Applications of stem cells in orthodontics and dentofacial orthopedics:Current trends and future perspectives

A simple overview of daily orthodontic practice involves use of brackets, wires and elastomeric modules. However, investigating the underlying effect of orthodontic forces shows various molecular and cellular changes. Also, orthodontics is in close relation with dentofacial orthopedics which involves bone regeneration. In this review current and future applications of stem cells(SCs) in orthodontics and dentofacial orthopedics have been discussed. For craniofacial anomalies, SCs have been applied to regenerate hard tissue(such as treatment of alveolar cleft) and soft tissue(such as treatment of hemifacial macrosomia). Several attempts have been done to reconstruct impaired temporomandibular joint. Also, SCs with or without bone scaffolds and growth factors have been used to regenerate bone following distraction osteogenesis of mandibular bone or maxillary expansion. Current evidence shows that SCs also have potential to be used to regenerate infrabony alveolar defects and move the teeth into regenerated areas. Future application of SCs in orthodontics could involve accelerating tooth movement, regenerating resorbed roots and expanding tooth movement limitations. However, evidence supporting these roles is weak and further studies are required to evaluate the possibility of these ideas.     

Redox signalling: from nitric oxide to oxidized lipids

Cellular redox signalling is mediated by the post-translational modification of proteins in signal-transduction pathways by ROS/RNS (reactive oxygen species/reactive nitrogen species) or the products derived from their reactions. NO is perhaps the best understood in this regard with two important modifications of proteins known to induce conformational changes leading to modulation of function. The first is the addition of NO to haem groups as shown for soluble guanylate cyclase and the newly discovered NO/cytochrome c oxidase signalling pathway in mitochondria. The second mechanism is through the modification of thiols by NO to form an S-nitrosated species. Other ROS/RNS can also modify signalling proteins although the mechanisms are not as clearly defined. For example, electrophilic lipids, formed as the reaction products of oxidation reactions, orchestrate adaptive responses in the vasculature by reacting with nucleophilic cysteine residues. In modifying signalling proteins ROS/RNS appear to change the overall activity of signalling pathways in a process that we have termed 'redox tone'. In this review, we discuss these different mechanisms of redox cell signalling, and give specific examples of ROS/RNS participation in signal transduction.     

Cytoprotective Effect of Estrogen on Ammonium Chloride–Treated C6-Glioma Cells

The potential cytoprotective effects of estrogen in the brain are of special interest in aging, neurodegenerative diseases, exposure to toxins, and trauma. Estrogen effects on neurons have been widely explored, but less is known about estrogen effects on glia. Glial cells are primary targets of ammonia toxicity, which arises from liver disease or failure (such as from cirrhosis in alcoholics), urea cycle disorders, or inborn errors of metabolism. We examined the ability of estrogen to protect glial cells from ammonium chloride toxicity using an in vitro model system. C6-glioma cells in later passage have many astrocytic characteristics and provided a convenient and well established model system for this work. When C6-glioma cells were exposed to 15 mM ammonium chloride, we observed major cell death (only 32% cell survival relative to control) within 72 h. Pretreatment with 17beta-estradiol (10 microM) significantly protected C6-glioma cells from ammonia toxicity (99% cell survival relative to control). In addition to enhancing the viability of C6-glioma cells against ammonia challenge, estrogen pretreatment was also found to protect mitochondrial function as assayed using the MTT reduction assay. Mitochondrial function was reduced to 39% of control levels in ammonia-challenged cultures and was mostly protected by estrogen (72% of control levels). The findings are potentially relevant for the development of therapeutic strategies to protect glial cells against ammonia toxicity resulting from hepatic failure or other causes.     

Trapping of growth factors by catechins: a possible therapeutical target for prevention of proliferative diseases

The prevention of cancer through dietary intervention is currently receiving considerable attention. Several epidemiological studies substantiate that green tea has a protective effect against a variety of malignant proliferative disorders such as lung cancer, breast cancer and prostate cancer. This preventive potential of green tea against cancer is attributed to the biologically active flavonoids called catechins. Epigallocatechin 3-o-gallate, the major catechin found in green tea, mediates diverse physiological and pharmacological actions in bringing about the regression of the tumors and also lowers the risk of nonmalignant cardiovascular proliferative diseases. Much of the current research is being focused on how these catechins specifically bring about the regression of the experimentally induced tumors both in vitro and in vivo. These catechins exert diverse physiological effects against proliferative diseases by several mechanisms, most of which are not completely characterized. This review summarizes the mechanisms by which these catechins play an essential role in regulating the process of carcinogenesis, with a special emphasis on how these catechins antagonize the growth factor-induced proliferative disorders.     

Synthesis of pyrrolo[2,1-c][1,4]benzodiazepines and their conjugates by azido reductive cyclization strategy as potential DNA-binding agents

Synthesis of pyrrolo[2,1-c][1,4]benzodiazepines via azido reductive cyclization process employing FeCl3-NaI reagent system. This methodology has been extended for the preparation of new nicotinamido-pyrrolobenzodiazepine hybrids linked through piperazino-alkane-oxy spacers that exhibit good DNA binding affinity.     

Nitroxia: the pathological consequence of dysfunction in the nitric oxide-cytochrome c oxidase signaling pathway

It is now recognized that mitochondria play an integral role in orchestrating the response of the cell to a wide variety of metabolic and environmental stressors. Of particular interest are the interactions of reactive oxygen and nitrogen species with the organelle and their potential regulatory function. The best understood example is the O(2) sensitive binding of NO (nitric oxide) to the heme group in cytochrome c oxidase. We have proposed that this reversible process serves the function of both regulating the formation of hydrogen peroxide from the respiratory chain for the purposes of signal transduction and controlling O(2) gradients in complex organs such as the liver or heart. It now appears that maladaptation in this pathway leads to a mitochondrial dysfunction which has some of the characteristics of hypoxia, such as a deficit in ATP, but occurs in the presence of normal or enhanced levels of O(2). These are the optimal conditions for the formation of reactive nitrogen species (RNS), such as peroxynitrite which lead to the irreversible modification of proteins. We term this unique pathological condition Nitroxia and describe how it may contribute to the pathology of chronic inflammatory diseases using ethanol-dependent hepatotoxicity as an example.     

Biotransformation of ferulic acid to acetovanillone using Rhizopus oryzae

Microbial transformation of ferulic acid to acetovanillone was studied using growing cells of Rhizopus oryzae. Ferulic acid was added to the growing medium (0.5 g L^-1) and incubated for 12 days. The progress of formation of metabolites was monitored by GC and GC-MS after extraction with ethyl acetate. The major metabolite was acetovanillone with minor metabolites formed, such as dihydroferulic acid, coniferyl alcohol and dihydroconiferyl alcohol. Traces of metabolites (≤1-3%), such as vanillin, vanillyl alcohol, vanillic acid and phenyl ethyl alcohol, were also produced. Formation of 4-vinyl guaiacol increased from day 1 (12.4%), reaching a maximum on day 4 (31.7%), and reducing to a minimum on day 12 (3.1%). The formation of acetovanillone increased only from day 2 onward, and reached a maximum (49.2%) on day 12. The optimum concentration of ferulic acid to be added into the medium was found to be only 0.5 g L^-1, as any increase in concentration (0.75 and 1.0 g L^-1) precipitated the precursor, resulting in no further degradation.     

Cloning, Expression, and Sequence Analysis of the Gene Encoding the Alkali-Stable, Thermostable Endoxylanase from Alkalophilic, Mesophilic Bacillus sp. Strain NG-27

Alkalophilic Bacillus sp. strain NG-27 produces a 42-kDa endoxylanase active at 70°C and at a pH of 8.4. The gene for this endoxylanase was cloned and sequenced. The gene contained one open reading frame of 1,215 bases. An active site characteristic of the family 10 β-glycanases was recognized between amino acids 303 and 313, with the active glutamate at position 310. Though highly thermostable, the enzyme contains no cysteine residue.     

Mitotic cells form actin-based bridges with adjacent cells to provide intercellular communication during rounding

In order to achieve accurate chromosome segregation, eukaryotic cells undergo a dramatic change in morphology to obtain a spherical shape during mitosis. Interphase cells communicate directly with each other by exchanging ions and small molecules via gap junctions, which have important roles in controlling cell growth and differentiation. As cells round up during mitosis, the gap junctional communication between mitotic cells and adjacent interphase cells ceases. Whether mitotic cells use alternative mechanisms for mediating direct cell-cell communication during rounding is currently unknown. Here, we have studied the mechanisms involved in the remodeling of gap junctions during mitosis. We further demonstrate that mitotic cells are able to form actin-based plasma membrane bridges with adjacent cells during rounding. These structures, termed “mitotic nanotubes,” were found to be involved in mediating the transport of cytoplasm, including Rab11-positive vesicles, between mitotic cells and adjacent cells. Moreover, a subpool of the gap-junction channel protein connexin43 localized in these intercellular bridges during mitosis. Collectively, the data provide new insights into the mechanisms involved in the remodeling of gap junctions during mitosis and identify actin-based plasma membrane bridges as a novel means of communication between mitotic cells and adjacent cells during rounding.