Mechanism of obesity affecting periodontal tissue regeneration and therapeutic strategies / 中华口腔医学杂志

Obesity is an important health problem in our society today, which can lead to the chronic low-grade inflammation state, to be an inducement for many chronic diseases such as hypertension, type 2 diabetes and non-alcoholic fatty liver disease. As a common oral chronic infectious disease, periodontitis is mainly characterized by gingival inflammation, periodontal pocket formation, alveolar bone resorption and tooth mobility. The ultimate goal of periodontitis treatment is to achieve periodontal tissue regeneration in the defect area. As a major risk factor for periodontitis, obesity can alter the periodontal inflammatory microenvironment in multiple ways, affecting the effects of periodontal tissue regeneration ultimately. Therefore, this paper will review the relationship between obesity and periodontal tissue regeneration, mechanism of obesity affecting periodontal tissue regeneration and the therapeutic strategies of periodontal tissue regeneration, providing new ideas for periodontal tissue regeneration treatment in obesity.

Gas chromatographic-tandem mass spectrometric analysis of ß-lyase metabolites of sulfur mustard adducts with glutathione in urine and its use in a rabbit cutaneous exposure model.

A method for quantitation of ß-lyase metabolites of sulfur mustard (SM) adducts with glutathione has been developed and validated using gas chromatography-tandem mass spectrometry (GC-MS/MS). The linear range of quantitation was 0.1-1000ng/mL in urine with a method detection limit of 0.02ng/mL. The method was applied in a rabbit exposure model. Domestic rabbits were cutaneously exposed to neat liquid SM in three dosage levels, and the ß-lyase metabolites in urine were determined as 1,1'-sulfonylbis[2-(methylthio)ethane] (SBMTE). The study showed that even though more than 99% of the total amount of ß-lyase metabolites was excreted in the first week after exposure, the ß-lyase metabolites of SM adducts with glutathione could be detected in urine from rabbits for up to 3 or 4 weeks after the SM cutaneous exposure. For high dosage group (15mg/kg, 0.15 LD50), the mean concentration of SBMTE detected was 0.32ng/mL on day 28. For middle (5mg/kg, 0.05 LD50) and low (2mg/kg, 0.02 LD50) dosage groups, the mean concentrations of SBMTE were 0.07ng/mL and 0.02ng/mL on day 21, respectively. The data from this study indicate that the method is sensitive and provides a relatively long time frame for the retrospective detection of SM exposure.

[In vitro O-demethylation of rotundine by recombinant human CYP isoenzymes].

Rotundine (1 micromol L(-1)) was incubated with a panel of rCYP enzymes (1A2, 2C9, 2C19, 2D6 and 3A4) in vitro. The remained parent drug in incubates was quantitatively analyzed by an Agilent LC-MS. CYP2C19, 3A4 and 2D6 were identified to be the isoenzymes involved in the metabolism of rotundine. The individual contributions of CYP2C19, 3A4 and 2D6 to the rotundine metabolism were assessed using the method of total normalized rate to be 31.46%, 60.37% and 8.17%, respectively. The metabolites of rotundine in incubates were screened with ESI-MS at selected ion mode, and were further identified using MS2 spectra and precise molecular mass obtained from an Agilent LC/Q-TOF-MSMS, as well as MS(n) spectra of LC-iTrap-MS(n). The predominant metabolic pathway of rotundine in rCYP incubates was O-demethylation. A total 5 metabolites were identified including 4 isomerides of mono demethylated rotundine and one di-demethylated metabolite. The results also showed that CYP2C19, 2D6 and 3A4 mediated O-demethylation of methoxyl groups at different positions of rotundine. Furthermore, the ESI-MS cleavage patterns of rotundine and its metabolites were explored by using LC/Q-TOF-MSMS and LC/iTrap-MS(n) techniques.

[The effect of Haynaldia villosa v chromosome on the mitochondrial proteome of wheat-H. villosa chromosome substitution line and translocation line].

Wheat-Haynaldia villosa chromosome substitution line (6A/6V) and translocation lines (6DL/6VS, 6AL/6VS) were obtained through hybridization of H. villosa with powdery mildew susceptible cultivated wheat. Substitution line and translocation lines contain V chromosome or the chromosome short arm (VS) of H. villosa. They are resistant to powdery mildew. In this study, mitochondrial proteome changes were analyzed by using substitution line (6A/6V), translocation line (6DL/6VS) as experimental materials in order to studying the effects of V chromosome on the mitochondrial proteome and related to powdery mildew resistance. The results indicated that 16 new mitochondrial protein spots (spot1, 22kDa/PI8.5; spot2, 31 kDa/PI 7.5; spot3, 28 kDa/PI 7.0; spot4, 31 kDa/PI 6.5; spot5, 40 kDa/PI 7.5; spot6, 40 kDa/PI 7.4; spot7, 80 kDa/PI 8.4; spot8, 50 kDa/PI 7.5; spot9, 60 kDa/PI 7.3; spot10, 65 kDa/PI 6.6; spot11, 65 kDa/PI 6.6; spot12, 73 kDa/PI 7.5; spot13, 73 kDa/PI 7.7; spot14, 46 kDa/PI 7.4; spot15, 46 kDa/PI 7.3; spot16, 38 kDa/PI 6.3) were produced and 7 mitochondrial protein spots (spot1, 40 kDa/PI 7.5; spot2, 43 kDa/PI 7.6; spot3, 48 kDa/PI 7.5; spot4, 42 kDa/PI 8.0; spot5, 43 kDa/PI 7.5; spot6, 32 kDa/PI 4.8; spot7, 40 kDa/PI 5.5) were absent in substitution line, 7 new mitochondrial protein spots (spotl, 43 kDa/PI 6.3; spot2, 60 kDa/PI 6.5; spot3, 60 kDa/PI 6.4; spot4, 65 kDa/PI 7.5; spot5, 55 kDa/PI 8.2; spot6, 31 kDa/PI 8.0; spot7, 43 kDa/PI 8.0) were produced and 6 mitochondrial protein spots (spot1', 66 kDa/PI 8.3; spot2', 58 kDa/PI 8.5; spot3', 36 kDa/PI 7.0; spot4', 48 kDa/PI 7.7; spot5', 48 kDa/PI 6.8; spot6', 43 kDa/PI 6.2) were absent in translocation line. These experimental results suggest that V chromosome or VS of H. villosa can obviously lead mitochondrial proteome changed. These changes may be associated with resistant to powdery mildew of substitution line and translocation line.

[Different proteins in mitochondrial proteome of T-type maize cytoplasmic male-sterile line and its maintainer line].

Using T-type maize cytoplasmic male sterile line (T-CMS) and maintainer line as experimental materials, we separated mitochondrial proteins from leaves at seedling, shooting, booting stages, mesocotyl, root and anther at meiosis of pollen mother cell, single-double nucleus stage of pollen grain by two-dimensional electrophoresis with immobilized pH3-10 gradients. About 150 mitochondrial protein spots in seedling leaves, 150 spots in mesocotyls, 150 spots in roots and 100 spots in meiosis anther were observed respectively in this investigation. 6 difference protein spots were identified by MALDI-TOF-MS analysis and NCBI database searching. r40c1 protein was present in mesocotyl of T-CMS and absent in maintainer line. Mature anther-specific protein, DNA-directed RNA polymerase 23kDa subunit, hexokinase II were present and glutathione S-transferase, putative polyprotein were absent in pollen aborted anther of T-CMS. Developmental changes in mitochondrial proteins were found in leaves but no differences were observed in T-CMS and its maintainer line. Obvious differences of mitochondrial proteins were found at single-double nucleus stage anther in T-CMS and maintainer line. These different proteins were considered to be associated to pollen aborted in T-CMS.