Abortive intussusceptive angiogenesis causes multi-cavernous vascular malformations.

Mosaic inactivation of CCM2 in humans causes cerebral cavernous malformations (CCMs) containing adjacent dilated blood-filled multi-cavernous lesions. We used CRISPR-Cas9 mutagenesis to induce mosaic inactivation of zebrafish ccm2 resulting in a novel lethal multi-cavernous lesion in the embryonic caudal venous plexus (CVP) caused by obstruction of blood flow by intraluminal pillars. These pillars mimic those that mediate intussusceptive angiogenesis; however, in contrast to the normal process, the pillars failed to fuse to split the pre-existing vessel in two. Abortive intussusceptive angiogenesis stemmed from mosaic inactivation of ccm2 leading to patchy klf2a overexpression and resultant aberrant flow signaling. Surviving adult fish manifested histologically typical hemorrhagic CCM. Formation of mammalian CCM requires the flow-regulated transcription factor KLF2; fish CCM and the embryonic CVP lesion failed to form in klf2a null fish indicating a common pathogenesis with the mammalian lesion. These studies describe a zebrafish CCM model and establish a mechanism that can explain the formation of characteristic multi-cavernous lesions.

Cerebral cavernous malformations are driven by ADAMTS5 proteolysis of versican.

Cerebral cavernous malformations (CCMs) form following loss of the CCM protein complex in brain endothelial cells due to increased endothelial MEKK3 signaling and KLF2/4 transcription factor expression, but the downstream events that drive lesion formation remain undefined. Recent studies have revealed that CCM lesions expand by incorporating neighboring wild-type endothelial cells, indicative of a cell nonautonomous mechanism. Here we find that endothelial loss of ADAMTS5 reduced CCM formation in the neonatal mouse model. Conversely, endothelial gain of ADAMTS5 conferred early lesion genesis in the absence of increased KLF2/4 expression and synergized with KRIT1 loss of function to create large malformations. Lowering versican expression reduced CCM burden, indicating that versican is the relevant ADAMTS5 substrate and that lesion formation requires proteolysis but not loss of this extracellular matrix protein. These findings identify endothelial secretion of ADAMTS5 and cleavage of versican as downstream mechanisms of CCM pathogenesis and provide a basis for the participation of wild-type endothelial cells in lesion formation.

Ccm3, a gene associated with cerebral cavernous malformations, is required for neuronal migration.

Loss of function of cerebral cavernous malformation 3 (CCM3) results in an autosomal dominant cerebrovascular disorder. Here, we uncover a developmental role for CCM3 in regulating neuronal migration in the neocortex. Using cell type-specific gene inactivation in mice, we show that CCM3 has both cell autonomous and cell non-autonomous functions in neural progenitors and is specifically required in radial glia and newly born pyramidal neurons migrating through the subventricular zone, but not in those migrating through the cortical plate. Loss of CCM3 function leads to RhoA activation, alterations in the actin and microtubule cytoskeleton affecting neuronal morphology, and abnormalities in laminar positioning of primarily late-born neurons, indicating CCM3 involvement in radial glia-dependent locomotion and possible interaction with the Cdk5/RhoA pathway. Thus, we identify a novel cytoplasmic regulator of neuronal migration and demonstrate that its inactivation in radial glia progenitors and nascent neurons produces severe malformations of cortical development.

Krit1/cerebral cavernous malformation 1 mRNA is preferentially expressed in neurons and epithelial cells in embryo and adult.

Cavernous malformations are capillaro-venous lesions mostly located within the central nervous system (CCM/OMIM#116860) and occasionally within the skin and/or retina. They occur as a sporadic or hereditary condition. Three CCM loci have been mapped, and the sole gene identified so far, CCM1, has been shown to encode KRIT1, a protein of unknown function. In an attempt to get some insight on the relationship between KRIT1 mutations and CCM lesions, we investigated Krit1 mRNA expression during mouse development from E7.5 to E20.5 and in adult tissues, of both mouse and human origin. A ubiquitous Krit1 mRNA expression was detected from E7.5 up to E9.5. Then, it became progressively restricted from E10.5 to E12.5, to become detectable later essentially in the nervous system and various epithelia. Strong labelling was observed in neurons in the brain, cerebellum, spinal cord, retina and dorsal root ganglia. In epithelia, Krit1 mRNA expression was detected in differentiating epidermal, digestive, respiratory, uterine and urinary epithelia. A similar pattern of expression persisted in mouse and man adult nervous system and epithelia. Unexpectedly, in vascular tissues, expression of Krit1 was detected only in large blood vessels of the embryo.