Koichi Hiratsuka

Effect of low-level laser irradiation on osteoglycin gene expression in osteoblasts

AbstractMany studies have attempted to elucidate the mechanism of the biostimulatory effects of low-level laser irradiation (LLLI), but the molecular basis of these effects remains obscure. We investigated the stimulatory effect of LLLI on bone formation during the early proliferation stage of cultured osteoblastic cells. A mouse calvaria-derived osteoblastic cell line, MC3T3-E1, was utilised to perform a cDNA microarray hybridisation to identify genes that induced expression by LLLI at the early stage. Among those genes that showed at least a twofold increased expression, the osteoglycin/mimecan gene was upregulated 2.3-fold at 2 h after LLLI. Osteoglycin is a small leucine-rich proteoglycan (SLRP) of the extracellular matrix which was previously called the osteoinductive factor. SLRP are abundantly contained in the bone matrix, cartilage cells and connective tissues, and are thought to regulate cell proliferation, differentiation and adhesion in close association with collagen and many other growth factors. We investigated the time-related expression of this gene by LLLI using a reverse transcription polymerase chain reaction (RT-PCR) method, and more precisely with a real-time PCR method, and found increases of 1.5–2-fold at 2–4 h after LLLI compared with the non-irradiated controls. These results suggest that the increased expression of the osteoglycin gene by LLLI in the early proliferation stage of cultured osteoblastic cells may play an important role in the stimulation of bone formation in concert with matrix proteins and growth factors.

ROLE OF PORPHYROMONAS GINGIVALIS 40-kDa OUTER MEMBRANE PROTEIN IN THE AGGREGATION OF P. GINGIVALIS VESICLES AND ACTINOMYCES VISCOSUS

Porphyromonas gingivalis, an important pathogen in periodontitis, produces extracellular vesicles that aggregate with Actinomyces viscosus cells. A 40-kDa outer membrane protein (OMP)-coding gene from P. gingivalis was cloned and the protein was found to be localized in these vesicles. The recombinant 40-kDa OMP did not show aggregation activity. However, affinity-purified antibody against the recombinant protein significantly inhibited aggregation of P. gingivalis vesicles with A. viscosus cells. The antibody also inhibited cellular coaggregation of several strains of P. gingivalis with A. viscosus cells, but not with other periodontal pathogens. Moreover, aggregation of A. viscosus cells with P. gingivalis vesicles was inhibited in a dose-dependent manner by pre-treatment of the A. viscosus cells with the recombinant protein. These findings suggest that the 40-kDa OMP may be an important aggregation factor of P. gingivalis.

A 35-kDa co-aggregation factor is a hemin binding protein in Porphyromonas gingivalis.

It has been known that Porphyromonas gingivalis has an obligate requirement for hemin or selected heme- or Fe-containing compounds for its growth. In addition, the influence of hemin on the expression of several putative virulence factors produced by this bacterium has also been recently documented; however, the mechanisms involved in hemin uptake are poorly defined. We succeeded in cloning the gene coding for the 35-kDa protein, which was specifically expressed in P. gingivalis and seemed to confer colonizing activities. Recently, we have constructed the P. gingivalis 381 mutant defective in the 35-kDa protein by insertion mutagenesis. The beige mutant exhibited little co-aggregation and the virulence was also decreased. Based on these results and homology search analysis, we focused on assessing the hemin bindings and found the heme regulatory motif (HRM) as a hemin direct binding site. The 35-kDa protein did possess the binding ability of selected protoporphyrins involving the hemin. These results demonstrated that 35-kDa protein is one of the hemin binding proteins in P. gingivalis and suggested that hemin binding ability of 35-kDa protein is important for the expression of virulence in P. gingivalis.

Stimulation of MCM3 Gene Expression in Osteoblast by Low Level Laser Irradiation

Abstract. Biostimulatory effect of cell proliferation and bone formation by laser irradiation has been reported, however, very little is known about the molecular basis of mechanisms. We previously constructed the cDNA library of mouse osteoblastic cells (MC3T3-E1) which enhanced gene expression by laser irradiation using a subtracted gene cloning procedure. In the present study, we focused on a gene clone, designated as MCL-140, which exhibited the high homology of DNA sequence with mouse minichromosome maintenance (MCM) 3 gene. MCM3 is involved in the initiation of DNA replication as licensing factor in eukaryotic cells. Nucleotide sequence of MCL-140 insert was determined and assessed in the nucleic acid databases. The transcription level of MCL-140 was examined by Northern blot analysis. The DNA sequences of clone MCL-140 insert exhibited 96.2% homology with MCM 3 gene coding P1 protein. Higher MCM3 mRNA levels were observed in laser-irradiated cells compared to the levels in non-irradiated cells; furthermore, radiolabelled thymidine incorporation was increased by laser irradiation. These findings suggest that low-level laser irradiation may enhance DNA replication and play a role in stimulating proliferation of osteoblast through the enhancement of the MCM3 gene expression.

Inhibition of a Porphyromonas gingivalis colonizing factor between Actinomyces viscosus ATCC 19246 by monoclonal antibodies against recombinant 40-kDa outer-membrane protein.

1. Porphyromonas gingivalis, an important pathogen in human periodontal disease, aggregates with Actinomyces viscosus ATCC 19246. 2. Monoclonal antibodies (mAbs) against purified recombinant 40-kDa outer-membrane protein (r40-kDa, OMP) of P. gingivalis 381 inhibited its coaggregation with A. viscosus ATCC 19246 in a dose-dependent manner. 3. Five mAb clones against r40-kDa OMP were selected. The isotype of the five was IgG1. 4. Pg-ompA2 inhibited the coaggregation of several strains of P. gingivalis with A. viscosus ATCC 19246 cells.

Microarray Analysis of Gene Expression Changes in Aging in Mouse Submandibular Gland

Little is known about the effect of salivary gland function during aging based on gene expression. Recently emerged DNA array technology provides a sensitive, quantitative, rapid approach to the monitoring of the global pattern of gene expression. In this study, we used high-density oligonucleotide arrays to monitor the changes of gene expression levels in the submandibular gland (SMG) by comparing adult mice with elderly adult mice. Of the 1328 genes screened, 160 genes (12.0%) showed more than two-fold changes; 154 (96.3%) of these genes, associated with transcription regulation, transport, signal transduction, and enzymes in the elderly mice, exhibited decreased expression levels. The remaining 6 genes (3.7%) in the elderly mice showed increased expression levels. In mouse SMG, analysis of these data suggests that aging may lead the gene expression to decrease than increase. Thus, DNA array technology can be a powerful tool for the identification of age-associated candidate genes for further analysis in aging.

Further development of an electroosmotic medium pump system for preparative disk gel electrophoresis

A simple and practical 6.8-cm-diameter (36.30-cm(2) cross-sectional-area) preparative disk gel electrophoresis device, based on the design of M. Hayakawa et al. (Anal. Biochem. 288 (2001) 168), in which the elution buffer is driven by an electroosmotic buffer flow through the membrane into the elution chamber from the anode chamber was constructed. We have found that the dialysis membranes employed provide suitable flow rates for the elution buffer, similar to those of an earlier 3.6-cm-diameter device, resulting in the prevention of excess eluate dilution. The efficiency of this device was demonstrated by the fractionation of a bovine serum albumin (BSA) Cohn V fraction into monomer, dimer, and oligomer components using nondenaturing polyacrylamide gel electrophoresis (native-PAGE). The maximum protein concentration of the eluate achieved was 133 mg/ml of BSA monomer, which required a dilution of the eluate for subsequent analytical PAGE performance. As a practical example, the two-dimensional fractionation of soluble dipeptidyl peptidase IV (sDPP IV) from 50 ml fetal bovine serum (3.20 g protein) per gel is presented. The sDPP IV enzyme protein was recovered in a relatively short time, utilizing a 6.5% T native-PAGE and subsequential sodium dodecyl sulfate-PAGE system. This device enhances the possibility of continuous electrophoretic fractionation of complex protein mixtures on a preparative scale.

Blue LED inhibits the growth of Porphyromonas gingivalis by suppressing the expression of genes associated with DNA replication and cell division

Blue light has been employed or investigated in both the medical and dental fields. Many studies have so far been reported a bactericidal effect of blue light emitting diodes (LED). However, it is still unclear whether exposure to blue LED kills or inhibits the growth of bacteria. We therefore investigated the effect of blue LED irradiation on the growth of Porphyromonas gingivalis compared with the effects of red LED.

Hemin-binding protein 35 (HBP35) plays an important role in bacteria–mammalian cells interactions in Porphyromonas gingivalis

Hemin-binding protein 35 (HBP35) may be an essential protein for bacterial survival in evasion from environmental stress in Porphyromonas gingivalis. The anti-recombinant HBP35 antibody inhibits P. gingivalis hemagglutination. This study considered the role of this protein for hemagglutination and adherence to host cells using the HBP35-deficient mutant (MD774) derived from P. gingivalis FDC381. FDC381 had strong hemagglutination activity, whereas MD774 had no activity. Anti-130-kDa hemagglutinin antibody, mAb-Pg-vc, reacted mainly with the 43- and 49-kDa molecules in the membrane fraction. However, no proteins reacted in the MD774. The hemolytic activity in MD774 was much lower than that in FDC381. Anti-recombinant HBP35 antibody strongly inhibited the P. gingivalis FDC381 adherence to epithelial cells. In addition, MD774 exhibited a significant decrease in the adherence. The hydrophobicity of MD774 was equal to 19.4% of that of FDC381. SDS-PAGE profiling of the membrane fractions of both strains showed very different profiles. Taken together, these findings suggest that HBP35 plays a role, not only in hemin-binding, but also in multiple P. gingivalis binding to erythrocytes, and host epithelial gingival cells. In addition, this protein may directly and/or indirectly affect the virulence of this organism.

Expression of Ten-m/Odz3 in the fibrous layer of mandibular condylar cartilage during postnatal growth in mice

It has been speculated that the mandibular condyle develops via the differentiation of the fibroblast‐like cells covering the condyle into chondrocytes; however, the developmental mechanisms behind this process have not been revealed. We used laser‐capture microdissection and cDNA microarray analysis to elucidate the genes that are highly expressed in these fibroblast‐like cells. Among these genes, the transcription of Ten‐m/Odz3 was significantly increased in the fibroblast‐like cells compared with other cartilage tissues. For the first time, we describe the temporal and spatial expression of Ten‐m/Odz3 mRNA in relation to the expression of type I, II, and X collagen mRNA, as determined by in‐situ hybridization in mouse mandibular condylar cartilage and mouse femoral cartilage during the early stages of development. Ten‐m/Odz3 was expressed in the fibrous layer and the proliferating and mature chondrocyte layers, which expressed type I and II collagen, respectively, but was not detected in the hypertrophic chondrocyte layer. Furthermore, we evaluated the in‐vitro expression of Ten‐m/Odz3 using ATDC5 cells, a mouse chondrogenic cell line. Ten‐m/Odz3 was expressed during the early stage of the differentiation of mesenchymal cells into chondrocytes. These findings suggest that Ten‐m/Odz3 is involved in the differentiation of chondrocytes and that it acts as a regulatory factor in the early stages of the development of mandibular condylar cartilage.