Objective:To investigate the phenotype, genotype and clinical course of centronuclear myopathy(CNM) in children.Methods:Clinical data of patients with CNM in the Department of Pediatrics, Peking University First Hospital from October 2008 to December 2018 were collected.The clinical, pathological and genetic data of 9 children with CNM were retrospectively analyzed.The patients were followed up from 8 months to 8.6 years [(4.4±3.1) years].Results:(1)Clinical phenotype: there were 6 males and 3 females with onset age ranging from 1 d to 10 years.Generalized muscle weakness or motor retardation was the main complaint in 8 cases, while elevated muscle enzymes presented in 1 case.Varying degrees of skeletal muscle weakness were noted on examination in all patients, with facial muscle involvement in 4 cases.Six patients were followed up.No deterioration in motor function was noted, while 2 patients had improvement.There was no significant cardiac involvement in all 6 patients.Scoliosis occurred in 4 patients.Restrictive ventilator disorder developed in 2 out of the 5 patients who underwent pulmonary function tests.(2)Genotype: 8 out of 9 patients underwent gene test, confirmed gene diagnosis in 4 patients including: DNM2 gene (c.1856C>T, c.1893+ 1G>A was novel) de novo heterozygous mutation in 2 cases, RYR1 gene (c.2044C>G, c.6823G>A, both were novel) compound heterozygous mutation in 1 case, and TTN gene (c.107377+ 1G>A, c.2106_2107 insAAGCTGTA was novel) compound heterozygous mutation in 1 case. Conclusions:The course of centronuclear myopathy is relatively static, with more frequent involvement of facial muscles than myocardium.This study enriched the gene mutation spectrum of centronuclear myopathy (4 novel mutations).

As a member of the Sirtuins family in mammals, SIRT7 locates in nucleus and is a highly specific H3K18Ac (acetylated lysine 18 of histone H3) deacetylase. Recent studies showed that SIRT7 could participate in the ribosomal RNA transcription, cell metabolism, cell stress and DNA damage repair through various signaling pathways. In addition, SIRT7 is also closely related with aging, heart disease and fatty liver. In particular, SIRT7 plays important roles in the regulation of initiation and development of various tumors, such as liver cancer, gastric cancer, breast cancer, bladder cancer, colorectal cancer, and head/neck squamous cell carcinoma. This review describes the cellular and molecular functions of SIRT7, and systematically summarizes recent progress of SIRT7 in human disease.
Animals ; Histones ; Humans ; Lysine ; Neoplasms ; Signal Transduction ; Sirtuins ; metabolism

OBJECTIVE To analyze the chemical constituents and components absorbed into plasma of the extract of Ardisia crenata and to elucidate its possible pharmacodynamic material basis. METHODS Overall， 12 rats were randomly assigned to the blank group （n＝6） and A. crenata group （n＝6） by the paired comparison method. The drug was administered once daily in the morning and afternoon for three days. Serum samples were prepared from serum after redosing on 4th day. The UPLC-QE-HF-MS/ MS was used to analyze and identify the chemical constituents in A. crenata extract and serum samples. Compound Discoverer 3.0 was employed for retention time correction， peak identification， and peak extraction. According to the secondary mass spectrometry information， the Thermo mzCloud online and Thermo mzVault local databases， referring to the relevant literature and control quality spectrum information were used to preliminarily identify the chemical constituents and components absorbed into plasma of A. crenata. RESULTS A total of 34 compounds were identified from the extract of A. crenata， mainly coumarins， flavonoids， organic acids， amino acids， including bergenin， quercetin， gallic acid， L-pyroglutamic acid， etc. Besides， 5 components absorbed into plasma were identified from serum samples: L-pyroglutamic acid， syringic acid， bergenin， cinnabar root saponin A， and mycophenolic acid. CONCLUSIONS L-pyroglutamic acid， syringic acid， bergenin， cinnabar root saponin A， and mycophenolic acid may act as the pharmacodynamic material basis of A. crenata.