To address whether brain-derived neurotrophic factor (BDNF) could be involved in periodontal tissue regeneration, we examined the effects of BDNF on proliferation and the expression of bone (cementum)- related proteins (osteopontin, bone morphogenetic protein [BMP]-2, type I collagen, alkaline phosphatase [ALPase], and osteocalcin) in cultures of human periodontal ligament (HPL) cells, which are thought to be prerequisite for periodontal tissue regeneration, and on proliferation and angiogenesis in human endothelial cells. Furthermore, we examined the effect of BDNF on the regeneration of periodontal tissues in experimentally induced periodontal defects in dogs. BDNF elevated the expression of ALPase and osteocalcin mRNAs and increased the synthesis of osteopontin, BMP-2, and type I collagen DNA in HPL cells. BDNF stimulated mRNA expression of vascular endothelial growth factor-B and tenascin-X, and proliferation and angiogenesis in human endothelial cells. In vivo studies showed that BDNF stimulated the formation of new alveolar bone cementum and connective new fibers, which were inserted into the newly formed cementum and bone. BDNF also stimulated blood capillary formation. These findings suggest that the regulation of functioning of periodontal ligament cells and endothelial cells by BDNF results in the promotion of periodontal tissue regeneration.
Calcium hydroxide is often used for induction of reparative dentin formation in endodontic treatment. However, little is known about the mechanism by which calcium hydroxide works. The calcium ion (Ca2+) is an important regulator of cell functions. In this study, we examined the effect of extracellular Ca2+ on gene expression of bone-related proteins in human cultured pulp cells in serum-free conditions. A Ca2+ level elevated by 0.7 mM induced an increase in mRNA expression of osteopontin and bone morphogenetic protein (BMP)-2. However, mRNA levels of BMP-4 and alkaline phosphatase decreased under the elevated Ca2+ culture condition. The same concentration of additional magnesium ions had little effect on expressions of the examined bone-related protein mRNAs. These findings suggest that Ca2+ in Ca(OH)2 specifically modulates osteopontin and BMP-2 levels during calcification in pulp.
The rare actinomycete Actinoplanes missouriensis forms terminal sporangia containing a few hundred flagellated spores, which can swim in aquatic environments after release from sporangium. However, gene regulation for its characteristic morphological development is largely unknown. Here, we report the functional analysis of an orphan response regulator, TcrA, which is encoded next to the chemotaxis-flagellar gene cluster. The tcrA null (ΔtcrA) mutant formed sporangium, in which sporulation proceeded. However, many distorted spores were produced and some spores ectopically germinated in the mutant sporangia. In addition, spores were hardly released from the mutant sporangia. A comparative RNA-Seq analysis between the wild-type and ΔtcrA strains showed that TcrA upregulated the transcription of more than 263 genes, which were integrated into 185 transcriptional units. In silico searches identified a 21-bp direct repeat sequence, 5'-nnGCA(A/C)CCG-n -GCA(A/C)CCGn-3', as the TcrA box, which was confirmed by electrophoretic mobility shift assays. Finally, we identified 34 transcriptional units as the TcrA regulon. TcrA seems to regulate a few hundred genes through the transcriptional activation of three FliA-family sigma factor genes besides its own regulon. We concluded that TcrA is a global transcriptional activator that controls many aspects of sporangium formation, including flagellar biogenesis, spore dormancy and sporangium dehiscence.
The major problem in cell therapy is the possibility of viral or bacterial infection and immune reactions. Therefore, it is expected of culture cells which are intended to be re-implanted with autologous serum rather than conventional bovine serum. Cell therapy with human mesenchymal stem cells (hMSC), differentiating to various cells, is thought to be curative. To culture hMSC with human autologous serum (HAS) and re-implant them for cell therapy, we developed a completely closed bag system separating serum, comparing proliferation and multipotency of hMSC cultured in HAS with those in foetal calf serum (FCS). HAS was simply, safely and efficiently obtained with the developed closed bag system. Cell proliferation of hMSC cultured in HAS was greater than that in FCS. hMSC, exposed to the defined induction medium containing HAS as well as FCS, differentiated into osteoblasts and adipocytes. These findings suggest that HAS obtained with the developed closed bag system is advantageous in a point of decrease in risk of virus or bacterial infection and foreign protein contamination and enhancement of proliferation of hMSC.
Actinoplanes missouriensis, a Gram-positive and soil-inhabiting bacterium, is a member of the rare actinomycetes. The filamentous cells produce sporangia, which contain hundreds of flagellated spores that can swim rapidly for a short period of time until they find niches for germination. These swimming cells are called zoospores, and the mechanism of this unique temporal flagellation has not been elucidated. Here, we report all of the flagellar genes in the bacterial genome and their expected function and contribution for flagellar morphogenesis. We identified a large flagellar gene cluster composed of 33 genes that encode the majority of proteins essential for assembling the functional flagella of Gram-positive bacteria. One noted exception to the cluster was the location of the fliQ gene, which was separated from the cluster. We examined the involvement of four genes in flagellar biosynthesis by gene disruption, fliQ, fliC, fliK, and lytA. Furthermore, we performed a transcriptional analysis of the flagellar genes using RNA samples prepared from A. missouriensis grown on a sporangium-producing agar medium for 1, 3, 6, and 40 days. We demonstrated that the transcription of the flagellar genes was activated in conjunction with sporangium formation. Eleven transcriptional start points of the flagellar genes were determined using the rapid amplification of cDNA 5= ends (RACE) procedure, which revealed the highly conserved promoter sequence CTCA(N 15-17 )GCCGAA. This result suggests that a sigma factor is responsible for the transcription of all flagellar genes and that the flagellar structure assembles simultaneously. IMPORTANCEThe biology of a zoospore is very interesting from the viewpoint of morphogenesis, survival strategy, and evolution. Here, we analyzed flagellar genes in A. missouriensis, which produces sporangia containing hundreds of flagellated spores each. Zoospores released from the sporangia swim for a short time before germination occurs. We identified a large flagellar gene cluster and an orphan flagellar gene (fliQ). These findings indicate that the zoospore flagellar components are typical of Gram-positive bacteria. However, the transcriptional analysis revealed that all flagellar genes are transcribed simultaneously during sporangium formation, a pattern differing from the orderly, regulated expression of flagellar genes in other bacteria, such as Salmonella and Escherichia coli. These results suggest a novel regulatory mechanism for flagellar formation in A. missouriensis.A ctinomycetes exhibit filamentous growth, and their hyphae are not motile. However, actinomycetes, which belong to a range of genera, including Actinoplanes, Catenuloplanes, Kineosporia, and Spirillospora, produce spores that can swim using the flagella prior to germination. These motile cells are called zoospores and are thought to specifically function for expansion into new habitats. Thus, zoospore-producing actinomycetes are motile only for a very short period of their complex life cycle. The zoospore biology is o...
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