The human reelin gene: isolation, sequencing, and mapping on chromosome 7.

The mouse reelin gene (Reln) encodes a novel protein that, when mutated, results in the characteristic reeler phenotype. A key component of this phenotype is the extensive disruption of the organization of many brain structures. Reelin is believed to be an extracellular protein that controls neural cell positioning during brain development. The reelin gene is conserved in many vertebrate species, including humans. To study the role of the reelin homolog in human brain development, we have isolated and characterized the human gene (RELN). Like its murine counterpart, RELN is large, encoding an mRNA of approximately 12 kb. Overlapping cDNA clones containing the entire open reading frame were isolated and sequenced, revealing that the predicted mouse and human proteins are similar in size (388 kD) and that the amino acid and nucleotide sequences are 94.2% and 87.2% identical, respectively. Northern hybridization analyses revealed that RELN is expressed in fetal and postnatal brain as well as liver. The expression of RELN in postnatal human brain was high in the cerebellum. RELN was mapped to human chromosome 7q22, based on both fluorescence in situ hybridization studies and localization within a well-positioned yeast artificial chromosome (YAC) contig. The YAC contig also contains a number of gentic markers. Together, these studies provide the sequence information and genetic tools for performing more detailed analyses of RELN in an attempt to define its role in human brain development and possibly in human disease.

Detection of the reelin breakpoint in reeler mice.

Disruption of the reelin gene by partial deletion causes the neurological phenotype known as reeler. Here we report the cloning and sequencing of the reelin breakpoint region from the Jackson reeler strain (rl). Based on this sequence, we developed a polymerase chain reaction screen that allows the identification of mutant mice prior to the appearance of the phenotype. The assay also permits discrimination of heterozygous from wild-type mice. These findings provide a strategy for the characterization of the early anatomical and physiological consequences of the reeler mutation.

A protein related to extracellular matrix proteins deleted in the mouse mutant reeler.

The autosomal recessive mouse mutation reeler leads to impaired motor coordination, tremors and ataxia. Neurons in affected mice fail to reach their correct locations in the developing brain, disrupting the organization of the cerebellar and cerebral cortices and other laminated regions. Here we use a previously characterized reeler allele (rl(tg)) to close a gene, reelin, deleted in two reeler alleles. Normal but not mutant mice express reelin in embryonic and postnatal neurons during periods of neuronal migration. The encoded protein resembles extracellular matrix proteins involved in cell adhesion. The reeler phenotype thus seems to reflect a failure of early events associated with brain lamination which are normally controlled by reelin.

Isolation of an allele of reeler by insertional mutagenesis.

Reeler (rl) is an autosomal recessive mutation that affects migration of postmitotic neurons in the mouse central nervous system. The reeler (rl/rl) mouse displays a disruption of laminar structures in both the cerebellum and the forebrain and it exhibits tremors, dystonia, and ataxia. The molecular basis of the reeler phenotype is unknown because the gene involved has not yet been identified. We report here the isolation and characterization of an allele of rl, reelertransgene (rltg). This allele was generated by the fortuitous insertion of a transgene, supfos (sf), into the mouse rl locus. Crosses between rl/+ and rltg/+ mice yielded offspring that exhibited the reeler phenotype, indicating that rl and rltg are allelic. We cloned the genomic sequences flanking the transgene insertion site from the rltg/rltg mouse genome. Chromosomal mapping studies revealed that the 5' flanking cellular sequence maps to a locus, D5Gmr1, that lies in a region of mouse chromosome 5 that also contains the rl locus. Southern blot analysis using a probe derived from the D5Gmr1 locus revealed no gross structural rearrangement in the rl locus. Thus, unlike the two rl alleles described previously, rltg provides a molecular probe that can now be used to identify and isolate the rl gene.

Cell transformation by c-fos requires an extended period of expression and is independent of the cell cycle.

The proto-oncogene transcription factors Fos and Jun form a heterodimeric complex that binds to DNA and regulates expression of specific target genes. Continuous expression of c-fos causes transformation of cultured fibroblasts and induces osteogenic sarcoma in mice. To investigate the molecular basis of fos-mediated oncogenesis, we developed a conditional cell transformation system in which Fos expression was regulated by isopropyl-beta-D-thiogalactopyranoside (IPTG). Synthesis or repression of Fos in L1-3c-fos cells occurred rapidly, within 30 min, after the removal or addition of IPTG to the culture medium. However, there was a significant delay between the induction of Fos expression and the appearance of morphological transformation. No effect was observed after 12 h of Fos expression, partial transformation was detected after 24 h, and full transformation required approximately 3 days of continuous Fos expression. Similarly, the transformed cell morphology persisted for at least 2 days after repression of Fos, and a normal phenotype was observed only after 3 days. Fos-Jun complexes, capable of binding to AP-1 sequences, were present continuously during the delay in morphological transformation. Furthermore, increased expression of several candidate Fos target genes, including those encoding Fra-1, transin (stromelysin), collagenase, and ornithine decarboxylase, was detected shortly after Fos induction. The induction of morphological transformation was not dependent on the cell cycle, as it occurred in both cycling and noncycling cells. Thus, the Fos-Jun complexes present before L1-3c-fos cells become fully transformed are transcriptionally active. These complexes disappeared, and the Fos target genes were repressed at least 2 days prior to reversion. Our results suggest that cell transformation by Fos requires increased expression of a target gene(s) with a long-lived product(s) that must reach a critical level.

The redox and DNA-repair activities of Ref-1 are encoded by nonoverlapping domains.

The DNA binding activity of transcription factor AP-1 is regulated in vitro by a posttranslational mechanism involving reduction/oxidation (redox). Redox regulation is mediated by a conserved cysteine residue in the DNA-binding domain of Fos and Jun. Previously, we demonstrated that a DNA repair protein, Ref-1, could stimulate the DNA binding activity of Fos-Jun dimers by reducing this cysteine residue. To examine the relationship between the redox and repair functions of Ref-1, we generated a series of deletion mutants. Analysis of the truncated proteins in vitro revealed that the redox and repair activities are encoded by distinct regions of Ref-1. Sequences in the N-terminal domain of Ref-1 that are not present in functionally related proteins from other organisms are required for the redox activity, whereas the DNA repair activity requires conserved C-terminal sequences. Chemical alkylation or oxidation of cysteine sulfhydryls inhibits the redox activity of Ref-1 without affecting its DNA repair activity. Crosslinking studies suggest that a direct cysteine-mediated interaction occurs between Ref-1 and Jun.

Continuous c-fos expression precedes programmed cell death in vivo.

The development of a multicellular organism involves a delicate balance among the processes of proliferation, differentiation and death. Naturally occurring cell death aids tissue remodelling, eliminates supernumerary cell populations and provides structural elements such as hair and skin. In the nervous system, selective cell death contributes to the formation and organization of the spinal cord and sympathetic ganglia, retina and corpus callosum. But cell death also occurs in several neuropathological conditions, such as amyelotrophic lateral sclerosis and Alzheimer's disease. Therefore an elucidation of the mechanisms responsible for cell death is critical for an appreciation of both normal development and neuropathological disorders. Using a fos-lacZ transgenic mouse, we provide evidence showing that the continuous expression of Fos, beginning hours or days before the morphological demise of the cell, appears to be a hallmark of terminal differentiation and a harbinger of death.