Leucine Zipper-bearing Kinase promotes axon growth in mammalian central nervous system neurons.

Leucine Zipper-bearing Kinase (LZK/MAP3K13) is a member of the mixed lineage kinase family with high sequence identity to Dual Leucine Zipper Kinase (DLK/MAP3K12). While DLK is established as a key regulator of axonal responses to injury, the role of LZK in mammalian neurons is poorly understood. By gain- and loss-of-function analyses in neuronal cultures, we identify LZK as a novel positive regulator of axon growth. LZK signals specifically through MKK4 and JNKs among MAP2Ks and MAPKs respectively in neuronal cells, with JNK activity positively regulating LZK protein levels. Neuronal maturation or activity deprivation activates the LZK-MKK4-JNK pathway. LZK and DLK share commonalities in signaling, regulation, and effects on axon extension. Furthermore, LZK-dependent regulation of DLK protein expression and the lack of additive effects on axon growth upon co-manipulation suggest complex functional interaction and cross-regulation between these two kinases. Together, our data support the possibility for two structurally related MAP3Ks to work in concert to mediate axonal responses to external insult or injury in mammalian CNS neurons.

Connexin47 protein phosphorylation and stability in oligodendrocytes depend on expression of Connexin43 protein in astrocytes.

Panglial networks are essential for normal physiology in the CNS, and the function of distinct connexins participating in these networks is not well understood. We generated Connexin32 (Cx32)-deficient mice with additional deletion of astrocytic Cx43 to explore the role of both connexins in panglial networks. Cx43/Cx32 double knock-out (dKO) mice revealed strong microglial activation in corpus callosum and cingulum along with severe astrogliosis and scar formation. In addition, most of the fine myelinated fibers projecting from the corpus callosum into the cortex were lost. Myelin loss was caused by a strong decrease of oligodendrocytes in the cingulum of Cx43/Cx32dKO mice. Immunoblot analyses using newly generated specific Cx47 antibodies revealed that oligodendrocytic Cx47 is phosphorylated in vivo depending on astrocytic Cx43 expression. In Cx43-deficient mice, Cx47 protein levels were strongly decreased, whereas Cx47 mRNA levels were not altered. Using Cx43G138R/Cx30KO mice, we show that Cx47 expression depends on the presence of astrocytic Cx43 protein and that its gap junctional channel function is not necessary for Cx47 stabilization. In consequence, Cx43/Cx32dKO mice additionally lack Cx47 expression and therefore cannot form oligodendrocytic gap junctions, which explains the phenotypic similarities to Cx32/Cx47dKO mice. Our findings provide strong evidence that phosphorylation and stability of oligodendrocytic Cx47 proteins is dependent on astrocytic Cx43 expression. These results further unravel the complexity of panglial networks and show that results of previous studies using astrocytic Cx43-deficient mice have to be reconsidered.

Changes in object recognition and anxiety-like behaviour in mice expressing a Cx47 mutation that causes Pelizaeus-Merzbacher-like disease.

Pelizaeus-Merzbacher-like disease is characterized by impaired psychomotor development, ataxia, progressive spasticity and mental retardation. It is induced by mutations in the gap junction gene GJC2 that encodes for the gap junction protein connexin 47. Mice bearing a human Cx47M283T missense mutation have been generated as a transgenic mouse model of Pelizaeus-Merzbacher-like disease. Homozygous expression of the mutant connexin 47 gene in oligodendrocytes resulted in a complex and variable neuropathologic phenotype, which was associated with impairments in motor coordination in juvenile, but not adult mice. In the present study, we have investigated anxiety-like behaviour and spatial working memory in juvenile (P23) and adult (3-month-old) Cx47M282T mutant mice. Adult Cx47M282T mice were also evaluated in terms of neuromotor functions and in the novel object recognition test. Juvenile Cx47M282T mutant mice exhibited an increase in anxiety-like behaviour in the open field test, but no changes in spatial working memory performance. No significant changes in anxiety-like behaviour, spatial working memory or neuromotor functions were observed in the adult Cx47M282T mutant mice. However, novel object recognition was significantly impaired in adult Cx47M282T mice. Our results suggest that the expression of the human Cx47M282T mutation in the mouse causes changes in anxiety-like behaviour in juvenile and novel object recognition impairments in adult mice. It appears that the distortion of panglial gap junction coupling in white and grey matter tissue in the Cx47M282T mice is associated with a complex age-dependent behavioural phenotype including changes in psychomotor, emotional and memory functions.

Panglial gap junctional communication is essential for maintenance of myelin in the CNS.

In this study, we have investigated the contribution of oligodendrocytic connexin47 (Cx47) and astrocytic Cx30 to panglial gap junctional networks as well as myelin maintenance and function by deletion of both connexin coding DNAs in mice. Biocytin injections revealed complete disruption of oligodendrocyte-to-astrocyte coupling in the white matter of 10- to 15-d-old Cx30/Cx47 double-deficient mice, while oligodendrocyte-to-oligodendrocyte coupling was maintained. There were no quantitative differences regarding cellular networks in acute brain slices obtained from Cx30/Cx47 double-null mice and control littermates, probably caused by the upregulation of oligodendrocytic Cx32 in Cx30/Cx47 double-deficient mice. We observed early onset myelin pathology, and ∼40% of Cx30/Cx47 double-deficient animals died within 42 to 90 d after birth, accompanied by severe motor impairments. Histological and ultrastructural analyses revealed severe vacuolization and myelination defects in all white matter tracts of the CNS. Furthermore, Cx30/Cx47 double-deficient mice exhibited a decreased number of oligodendrocytes, severe astrogliosis, and microglial activation in white matter tracts. Although less affected concerning motor impairment, surviving double-knock-out (KO) mice showed behavioral alterations in the open field and in the rotarod task. Vacuole formation and thinner myelin sheaths were evident also with adult surviving double-KO mice. Since interastrocytic coupling due to Cx43 expression and interoligodendrocytic coupling because of Cx32 expression are still maintained, Cx30/Cx47 double-deficient mice demonstrate the functional role of both connexins for interastrocytic, interoligodendrocytic, and panglial coupling, and show that both connexins are required for maintenance of myelin.

Peripheral lymphangiogenesis in mice depends on ectodermal connexin-26 (Gjb2).

In order to study the specific function of connexin-26 (Cx26, also known as gap junction beta-2 protein; Gjb2), we generated knockin mice that expressed either a floxed lacZ reporter or, after Cre-mediated deletion, connexin-32 (Cx32)-coding DNA, both driven by the endogenous Cx26 promoter. Heterozygous Cx26knock-inCx32 (Cx26KICx32) embryos developed normally until embryonic day 14.5 but died before birth with severe lymphedemas. Although the jugular lymph sacs were normally developed, these embryos had a strongly reduced dermal lymphatic capillary network. By analyses of ß-galactosidase reporter protein expression and lymphatic or blood endothelial-specific marker proteins, we demonstrated that Cx26 expression is temporally closely linked to lymphangiogenesis. No obvious phenotypic abnormalities were observed in Cx26KICx32 mice when Cre-mediated recombination was directed to mesenchyme or blood endothelium using the Prx1-Cre or Tie2-Cre mouse strains, respectively. By contrast, keratin-5-Cre-mediated replacement of Cx26 with Cx32 or deletion of both Cx26 alleles revealed severe lymphedemas similar to the general Cx26KICx32 phenotype. Thus, conditional ablation of Cx26 (loss of function) in ectoderm leads to partial disruption of lymphatic capillaries and embryonic death. We conclude that appropriate development of dermal lymphatic vessels in mice is dependent on the expression of Cx26 in the ectoderm.

Pathologic and phenotypic alterations in a mouse expressing a connexin47 missense mutation that causes Pelizaeus-Merzbacher-like disease in humans.

Gap junction channels are intercellular conduits that allow diffusional exchange of ions, second messengers, and metabolites. Human oligodendrocytes express the gap junction protein connexin47 (Cx47), which is encoded by the GJC2 gene. The autosomal recessive mutation hCx47M283T causes Pelizaeus-Merzbacher-like disease 1 (PMLD1), a progressive leukodystrophy characterized by hypomyelination, retarded motor development, nystagmus, and spasticity. We introduced the human missense mutation into the orthologous position of the mouse Gjc2 gene and inserted the mCx47M282T coding sequence into the mouse genome via homologous recombination in embryonic stem cells. Three-week-old homozygous Cx47M282T mice displayed impaired rotarod performance but unchanged open-field behavior. 10-15-day-old homozygous Cx47M282T and Cx47 null mice revealed a more than 80% reduction in the number of cells participating in glial networks after biocytin injections into oligodendrocytes in sections of corpus callosum. Homozygous expression of mCx47M282T resulted in reduced MBP expression and astrogliosis in the cerebellum of ten-day-old mice which could also be detected in Cx47 null mice of the same age. Three-month-old homozygous Cx47M282T mice exhibited neither altered open-field behavior nor impaired rotarod performance anymore. Adult mCx47M282T expressing mice did not show substantial myelin alterations, but homozygous Cx47M282T mice, additionally deprived of connexin32, which is also expressed in oligodendrocytes, died within six weeks after birth and displayed severe myelin defects accompanied by astrogliosis and activated microglia. These results strongly suggest that PMLD1 is caused by the loss of Cx47 channel function that results in impaired panglial coupling in white matter tissue.

Role of astroglial connexin30 in hippocampal gap junction coupling.

The impact of connexin30 (Cx30) on interastrocytic gap junction coupling in the normal hippocampus is matter of debate; reporter gene analyses indicated a weak expression of Cx30 in the mouse hippocampus. In contrast, mice lacking connexin43 (Cx43) in astrocytes exhibited only 50% reduction in coupling. Complete uncoupling of hippocampal astrocytes in mice lacking both Cx30 and Cx43 suggested that Cx30 participates in interastrocytic gap junction coupling in the hippocampus. With comparative reporter gene assays, immunodetection, and cre/loxP-based reporter approaches we demonstrate that Cx30 is more abundant than previously thought. The specific role of Cx30 in interastrocytic coupling has never been investigated. Employing tracer coupling analyses in acute slices of Cx30 deficient mice here we show that Cx30 makes a substantial contribution to interastrocytic gap junctional communication in the mouse hippocampus.

Dynamic expression of Cx47 in mouse brain development and in the cuprizone model of myelin plasticity.

The study shows the dynamic expression of connexin47 (Cx47) in oligodendrocytes and myelin of mice, either in myelinogenesis occurring in early development or in an experimental model of new-myelinogenesis of adult mice. Cx47 first appeared in the embryonic mouse brain at E10.5 successively the expression increased, principally in regions populated by developing oligodendrocytes. The expression declined postnatally toward adulthood and immunoreactivity was restricted to a few specific areas, such as the corpus callosum, the striatum, the cerebellum, and the spinal cord. Since the expression of Cx47 in developing oligodendrocytes preceded those of Cx32 and Cx29, a role of Cx47 in myelinogenesis was postulated. This hypothesis was tested in a model of re-myelination, which principally involved the corpus callosum, occurring in adult mice by treatment with cuprizone. Cx47 was upregulated during demyelination and recovered during the remyelination phase. During demyelination, Cx47 was first over-expressed in the corpus callosum and later, when the myelin virtually disappeared in the injured areas, Cx47 was expressed in astrocytes located inside and closely around the demyelinated areas. The remyelination of injured areas occurred after stopping the administration of cuprizone and continued to complete recovery. In this period the expression of Cx47 shifted from astrocytes to newly-formed myelin. Thus, Cx47 exhibits in this model a transient and de novo expression in astrocytes with a topographic segregation in the injured areas, only when oligodendrocytes and the myelin were most severely affected. Taken as a whole the evidence suggests that Cx47 play a key role in myelination.

Oligodendrocytes in mouse corpus callosum are coupled via gap junction channels formed by connexin47 and connexin32.

According to previously published ultrastructural studies, oligodendrocytes in white matter exhibit gap junctions with astrocytes, but not among each other, while in vitro oligodendrocytes form functional gap junctions. We have studied functional coupling among oligodendrocytes in acute slices of postnatal mouse corpus callosum. By whole-cell patch clamp we dialyzed oligodendrocytes with biocytin, a gap junction-permeable tracer. On average 61 cells were positive for biocytin detected by labeling with streptavidin-Cy3. About 77% of the coupled cells stained positively for the oligodendrocyte marker protein CNPase, 9% for the astrocyte marker GFAP and 14% were negative for both CNPase and GFAP. In the latter population, the majority expressed Olig2 and some NG2, markers for oligodendrocyte precursors. Oligodendrocytes are known to express Cx47, Cx32 and Cx29, astrocytes Cx43 and Cx30. In Cx47-deficient mice, the number of coupled cells was reduced by 80%. Deletion of Cx32 or Cx29 alone did not significantly reduce the number of coupled cells, but coupling was absent in Cx32/Cx47-double-deficient mice. Cx47-ablation completely abolished coupling of oligodendrocytes to astrocytes. In Cx43-deficient animals, oligodendrocyte-astrocyte coupling was still present, but coupling to oligodendrocyte precursors was not observed. In Cx43/Cx30-double deficient mice, oligodendrocyte-to-astrocyte coupling was almost absent. Uncoupled oligodendrocytes showed a higher input resistance. We conclude that oligodendrocytes in white matter form a functional syncytium predominantly among each other dependent on Cx47 and Cx32 expression, while astrocytic connexins expression can promote the size of this network.