ABSTRACT
Insect-borne diseases are serious life-threatening infectious diseases. Rapid and accurate etiological diagnosis are the premise of timely and effective clinical treatments, reducing mortality and sequelae. Laboratory diagnoses of insect-borne diseases mainly focus on targeted serological detection and polymerase chain reaction, which is difficult to detect rare insect borne pathogens. At present, the metagenomic next-generation sequencing (mNGS) technology has moved from scientific research into clinical application. The detection of nucleic acid sequences of all organisms in infected samples by mNGS exhibited significant advantages in the diagnosis and traceability of rare pathogens. But at the same time, mNGS is also suffered with challenges such as background microbial interference, false results caused by database restrictions, pathogen resistance and host immune status information that are urgently needed for clinical treatments. This article systematically summarized applications of mNGS in the diagnosis of insect-borne pathogens and the challenges and difficulties it faces. With the continuous optimization of mNGS in the detection, it will bring new development and innovation to the etiology diagnosis of clinical infectious diseases.
ABSTRACT
Paget's disease of bone (PDB) is a common metabolic bone disease that is characterized by aberrant focal bone remodeling, which is caused by excessive osteoclastic bone resorption followed by disorganized osteoblastic bone formation. Genetic factors are a critical determinant of PDB pathogenesis, and several susceptibility genes and loci have been reported, including SQSTM1, TNFSF11A, TNFRSF11B, VCP, OPTN, CSF1 and DCSTAMP. Herein, we report a case of Chinese familial PDB without mutations in known genes and identify a novel c.163G>C (p.Val55Leu) mutation in FKBP5 (encodes FK506-binding protein 51, FKBP51) associated with PDB using whole-exome sequencing. Mutant FKBP51 enhanced the Akt phosphorylation and kinase activity in cells. A study of osteoclast function using FKBP51V55L KI transgenic mice proved that osteoclast precursors from FKBP51V55L mice were hyperresponsive to RANKL, and osteoclasts derived from FKBP51V55L mice displayed more intensive bone resorbing activity than did FKBP51WT controls. The osteoclast-specific molecules tartrate-resistant acid phosphatase, osteoclast-associated receptor and transcription factor NFATC1 were increased in bone marrow-derived monocyte/macrophage cells (BMMs) from FKBP51V55L mice during osteoclast differentiation. However, c-fos expression showed no significant difference in the wild-type and mutant groups. Akt phosphorylation in FKBP51V55L BMMs was elevated in response to RANKL. In contrast, IκB degradation, ERK phosphorylation and LC3II expression showed no difference in wild-type and mutant BMMs. Micro-CT analysis revealed an intensive trabecular bone resorption pattern in FKBP51V55L mice, and suspicious osteolytic bone lesions were noted in three-dimensional reconstruction of distal femurs from mutant mice. These results demonstrate that the mutant FKBP51V55L promotes osteoclastogenesis and function, which could subsequently participate in PDB development.