Skip to main content
Skip to main content
Am J Pathol. 2009 Dec; 175(6): 2288–2298.
doi: 10.2353/ajpath.2009.090474
PMCID: PMC2789615
PMID: 19893032

Gla-Rich Protein Is a Novel Vitamin K-Dependent Protein Present in Serum That Accumulates at Sites of Pathological Calcifications

Carla S.B. Viegas,*† Sofia Cavaco,* Pedro L. Neves, Ana Ferreira,§ Alexandre João,§ Matthew K. Williamson, Paul A. Price, M. Leonor Cancela,*† and Dina C. Simes*†§
Author information Article notes Copyright and License information PMC Disclaimer

Associated Data

Supplementary Materials

Abstract

Mineralization of soft tissues is an abnormal process that occurs in any body tissue and can greatly increase morbidity and mortality. Vitamin K-dependent (VKD) proteins play a crucial role in these processes; matrix Gla protein is considered one of the most relevant physiological inhibitors of soft tissue calcification know to date. Several studies have suggested that other, still unknown, VKD proteins might also be involved in soft tissue calcification pathologies. We have recently identified in sturgeon a new VKD protein, Gla-rich protein (GRP), which contains the highest ratio between number of Gla residues and size of the mature protein so far identified. Although mainly expressed in cartilaginous tissues of sturgeon, in rat GRP is present in both cartilage and bone. We now show that GRP is a circulating protein that is also expressed and accumulated in soft tissues of rats and humans, including the skin and vascular system in which, when affected by pathological calcifications, GRP accumulates at high levels at sites of mineral deposition, indicating an association with calcification processes. The high number of Gla residues and consequent mineral binding affinity properties strongly suggest that GRP may directly influence mineral formation, thereby playing a role in processes involving connective tissue mineralization.

Extracellular matrix (ECM) calcification can be either a physiological or a pathological process depending on site and time of occurrence. Physiological ECM calcification is restricted to bone and to the hypertrophic zones of growth plate cartilage, whereas pathological or ectopic ECM calcification, defined as inappropriate biomineralization occurring in soft tissues and consisting of calcium phosphate salts that include hydroxyapatite, is an abnormal process that can occur virtually in any tissue of the body.1 However, skin, kidney, tendons, and the cardiovascular system appear particularly prone to develop this pathology.2

First considered to be a passive process occurring as a nonspecific response to tissue injury or necrosis, recent evidence now indicates that ECM calcification is a naturally occurring process that must be actively inhibited and starts to appear as soon as inhibitors are removed from the matrix.1,3,4 In a healthy organism, cells appear to synthesize natural inhibitors of mineralization that prevent ectopic calcification, which initiates when disequilibrium occurs between expression of calcification inhibitors and enhancers, emphasizing the need for a tight regulation to prevent ectopic calcifications.

Key genes known to be involved in the regulation of this complex process are those acting as calcification inhibitors such as matrix Gla protein (MGP), osteocalcin (BGP), bone sialoprotein (BSP), osteoprotegerin (Opg), and fetuin.1,3 Among those, MGP, a vitamin K-dependent protein (VKD), is widely accepted as playing a pivotal role in preventing soft tissue calcification, local mineralization of the vascular wall,5 and more recently, skin elastic fiber mineralization in pseudoxanthoma elasticum (PXE)6,7,8 and in scleroderma with and without calcinosis.9 It is also known that several factors, such as insufficient intake of vitamin K, mutations in the γ-carboxylase enzyme, and warfarin treatment, which can all induce arterial10,11,12 and skin calcifications,7,13,14,15 may act by reducing or abolishing γ-carboxylation of VKD proteins. Those pathologies have also been associated with a loss of MGP function, until now considered to be the central Gla protein for prevention of connective tissue mineralization, both in the vascular system and skin. Although many efforts have been made to understand the mechanisms controlling these abnormal calcifications, the existence of other potential, still unknown, calcification inhibitors has been suggested to explain some reported phenotypes and occurrences that are not completely justified by the presence or absence of MGP.1,16,17

We have recently identified in sturgeon a new VKD protein, Gla-rich protein (GRP), with an unprecedented high content of Gla residues and uncommonly high capacity to bind calcium, with orthologs in all taxonomic groups of vertebrates and highly conserved throughout evolution (78% identity between sturgeon and human GRP).18 GRP mRNA was found to be highly expressed in sturgeon cartilaginous tissues, and in rat skeletal tissues, both cartilage and bone, which invalidated the concept that this protein could be solely a specific marker for distal chondrocytes, as previously proposed by others.18 In this study we show, for the first time, that GRP is a circulating protein also expressed and accumulated in soft tissues like skin and vascular system of rats and humans and that it is clearly associated with calcification pathologies in these tissues, being highly accumulated at sites of ectopic mineral deposits. Furthermore, the extensive number of Gla residues (16 Gla residues in sturgeon and, by comparison, 15 in all mammals) and the absence of other identifiable functional domains, together with our in vivo and in vitro evidence for a high mineral binding affinity, strongly suggest that GRP might be a potent physiological modulator of soft tissue calcification, acting by directly influence mineral formation and or recruitment, and an important new player in the complexity of phenotypes involving connective tissue mineralization, whose mechanisms and regulatory pathways remain to be fully understood.

Materials and Methods

Biological Material

This study was approved by the Faro Hospital and Lisbon Central Hospital ethics committee. We included in our study patients with stage 5 chronic kidney disease who underwent surgery for arteriovenous fistula creation. A sample of the radial artery wall was collected at the time of surgery from each patient. Calcified and noncalcified carotid samples were also collected at autopsy. Skin biopsies were taken under local anesthesia from the affected skin of PXE, dermatomyositis with calcinosis, and scleroderma with calcinosis (lateral neck or axilla) patients. All patients exhibited clinical signs and were diagnosed for the corresponding pathology. Control skin biopsies were obtained from forearm regions of volunteer healthy subjects. Human blood was collected from volunteer healthy subjects by venipuncture at Faro Hospital. Informed consent was obtained from all participants.

Pig ears were obtained from the local slaughterhouse, immediately frozen for transport, and kept at −80° until further processing. Rat skin and blood samples were obtained from Mus musculus specimens maintained at the University of Algarve animal facilities.

Gene Expression by Quantitative Real-Time Polymerase Chain Reaction

Total RNA was extracted from rat adult tissues (including bony, cartilaginous, and major soft tissues) as described.19 One microgram of total RNA was treated with RQ1 RNase-free DNase (Promega, Madison, WI) and reverse-transcribed at 37°C with MMLV-RT (Invitrogen, San Diego, CA) using specific reverse primers RnGRP1R (5′-CACTCAAAAACAAGACAAAGCAAACATCCG-3′), RnGAPDH_RT1R (5′-GAAGACGCCAGTAGACTCCACGACAT-3′) and RnHPRTI_RT1R (5′-CACAAGGGAAGTGACAATCTACCTGACG-3′). Quantitative real-time polymerase chain reaction (qPCR) was performed with an iCycler iQ apparatus (Bio-Rad, Amadora, Portugal), using primer sets RnGRP1F (5′-TCCTTCCTACCTCTACAACCGCCAAAA-3′)/RnGRP1R to amplify rat GRP, RnGAPDH_RT1F (5′-CGGCAAGTTCAACGGCACAGTCAAG-3′)/RnGAPDH_RT1R to amplify rat glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and RnHPRTI_RT1F (5′-AAATGTCTGTTGCTGCGTCCCTTTTGAT-3′)/RnHPRTI_RT1R to amplify rat HPRTI. PCR reactions, set up in duplicates, were performed as previously described18 using Absolute QPCR SYBR green fluorescein mix (ABgene, Epsom, UK). Fluorescence was measured at the end of each extension cycle in the FAM-490 channel and melting profiles of each reaction were performed to check for unspecific product amplification. Levels of gene expression were calculated using the comparative method (ΔΔCt) and normalized using gene expression levels of GAPDH or HPRTI housekeeping genes. Gene expression in lung was set to 1 and used as reference for relative expression in other tissues. qPCR was performed in quadruplicates and a normalized SD was calculated.

Histological Sample Preparation

Samples were collected as previously described18 and included either in paraffin or in Historesin Plus (Leica Microsystems, Lisbon, Portugal), according to the manufacturer’s instructions. Mineral deposits were detected with silver nitrate (Sigma-Aldrich, Taufkirchen, Germany) by the von Kossa method, and physiological structures were identified by counterstaining with hematoxylin and eosin or toluidine blue.20

In Situ Hybridization

A 417-bp fragment of rat GRP cDNA (spanning from nucleotide 417 to the 3′ end) cloned in pCRII-TOPO was either linearized with ApaI and transcribed with SP6 RNA polymerase to generate an antisense riboprobe or linearized with KpnI and transcribed with T7 RNA polymerase to generate a sense riboprobe. A 364-bp fragment of the human GRP cDNA (spanning from nucleotide 459 to 822 according to EST sequences retrieved from GenBank sequence data base and previously identified as GRP),18 amplified by PCR with HsGRPis2F (5′-CATCCTATCTCTACAACCGCCACC-3′) and HsGRPis1R (5′-TTCAGCGTTTTTATTTGTAAGCCATA-3′) primers and genomic DNA, and cloned in pCRII-TOPO, was either linearized with KpnI and transcribed with T7 RNA polymerase to generate an antisense riboprobe or linearized with ApaI and transcribed with SP6 RNA polymerase to generate a sense riboprobe. Probes were then labeled with digoxigenin using RNA labeling kit (Roche, Mannheim, Germany) according to the manufacturer’s instructions. RNA in situ hybridization was performed on paraffin sections of rat and human tissues with digoxigenin-labeled antisense riboprobes, as previously described.18 Briefly, sections were digested with 40 μg/ml proteinase K (Sigma) in 1X phosphate-buffered saline containing 0.1% Tween 20 (Sigma) for 30 minutes and then hybridized at 68°C overnight in a humidified chamber. After hybridization, sections were washed and the signal revealed with the alkaline phosphatase-coupled antidigoxigenin-AP antibody (Roche) and nitro blue tetrazolium/5-bromo-4-chloro-3-indolyl phosphate substrate solution (Sigma). Negative controls for GRP mRNA detection were performed with sense probes.

Production of Polyclonal Rabbit Antibody (CTerm-GRP) against GRP

Affinity-purified rabbit polyclonal antibody against GRP was obtained from SDI- Strategic Diagnostics (Newark, DE), using for immunization a synthetic amino acid peptide corresponding to the C terminus of rat GRP (RQWHYDGLYPSYLYNRQNI), synthesized by NeoMPS, Inc. (San Diego, CA), purified to 95% purity, and conjugated to keyhole limpet hemocyanin. A cysteine residue was introduced at the N terminus of the peptide for binding to keyhole limpet hemocyanin. The affinity purified antiserum was termed CTerm-GRP.

Protein Extraction and Detection from Noncalcified Mammalian Tissues

Pig and rat skin (dermis and epidermis) and human blood vessels were cleaned from fat tissue, lyophilized, and reduced to fine powder. From the calculated weight a 10-fold excess (w/v) of 4 mol/L guanidine HCl (Sigma-Aldrich) extraction solution was added with vigorous stirring at 4°C for 24 hours, and the extracted material was separated by centrifugation for 10 minutes at 10000 × g. A portion of these crude guanidine extract was dialyzed against 50 mmol/HCI, using 3500 molecular weight tubing (Spectra-Por 3, Spectrum, Gardena, CA) with four changes of medium over 2 days and analyzed for the presence of GRP by Western blotting using the purified CTerm-GRP antibody. Rat GRP was further isolated from the crude guanidine HCl extract by reverse-phase high performance liquid chromatography as previously described.18 Resulting fractions were analyzed for the presence of GRP and Gla-containing proteins by dot blot using the CTerm-GRP and M3B (American Diagnostica, Stamford, CT) antibodies, respectively.

For further isolation, pig guanidine HCl extract was incubated with 0.1% hydroxyapatite (Calbiochem, San Diego, CA) for 24 hours at 4°C, with constant rotation. After incubation, hydroxyapatite was separated from the crude extract by centrifugation for 10 minutes at 10000 × g. Hydroxyapatite was further cleaned by washing twice with 6 mol/L guanidine HCl for 1 hour and twice with distillated water for 30 minutes at room temperature with constant stirring. The resulting hydroxyapatite powder was demineralized using a 10-fold excess of 10% formic acid for 4 hours at 4°C with vigorous stirring, as described for bone demineralization18,21 and further dialyzed against 50 mmol/L HCl as described above. Aliquots of the formic acid dialyzed extract were analyzed by Western blotting using the purified CTerm-GRP antibody.

Electrophoresis and Western Blotting

Aliquots of total protein were fractionated into a 4 to 12% gradient polyacrylamide precast gel containing 0.1% sodium dodecyl sulfate (NuPage, Invitrogen), and protein profile revealed by staining the gel as described.18,21 Transfer onto nitrocellulose membranes (Amersham Biosciences, Carnaxide, Portugal) and protein immunodetection was performed as described previously.21,22 GRP protein was detected by incubating blots overnight with 5 μg/ml anti-CTerm-GRP antibody in 5% (w/v) nonfat dried milk powder in Tris-buffered saline/Tween 20 (15 mmol/L NaCl, 10 mmol/L Tris-HCl buffer, pH 8, 0.05% Tween 20) as primary antibody and alkaline phosphatase-labeled goat anti-rabbit IgG antibody (Sigma-Aldrich) diluted 1:30,000 in Tris-buffered saline/Tween 20, as secondary antibody. Visualization of immunoreactive bands was achieved using nitro blue tetrazolium/5-bromo-4-chloro-3-indolyl phosphate substrate solution (Calbiochem) as described.21,22

Dot Blotting

Samples of total protein were applied onto a nitrocellulose membrane (Invitrogen) as previously described.22 GRP detection was performed using the purified CTerm-GRP antibody as primary antibody and alkaline phosphatase-labeled goat anti-rabbit IgG (Sigma-Aldrich), as secondary antibody. Gla-containing proteins were detected using 5 μg/ml of the purified monoclonal M3B antibody (American Diagnostica) as primary antibody and alkaline phosphatase-labeled goat anti-mouse IgG as secondary antibody.

Immunolocalization

Immunohistochemical staining experiments were performed on paraffin and Historesin Plus-embedded tissue sections as described.20,21 Briefly, the endogenous peroxidase activity was blocked with 3% H2O2 in Coons buffer (CBT: 0.1 mol/L Veronal, 0.15 mol/L NaCl, 0.1% Triton X-100) for 15 minutes. Nonspecific antibody binding was blocked with 0.5% (w/v) bovine serum albumin directly after peroxidase activity blocking, or after treatment with chondroitinase ABC (Sigma-Aldrich) (0.1 U/ml) for 1 hour at 37°C. Incubation with the purified polyclonal CTerm-GRP or the M3B antibodies (5 μg/ml and 5 μg/ml, respectively, diluted in CBT), as primary antibodies, was performed overnight in a humidified chamber at room temperature. Peroxidase activity was detected using as secondary antibodies the peroxidase-conjugated goat anti-rabbit and anti-mouse IgG, respectively (Sigma- Aldrich), and 0.025% 3,3-diaminobenzidine (Sigma- Aldrich) as described.20,21 Negative controls consisted in the substitution of the primary antibody with both normal rabbit serum and CBT. Counterstaining was performed with hematoxylin and eosin or toluidine blue.

Depletion of High Abundant Serum Proteins and GRP Detection

Human and rat sera were prepared as described,23,24 quick-frozen in 1-ml aliquots on dry ice, and stored at −80°C until use. Depletion of the high abundant proteins was performed for each 1 ml of human and rat serum aliquots using the ProteoMiner kit (Bio-Rad), according to the manufacturer’s instructions. Five microliters of each of the eluted fractions was applied onto a nitrocellulose membrane (Invitrogen). GRP detection was performed with the purified CTerm-GRP antibody as described in dot blotting.

Results

The GRP Gene Is Expressed Both in Skeletal and in Soft Tissues

We have recently shown that GRP in sturgeon is expressed exclusively by cartilage-associated cells, while in rat it was also expressed by bone cells. However, our in silico analysis further suggested that GRP could be present in other nonskeletal tissues.18 To continue these studies and establish the pattern of GRP tissue distribution, we have determined its spatial levels of expression in adult rat skeletal and soft tissues. Expression of GRP was detected by real-time PCR in all 16 tissues analyzed, the most significant levels being observed in cartilage- and bone-containing tissues such as skull, inner ear, tail, outer ear, and nose (see Supplemental Figure S1 at http://ajp.amjpathol.org). However, the presence of higher levels of expression in outer ear and nose, a result confirmed when using GAPDH to normalize GRP gene expression (results not shown), could not be easily explained. To further elucidate this question and clearly establish the identity of GRP-expressing cells, we performed in situ hybridization in sections from all rat tissues expressing GRP. Interestingly, in sections of outer ear (Figure 1) and nose (results not shown) GRP was found to be highly expressed in skin and its appendages, at the levels of epidermis and dermis. In rat outer ear skin, GRP mRNA was detected in epidermis (Ep) (Figure 1, A and D) and in all main structures housed in the dermis (De); in the fibroblasts (Fb) that compose the reticular layer of the dermis (Figure 1, B and D); in the hair follicles (HF) (Figure 1, B and C); and in sweat (SwG) (Figure 1A) and sebaceous (SG) (Figure 1, B and C) glands. Negative controls were performed through hybridization of consecutive sections with GRP sense probe (Figure 1E), confirming the specificity of the signal observed in the above described structures. Figure 1F shows GRP positive expression in an artery from the dermis of rat outer ear, with higher expression found in vascular smooth muscle cells (VSMC) of the tunica intima (TI), and lower expression in the tunica media. In rat outer ear, GRP mRNA is also expressed by elastic cartilage (EC) chondrocyte cells (Cd) from all stages of differentiation (Figure 1G).

An external file that holds a picture, illustration, etc. Object name is zjh0120983170001.jpg

Rat GRP gene is highly expressed in nonskeletal tissues. Sites of gene expression were determined by in situ hybridization with digoxigenin-labeled antisense probes in outer ear paraffin sections, and signal was revealed with alkaline phosphatase-coupled antidigoxigenin-AP antibody and nitro blue tetrazolium /5-bromo-4-chloro-3-indolyl phosphate substrate solution, yielding a characteristic blue color. GRP is highly expressed in the skin and its appendages in both epidermis (Ep, A and D) and dermis (De, A and D). Within the dermis GRP is detected in the fibroblasts (Fb, B and D), hair follicles (HF, C), and sebaceous (SG, B and C) and sweat glands (SwG, A). In blood vessels, GRP is detected mainly in vascular smooth muscle cells (VSMC) of the tunica intima (TI, F). In the elastic cartilage (EC) composing the outer ear, GRP is detected in chondrocyte (Cd) cells (G). Negative control performed through in situ hybridization with GRP sense probe is presented in E. Magnifications: A, D, E, ×10; B, C, F, G, ×20.

These high levels of GRP expression found in both skin and its appendages, as well as in the elastic cartilage, which together constitute the main structures present in rat nose and in outer ear, can explain the highest GRP levels obtained in these tissues by qPCR (see Supplemental Figure S1 at http://ajp.amjpathol.org). The results presented here, together with our previous findings, clearly indicate that GRP is present in all types of cartilage. Also the presence of GRP mRNA in blood vessels could explain the levels of GRP obtained by qPCR in all irrigated organs.

In Soft Tissues, GRP Accumulates in Skin and in the Vascular System

Specific GRP rabbit polyclonal antibodies (CTerm-GRP antibody) were produced using a 19-amino-acid synthetic peptide homologous to the C-terminal of rat GRP, and cross-reactivity against GRP from other species was checked by Western blot. The antibody was validated by Western blot using purified sturgeon GRP18; a crude rat skin extract, prepared using 4 mol/L guanidine HCl; a crude pig skin extract, obtained as described above, followed by a direct incubation with hydroxyapatite from which proteins with affinity for this mineral phase were eluted; and a crude guanidine extract of medium-size human blood vessels with no apparent calcifications and collected at autopsy. In all cases, a single positive immunoreactive band, with a migration profile similar to that of sturgeon GRP, was obtained (see Supplemental Figure S2A at http://ajp.amjpathol.org),18 indicating that GRP is not only expressed but also accumulated in skin and/or in vascular system in sufficient amounts to be detected from a crude extract. Furthermore, our data provided evidence that mammalian GRP shows a clear binding affinity for hydroxyapatite.

To further confirm the γ-carboxylation status of the protein, we further purified rat GRP from the skin guanidine crude extract using reverse-phase high performance liquid chromatography as previously described.18 Individual peak fractions were analyzed for the presence of GRP by dot blot using the CTerm-GRP antibody (results not shown) and the GRP peak containing fraction was then further analyzed for the presence of Gla residues using the anti-Gla M3B antibody. Positive M3B antibody immunoreaction was obtained by dot blot for rat skin GRP (see Supplemental Figure S2B (rGRP) at http://ajp.amjpathol.org),18 using as positive control, the purified sturgeon GRP protein (see Supplemental Figure S2B (StGRP) at http://ajp.amjpathol.org)18 whose γ-carboxylation status was previously confirmed by amino acid analysis.18 These results provided additional evidence for the presence of γ-carboxylated residues in rat GRP isolated from skin.

Spatial Profile of GRP Accumulation in Rat Tissues

Sites of GRP accumulation were determined by immunohistochemistry in paraffin sections of several adult rat tissues, using the CTerm-GRP antibody. In skeletal tissues, GRP antigen was mainly detected inside cartilaginous (Figure 2, A and B) and bony cells (Figure 2C), following a pattern similar to that previously observed for GRP mRNA.18,25 In the rat rib, GRP was localized in mature (MC), columnar (CC), hypertrophic (HC) (Figure 2A), and immature (IC) (Figure 2B) chondrocytes, as well as in compact bone osteocytes (Oc) (Figure 2C). In addition, when we performed a chondroitinase pretreatment of the sections, we were able to detect GRP in the extracellular matrix of calcified hypertrophic cartilage and in the matrix surrounding the rib cartilage (results not shown), in concordance with previously reported results.25 In skin, GRP accumulation also followed the pattern of its mRNA distribution. It accumulated in epidermis (Ep) (Figure 2, D and E), within those fibroblasts (Fb) responsible for synthesis of dermis collagen elastic fibers (Figure 2E), and in skin appendages, eg, hair follicles (HF) (Figure 2D), sebaceous (SG) (Figure 2D), and sweat (results not shown) glands. In the elastic cartilage (EC) of the outer ear, GRP was mainly detected inside the chondrocytes (Cd) (Figure 2F). The absence of signal in the extracellular matrix was probably due to lack of chondroitinase pretreatment of these tissue sections. In addition to cartilage, bone and skin, the vascular system also appears to be one of the primary sites of GRP accumulation. Small and medium blood vessels from several irrigated tissues showed high levels of GRP accumulated in their walls, as can be observed in sections of rat outer ear (Figure 2, G and H), heart (Figure 2I), and kidney (Figure 2J).

An external file that holds a picture, illustration, etc. Object name is zjh0120983170002.jpg

Rat GRP is highly accumulated in cartilage (A, B, F), bone (C), skin and its appendages (D and E), and in the vascular system (G–J) as determined by immunohistochemistry using the CTerm-GRP primary antibody and peroxidase-conjugated goat anti-rabbit IgG as secondary antibody. Peroxidase activity was visualized using 3,3-diaminobenzidine substrate yielding a brown color. A and B: Sites of GRP accumulation in sections of rib cartilage showing protein detection inside chondrocytes in all stages of maturation: columnar chondrocytes (CC), mature chondrocytes (MC), hypertrophic chondrocytes (HC), and immature chondrocytes (IC). C: GRP detection in bone sections showing protein inside osteocytes (Oc). D–F: GRP detection in outer ear sections showing protein accumulation in skin epidermis (Ep) and dermis (De, D and E) and its appendages: hair follicles (HF, D), sebaceous glands (SG, D), and dermal fibroblast (Fb, E). In addition, GRP was detected in chondrocytes (Cd) of the elastic cartilage (EC, F). G–J: GRP accumulation in the vascular system in sections of outer ear (G and H), heart (I), and kidney (J), showing GRP highly accumulated in the walls of blood vessels (Bv) and capillaries (Cp). TM, tunica media; TI, tunica intima; EL, elastic lamina. Magnifications: A–E and J, ×10; F–H and I, ×20.

GRP Accumulated in Skin and in Vascular Tissues Is γ-Carboxylated

The pattern of distribution of Gla-containing proteins was compared, in selected tissues, to that of GRP accumulation through immunohistochemistry analysis. Studies were performed on consecutive sections of rat outer ear (Figure 3, A–C) and rib (Figure 3D) tissues using a monoclonal antibody that specifically recognizes Gla residues, (M3B antibody). Until now, MGP was the only known Gla protein that was associated with skin elastic fibers, although mainly in pathological situations involving ectopic calcifications.6 MGP was also the only known Gla containing protein accumulated in cartilage, although with a restricted pattern of distribution. We have previously identified distinct patterns of GRP and MGP expression in the cartilaginous cells of rat rib, clearly showing that MGP is not expressed by hypertrophic chondrocytes of the central zone of hyaline cartilage.18

An external file that holds a picture, illustration, etc. Object name is zjh0120983170003.jpg

Gla proteins detection co-localize in rat skin and cartilage with GRP accumulation. Immunolocalization of Gla proteins was performed using the Gla-specific monoclonal antibody M3B, and peroxidase-conjugated goat anti-mouse IgG as secondary antibody, in sections of rat outer ear (A–C) and rib (D), showing a positive co-localization (brown) with GRP, presented in Figure 2. De, dermis; Ep, epidermis; Fb, fibroblasts (arrowheads); SG, sebaceous gland; and HF, hair follicle. CHC, cartilage of the hypertrophic zone. Black star is located within the calcified cartilage. Magnification, ×10.

The presence of Gla proteins within skin and cartilage tissue sections was confirmed using the M3B antibody. In rat skin, Gla proteins were detected in epidermis (Ep, Figure 3, A and B), dermis (De), fibroblasts (Fb) of elastic fibers (Figure 3, A–C), hair follicles (HF, Figure 3B), and sebaceous (SG, Figure 3C) and sweat (results not shown) glands. In cartilage, Gla proteins were detected in all stages of chondrocyte differentiation, which included the hypertrophic chondrocytes (CHC) of the central zone (black star) where GRP is the only known Gla protein expressed (Figure 3D). Although we cannot exclude the possibility that, at these sites, other Gla containing proteins in addition to GRP are being recognized by the M3B antibody, the perfect co-localization observed between M3B and CTerm-GRP antibody immunolocalizations, together with our positive dot blot result showing the presence of Gla residues in GRP from rat skin obtained following reverse-phase high performance liquid chromatography (see Supplemental Figure S2B at http://ajp.amjpathol.org),18 strongly suggests that GRP is in fact γ-carboxylated in these tissues.

GRP Is Also Expressed in Normal Human Skin and in Vascular Tissues

The presence of high levels of GRP in rat skin and vascular system raised the question of whether GRP had a similar pattern of accumulation and expression in human tissues. Human GRP mRNA localization and protein accumulation were detected in paraffin embedded sections of healthy human skin by in situ hybridization (Figure 4, A–C) and immunohistochemistry using the previously validated CTerm-GRP antibody (Figure 4, D–F). The pattern of human GRP accumulation in skin (Figure 4, D–F) follows the pattern of mRNA localization (Figure 4, A–C), which is similar to the results we obtained for rat GRP (Figure 1, A–C). In human skin, GRP is detected at the epidermis and dermis (Figure 4, A and D) levels, being highly expressed and accumulated in fibroblasts (Fb) of both papillary and reticular dermis (Figure 4, A and D), in hair follicles (HF, Figure 4, B and E), in sweat (SwG) (Figure 4, C and F) and sebaceous (results not shown) glands, and in small blood vessels and capillaries (Cp) that irrigate the skin (Figure 4A).

An external file that holds a picture, illustration, etc. Object name is zjh0120983170004.jpg

GRP is present in human skin (A–F) and vascular system (G–I). A–C: Sites of GRP expression determined by in situ hybridization with digoxigenin-labeled antisense probes (blue) in healthy human skin. D–F: Sites of GRP accumulation determined by immunohistochemistry with the CTerm-GRP primary antibody and peroxidase-conjugated goat anti-rabbit IgG as secondary antibody (brown), in healthy human skin. D–F show consecutive sections of A–C. Human GRP is detected in skin at the levels of epidermis (Ep) and dermis (De, A and D), small capillaries (Cp, A), and skin appendages (B, C, E, F), similarly to what is observed for rat GRP (Figures 1 and and2).2). Fb, fibroblast; HF, hair follicle; SwG, sweat gland. G–I: GRP accumulation in noncalcified human carotids showing GRP in vascular smooth muscle cells (VSMC) located in the tunica media (TM, G and H), and in small blood vessels (Bv) of the tunica adventitia (TA, G and I). Magnifications: A–G, ×10; H and I, ×20.

After showing by Western blot that GRP was present in human vascular system (see Supplemental Figure S2A at http://ajp.amjpathol.org),18 the detailed pattern of GRP accumulation was evaluated in carotid samples obtained at autopsy. Samples were embedded in paraffin and analyzed by immunohistochemistry using the CTerm-GRP antibody (Figure 4, G–I). Histomorphological evaluations were performed by staining consecutive sections with hematoxylin and eosin, and the presence of mineral deposits was monitored by von Kossa staining. At sites showing normal histomorphological features and absence of calcification (results not shown), GRP was found mainly associated with vascular smooth muscle cells (VSMC) of the tunica media (TM, Figure 4, G and H), and in small blood vessels (Bv) irrigating the tunica adventitia (TA, Figure 4, G and I). The apparent lack of GRP in the extracellular matrix could be due to the absence of protein accumulation in normal, non-pathological conditions, as also described for MGP in normal blood vessels.5

GRP Is Highly Accumulated at Sites of Ectopic Calcification in Human Skin and in the Vascular System

The in vivo calcium mineral binding properties of GRP were originally detected by our results in sturgeon, since the protein was found to accumulate in the mineralized branchial arches, being extracted using a selective acid demineralization procedure.18 We now show, using an in vitro assay, that pig GRP has the ability to bind to hydroxyapatite crystals, suggesting the possibility of GRP being associated with ectopic mineralization of connective tissue, either in skin or in vascular system or both. To address this question, the CTerm-GRP antibody was used for GRP immunolocalization in human samples derived from patients diagnosed with skin and vascular system-associated calcification pathologies (Figures 5 and and6,6, respectively). The presence of mineral deposits in samples from patients diagnosed with dermatomyositis with calcinosis (Figure 5, A–C) and PXE (Figure 5, D–F) were identified by von Kossa staining (Figure 5, C and F), and presence of GRP accumulated at the same sites was detected by immunohistochemistry (Figure 5, A, B, D, and E). Consecutive sections incubated in the same conditions but without the CTerm-GRP antibody (NC insets in Figure 5, A and D) were used as negative controls. GRP was found to be highly accumulated at sites of calcification in both pathological situations, either when massive calcified material was deposited in the reticular dermis (Figure 5, A and B) or when small calcified spots were diffused along the elastic fibers (Figure 5, D and E). Results clearly show that GRP is associated with the mineralized material since mineral staining and GRP accumulation are clearly co-localized.

An external file that holds a picture, illustration, etc. Object name is zjh0120983170005.jpg

GRP is highly accumulated at sites of pathological calcification in human skin diagnosed with dermatomyositis with calcinosis (DC) (A–C) and PXE (D–F). Sites of GRP accumulation were determined by immunohistochemistry using the CTerm-GRP primary antibody and peroxidase-conjugated goat anti-rabbit IgG as secondary antibody (brown pointed by arrows, A and B, D and E). Mineral detection was achieved by staining consecutive sections of DC and serial sections of PXE with silver nitrate by the von Kossa staining method (open arrows, C and F, respectively). In both pathological situations, GRP is co-localized with sites of mineral deposition, either in DC samples when massive mineral deposits are present (A and B) or in PXE samples where disperse small mineral spots are detected (D and E). A–C were counterstained with toluidine blue and F with hematoxylin and eosin. Negative controls were performed by omitting the CTerm-GRP antibody in consecutive sections of DC (NC, inset in A) and PXE (NC, inset in D) samples. Magnification, ×10.

An external file that holds a picture, illustration, etc. Object name is zjh0120983170006.jpg

GRP is highly accumulated in the human vascular system at sites of pathological calcification of human arteries from both CDK patients (A–D) and postmortem samples (pM) (E–H). Sites of GRP accumulation were determined by immunohistochemistry using the CTerm-GRP primary antibody and peroxidase-conjugated goat anti-rabbit as secondary antibody (brown) (B, D, F, H), and mineral detection was achieved by staining consecutive sections of both CDK and pM with silver nitrate by the von Kossa staining method (A and C and E and G, respectively). In CDK samples GRP is highly accumulated at sites showing mineral deposition (A and B), when compared with non-calcified areas (C and D). In pM samples GRP is co-localized with sites of disperse (E and F) and massive (G and H) calcification. E–H were counterstained with toluidine blue. Magnification, A–G, ×10.

Arterial calcification is a very common process that normally progresses with age, and in fact, up to 95% of men and women at autopsy show coronary artery calcification regardless of death cause.3 Also, among the normal population, patients with chronic kidney disease (CDK) are a high risk group for development of vascular calcifications.26 The pattern of GRP accumulation was thus studied in a group of patients with CDK (Figure 6, B and D) and in a group of samples collected at autopsy from vascular tissue showing ectopic calcifications (Figure 6, F and H), as detected by von Kossa staining (Figure 6, A, C, E, and G). In both groups, the calcification observed by von Kossa staining was at the media level, characterized by the absence of macrophages and lipids.

Our results provided clear evidence that GRP was highly accumulated at sites of medial calcification, either in mildly calcified arteries, showing disperse mineral deposits (Figure 6, B and F), or in extensive and advanced lesions (Figure 6H). In cases where calcification was homogenously dispersed along the fibers of the tunica media (Figure 6A), GRP was detected both inside the vascular smooth muscle cells and in the extracellular matrix (Figure 6B), in contrast with its almost absence in noncalcified areas (Figure 6, C and D). When calcification was localized, either as disperse (Figure 6E) or massive (Figure 6G) mineral deposits, GRP was easily identified as co-localizing with the mineral (Figure 6, F and H). This high accumulation of the protein at sites of mineral deposits, in contrast with its absence in the extracellular matrix detected in normal situations, reveals that GRP is definitively associated with the processes of abnormal calcification in the vascular system.

Discussion

Our recent discovery of GRP, a new VKD protein originally purified from sturgeon mineralized cartilage and presenting highly conserved orthologs in all vertebrate groups, an unprecedented high density of Gla residues, and a strong association with cartilaginous tissues, lead us to suggest a function for GRP in the regulation of calcium in the extracellular matrix environment.18 Although in sturgeon GRP was mainly associated with cartilaginous tissues, in rat we have previously shown that GRP was also expressed in bone cells.18 In the present report we show that GRP in rat and human is also expressed and accumulated in the skin and in the vascular system. Our results of immunohistochemistry and Western blot were performed using a newly developed antibody that was validated, in addition to sturgeon GRP, for all mammalian species used, which included rat, pig, and human. Moreover, we were able to confirm that rat GRP is γ-carboxylated using a Gla-specific antibody, reinforcing the previously proposed theory that GRP should be γ-carboxylated in all species.18

The high levels of GRP found in the skin, although surprising, cannot be considered as unexpected. Since the late 1970s, a relation between Gla proteins and skin has been suggested. The presence of γ-carboxylase activity in both epidermal and dermal tissue and the accumulation of non-carboxylated precursor proteins in both dermal and epidermal microsomes after warfarin treatment,17 together with the reported occurrence of Gla-containing proteins in pathological depositions of calcified material in skin of patients suffering from scleroderma and dermatomyositis,27,28 pointed to the presence of a still unknown Gla protein localized in skin, with a role in skin calcium metabolism and involved in the regulation of the calcification process.17 In fact, the strongest reported evidences for the presence of Gla-containing proteins in skin emerged from studies involving skin pathological situations with ectopic mineralization.

Human skin is an organ containing the complete biochemical machinery to develop calcification, as shown by the high abundance of reported pathologies ranging from mild to severe skin calcifications (dermatomyositis, scleroderma, PXE, Keutel syndrome, among others), although the molecular mechanisms behind this ectopic calcifications have only started to be elucidated. The reported effect of warfarin in these skin pathologies is still controversial. While sometimes a profound and rapid decrease of the calcified lesions with complete disappearance has been reported,29,30 more often other authors have described a pathological effect of warfarin in the skin30,31 and related it to the inhibition of γ-carboxylation of local Gla-containing proteins. Until now, the identity of this skin Gla protein has not been clearly elucidated, but the recent and strong association of MGP with several skin pathologies,6,7,8,9,32 and in particularly to the presence of different processed forms of this protein,7,14,32 supports and points to an essential role of MGP in the prevention of these skin calcifications.

PXE, an autosomal recessive disease characterized by a progressive mineralization of connective tissue resulting in skin, arterial, and eye disease, can be divided into the classical PXE, caused by mutations in the ABCC6 gene, which encodes an ABC transporter protein,13 and the so called PXE-like, identified more recently, as being caused by missense mutations in the γ-glutamyl carboxylase (GGCX) gene.15,33 Either by direct reduction of carboxylation, caused by reduced GGCX activity,14,15 or by a deficiency in the reduced form of vitamin K, an obligatory cofactor for carboxylation, postulated to be transported from the liver into circulation and peripheral tissues by the ABCC6 transporter,34 it is now assumed that ectopic mineralization, the pathological hallmark of PXE clinical manifestations, is caused by a local tissue deficiency in vitamin K-dependent protein carboxylation. Again, functional MGP has being assumed as having an essential role in preventing aberrant mineralization.6,8,13,14

The discovery of GRP in skin and, moreover, its strong association with abnormal calcifications in both PXE and dermatomyositis patients, shown by the high accumulation of protein co-localized with the mineral deposits, strongly suggest that GRP may be the unknown skin Gla protein that remained elusive until now, and a new important player in modulating skin ectopic mineralization. Although MGP is widely accepted as one of the strongest physiological inhibitors of soft tissue calcification known to date, and its association with skin mineralization has been proved, it was never clearly established whether MGP is produced/accumulated in normal skin, as it is in cartilage, bone matrix, and arterial walls.5 On the contrary, GRP is systemically synthesized and accumulated in skin, as shown by the high levels of mRNA and protein found both in rat and human, which suggests that GRP is a naturally occurring agent affecting ectopic skin calcification. Moreover, MGP-deficient knockout mice manifest extensive calcification of the aorta and articular cartilage, dying by artery rupture within the first 2 months of age.35 However, there is no reported phenotype relating it to skin calcifications. Furthermore, Keutel syndrome, which is characterized by loss-of-function mutations in the MGP gene, result in abnormal calcification of the soft tissues with diffuse cartilage calcification and short terminal phalanges. Other findings include peripheral pulmonary stenosis, hearing loss, dysmorphic facies and mental retardation,36 but abnormal skin changes are not reported in patients with Keutel syndrome. However, a new variant of Keutel syndrome characterized by a new MGP mutation recently identified in a consanguineous family, showed overlapping features of cutis laxa.37 Whether loss of MGP function can explain all of the clinical manifestations observed within these patients, in particular the skin alterations, was further discussed and questioned, and other possibilities such as additional unidentified mutations in other genes were suggested.16

Besides skin, we found GRP highly accumulated in small and medium size blood vessels in rat, and we were able to confirm its presence in the human vascular system, both by immunohistochemistry and Western blot. Furthermore, we show high accumulation of the protein co-localized with mineral deposits in situations of massive and disperse mineralization, associated with media calcification. Although the presence of Gla proteins in the vascular system is known, as is the case of MGP and Gas6, our discovery of a new Gla protein also present in the same tissues raises many questions about previously reported work describing phenotypes based solely on general interference in γ-carboxylation mechanisms.

Our work underlines the need for a strict re-evaluation of the role of each target Gla protein involved in vascular calcification and the elucidation of their corresponding specific functions. It has been shown that inhibiting extrahepatic γ-carboxylation by warfarin induces vascular media calcification in rats,10,38 consistent with the finding that in human, high vitamin K intake is associated with low aorta calcification39 and beneficial effects on the elastic properties of the vessel wall.40 Moreover a high vitamin K intake can reverse pre-existing arterial calcification in rats.11 As vitamin K is an essential cofactor in the γ-carboxylation reaction catalyzed by the γ-glutamyl carboxylase, and warfarin prevents γ-carboxylation, interfering with the VKOR enzyme, responsible for the vitamin K recycling, it is conceivable that some of the effects observed with warfarin and/or vitamin K administration are due to impairment and/or improvement of GRP function. Although emerging in vitro and whole animal data suggest that warfarin may induce vascular calcification,4,41 always through a proposed relation with the under-carboxylation of MGP, this has not yet been well studied in humans.

In rats, MGP has been extensively shown to be a vascular calcification inhibitor, with widespread and extensive vascular calcification in the MGP knockout mice35 and phenotype rescue after restoration of MGP expression.42 However, in humans, MGP loss of function, as in Keutel syndrome, show less severe vascular calcifications, suggesting additional agents or more complex mechanisms preventing arterial calcification. The existence of other inhibitors, yet to be found, that function to prevent ECM calcification, in particular in tissues as skin, has been previously suggested.1 The structural property of GRP, with an uncommonly extensive Gla domain showing high mineral-binding affinity, its presence in normal soft tissues like skin and vascular system, and its association with ectopic mineral deposits, is consistent with a putative role for GRP as being a naturally occurring modulator of calcium availability in the ECM and thus a potential inhibitor of cardiovascular and skin calcifications, constitutively expressed, acting by directly influencing mineral formation.

The complex chemical nature of GRP, as all other VKD proteins, which are strictly dependent on their Gla residues for proper function,5,12 indicates the need of additional studies concerning the evaluation of GRP γ-carboxylation status accumulated at the mineral deposits, both in skin and blood vessels. Antibodies specific to both forms, γ-carboxylated (Gla-GRP) and non-carboxylated (Glu-GRP), are currently under development (GenoGla Diagnostics, Faro, Portugal) and will be a valuable tool for further studies on GRP function. Similar to what was suggested for MGP,12,14 Gla and Glu-GRP forms may have different patterns of accumulation, with different roles in the mineralization process, and this can be dependent on the vitamin K bioavailability in these peripheral tissues.

To access whether GRP was present in blood serum, we used the ProteoMiner kit (Bio-Rad, Amadora, Portugal) to remove the most abundant serum proteins from rat and human serum. Using this approach together with the validated CTerm-GRP antibody, we were able to detect GRP, as one of the less abundant circulating proteins present in rat and human serum (results not shown). The evidence for the presence of GRP in blood opens new perspectives for future studies aiming to establish a relationship between levels of circulating Gla and Glu-GRP and the degree of vascular and skin calcifications. We are currently developing a GRP enzyme-linked immunosorbent assay (GenoGla Diagnostics, Faro, Portugal) that will be able to differentiate the possible forms of GRP circulating in serum. This assay could be used to monitor serum GRP levels in relation with a given pathology and establish its potential use as tool suitable for diagnostic and prognostic evaluation of skin and vascular calcification risk association. Further understanding of the mechanisms and active players involved in the occurrence of pathological extracellular matrix calcification should offer a potential hope for the development of new therapeutic strategies to control these processes.

Supplementary Material

[Supplemental Material]

Acknowledgments

We thank Dr. Idalécio Bernardo, Department of Nephrology, Faro Hospital, for collecting CDK samples during surgery for arteriovenous fistula creation and to Dr. Vera Maria for blood collection at Faro Hospital.

Footnotes

Address reprint requests to Dina C. Simes, Ph.D., Centre of Marine Sciences (CCMAR), University of Algarve, Campus de Gambelas, 8005-139 Faro, Portugal, E-mail: tp.glau@semisd.

Supported in part by Centre of Marine Sciences (M.L.C. and D.C.S.), project POCTI MAR 57921 2004 (D.C.S., M.L.C., C.S.B.V.) and NIH grant HL58090 (to P.A.P.). C.S.B.V. was the recipient of Ph.D. fellowship SFRH/BD/9077/2002 from the Portuguese Science and Technology Foundation. Methods and tools described and obtained during the course of this work are included in United States priority application 61/136.315, August 27, 2008, and PCT patent application PCT/PT2009000046, August 27, 2009.

D.C.S., M.L.C., and C.S.B.V. are cofounders of GenoGla Diagnostics.

Supplemental material for this article can be found on http://ajp.amjpathol.org.

References

  • Schinke T, McKee MD, Karsenty G. Extracellular matrix calcification: where is the action? Nat Genet. 1999;21:225–229. [PubMed] [Google Scholar]
  • Giachelli CM. Ectopic calcification: gathering hard facts about soft tissue mineralization. Am J Pathol. 1999;154:671–675. [PMC free article] [PubMed] [Google Scholar]
  • Wallin R, Wajih N, Greenwood GT, Sane DC. Arterial calcification: a review of mechanisms, animal models, and the prospects for therapy. Med Res Rev. 2001;21:274–301. [PubMed] [Google Scholar]
  • Danziger J. Vitamin K-dependent proteins, warfarin, and vascular calcification. Clin J Am Soc Nephrol. 2008;3:1504–1510. [PMC free article] [PubMed] [Google Scholar]
  • Cranenburg EC, Schurgers LJ, Vermeer C. Vitamin K: the coagulation vitamin that became omnipotent. Thromb Haemost. 2007;98:120–125. [PubMed] [Google Scholar]
  • Gheduzzi D, Boraldi F, Annovi G, DeVincenzi CP, Schurgers LJ, Vermeer C, Quaglino D, Ronchetti IP. Matrix Gla protein is involved in elastic fiber calcification in the dermis of pseudoxanthoma elasticum patients. Lab Invest. 2007;87:998–1008. [PubMed] [Google Scholar]
  • Li Q, Jiang Q, Schurgers LJ, Uitto J. Pseudoxanthoma elasticum: reduced gammaglutamyl carboxylation of matrix gla protein in a mouse model (Abcc6-/-). Biochem Biophys Res Commun. 2007;364:208–213. [PMC free article] [PubMed] [Google Scholar]
  • Hendig D, Zarbock R, Szliska C, Kleesiek K, Götting C. The local calcification inhibitor matrix Gla protein in pseudoxanthoma elasticum. Clin Biochem. 2008;41:407–412. [PubMed] [Google Scholar]
  • Davies CA, Jeziorska1 M, Freemont AJ, Herrick AL. Expression of osteonectin and matrix Gla protein in scleroderma patients with and without calcinosis. Rheumatology. 2006;45:1349–1355. [PubMed] [Google Scholar]
  • Price PA, Faus SA, Williamson MK. Warfarin causes rapid calcification of the elastic lamellae in rat arteries and heart valves. Arterioscler Thromb Vasc Biol. 1998;18:1400–1407. [PubMed] [Google Scholar]
  • Schurgers LJ, Spronk HM, Soute BA, Schiffers PM, DeMey JG, Vermeer C. Regression of warfarin-induced medial elastocalcinosis by high intake of vitamin K in rats. Blood. 2007;109:2823–2831. [PubMed] [Google Scholar]
  • Schurgers LJ, Spronk HM, Skepper JN, Hackeng TM, Shanahan CM, Vermeer C, Weissberg PL, Proudfoot D. Post-translational modifications regulate matrix Gla protein function: importance for inhibition of vascular smooth muscle cell calcification. J Thromb Haemost. 2007;5:2503–2511. [PubMed] [Google Scholar]
  • Li Q, Jiang Q, Pfendner E, Váradi A, Uitto J. Pseudoxanthoma elasticum: clinical phenotypes, molecular genetics and putative pathomechanisms. Exp Dermatol. 2009;18:1–11. [PMC free article] [PubMed] [Google Scholar]
  • Li Q, Schurgers LJ, Smith AC, Tsokos M, Uitto J, Cowen EW. Co-existent pseudoxanthoma elasticum and vitamin K-dependent coagulation factor deficiency: compound heterozygosity for mutations in the GGCX gene. Am J Pathol. 2009;174:534–540. [PMC free article] [PubMed] [Google Scholar]
  • Vanakker OM, Martin L, Gheduzzi D, Leroy BP, Loeys BL, Guerci VI, Matthys D, Terry SF, Coucke PJ, Pasquali-Ronchetti I, De Paepe A. Pseudoxanthoma elasticum-like phenotype with cutis laxa and multiple coagulation factor deficiency represents a separate genetic entity. J Invest Dermatol. 2007;127:581–587. [PubMed] [Google Scholar]
  • Nanda A, Anim JT, Al-Gareeb M, Alsaleh QA. Keutel syndrome with overlapping features of cutis laxa: a new variant. Am J Med Genet A. 2006;140:1487–1489. [PubMed] [Google Scholar]
  • Boer-van den Berg MA, Verstijnen CP, Vermeer C. Vitamin K-dependent carboxylase in skin. J Invest Dermatol. 1986;87:377–380. [PubMed] [Google Scholar]
  • Viegas CS, Simes DC, Laizé V, Williamson MK, Price PA, Cancela ML. Gla-rich Protein (GRP), a new vitamin K-dependent protein identified from sturgeon cartilage and highly conserved in vertebrates. J Biol Chem. 2008;283:36655–36664. [PMC free article] [PubMed] [Google Scholar]
  • Chomczynski P, Sacchi N. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal Biochem. 1987;162:156–159. [PubMed] [Google Scholar]
  • Ortiz-Delgado JB, Simes DC, Viegas CS, Schaff BJ, Sarasquete C, Cancela ML. Cloning of matrix Gla protein in a marine cartilaginous fish. Prionace glauca: preferential protein accumulation in skeletal and vascular systems. Histochem Cell Biol. 2006;126:89–101. [PubMed] [Google Scholar]
  • Simes DC, Williamson MK, Delgado JBO, Viegas CSB, Price PA, Cancela ML. Purification of Matrix Gla protein (MGP) from a marine teleost fish. Argyrosomus regius: calcified cartilage and not bone as the primary site of MGP accumulation in fish. J Bone Min Res. 2003;18:244–259. [PubMed] [Google Scholar]
  • Simes DC, Williamson MK, Schaff BJ, Gavaia PJ, Ingleton PM, Price PA, Cancela ML. Characterization of osteocalcin (BGP) and matrix Gla protein (MGP) fish specific antibodies: validation for immunodetection studies in lower vertebrates. Calcif Tissue Int. 2004;74:170–180. [PubMed] [Google Scholar]
  • Cranenburg EC, Vermeer C, Koos R, Boumans ML, Hackeng TM, Bouwman FG, Kwaijtaal M, Brandenburg VM, Ketteler M, Schurgers LJ. The circulating inactive form of matrix Gla Protein (ucMGP) as a biomarker for cardiovascular calcification. J Vasc Res. 2008;45:427–436. [PubMed] [Google Scholar]
  • Price PA, Nguyen TM, Williamson MK. Biochemical characterization of the serum fetuin-mineral complex. J Biol Chem. 2003;278:22153–22160. [PubMed] [Google Scholar]
  • Surmann-Schmitt C, Dietz U, Kireva T, Adam N, Park J, Tagariello A, Onnerfjord P, Heinegard D, Schlötzer-Schrehardt U, Deutzmann R, von der Mark K, Stock M. Ucma, a novel secreted cartilage-specific protein with implications in osteogenesis. J Biol Chem. 2008;283:7082–7093. [PubMed] [Google Scholar]
  • Moe SM, Chen NX. Pathophysiology of vascular calcification in chronic kidney disease. Circ Res. 2004;95:560–567. [PubMed] [Google Scholar]
  • Lian JB, Skinner M, Glimcher MJ, Gallop P. The presence of gamma-carboxyglutamic acid in the proteins associated with ectopic calcification. Biochem Biophys Res Commun. 1976;73:349–355. [PubMed] [Google Scholar]
  • Lian JB, Boivin G, Patterson-Allen P, Grynpas M, Walzer C. Calcergy and calciphylaxis: timed appearance of gamma-carboxyglutamic acid and osteocalcin in mineral deposits. Calcif Tissue Int. 1983;35:555–561. [PubMed] [Google Scholar]
  • Berger RG, Featherstone GL, Raasch RH, McCartney WH, Hadler NM. Treatment of calcinosis universalis with low-dose warfarin. Am J Med. 1987;83:72–76. [PubMed] [Google Scholar]
  • Cukierman T, Elinav E, Korem M, Chajek-Shaul T. Low dose warfarin treatment for calcinosis in patients with systemic sclerosis. Ann Rheum Dis. 2004;63:1341–1343. [PMC free article] [PubMed] [Google Scholar]
  • Lassoued K, Saiag P, Anglade MC, Roujeau JC, Touraine RL. Failure of warfarin in treatment of calcinosis universalis. Am J Med. 1988;84:795–796. [PubMed] [Google Scholar]
  • van Summeren MJ, Spliet WG, van Royen-Kerkhof A, Vermeer C, Lilien M, Kuis W, Schurgers LJ. Calcinosis in juvenile dermatomyositis: a possible role for vitamin K-dependent protein matrix Gla protein. Rheumatology (Oxford) 2008;47:267–271. [PubMed] [Google Scholar]
  • Uitto J, Jiang Q. Pseudoxanthoma elasticum-like phenotypes: more diseases than one. J Invest Dermatol. 2007;127:507–510. [PubMed] [Google Scholar]
  • Borst P, van de Wetering K, Schlingemann R. Does the absence of ABCC6 (multidrug resistance protein 6) in patients with Pseudoxanthoma elasticum prevent the liver from providing sufficient vitamin K to the periphery? Cell Cycle. 2008;7:1575–1579. [PubMed] [Google Scholar]
  • Luo G, Ducy P, McKee MD, Pinero GJ, Loyer E, Behringer RR, Karsenty G. Spontaneous calcification of arteries and cartilage in mice lacking matrix GLA protein. Nature. 1997;386:78–81. [PubMed] [Google Scholar]
  • Parmar H, Blaser S, Unger S, Yoo SJ, Papsin B. Petrified ears in a patient with Keutel syndrome: temporal bone CT findings. Pediatr Radiol. 2006;36:241–243. [PubMed] [Google Scholar]
  • Hur DJ, Raymond GV, Kahler SG, Riegert-Johnson DL, Cohen BA, Boyadjiev SA. A novel MGP mutation in a consanguineous family: review of the clinical and molecular characteristics of Keutel syndrome. Am J Med Genet A. 2005;135:36–40. [PubMed] [Google Scholar]
  • Spronk HM, Soute BA, Schurgers LJ, Thijssen HH, De Mey JG, Vermeer C. Tissue-specific utilization of menaquinone-4 results in the prevention of arterial calcification in warfarin-treated rats. J Vasc Res. 2003;40:531–537. [PubMed] [Google Scholar]
  • Geleijnse JM, Vermeer C, Grobbee DE, Schurgers LJ, Knapen MH, van der Meer IM, Hofman A, Witteman JC. Dietary intake of menaquinone is associated with a reduced risk of coronary heart disease: the Rotterdam Study. J Nutr. 2004;134:3100–3105. [PubMed] [Google Scholar]
  • Braam LA, Hoeks AP, Brouns F, Hamulyák K, Gerichhausen MJ, Vermeer C. Beneficial effects of vitamins D and K on the elastic properties of the vessel wall in postmenopausal women: a follow-up study. Thromb Haemost. 2004;91:373–380. [PubMed] [Google Scholar]
  • Becker RC. Warfarin-induced vasculopathy. J Thromb Thrombolysis. 2007;23:79–81. [PubMed] [Google Scholar]
  • Murshed M, Schinke T, McKee MD, Karsenty G. Extracellular matrix mineralization is regulated locally; different roles of two gla-containing proteins. J Cell Biol. 2004;165:625–630. [PMC free article] [PubMed] [Google Scholar]
Articles from The American Journal of Pathology are provided here courtesy of American Society for Investigative Pathology