Martine Jaegle scite author profile

The genetic hierarchy that controls myelination of peripheral nerves by Schwann cells includes the POU domain Oct-6/Scip/Tst-1 and the zinc-finger Krox-20/Egr2 transcription factors. These pivotal transcription factors act to control the onset of myelination during development and tissue regeneration in adults following damage. In this report we demonstrate the involvement of a third transcription factor, the POU domain factor Brn-2. We show that Schwann cells express Brn-2 in a developmental profile similar to that of Oct-6 and that Brn-2 gene activation does not depend on Oct-6. Overexpression of Brn-2 in Oct-6-deficient Schwann cells, under control of the Oct-6 Schwann cell enhancer (SCE), results in partial rescue of the developmental delay phenotype, whereas compound disruption of both Brn-2 and Oct-6 results in a much more severe phenotype. Together these data strongly indicate that Brn-2 function largely overlaps with that of Oct-6 in driving the transition from promyelinating to myelinating Schwann cells. The high conduction velocity of nerve fibers is a hallmark of the nervous system of higher vertebrates and depends on structural and molecular specializations that are elaborated during development. These specializations occur through intimate and continued interactions between the neuron and its associated glial cells and result in the elaboration by glial cells of myelin, the important membranous structure that ensheaths and insulates axons (Arroyo and Scherer 2000; Fields and StevensGraham 2002;Mirsky et al. 2002). Two glial cell types produce myelin: the oligodendrocyte in the central nervous system (CNS) and the Schwann cell in the peripheral nervous system (PNS). Although very similarly organized, the molecular composition of CNS and PNS myelin differs significantly, and oligodendrocytes and Schwann cells have adopted different, but overlapping, sets of transcriptional regulators to coordinate myelogenesis (Hudson 2001; Topilko and Meijer 2001). These differences reflect their distinct embryonic origins. Whereas oligodendrocytes originate from the neuroepithelial precursors that line the lumen of the spinal cord and ventricles of the brain, Schwann cells derive mainly from the neural crest, a transient embryonic stem (ES) cell population that generates a wide variety of cell types including sensory and autonomic neurons and melanocytes (Le Douarin and Kalcheim 1999;Richardson 2001). Schwann cell precursors populate the early outgrowing nerve bundles, where they proliferate and segregate individual and groups of fibers until the number of Schwann cells and fibers is eventually matched. During the first few days of postnatal development, many Schwann cells establish a 1:1 relationship with axons, cease to proliferate, and initiate myelin formation such that by the end of the first postnatal week of development, all myelin-competent axons are actively being myelinated. Schwann cells that remain associated with groups of lower-caliber fibers will segregate these fibers in cytoplasmic cuffs without mye...

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The POU Factor Oct-6 and Schwann Cell Differentiation

Jaegle

Mandemakers

Broos

et al. 1996

Science

277

257

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The POU transcription factor Oct-6, also known as SCIP or Tst-1, has been implicated as a major transcriptional regulator in Schwann cell differentiation. Microscopic and immunochemical analysis of sciatic nerves of Oct-6(-/-) mice at different stages of postnatal development reveals a delay in Schwann cell differentiation, with a transient arrest at the promyelination stage. Thus, Oct-6 appears to be required for the transition of promyelin cells to myelinating cells. Once these cells progress past this point, Oct-6 is no longer required, and myelination occurs normally.

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The translocation (6;9), associated with a specific subtype of acute myeloid leukemia, results in the fusion of two genes, dek and can, and the expression of a chimeric, leukemia-specific dek-can mRNA.

et al. 1992

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The translocation (6;9) is associated with a specific subtype of acute myeloid leukemia (AML). Previously, it was found that breakpoints on chromosome 9 are clustered in one of the introns of a large gene named Cain (can). cDNA probes derived from the 3' part of can detect an aberrant, leukemia-specific 5.5-kb transcript in bone marrow cells from t(6;9) AML patients. cDNA cloning of this mRNA revealed that it is a fusion of sequences encoded on chromosome 6 and 3' can. A novel gene on chromosome 6 which was named dek was isolated. In dek the t(6;9) breakpoints also occur in one intron. As a result the dek-can fusion gene, present Defined karyotypic aberrations are associated with specific subtypes of leukemia. Detailed molecular characterization of these aberrations may identify genes involved in leukemogenesis and in the precise regulation of proliferation and differentiation in the hematopoietic system. Translocations are the best-studied chromosomal abnormalities. As the result of a translocation, the function or activity of oncogenes located at or near the translocation breakpoint is altered. In myeloid leukemia three translocation breakpoints have been cloned and analyzed at the molecular level.The two best studied, t(9;22) in chronic myeloid leukemia (27, 43) and t(15;17) in acute promyelocytic leukemia (2,8,12), result in the formation of chimeric genes that encode fusion proteins. In chronic myeloid leukemia this is a BCR-ABL protein that has an enhanced tyrosine kinase activity (34, 49) directly responsible for its in vivo tumorigenic potential (14,25). In acute promyelocytic leukemia a PMLRARa fusion protein that represents an altered transcription factor (16, 33) is found.The third translocation is the t(6;9) (p23;q34), found in a specific subtype of acute myeloid leukemia (AML) (1,39,41). This leukemia is characterized by a poor prognosis, affects young adults, and is classified mostly as M2 or M4 and rarely as Ml (according to the French-American-British classification of AML). A region on chromosome 9 situated 360 kb downstream of the c-abl gene was cloned and analyzed. It was found that breakpoints were clustered in a region of 8 kb in five patients, four with t(6;9) AML and one with acute undifferentiated leukemia (AUL) (47). Through cDNA cloning this region could be identified as one of the introns of a large gene (>100 kb) encoding a 7-kb transcript. This intron was named icb-9; the intron containing the breakpoints on chromosome 9 and situated in the middle of * Corresponding author. a gene named Cain (can). The 3' part of can is translocated to the 6p-chromosome, and only 3' can probes detect an additional, leukemia-specific 5.5-kb transcript in bone marrow cells from t(6;9) AML patients. No additional transcripts were detected with 5' can probes. The breakpoint region on chromosome 6p23 was isolated from a genomic XEMBL3 library constructed of bone marrow DNA from one of the t(6;9) patients. An area of 40 kb of chromosome 6 DNA was cloned in overlapping phages. Southern blot analysis sh...

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Neural crest stem cells undergo multilineage differentiation in developing peripheral nerves to generate endoneurial fibroblasts in addition to Schwann cells

et al. 2004

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Neural crest stem cells (NCSCs) persist in peripheral nerves throughout late gestation but their function is unknown. Current models of nerve development only consider the generation of Schwann cells from neural crest, but the presence of NCSCs raises the possibility of multilineage differentiation. We performed Crerecombinase fate mapping to determine which nerve cells are neural crest derived. Endoneurial fibroblasts, in addition to myelinating and non-myelinating Schwann cells, were neural crest derived, whereas perineurial cells, pericytes and endothelial cells were not. This identified endoneurial fibroblasts as a novel neural crest derivative, and demonstrated that trunk neural crest does give rise to fibroblasts in vivo, consistent with previous studies of trunk NCSCs in culture. The multilineage differentiation of NCSCs into glial and non-glial derivatives in the developing nerve appears to be regulated by neuregulin, notch ligands, and bone morphogenic proteins, as these factors are expressed in the developing nerve, and cause nerve NCSCs to generate Schwann cells and fibroblasts, but not neurons, in culture. Nerve development is thus more complex than was previously thought, involving NCSC self-renewal, lineage commitment and multilineage differentiation.

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Targeted mutation of Cyln2 in the Williams syndrome critical region links CLIP-115 haploinsufficiency to neurodevelopmental abnormalities in mice

et al. 2002

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Williams syndrome is a neurodevelopmental disorder caused by the hemizygous deletion of 1.6 Mb on human chromosome 7q11.23. This region comprises the gene CYLN2, encoding CLIP-115, a microtubule-binding protein of 115 kD. Using a gene-targeting approach, we provide evidence that mice with haploinsufficiency for Cyln2 have features reminiscent of Williams syndrome, including mild growth deficiency, brain abnormalities, hippocampal dysfunction and particular deficits in motor coordination. Absence of CLIP-115 also leads to increased levels of CLIP-170 (a closely related cytoplasmic linker protein) and dynactin at the tips of growing microtubules. This protein redistribution may affect dynein motor regulation and, together with the loss of CLIP-115-specific functions, underlie neurological alterations in Williams syndrome.

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Martine Jaegle

The POU proteins Brn-2 and Oct-6 share important functions in Schwann cell development

The POU Factor Oct-6 and Schwann Cell Differentiation

The translocation (6;9), associated with a specific subtype of acute myeloid leukemia, results in the fusion of two genes, dek and can, and the expression of a chimeric, leukemia-specific dek-can mRNA.

Neural crest stem cells undergo multilineage differentiation in developing peripheral nerves to generate endoneurial fibroblasts in addition to Schwann cells

Targeted mutation of Cyln2 in the Williams syndrome critical region links CLIP-115 haploinsufficiency to neurodevelopmental abnormalities in mice

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