IgA nephropathy is the most common glomerular disease worldwide, yet there is no international consensus for its pathological or clinical classification. Here a new classification for IgA nephropathy is presented by an international consensus working group. The goal of this new system was to identify specific pathological features that more accurately predict risk of progression of renal disease in IgA nephropathy, thus enabling both clinicians and pathologists to improve individual patient prognostication. In a retrospective analysis, sequential clinical data were obtained on 265 adults and children with IgA nephropathy who were followed for a median of 5 years. Renal biopsies from all patients were scored by pathologists blinded to the clinical data for pathological variables identified as reproducible by an iterative process. Four of these variables: (1) the mesangial hypercellularity score, (2) segmental glomerulosclerosis, (3) endocapillary hypercellularity, and (4) tubular atrophy/interstitial fibrosis were subsequently shown to have independent value in predicting renal outcome. These specific pathological features withstood rigorous statistical analysis even after taking into account all clinical indicators available at the time of biopsy as well as during follow-up. The features have prognostic significance and we recommended they be taken into account for predicting outcome independent of the clinical features both at the time of presentation and during follow-up. The value of crescents was not addressed due to their low prevalence in the enrolled cohort.
Pathological classifications in current use for the assessment of glomerular disease have been typically opinion-based and built on the expert assumptions of renal pathologists about lesions historically thought to be relevant to prognosis. Here we develop a unique approach for the pathological classification of a glomerular disease, IgA nephropathy, in which renal pathologists first undertook extensive iterative work to define pathologic variables with acceptable inter-observer reproducibility. Where groups of such features closely correlated, variables were further selected on the basis of least susceptibility to sampling error and ease of scoring in routine practice. This process identified six pathologic variables that could then be used to interrogate prognostic significance independent of the clinical data in IgA nephropathy (described in the accompanying article). These variables were (1) mesangial cellularity score; percentage of glomeruli showing (2) segmental sclerosis, (3) endocapillary hypercellularity, or (4) cellular/fibrocellular crescents; (5) percentage of interstitial fibrosis/tubular atrophy; and finally (6) arteriosclerosis score. Results for interobserver reproducibility of individual pathological features are likely applicable to other glomerulonephritides, but it is not known if the correlations between variables depend on the specific type of glomerular pathobiology. Variables identified in this study withstood rigorous pathology review and statistical testing and we recommend that they become a necessary part of pathology reports for IgA nephropathy. Our methodology, translating a strong evidence-based dataset into a working format, is a model for developing classifications of other types of renal disease.
X-linked hypophosphataemia (XLH) is an X-linked dominant disorder caused by mutations in PHEX (located at Xp22.1), which encodes a cell-surface-bound protein-cleavage enzyme (phosphate-regulating neutral endopeptidase PHEX), predominantly expressed in osteoblasts, osteocytes and teeth (odontoblasts and cementoblasts). XLH is the most common cause of inherited phosphate wasting, with an incidence of 3.9 per 100,000 live births and a prevalence ranging from 1.7 per 100,000 children to 4.8 per 100,000 persons (children and adults) 1-3. Although the pathogenesis of XLH is not fully understood, animal studies indicate that loss of Phex function results in enhanced secretion of the phosphaturic hormone fibroblast growth factor 23 (FGF23), with osteocytes being the primary source of FGF23 production 4. These effects explain most of the characteristic features of the disease, including renal phosphate wasting with consequent hypophosphataemia, diminished synthesis of active vitamin D (1,25(OH) 2 vitamin D), rickets, osteomalacia, odontomalacia and disproportionate short stature 4-6. Patients usually develop clinical symptoms during the first or second year of life. Early treatment with oral phosphate supplementation and active vitamin D heals rickets, limits dental abscess formation and prevents progressive growth failure, but in a substantial proportion of patients treatment is unsuccessful and/or associated with adverse effects (for example, hyper parathyroidism and nephrocalcinosis) 7,8. Up to two-thirds of children with XLH require lower limb surgery 9-12. Conventional therapy further stimulates FGF23 levels and thereby renal phosphate wasting, resulting in a vicious circle, which might limit its efficacy 6,13-15. Adult patients with XLH are at risk of complications such as early osteoarthritis, enthesopathies, spinal stenosis, pseudofractures and hearing loss, which might limit quality of life 16-18. In 2018, burosumab, a fully human monoclonal IgG1 antibody neutralizing FGF23, was approved by health authorities for the treatment of patients with
Maintenance of a constant cell volume in the face of osmotic stress is an evolutionarily ancient homeostatic process. Over the last two decades physiologists have gained an impressive understanding of the "volume-sensitive" channels, cotransporters, exchangers, metabolic pathways, and genes that are responsible for modulating intracellular solute content and cell volume. This review focuses on one part of this story, the characteristics and osmoregulatory functions of volume-sensitive anion channels. Three distinct types of swelling-activated anion channels have been observed and studied extensively in animal cells. These channels include 1) ClC-2, which is a member of the ClC family of voltage-gated anion channels, 2) an outwardly rectifying intermediate conductance channel, and 3) a large-conductance or "maxi" channel. In addition to these three channels, several other less well-characterized anion channels have been observed. This review discusses the electrophysiological and molecular biological characteristics and regulation of these channels. The possible roles different types of anion channels might play in cell volume homeostasis are also discussed.
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