrated that the presecretory ameloblasts in their early stages of differentiation both synthesized amelogenin and secreted through a classical merocrine secretory pathway. In some presecretory ameloblasts as well as ameloblasts we observed the distended cisternae of rough endoplasmic reticulum (rER) which demonstrated heterogenous immunolabelling. The immunolabellings were also detected in the predentin as well as the intercellular spaces of odontoblasts and dental pulp cells which indicated penetration of amelogenin from the presecretory ameloblast layer to the dental pulp. The presence of coated pits at the plasma membrane of odontoblasts in close proximity to enamel protein along with the immunolabelling of lysosomes of the odontoblasts suggests the phagocytosis of the enamel protein into the odontoblasts. These observations suggest the possibility that the penetration of enamel protein toward the dental pulp and odontoblasts plays a role in the interaction between ameloblasts and odontoblasts.

Biochemical characterization of stable high molecular-weight aggregates of amelogenins formed during porcine enamel development

Analysis of the enamel matrix during porcine tooth formation has revealed a number of high molecular-weight (Mr) enamel proteins (greater than 30 kDa), which are related to the major amelogenins (20-26 kDa). To examine the nature of these proteins, amelogenins were extracted and separated by conventional gel filtration and reverse phase HPLC. Many of the proteins in the high Mr fraction reacted with a polyclonal antibody, affinity-purified against a mixture of 20-26 kDa amelogenins. Another antibody, affinity-purified against a fraction containing the LRAP, reacted with amelogenins 30-36 kDa in size but not with amelogenins 40 kDa or larger, indicating that the high Mr amelogenins were a heterogeneous group of enamel proteins. Analysis of amino acid composition and N-terminal amino acid sequence, as well as PASGE of electrophoretically eluted proteins, indicated that the high Mr amelogenins were aggregates of various major amelogenins. Three amelogenin aggregates (43, 40 and 32 kDa) isolated by electrophoretic elution were less stable at 100 degrees C in SDS-containing buffer than at 60 degrees C. In contrast to the major amelogenins, which are found in constant proportions throughout enamel development, the high Mr amelogenins appeared to increase in maturing enamel relative to the total matrix protein. Thus, at least in the pig high Mr amelogenins appear to be naturally occurring, stable aggregates of major amelogenins. It is proposed that amelogenin aggregation occurs as a consequence of the diminishing spaces between growing crystals in maturing enamel.

Structure and function of enamel gene products

The present paper reviews the main features of amelogenin and enamelin biochemistry, molecular biology, structural and ultrastructural localization, and immunology. It also examines recent studies concerning the origin, chemical characterization, suggested role, and participation of these two major classes of extracellular developing enamel matrix proteins in the complex process of "matrix-mediated" mineralization.

Degradation and loss of matrix proteins from developing enamel

The pattern and timing of the breakdown and loss of matrix proteins were studied in developing rat incisor enamel using sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), fluorography, radioautography, and in vitro incubations of proteins isolated from freshly dissected, crushed pieces of enamel. For biochemical studies, the technique of Robinson et al. (1974, 1977, 1983) was used to transect the enamel organ and enamel into a series of strips at 1 mm intervals along the length of the tooth. The proteins in each strip were extracted and either quantified by Lowry analysis or applied to 12% slab (enamel) or 5-15% continuous gradient (enamel organ) SDS-polyacrylamide gels and separated by electrophoresis. The biochemical studies indicated that the amount of protein contained within an enamel strip increased gradually by volume across the secretory stage, reached a peak early during the maturation stage, and then declined rapidly thereafter. The distribution of enamel proteins on SDS-polyacrylamide gels changed markedly throughout this period. These changes included increases and decreases in the intensity of staining of proteins at certain molecular weights (e.g., 18 kDa) and the appearance and disappearance of some proteins not seen clearly near the start of the secretory stage of amelogenesis (e.g., 32 and 10 kDa). Labeling studies with 35S-methionine suggested that the "stacked" arrangement of proteins typical of forming enamel (secretory stage) actually represented a very dynamic association of proteins, with new ones being added at the top of the stack and then breaking down with time to become those seen at lower molecular weights. Across the secretory stage, new proteins were always added to the top of the stack, but during early maturation this activity slowed dramatically, allowing the breakdown of aging proteins to be visualized more clearly. Radioautographic studies with 3H-methionine indicated that the breakdown of newly secreted proteins also was correlated with a movement of label from the site of secretion into deeper, previously unlabeled, areas of forming enamel. In vitro studies revealed that the rate and degree of breakdown of enamel proteins varied markedly, depending on the stage of amelogenesis from which the proteins were extracted. Secretory stage enamel proteins showed slow in vitro degradation with accumulation of proteins near 18 kDa. Early maturation stage enamel proteins showed more rapid breakdown with little accumulation of proteins near 18 kDa, whereas late maturation stage enamel proteins showed complete degradation by 2 days of incubation in vitro.(ABSTRACT TRUNCATED AT 400 WORDS)

Biosynthesis and characterization of rabbit tooth enamel extracellular-matrix proteins

Tooth enamel biomineralization is mediated by enamel proteins synthesized by ameloblast cells. Two classes of proteins have been described: enamelins and amelogenins. In lower vertebrates the absence of amelogenins is believed to give rise to aprismatic enamel; however, rabbit teeth, which apparently do not synthesize amelogenins, form prismatic enamel. The present study was designed to characterize the enamel proteins present in rabbit tooth organs and to gain an insight into the process of biomineralization. Rabbit enamel extracellular-matrix proteins were isolated and characterized during sequential stages of rabbit tooth organogenesis. The biosynthesis of enamel proteins was analysed by metabolic 'pulse-chase' experiments as well as mRNA-translation studies in cell-free systems. Our results indicated that rabbit enamel extracellular matrix contains 'amelogenin-like' proteins. However, these proteins are not synthesized as typical amelogenins, as in other mammalian species, thus suggesting that they are the processing products of higher-molecular-mass precursors. An N-terminal amino acid sequence of 29 residues, considered characteristic of mammalian amelogenins, was present in the rabbit 'amelogenin-like' proteins. By using anti-peptide antibodies to this region, similar epitopes were detected in all nascent enamel proteins, including enamelins. These studies suggest that the N-terminal sequence might be characteristic of all enamel proteins, not only amelogenins.

Production of monoclonal antibodies against enamelin and against amelogenin proteins of developing enamel matrix

The extracellular matrix of developing enamel contains two major classes of proteins, the hydrophobic proline-rich amelogenins and the acidic serine-, glycine-, and aspartic-rich enamelins. These proteins have been postulated as playing a major role in the mineralization and structural organization of developing enamel. To identify and further characterize these different proteins and their possible role in this complex process of biological mineralization, we have in recent years been concerned with the production of specific probes for these proteins. Previously, we have reported on the successful production of specific polyclonal antibodies against enamelin proteins, which did not cross-react with amelogenins, and against amelogenin proteins, which did not cross-react with enamelins (Deutsch et al., 1986, 1987). We now report the production of monoclonal antibodies against a major bovine amelogenin protein (28 kDa) and against a major bovine enamelin protein (66 kDa). One monoclonal antibody against amelogenin and one against enamelin are described. The results showed that the monoclonal antibody against the amelogenin protein reacted strongly with the 28-kDa amelogenin protein band but did not cross-react with enamelins, and the one against the enamelin protein reacted with the 66-kDa enamelin protein but did not cross-react with amelogenins. These monoclonal antibodies provide a specific and powerful tool to distinguish between and further characterize these different classes of proteins, and to improve our understanding of the process of enamel formation.

Immunochemical and biochemical studies of human enamel proteins during neonatal development

The present communication provides descriptions of the developmental, biochemical, and immunological properties of the human enamel extracellular matrix proteins. We report the isolation and partial characterization of the major human enamel proteins, the production of polyclonal antibodies directed against the human enamelins, and a comparison between the immunogenicity of enamelins and amelogenins from human and mouse enamel extracellular matrices. Our results indicate that although enamelins and amelogenins share some epitopes, each one of these proteins appears to invoke a different degree of immunogenicity.

mRNA characterization of human fetal enamel matrix

Preliminary characterization of the human enamel matrix at 16-18 weeks in utero was performed. Using an homogenizing buffer, the proteins were extracted and analysed by gel electrophoresis. Total cellular RNA was isolated and the cell-free mRNA translated. The major component was a 68,000 protein with an enamelin-like amino-acid composition. Other translation products included a 55,000 polypeptide and lower mol. wt components of 26,000, 22,000 and 20,000 size of amelogenin size. It is suggested that high mol. wt component in the enamelin range is the most prevalent at the early stage of human tooth development.

Production of a monoclonal antibody to enamelins which does not cross-react with amelogenins

Developing enamel matrix contains a complex mixture of proteins whose characterization is essential to an understanding of amelogenesis. It is not known whether each component is the product of an individual gene, or whether they are interrelated by physiologic or artifactual breakdown. To define these relationships, monoclonal antibodies were prepared to enamel proteins and we have previously reported the characterization of six antibodies to amelogenins which did not react with enamelins (Christner et al. (1985) Arch. Oral Biol. 30:849-854). We now report the isolation of antibody to enamelins which stains the enamel matrix but does not cross-react with amelogenins. These results suggest that amelogenins and enamelins are distinct classes of proteins.

Effects of different extraction media on the electrophoretic pattern of proteins from partly mineralized bovine enamel

Five different extraction solutions were used to isolate matrix proteins from immature bovine enamel, to evaluate the effect of this procedure on the pattern obtained after electrophoresis. By sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the dominating protein fraction in the ethylenediaminetetraacetic acid extract had a molecular weight of 67,000 daltons. The acetic acid and phosphate buffer extracts contained mostly low molecular weight proteins. Isoelectric focusing showed that most of the enamel proteins had isoelectric points below pH 7.0.

An in-vitro study of enamel protein degradation in developing bovine enamel

An immature enamel fraction, as far as possible without cells, was prepared from fetal bovine molars, using aqueous-density fractionation. Portions were incubated at 37 degrees C with or without protease inhibitors. Amelogenins and enamelins were then examined for their molecular weight using HPLC-gel permeation. Degradation of amelogenins occurred rapidly and appeared to be related to proteolytic activity, probably localized extra-cellularly. Enamelins remained almost stable over the time intervals used.

Synthesis and degradation in vivo of a phosphoprotein from rat dental enamel. Identification of a phosphorylated precursor protein in the extracellular organic matrix

The cellular enamel organ and the cell-free organic matrix of developing enamel of female rats injected intravascularly with [3H]serine and [3H]proline were extracted in a number of solvents and examined by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and h.p.l.c. in 6M-guanidinium chloride at intervals varying from 5 min to 1 week after injection. Three major species soluble in NH4HCO3 with Mr values of approx. 100 000, 25 000 and 11 000 were identified in the cellular enamel organ. The Mr 100 000 and 11 000 components were not secreted but remained intracellular for periods of up to 1 week after injection of the radioactively labelled amino acids. In contrast, the Mr 25 000 species was secreted from the cells and was first detected in the extracellular organic matrix approx. 15-30 min after injection. With time, labelled components, first of Mr approx. 11 000 and subsequently approx. 6500, were detected in the organic matrix concomitant with a relative decrease in the Mr 25 000 component, demonstrating that the lower Mr species were derived from degradation of the putative extracellular precursor protein (Mr 25 000). All of the extracellular components were found to contain O-phosphoserine. No radioactively labelled component with an Mr greater than approx. 25 000, either an amelogenin or an enamelin, was observed in the extracellular organic matrix or in an intracellular component which subsequently was lost from the intracellular pool. The Mr of the highest Mr protein or class of proteins is calculated to be approx. 22 000-26 000 when standard proteins are used as markers, but only 15 000-18 000 when using the CNBr peptides of alpha 1 chains of rat tail tendon collagen as markers.

Morphological studies on the distribution of enamel matrix proteins using routine electron microscopy and freeze-fracture replicas in the rat incisor

Enamel contains two categories of biochemically characterized proteins. Amelogenins are dissociated from enamel without physical disruption of the tissue whereas enamelins are obtained only when the crystallites are dissolved. Ultrastructural visualization of these proteins was attempted using routine electron microscopy and freeze-fracture replicas. Fresh, fixed, and 4.0 M guanidine-HCl-extracted samples of enamel from the secretory (young) and maturation (maturing) stages were compared. Decalcified and stained thin sections of fixed enamel revealed intercrystallite particulate material and "crystallite ghosts" which were identical to the crystallites themselves in young enamel and which corresponded to the periphery of the crystallites in maturing enamel. In contrast, 4.0 M guanidine-extracted enamel contained no intercrystallite particulate material but only "crystallite ghosts." Globular particles observed in freeze-fracture replicas of fresh and fixed enamel samples were also removed by 4.0 M guanidine extraction. Incubation of guanidine-extracted enamel with albumin and ovalbumin solutions restored the globular particles. It was concluded that amelogenins are the nonstructural, heterodispersed particulate material in the intercrystallite space. Enamelins constitute the integral template protein which initially provides for elongation of enamel crystallites. They then regulate the continuous growth in width and thickness during maturation and are progressively displaced to the periphery. The illusion that these "protein ghosts" are contained within the crystallite profile can be explained by the parallelepiped shape of the crystallite segment in thin sections.

Ameloblastic secretion and calcification of the enamel layer in shark teeth

Tooth primordia at early stages of mineralization in the sharks Negaprion brevirostris and Triaenodon obesus were examined electron microscopically for evidence of ameloblastic secretion and its relation to calcification of the enamel (enameloid) layer. Ameloblasts are polarized with most of the mitochondria and all of the Golgi dictyosomes localized in the infranuclear end of the cell toward the squamous outer cells of the enamel organ. Endoplasmic reticular membranes and ribosomes are also abundant in this region. Ameloblastic vesicles bud from the Golgi membranes and evidently move through perinuclear and supranuclear zones to accumulate at the apical end of the cell. The vesicles secrete their contents through the apical cell membrane in merocrine fashion and appear to contribute precursor material both for the basal lamina and the enameline matrix. The enamel layer consists of four zones: a juxta-laminar zone containing newly polymerized mineralizing fibrils (tubules); a pre-enamel zone of assembly of matrix constituents; palisadal zones of mineralizing fibrils (tubules); and interpalisadal zones containing granular amorphous matrix, fine unit fibrils, and giant cross-banded fibers with a periodicity of 17.9 nm. It seems probable that amorphous, non-mineralizing fibrillar and mineralizing fibrillar constituents of the matrix are all products of ameloblastic secretion. Odontoblastic processes are tightly embedded in the matrix of the palisadal zones and do not appear to be secretory at the stages investigated. The shark tooth enamel layer is considered homologous with that of other vertebrates with respect to origin of its mineralizing fibrils from the innerental epithelium. The term enameloid is appropriate to connote the histological distinction that the enamel layer contains odontoblastic processes but should not signify that shark tooth enamel is a modified type of dentine. How amelogenins and/or enamelins secreted by amelo- blasts in the shark and other vertebrates are related to nucleation and growth of enamel crystallites is still not known.

Monoclonal antibodies to different epitopes in amelogenins from fetal bovine teeth recognize high-molecular-weight components

Enamel proteins were extracted and partitioned into amelogenin and enamelin fractions. Although several attempts were made to raise monoclonal antibodies to each protein fraction, monoclonal antibodies were only obtained against the amelogenin fraction. Six monoclonal antibodies were generated, and these could be classified into three groups recognizing different epitopes by a competitive enzyme-linked immuno-absorbent assay. A model for the arrangement of the epitopes is proposed. In Western-blotting experiments, all six monoclonal antibodies recognized amelogenin components of approx. 45,000 and 60,000 daltons as well as lower molecular-weight components of 10,000 to 30,000. It is proposed that the 45,000 and 60,000 dalton components are precursors of the lower molecular-weight components.

Extraction of enamel proteins

Two multi-step extraction procedures were used to isolate matrix proteins from fetal bovine enamel. Using SDS-PAGE and gel isoelectric focusing it was concluded that extraction procedures influence the number of protein bands in the gel, their pI, apparent molecular weight and staining intensity.