RESUMO
BACKGROUND: Polycystic liver disease (PLD) is present in most patients with autosomal dominant polycystic kidney disease (ADPKD). PLD can alternatively be found with few, if any, kidney cysts as a diagnosis of isolated polycystic liver disease (ADPLD). Several genes are identified as causative for this spectrum of phenotypes, however, the relative incidence of genetic etiologies amongst patients with severe PLD is unknown. METHODS: Patients with ADPKD or ADPLD having severe PLD defined as height-adjusted total liver volume (hTLV) over 1,800mL/m were recruited. Subsequent clinical care was followed. Genetic analysis was performed using whole exome sequencing. RESULT: We enrolled and sequenced 49 patients (38 females, 11 males). Pathogenic or suspected pathogenic variants in polycystic disease genes were found in 44 out of 49 patients (90%). The disease gene was PKD1 in 20/44 (45%), PKD2 in 15/44 (34%), PRKCSH in 5/44 (11%), GANAB in 2/44 (5%), SEC63 in 1/44 (2%), and ALG8 in 1/44 (2%). The median hTLV was no different between genetically-defined ADPKD and ADPLD groups (4431 (range 1817-9148) versus 3437 (range 1860-8211) mL, p=0.77), whereas height-adjusted kidney volume (hTKV) was larger as expected in ADPKD than ADPLD (607 (range 190-2842) versus 179 (range 138-234) mL/m, p<0.01). Of the clinically-defined ADPKD cases, 20/38 (53%) were PKD1, 15/38 (39%) were PKD2, and 3 (8%) remain genetically unsolved. Among patients with a pathogenic PKD1 or PKD2 variant, we found three cases with a liver-dominant ADPKD (severe PLD with hTKV <250mL/m). CONCLUSION: ADPLD-related genes represent 20% of severe PLD patients in our cohort. Of those enrolled with ADPKD, we observed a higher frequency of PKD2 carriers than in any previously reported ADPKD cohorts. While there was no significant difference in the hTLV between PKD1 versus PKD2 patients in this cohort, our data suggests that enrollment on the basis of severe PLD may enrich for PKD2 patients.
RESUMO
Functional human brown and white adipose tissue (BAT and WAT) are vital for thermoregulation and nutritional homeostasis, while obesity and other stressors lead, respectively, to cold intolerance and metabolic disease. Understanding BAT and WAT physiology and dysfunction necessitates clinical trials complemented by mechanistic experiments at the cellular level. These require standardized in vitro models, currently lacking, that establish references for gene expression and function. We generated and characterized a pair of immortalized, clonal human brown (hBA) and white (hWA) preadipocytes derived from the perirenal and subcutaneous depots, respectively, of a 40-year-old male individual. Cells were immortalized with hTERT and confirmed to be of a mesenchymal, nonhematopoietic lineage based on fluorescence-activated cell sorting and DNA barcoding. Functional assessments showed that the hWA and hBA phenocopied primary adipocytes in terms of adrenergic signaling, lipolysis, and thermogenesis. Compared to hWA, hBA were metabolically distinct, with higher rates of glucose uptake and lactate metabolism, and greater basal, maximal, and nonmitochondrial respiration, providing a mechanistic explanation for the association between obesity and BAT dysfunction. The hBA also responded to the stress of maximal respiration by using both endogenous and exogenous fatty acids. In contrast to certain mouse models, hBA adrenergic thermogenesis was mediated by several mechanisms, not principally via uncoupling protein 1 (UCP1). Transcriptomics via RNA-seq were consistent with the functional studies and established a molecular signature for each cell type before and after differentiation. These standardized cells are anticipated to become a common resource for future physiological, pharmacological, and genetic studies of human adipocytes.
