Galectin-3 associates with the primary cilium and modulates cyst growth in congenital polycystic kidney disease.

Several lines of evidence implicate the beta-galactoside-binding lectin galectin-3 in development and pathological processes in renal collecting ducts: galectin-3 is expressed in the ureteric bud/collecting duct lineage during nephrogenesis, modulates collecting duct growth/differentiation in vitro, and is expressed in human autosomal recessive polycystic kidney disease in cyst epithelia, almost all of which arise from collecting ducts. Moreover, exogenous galectin-3 restricts growth of cysts generated by Madin-Darby canine kidney collecting duct-derived cells in three-dimensional culture in collagen. Using the cpk mouse model of recessively inherited polycystic kidney disease, we observed widespread galectin-3 mRNA and protein in cyst epithelia. Exogenous galectin-3 reduced cyst formation in suspension culture, and mice-null mutant for galectin-3 had more extensive renal cysts in vivo. Galectin-3 was also detected for the first time in the centrosome/primary cilium, which has been implicated in diverse polycystic kidney disease. Cilia structure/number appeared normal in galectin-3-null mutants. Finally, paclitaxel, a therapy that retards polycystic kidney disease in cpk mice, increased extracellular galectin-3, in which the lectin could potentially interact with cilia. These data raise the possibility that galectin-3 may act as a natural brake on cystogenesis in cpk mice, perhaps via ciliary roles.

Specificity of interactions of galectin-3 with Chrp, a cysteine- and histidine-rich cytoplasmic protein.

Earlier work described the cloning of a gene from murine 3T3 cells encoding a cytoplasmic protein Chrp containing a cysteine- and histidine-rich motif characteristic of Zn-finger proteins. The interaction of Chrp with murine galectin-3 first became evident in a yeast two-hybrid screen, but it was also observed in co-precipitation experiments from 3T3 cell lysates. Here, the formation of equimolar complexes by murine Chrp and hamster galectin-3 is shown. Moreover, we found that Chrp binds to the carbohydrate-recognition domain (CRD) of hamster galectin-3 and not to the N-terminal domain carrying the proline- and glycine-rich repeats characteristic of galectin-3 and absent in other galectins. However, galectin-1 does not bind to Chrp, although its CRD is homologous to the galectin-3 CRD. Finally, we report that galectin-3, in a complex with Chrp, binds to laminin in surface plasmon resonance experiments with similar kinetics and affinity as it does in the free state. The formation of higher-order complexes containing these proteins and additional binding partners may be relevant to cytoplasmic functions involving galectin-3.

Galectins in kidney development.

Galectins are a family of proteins with overlapping but distinct carbohydrate-binding specificities. They differ in cell-type and tissue distribution, and have various functions. Extracellularly several galectins can modulate cellular adhesive interactions and signalling pathways, effects that may be important in the establishment and maintenance of tissue organization during normal development. This review will summarise recent progress in defining the roles of galectins that are expressed in the kidney in normal development, and discuss the evidence linking aberrant expression of galectins with kidney disease.

Galectin-3 modulates ureteric bud branching in organ culture of the developing mouse kidney.

Galectin-3 is a mammalian beta-galactoside-specific lectin with functions in cell growth, adhesion, and neoplastic transformation. On the basis of expression patterns in humans, it is proposed that galectin-3 modulates fetal collecting duct growth. This article provides evidence that galectin-3 can modulate branching morphogenesis of the mouse ureteric bud/collecting duct lineage. With the use of immunohistochemistry, galectin-3 was not detected in early metanephrogenesis but was upregulated later in fetal kidney maturation when the protein was prominent in basal domains of medullary collecting ducts. Addition of galectin-3 to embryonic days 11 and 12 whole metanephric cultures inhibited ureteric bud branching, whereas galectin-1 did not perturb morphogenesis, nor did a galectin-3 mutant lacking wild-type high-affinity binding to extended oligosaccharides. Exogenous galectin-3 retarded conversion of renal mesenchyme to nephrons in whole metanephric explants but did not affect nephron induction by spinal cord in isolated renal mesenchymes. Finally, addition of a blocking antiserum to galectin-3 caused dilation and distortion of developing epithelia in embryonic day 12 metanephroi cultured for 1 wk. The upregulation of galectin-3 protein during kidney maturation, predominantly at sites where it could mediate cell/matrix interactions, seems to modulate growth of the ureteric tree.