Osteopontin regulates dentin and alveolar bone development and mineralization.

The periodontal complex is essential for tooth attachment and function and includes the mineralized tissues, cementum and alveolar bone, separated by the unmineralized periodontal ligament (PDL). To gain insights into factors regulating cementum-PDL and bone-PDL borders and protecting against ectopic calcification within the PDL, we employed a proteomic approach to analyze PDL tissue from progressive ankylosis knock-out (Ank-/-) mice, featuring reduced PPi, rapid cementogenesis, and excessive acellular cementum. Using this approach, we identified the matrix protein osteopontin (Spp1/OPN) as an elevated factor of interest in Ank-/- mouse molar PDL. We studied the role of OPN in dental and periodontal development and function. During tooth development in wild-type (WT) mice, Spp1 mRNA was transiently expressed by cementoblasts and strongly by alveolar bone osteoblasts. Developmental analysis from 14 to 240days postnatal (dpn) indicated normal histological structures in Spp1-/- comparable to WT control mice. Microcomputed tomography (micro-CT) analysis at 30 and 90dpn revealed significantly increased volumes and tissue mineral densities of Spp1-/- mouse dentin and alveolar bone, while pulp and PDL volumes were decreased and tissue densities were increased. However, acellular cementum growth was unaltered in Spp1-/- mice. Quantitative PCR of periodontal-derived mRNA failed to identify potential local compensators influencing cementum in Spp1-/- vs. WT mice at 26dpn. We genetically deleted Spp1 on the Ank-/- mouse background to determine whether increased Spp1/OPN was regulating periodontal tissues when the PDL space is challenged by hypercementosis in Ank-/- mice. Ank-/-; Spp1-/- double deficient mice did not exhibit greater hypercementosis than that in Ank-/- mice. Based on these data, we conclude that OPN has a non-redundant role regulating formation and mineralization of dentin and bone, influences tissue properties of PDL and pulp, but does not control acellular cementum apposition. These findings may inform therapies targeted at controlling soft tissue calcification.

Conditional Alpl Ablation Phenocopies Dental Defects of Hypophosphatasia.

Loss-of-function mutations in ALPL result in hypophosphatasia (HPP), an inborn error of metabolism that causes defective skeletal and dental mineralization. ALPL encodes tissue-nonspecific alkaline phosphatase, an enzyme expressed in bone, teeth, liver, and kidney that hydrolyzes the mineralization inhibitor inorganic pyrophosphate. As Alpl-null mice die before weaning, we aimed to generate mouse models of late-onset HPP with extended life spans by engineering a floxed Alpl allele, allowing for conditional gene ablation (conditional knockout [cKO]) when crossed with Cre recombinase transgenic mice. The authors hypothesized that targeted deletion of Alpl in osteoblasts and selected dental cells ( Col1a1-cKO) or deletion in chondrocytes, osteoblasts, and craniofacial mesenchyme ( Prx1-cKO) would phenocopy skeletal and dental manifestations of late-onset HPP. Col1a1-cKO and Prx1-cKO mice were viable and fertile, and they did not manifest the epileptic seizures characteristic of the Alpl-/- model of severe infantile HPP. Both cKO models featured normal postnatal body weight but significant reduction as compared with wild type mice by 8 to 12 wk. Plasma alkaline phosphatase for both cKO models at 24 wk was reduced by approximately 75% as compared with controls. Radiography revealed profound skeletal defects in cKO mice, including rachitic changes, hypomineralized long bones, deformations, and signs of fractures. Microcomputed tomography confirmed quantitative differences in cortical and trabecular bone, including decreased cortical thickness and mineral density. Col1a1-cKO mice exhibited classic signs of HPP dentoalveolar disease, including short molar roots with thin dentin, lack of acellular cementum, and osteoid accumulation in alveolar bone. Prx1-cKO mice exhibited the same array of periodontal defects but featured less affected molar dentin. Both cKO models exhibited reduced alveolar bone height and 4-fold increased numbers of osteoclast-like cells versus wild type at 24 wk, consistent with HPP-associated periodontal disease. These novel models of late-onset HPP can inform on long-term skeletal and dental manifestations and will provide essential tools to further studies of etiopathologies and therapeutic interventions.

Role of PHOSPHO1 in Periodontal Development and Function.

The tooth root and periodontal apparatus, including the acellular and cellular cementum, periodontal ligament (PDL), and alveolar bone, are critical for tooth function. Cementum and bone mineralization is regulated by factors including enzymes and extracellular matrix proteins that promote or inhibit hydroxyapatite crystal growth. Orphan Phosphatase 1 (Phospho1, PHOSPHO1) is a phosphatase expressed by chondrocytes, osteoblasts, and odontoblasts that functions in skeletal and dentin mineralization by initiating deposition of hydroxyapatite inside membrane-limited matrix vesicles. The role of PHOSPHO1 in periodontal formation remains unknown and we aimed to determine its functional importance in these tissues. We hypothesized that the enzyme would regulate proper mineralization of the periodontal apparatus. Spatiotemporal expression of PHOSPHO1 was mapped during periodontal development, and Phospho1(-/-) mice were analyzed using histology, immunohistochemistry, in situ hybridization, radiography, and micro-computed tomography. The Phospho1 gene and PHOSPHO1 protein were expressed by active alveolar bone osteoblasts and cementoblasts during cellular cementum formation. In Phospho1(-/-) mice, acellular cementum formation and mineralization were unaffected, whereas cellular cementum deposition increased although it displayed delayed mineralization and cementoid. Phospho1(-/-) mice featured disturbances in alveolar bone mineralization, shown by accumulation of unmineralized osteoid matrix and interglobular patterns of protein deposition. Parallel to other skeletal sites, deposition of mineral-regulating protein osteopontin (OPN) was increased in alveolar bone in Phospho1(-/-) mice. In contrast to the skeleton, genetic ablation of Spp1, the gene encoding OPN, did not ameliorate dentoalveolar defects in Phospho1(-/-) mice. Despite alveolar bone mineralization defects, periodontal attachment and function appeared undisturbed in Phospho1(-/-) mice, with normal PDL architecture and no evidence of bone loss over time. This study highlights the role of PHOSPHO1 in mineralization of alveolar bone and cellular cementum, further revealing that acellular cementum formation is not substantially regulated by PHOSPHO1 and likely does not rely on matrix vesicle-mediated initiation of mineralization.

Periodontal Defects in the A116T Knock-in Murine Model of Odontohypophosphatasia.

Mutations in ALPL result in hypophosphatasia (HPP), a disease causing defective skeletal mineralization. ALPL encodes tissue nonspecific alkaline phosphatase (ALP), an enzyme that promotes mineralization by reducing inorganic pyrophosphate, a mineralization inhibitor. In addition to skeletal defects, HPP causes dental defects, and a mild clinical form of HPP, odontohypophosphatasia, features only a dental phenotype. The Alpl knockout (Alpl (-/-)) mouse phenocopies severe infantile HPP, including profound skeletal and dental defects. However, the severity of disease in Alpl (-/-) mice prevents analysis at advanced ages, including studies to target rescue of dental tissues. We aimed to generate a knock-in mouse model of odontohypophosphatasia with a primarily dental phenotype, based on a mutation (c.346G>A) identified in a human kindred with autosomal dominant odontohypophosphatasia. Biochemical, skeletal, and dental analyses were performed on the resulting Alpl(+/A116T) mice to validate this model. Alpl(+/A116T) mice featured 50% reduction in plasma ALP activity compared with wild-type controls. No differences in litter size, survival, or body weight were observed in Alpl(+/A116T) versus wild-type mice. The postcranial skeleton of Alpl(+/A116T) mice was normal by radiography, with no differences in femur length, cortical/trabecular structure or mineral density, or mechanical properties. Parietal bone trabecular compartment was mildly altered. Alpl(+/A116T) mice featured alterations in the alveolar bone, including radiolucencies and resorptive lesions, osteoid accumulation on the alveolar bone crest, and significant differences in several bone properties measured by micro-computed tomography. Nonsignificant changes in acellular cementum did not appear to affect periodontal attachment or function, although circulating ALP activity was correlated significantly with incisor cementum thickness. The Alpl(+/A116T) mouse is the first model of odontohypophosphatasia, providing insights on dentoalveolar development and function under reduced ALP, bringing attention to direct effects of HPP on alveolar bone, and offering a new model for testing potential dental-targeted therapies in future studies.

Tooth root dentin mineralization defects in a mouse model of hypophosphatasia.

Tissue-nonspecific alkaline phosphatase (TNAP) is expressed in mineralizing tissues and functions to reduce pyrophosphate (PP(i) ), a potent inhibitor of mineralization. Loss of TNAP function causes hypophosphatasia (HPP), a heritable disorder marked by increased PP(i) , resulting in rickets and osteomalacia. Tooth root cementum defects are well described in both HPP patients and in Alpl(-/-) mice, a model for infantile HPP. In Alpl(-/-) mice, dentin mineralization is specifically delayed in the root; however, reports from human HPP patients are variable and inconsistent regarding dentin defects. In the current study, we aimed to define the molecular basis for changes in dentinogenesis observed in Alpl(-/-) mice. TNAP was found to be highly expressed by mature odontoblasts, and Alpl(-/-) molar and incisor roots featured defective dentin mineralization, ranging from a mild delay to severely disturbed root dentinogenesis. Lack of mantle dentin mineralization was associated with disordered and dysmorphic odontoblasts having disrupted expression of marker genes osteocalcin and dentin sialophosphoprotein. The formation of, initiation of mineralization within, and rupture of matrix vesicles in Alpl(-/-) dentin matrix was not affected. Osteopontin (OPN), an inhibitor of mineralization that contributes to the skeletal pathology in Alpl(-/-) mice, was present in the generally unmineralized Alpl(-/-) mantle dentin at ruptured mineralizing matrix vesicles, as detected by immunohistochemistry and by immunogold labeling. However, ablating the OPN-encoding Spp1 gene in Alpl(-/-) mice was insufficient to rescue the dentin mineralization defect. Administration of bioengineered mineral-targeting human TNAP (ENB-0040) to Alpl(-/-) mice corrected defective dentin mineralization in the molar roots. These studies reveal that TNAP participates in root dentin formation and confirm that reduction of PP(i) during dentinogenesis is necessary for odontoblast differentiation, dentin matrix secretion, and mineralization. Furthermore, these results elucidate developmental mechanisms underlying dentin pathology in HPP patients, and begin to explain the reported variability in the dentin/pulp complex pathology in these patients.

Intestinal alkaline phosphatase preserves the normal homeostasis of gut microbiota.

BACKGROUND AND AIMS: The intestinal microbiota plays a critical role in maintaining human health; however, the mechanisms governing the normal homeostatic number and composition of these microbes are largely unknown. Previously it was shown that intestinal alkaline phosphatase (IAP), a small intestinal brush border enzyme, functions as a gut mucosal defence factor limiting the translocation of gut bacteria to mesenteric lymph nodes. In this study the role of IAP in the preservation of the normal homeostasis of the gut microbiota was investigated. METHODS: Bacterial culture was performed in aerobic and anaerobic conditions to quantify the number of bacteria in the stools of wild-type (WT) and IAP knockout (IAP-KO) C57BL/6 mice. Terminal restriction fragment length polymorphism, phylogenetic analyses and quantitative real-time PCR of subphylum-specific bacterial 16S rRNA genes were used to determine the compositional profiles of microbiotas. Oral supplementation of calf IAP (cIAP) was used to determine its effects on the recovery of commensal gut microbiota after antibiotic treatment and also on the colonisation of pathogenic bacteria. RESULTS: IAP-KO mice had dramatically fewer and also different types of aerobic and anaerobic microbes in their stools compared with WT mice. Oral supplementation of IAP favoured the growth of commensal bacteria, enhanced restoration of gut microbiota lost due to antibiotic treatment and inhibited the growth of a pathogenic bacterium (Salmonella typhimurium). CONCLUSIONS: IAP is involved in the maintenance of normal gut microbial homeostasis and may have therapeutic potential against dysbiosis and pathogenic infections.

Upregulation of alkaline phosphatase and pyrophosphate hydrolysis: potential mechanism for uremic vascular calcification.

Pyrophosphate is a potent inhibitor of medial vascular calcification where its level is controlled by hydrolysis via a tissue-nonspecific alkaline phosphatase (TNAP). We sought to determine if increased TNAP activity could explain the pyrophosphate deficiency and vascular calcification seen in renal failure. TNAP activity increased twofold in intact aortas and in aortic homogenates from rats made uremic by feeding adenine or by 5/6 nephrectomy. Immunoblotting showed an increase in protein abundance but there was no increase in TNAP mRNA assessed by quantitative polymerase chain reaction. Hydrolysis of pyrophosphate by rat aortic rings was inhibited about half by the nonspecific alkaline phosphatase inhibitor levamisole and was reduced about half in aortas from mice lacking TNAP. Hydrolysis was increased in aortic rings from uremic rats and all of this increase was inhibited by levamisole. An increase in TNAP activity and pyrophosphate hydrolysis also occurred when aortic rings from normal rats were incubated with uremic rat plasma. These results suggest that a circulating factor causes pyrophosphate deficiency by regulating TNAP activity and that vascular calcification in renal failure may result from the action of this factor. If proven by future studies, this mechanism will identify alkaline phosphatase as a potential therapeutic target.

Conserved epitopes in human and mouse tissue-nonspecific alkaline phosphatase. Second report of the ISOBM TD-9 workshop.

A panel of 19 monoclonal antibodies (MAbs) against human tissue-nonspecific (liver/bone/kidney) alkaline phosphatase (TNAP) was obtained through the ISOBM TD-9 workshop. In the present study, the reactivity of these MAbs has been characterized against mouse TNAP. A mouse embryonic stem cell line, frozen sections of long bones, alkaline phosphatase extracted from mouse bone, and serum were used as the source of TNAP for individual assays. Each MAb was tested for immunoreactivity to mouse TNAP by Western blot analysis, immunohistochemistry and enzyme immunoassay. Antibodies 314 and 315 reacted strongly with mouse TNAP in Western blots, while all other antibodies were negative. By immunohistochemistry, antibodies 314, 315 and 333 produced strong positive staining using frozen sections, while antibody 334 was moderately positive. Enzyme immunoassays indicated that MAb 333 was also able to bind to serum TNAP. These antibodies represent very useful reagents to study the pathophysiological expression of TNAP in mouse tissues and in mouse serum.

Abnormal vitamin B6 metabolism in alkaline phosphatase knock-out mice causes multiple abnormalities, but not the impaired bone mineralization.

The tissue non-specific alkaline phosphatase (TNAP) knock-out mouse is a model of infantile hypophosphatasia displaying impaired bone mineralization, epileptic seizures, apnoea, abnormal apoptosis in the thymus, abnormal lumbar nerve roots, and postnatal death. Administration of vitamin B6 suppresses the epileptic seizures in TNAP-/- mice. This paper examines to what extent the diverse abnormalities seen in these mice are due to impaired utilization of vitamin B6, using two complementary approaches: administration of vitamin B6 to TNAP null mice and deprivation of vitamin B6 in wild-type and TNAP heterozygous mice. Administration of exogenous pyridoxal HCl delayed the onset of epileptic attacks and increased the life span of TNAP-/- mice. The episodes of apnoea ceased and the appearance of lumbar nerve roots improved, but hypomineralization and accumulation of osteoid continued to worsen with age. Control mice fed a vitamin B6-depleted diet developed epileptic seizures indistinguishable from those observed in TNAP-/- mice, abnormal apoptosis in the thymus, and thinning of the nerve roots, but showed no evidence of bone mineralization abnormalities. Depletion of vitamin B6 did not affect the ability of primary cultures of osteoblasts to deposit bone mineral in vitro. While abnormal metabolism of vitamin B6 explains many of the abnormalities in this mouse model of infantile hypophosphatasia, it is not the basis of the abnormal mineralization that characterizes this disease.

Functional characterization of osteoblasts and osteoclasts from alkaline phosphatase knockout mice.

Tissue nonspecific alkaline phosphatase (TNAP) knockout (ko) mice manifest defects in bone mineralization that mimic the phenotypic abnormalities of infantile hypophosphatasia. In this article, we have searched for phenotypic differences between calvarial osteoblasts and osteoclasts in wild-type (wt), heterozygous and homozygous TNAP null mice. In vitro release of 45Ca from calvarial bones, with and without stimulation with parathyroid hormone (PTH), revealed no functional difference between osteoclasts from the three TNAP genotypes. Studies of primary cultures of TNAP+/+, TNAP+/-, and TNAP-/- calvarial osteoblasts revealed no differences in the rate of protein synthesis or in the expression levels of messenger RNAs (mRNAs) for osteopontin (OP), osteocalcin (OC), collagen type I, core binding factor alpha1 (Cbfa 1), N-cadherin, Smad 5, and Smad 7. Release of interleukin-6 (IL-6) from calvarial osteoblasts under basal conditions and after stimulation with PTH, tumor necrosis factor alpha (TNF-alpha) or IL-1beta was similar in all genotypes. The amount of cyclic adenosine monophosphate (cAMP) accumulation also was comparable. However, although cultures of primary TNAP-/- osteoblasts were able to form cellular nodules as well as TNAP positive osteoblasts do, they lacked the ability to mineralize these nodules in vitro. Mineralization also was delayed in TNAP+/- osteoblast cultures compared with cultures of wt osteoblasts. Incubation with media supplemented with recombinant TNAP, but not with enzymatically inactive TNAP, restored mineralization in ko osteoblast cultures. Our data provide evidence that osteoblasts in TNAP null mice differentiate normally but are unable to initiate mineralization in vitro. The fact that even heterozygous osteoblasts show delayed mineralization provides a rationale for the presence of bone disease in carriers of hypophosphatasia.

Effect of tissue non-specific alkaline phosphatase in maintenance of structure of murine colon and stomach.

The gastrointestinal tract of mammals secretes a phospholipid-rich membrane that is enriched in alkaline phosphatase (AP) and surfactant proteins (surfactant-like particle, SLP). The production of this particle is stimulated in the small intestine by fat feeding and in cultured cells in vitro by transfection with intestinal alkaline phosphatase (IAP). To test whether tissue non-specific alkaline phosphatase (TNAP) was a factor in stimulating surfactant-like particle production in stomach and colon (tissues expressing TNAP), mice lacking this enzyme were studied. Mice were harvested at 8 days of life, when body weight of homozygous animals (TNAP -/-) was about half that of congenic controls (TNAP +/+) or heterozygotes (TNAP +/-), but before seizures had begun. No difference in content of the major SLP protein (65 kDa) by Western blotting or immunocytochemistry was seen in stomach or colon of TNAP -/- vs. TNAP +/+ animals, but the content was only about half in the IAP-expressing small bowel. Transmission electron microscopy of the TNAP -/- small bowel showed large dilated lysosomes and residual bodies. Colonocytes and gastric surface epithelial cells from the same animals showed mitochondria containing homogeneous dense inclusions, consistent with neutral lipid. In the underweight homozygous animals, there was a decrease in the neuronal content of submucosal ganglia in the jejunum and ileum and of myenteric ganglia in the jejunum of TNAP -/- animals. These findings suggest that (1) TNAP is not important in maintaining surfactant-like particle content of tissues that express TNAP, (2) normal fat absorption is important in maintaining SLP content in the small intestine, and (3) TNAP is important in the maintenance of some intestinal structures, and perhaps their function.

Osteoblast tissue-nonspecific alkaline phosphatase antagonizes and regulates PC-1.

Tissue-nonspecific alkaline phosphatase (TNAP) is essential for bone matrix mineralization, but the central mechanism for TNAP action remains undefined. We observed that ATP-dependent (45)Ca precipitation was decreased in calvarial osteoblast matrix vesicle (MV) fractions from TNAP-/- mice, a model of infantile hypophosphatasia. Because TNAP hydrolyzes the mineralization inhibitor inorganic pyrophosphate (PP(i)), we assessed phosphodiesterase nucleotide pyrophosphatase (PDNP/NTPPPH) activity, which hydrolyzes ATP to generate PP(i). Plasma cell membrane glycoprotein-1 (PC-1), but not the isozyme B10 (also called PDNP3) colocalized with TNAP in osteoblast MV fractions and pericellular matrix. PC-1 but not B10 increased MV fraction PP(i) and inhibited (45)Ca precipitation by MVs. TNAP directly antagonized inhibition by PC-1 of MV-mediated (45)Ca precipitation. Furthermore, the PP(i) content of MV fractions was greater in cultured TNAP-/- than TNAP+/+ calvarial osteoblasts. Paradoxically, transfection with wild-type TNAP significantly increased osteoblast MV fraction NTPPPH. Specific activity of NTPPPH also was twofold greater in MV fractions of osteoblasts from TNAP+/+ mice relative to TNAP-/- mice. Thus TNAP attenuates PC-1/NTPPPH-induced PP(i) generation that would otherwise inhibit MV-mediated mineralization. TNAP also paradoxically regulates PC-1 expression and NTPPPH activity in osteoblasts.

Effects of disruption of the embryonic alkaline phosphatase gene on preimplantation development of the mouse.

Embryonic alkaline phosphatase (EAP) is expressed during the preimplantation period of mouse development; however, its function is unknown. To determine whether the absence of an EAP gene affects development of preimplantation embryos, we studied mice homozygous for the disrupted EAP gene (EAP.ko mice). Time to reach morphologically definedpreimplantation stages, preimplantation loss, cell count, gestation length, and litter size were monitored, and it was found that EAP.ko embryos have slower development and higher rates of degeneration during in vitro preimplantation development. In vivo, EAP.ko mice had a longergestation, smaller litter size, and fewer cells at 93 hr after human chorionic gonadotropin injection. Furthermore, there was no compensation for the absence of EAP gene in EAP.ko embryos by other isozymes of alkaline phosphatase. We conclude that the presence of an active EAP gene is beneficial for preimplantation development of the mouse embryo, and its absence leads to fewer blastocysts in vitro, delayed parturition, and reduced litter size in vivo.

A novel prodrug approach for tertiary amines. 2. Physicochemical and in vitro enzymatic evaluation of selected N-phosphonooxymethyl prodrugs.

Quaternary amine prodrugs resulting from N-phosphonooxymethyl derivatization of the tertiary amine functionality of drugs represents a novel approach for improving their water solubility. Separate reports have demonstrated the synthetic feasibility and rapid and quantitative prodrug to parent drug conversion in rats and dogs. This work is a preliminary evaluation of the physicochemical and in vitro enzymatic reversion properties of selected prodrugs. The loxapine prodrug had over a 15 000-fold increase in aqueous solubility relative to loxapine free base at pH 7.4. The loxapine prodrug was also shown to be quite stable at neutral pH values. The time for degradation product (parent drug) precipitation from an aqueous prodrug formulation would be expected to dictate the shelf life. Using this assumption, together with solubility and elevated temperature chemical stability studies, the shelf life of a parenteral formulation of the loxapine prodrug was projected to be close to 2 years at pH 7.4 and 25 degrees C. In addition, the prodrugs of cinnarizine and loxapine have been shown to be substrates for alkaline phosphatase, an enzyme found throughout the human body, and revert to the parent compound in its presence. The results from these evaluations demonstrate that the derivatives examined have many of the ideal properties required for potential clinical application.

Alkaline phosphatase knock-out mice recapitulate the metabolic and skeletal defects of infantile hypophosphatasia.

Hypophosphatasia is an inborn error of metabolism characterized by deficient activity of the tissue-nonspecific isoenzyme of alkaline phosphatase (TNSALP) and skeletal disease due to impaired mineralization of cartilage and bone matrix. We investigated two independently generated TNSALP gene knock-out mouse strains as potential models for hypophosphatasia. Homozygous mice (-/-) had < 1% of wild-type plasma TNSALP activity; heterozygotes had the predicted mean of approximately 50%. Phosphoethanolamine, inorganic pyrophosphate, and pyridoxal 5'-phosphate are putative natural substrates for TNSALP and all were increased endogenously in the knock-out mice. Skeletal disease first appeared radiographically at approximately 10 days of age and featured worsening rachitic changes, osteopenia, and fracture. Histologic studies revealed developmental arrest of chondrocyte differentiation in epiphyses and in growth plates with diminished or absent hypertrophic zones. Progressive osteoidosis from defective skeletal matrix mineralization was noted but not associated with features of secondary hyperparathyroidism. Plasma and urine calcium and phosphate levels were unremarkable. Our findings demonstrate that TNSALP knock-out mice are a good model for the infantile form of hypophosphatasia and provide compelling evidence for an important role for TNSALP in postnatal development and mineralization of the murine skeleton.

Increased shelf-life of fosphenytoin: solubilization of a degradant, phenytoin, through complexation with (SBE)7m-beta-CD.

Fosphenytoin, a water-soluble prodrug of phenytoin, degrades primarily to phenytoin at pH values <8 during long term storage; phenytoin readily precipitates when formed from fosphenytoin due to its limited aqueous solubility. The objective of this study was to develop stable formulations of fosphenytoin in the pH range of 7.4-8. 0 by inhibiting the phenytoin precipitation through complexation with a parenterally safe cyclodextrin, (SBE)7m-beta-CD. Phase solubility studies at 25 degreesC revealed that phenytoin could be effectively solubilized by (SBE)7m-beta-CD both in the presence and absence of 80.6 mg/mL fosphenytoin (as its dihydrate). The binding constants for the phenytoin/cyclodextrin complex were found to be 1073 and 792 M-1 at pH 7.4 and pH 8.0, respectively. Because of the competitive inclusion between fosphenytoin and phenytoin with (SBE)7m-beta-CD, the extent of solubilization of phenytoin was lower, as expected, in the presence of fosphenytoin than in the absence of fosphenytoin, even though the binding constants for the fosphenytoin/cyclodextrin complex were relatively small (41-45 M-1). Initial rates were used to follow the production of phenytoin from fosphenytoin. Zero-order kinetics were observed under all conditions investigated. Phenytoin production rates were followed at 25, 37, and 50 degreesC in the presence of 0.03 or 0.06 M (SBE)7m-beta-CD. It was projected from the solubility of phenytoin and the kinetic information that fosphenytoin shelf lives as high as nine years at 25 degreesC and pH 7.4 in the presence of 60 mM of (SBE)7m-beta-CD might be possible while longer shelf lives might be possible at pH 8.

Stimulation of rat hepatocyte proliferation in vitro and in vivo by factors derived from the bovine small intestinal mucosa.

A factor with a molecular weight of less than 1 kDa in the mucosa of the bovine small intestine (low molecular weight factor or LMW factor) stimulated DNA synthesis in rat hepatocytes in primary culture. This factor only showed its activity when it was added with a larger factor with a molecular weight of 30 kDa that was also found in the same tissue (high molecular weight factor or HMW factor). The LMW factor probably acts to enhance the action of a hepatotrophic growth factor, since EGF and HGF can substitute for the HMW factor. The action of the LMW factor was not due to the actions of low molecular weight substances such as norepinephrine, estradiol, triiodothyronine, and putrescine, which enhance the action of EGF or HGF, since substantial amounts of these substances were not found in the extract. When intraperitoneally administered into rats, after two-thirds hepatectomy, the LMW factor enhanced hepatocyte proliferation without the administration of the HMW factor. In the regenerating liver, a hepatotrophic growth factor(s), which acts synergistically with the LMW factor, might be properly provided, but the supply of the LMW factor might be below the level that maximally stimulates hepatocyte proliferation.

Ethanolamine modulates the rate of rat hepatocyte proliferation in vitro and in vivo.

A low molecular weight, heat-resistant hepatotrophic factor in an extract from the bovine intestinal mucosa was purified and identified as ethanolamine by structural analyses. The mode of action of ethanolamine in vitro and in vivo coincided with that of the crude extract of the tissue, indicating that ethanolamine is the active component. Ethanolamine synergistically elevated the stimulation of DNA synthesis in hepatocytes in primary culture when added together with a growth factor, such as epidermal growth factor, with the ED50 being 20 microM, although it showed little stimulatory effect by itself. Contrary to these in vitro results, the intraperitoneal administration of ethanolamine hydrochloride (24 mg of ethanolamine per kg of body weight) enhanced hepatocyte proliferation in regenerating rat livers after two-thirds hepatectomy without the administration of any growth factors. In the regenerating liver, hepatocyte proliferation may be initiated by an endogenous growth factor, but the supply of ethanolamine in circulation may not be sufficient for optimal hepatocyte proliferation; thus, the exogenous administration of ethanolamine may further enhance hepatocyte proliferation. Ethanolamine in circulation may be a humoral hepatotrophic factor.

Inactivation of two mouse alkaline phosphatase genes and establishment of a model of infantile hypophosphatasia.

We report the inactivation, via homologous recombination, of two of the three active mouse alkaline phosphatase genes, i.e., embryonic (EAP) and tissue nonspecific (TNAP). Whereas expression of the EAP isozyme was abolished in all tissues that express EAP developmentally (such as the preimplantation embryo, thymus, and testis), the EAP knock-out mice show no obvious phenotypic abnormalities. They reproduce normally and give birth to live offspring, indicating the nonessential role of EAP during embryonic development. Mice deficient in the TNAP gene mimic a severe form of hypophosphatasia. These TNAP-/- mice are growth impaired, develop epileptic seizures and apnea, and die before weaning. Examination of the tissues indicates abnormal bone mineralization and morphological changes in the osteoblasts, aberrant development of the lumbar nerve roots, disturbances in intestinal physiology, increased apoptosis in the thymus, and abnormal spleens. Our results indicate that, in the mouse, TNAP appears not to be essential for the initial events leading to bone mineral deposition but that TNAP seems to play a role in the maintenance of this process after birth. The other phenotypic manifestations may be a consequence of the lack of TNAP in the developing neural tube between stages E8.5 and E13.5 of embryogenesis. We hypothesize that the autonomic nervous system is compromised in these TNAP-/- mice.

An organic acid-induced sigmoidal release system for oral controlled-release preparations. 2. Permeability enhancement of Eudragit RS coating led by the physicochemical interactions with organic acid.

The drug release mechanism of the sigmoidal release system (SRS), which is a newly developed multiple-unit type time-controlled release system, was investigated. The drug release rate from the Eudragit RS-coated theophylline beads was considerably enhanced in succinic acid aqueous solution compared with the release rate in water. However, the drug release rate from the beads coated with Eudragit NE 30D, which has no quaternary ammonium groups in the polymer chain, was not affected by succinic acid, suggesting that the quaternary ammonium groups of Eudragit RS are essential to produce the unique drug release profile of the SRS. Ion-exchange experiments revealed that organic acids could interact with Eudragit RS by an ion exchanging mode to various extents depending on the acid species. To examine the individual effect of dissociated and undissociated forms of succinic acid on the drug release behavior of the Eudragit RS-coated theophylline beads, dissolution studies were performed in succinic acid or monosodium succinate aqueous solutions with various concentrations. The drug release rate was found to change depending on the concentration of either the dissociated or the undissociated form of succinic acid with different concentration dependency. From the glass transition temperature measurement using Eudragit RS cast film, it was assumed that the undissociated succinic acid was distributed to the hydrophobic segment of the polymer, resulting in the increase in mechanical flexibility of the film; whereas the dissociated succinic acid electrostatically interacted with the quaternary ammonium groups of the polymer to promote the distribution and to create new ionic circumstances: both effects of the organic acid can accelerate the hydration of Eudragit RS film. All these results suggest that the unique S-shaped drug release profile of SRS can be brought about by a drastic increase in the permeability through the hydration of Eudragit RS-based coating during the drug release process.