Jeanette M. Cunningham scite author profile

Laminins are the major noncollagenous glycoproteins of all basal laminae (BLs). They are α/β/γ heterotrimers assembled from 10 known chains, and they subserve both structural and signaling roles. Previously described mutations in laminin chain genes result in diverse disorders that are manifested postnatally and therefore provide little insight into laminin's roles in embryonic development. Here, we show that the laminin α5 chain is required during embryogenesis. The α5 chain is present in virtually all BLs of early somite stage embryos and then becomes restricted to specific BLs as development proceeds, including those of the surface ectoderm and placental vasculature. BLs that lose α5 retain or acquire other α chains. Embryos lacking laminin α5 die late in embryogenesis. They exhibit multiple developmental defects, including failure of anterior neural tube closure (exencephaly), failure of digit septation (syndactyly), and dysmorphogenesis of the placental labyrinth. These defects are all attributable to defects in BLs that are α5 positive in controls and that appear ultrastructurally abnormal in its absence. Other laminin α chains accumulate in these BLs, but this compensation is apparently functionally inadequate. Our results identify new roles for laminins and BLs in diverse developmental processes.

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The renal glomerulus of mice lacking s–laminin/laminin β2: nephrosis despite molecular compensation by laminin β1

Noakes

et al. 1995

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S-laminin/laminin beta 2, a homologue of the widely distributed laminin B1/beta 1 chain, is a major component of adult renal glomerular basement membrane (GBM). Immature GBM bears beta 1, which is replaced by beta 2 as development proceeds. In mutant mice that lack beta 2, the GBM remains rich in beta 1, suggesting that a feedback mechanism normally regulates GBM maturation. The beta 2-deficient GBM is structurally intact and contains normal complements of several collagenous and noncollagenous glycoproteins. However, mutant mice develop massive proteinuria due to failure of the glomerular filtration barrier. These results support the idea that laminin beta chains are functionally distinct although they assemble to form similar structures. Laminin beta 2-deficient mice may provide a model for human congenital or idiopathic nephrotic syndromes.

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Roles for the integrin VLA-4 and its counter receptor VCAM-1 in myogenesis

Rosen

Sanes

Lachance

et al. 1992

Cell

375

263

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Podocyte-Specific Deletion of Dicer Alters Cytoskeletal Dynamics and Causes Glomerular Disease

et al. 2008

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MicroRNAs (miRNAs) regulate gene expression by binding the 3Ј untranslated region of mRNAs. To define their role in glomerular function, miRNA biogenesis was disrupted in mouse podocytes using a conditional Dicer allele. Mutant mice developed proteinuria by 3 wk after birth and progressed rapidly to end-stage kidney disease. Podocyte pathology included effacement, vacuolization, and hypertrophy with crescent formation. Despite normal expression of WT1, podocytes underwent dedifferentiation, exemplified by cytoskeletal disruption with early transcriptional downregulation of synaptopodin. These abnormalities differed from Cd2ap Ϫ/Ϫ mice, indicating they were not a general consequence of glomerular disease. Glomerular labeling of ezrin, moesin, and gelsolin was altered at 3 wk, but expression of nestin and ␣-actinin was unchanged. Abnormal cell proliferation or apoptosis was not responsible for the glomerular injury. Mutant podocytes were incapable of synthesizing mature miRNA, as revealed by their loss of miR-30a. In contrast, expression of glomerular endothelial and mesangial cell miRNAs (miR-126 and miR-145, respectively) was unchanged. These findings demonstrate a critical role for miRNA in glomerular function and suggest a pathway that may participate in the pathogenesis of kidney diseases of podocyte origin. The unique architecture of podocytes may make them especially susceptible to cytoskeletal alterations initiated by aberrant miRNA dynamics.

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Properly formed but improperly localized synaptic specializations in the absence of laminin α4

et al. 2001

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Precise apposition of pre- to postsynaptic specializations is required for optimal function of chemical synapses, but little is known about how it is achieved. At the skeletal neuromuscular junction, active zones (transmitter release sites) in the nerve terminal lie directly opposite junctional folds in the postsynaptic membrane. Few active zones or junctional folds form in mice lacking the laminin beta2 chain, which is normally concentrated in the synaptic cleft. beta2 and the broadly expressed gamma1 chain form heterotrimers with alpha chains, three of which, alpha2, alpha4 and alpha5, are present in the synaptic cleft. Thus, alpha2beta2gamma1, alpha4beta2gamma1 and alpha5beta2gamma1 heterotrimers are all lost in beta2 mutants. In mice lacking laminin alpha4, active zones and junctional folds form in normal numbers, but are not precisely apposed to each other. Thus, formation and localization of synaptic specializations are regulated separately, and alpha4beta2gamma1 (called laminin-9) is critical in the latter process.

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