Novel targets of ß-TrCP cooperatively accelerate carbohydrate and fatty acid consumption.

Cellular energy is primarily produced from glucose and fat through glycolysis and fatty acid oxidation (FAO) followed by the tricarboxylic acid cycle in mitochondria; energy homeostasis is carefully maintained via numerous feedback pathways. In this report, we uncovered a new master regulator of carbohydrate and lipid metabolism. When ubiquitin E3 ligase ß-TrCP2 was inducibly knocked out in ß-TrCP1 knockout adult mice, the resulting double knockout mice (DKO) lost fat mass rapidly. Biochemical analyses of the tissues and cells from ß-TrCP2 KO and DKO mice revealed that glycolysis, FAO, and lipolysis were dramatically upregulated. The absence of ß-TrCP2 increased the protein stability of metabolic rate-limiting enzymes including 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase (PFKFB3), adipose triglyceride lipase (ATGL), carnitine palmitoyltransferase 1A (CPT1A), and carnitine/acylcarnitine translocase (CACT). Our data suggest that ß-TrCP is a potential regulator for total energy homeostasis by simultaneously controlling glucose and fatty acid metabolism and that targeting ß-TrCP could be an effective strategy to treat obesity and other metabolic disorders.

Reinforced technique of tension band wiring for tibial tuberosity fracture in adolescents: a case report for surgical technique.

Most of the fractures had been previously treated with open reduction and internal fixation. Although there are a number of fixation methods, a consensus on the treatment options has not been reached yet. Case presentation: We demonstrated the reinforced technique of tension band wiring and its surgical outcomes in the tibial tuberosity fracture of a 14-year-old male basketball player. For the modified technique, the wire was inserted between the patellar tendon and tibial tuberosity (insertion site of patellar tendon) and passed distally through the 2-mm-sized predrill cortical hole. Tightening the figure of the eight loops draws the fractured fragments together and anatomically reduces under appropriate compression. This technique can achieve the reduction and fixation of the fracture simultaneously. We confirmed the fixation stability with a range of knee joint motions. The patient was able to return back to the pre-injury level of sports activity at postoperative 2 months. Clinical discussion: The original technique of tension band wiring utilized the Kirschner wire to make a figure-of-eight loop. However, we used the patellar tendon and its insertion site of the tibial tuberosity for making a figure-of-eight loop. Moreover, the reduction and fixation of fracture were achieved simultaneously by tightening the tension band wire. This reinforced technique was firm enough for postoperative rehabilitation. Conclusion: The most certain advantage of this technique was to be able to reduce anatomically and fixate firmly with appropriate compression simultaneously. We recommend open reduction internal fixation with the reinforced technique of tension band wiring for displaced tibial tuberosity fracture in adolescent athletes.