Yoram Groner

The Runx3 transcription factor regulates development and survival of TrkC dorsal root ganglia neurons

The RUNX transcription factors are important regulators of linage‐specific gene expression in major developmental pathways. Recently, we demonstrated that Runx3 is highly expressed in developing cranial and dorsal root ganglia (DRGs). Here we report that within the DRGs, Runx3 is specifically expressed in a subset of neurons, the tyrosine kinase receptor C (TrkC) proprioceptive neurons. We show that Runx3‐deficient mice develop severe limb ataxia due to disruption of monosynaptic connectivity between intra spinal afferents and motoneurons. We demonstrate that the underlying cause of the defect is a loss of DRG proprioceptive neurons, reflected by a decreased number of TrkC‐, parvalbumin‐ and β‐galactosidase‐positive cells. Thus, Runx3 is a neurogenic TrkC neuron‐specific transcription factor. In its absence, TrkC neurons in the DRG do not survive long enough to extend their axons toward target cells, resulting in lack of connectivity and ataxia. The data provide new genetic insights into the neurogenesis of DRGs and may help elucidate the molecular mechanisms underlying somatosensory‐related ataxia in humans.

Runx3 and Runx1 are required for CD8 T cell development during thymopoiesis

The RUNX transcription factors are important regulators of lineage-specific gene expression. RUNX are bifunctional, acting both as activators and repressors of tissue-specific target genes. Recently, we have demonstrated that Runx3 is a neurogenic transcription factor, which regulates development and survival of proprioceptive neurons in dorsal root ganglia. Here we report that Runx3 and Runx1 are highly expressed in thymic medulla and cortex, respectively, and function in development of CD8 T cells during thymopoiesis. Runx3-deficient (Runx3 KO) mice display abnormalities in CD4 expression during lineage decisions and impairment of CD8 T cell maturation in the thymus. A large proportion of Runx3 KO peripheral CD8 T cells also expressed CD4, and in contrast to wild-type, their proliferation ability was largely reduced. In addition, the in vitro cytotoxic activity of alloimmunized peritoneal exudate lymphocytes was significantly lower in Runx3 KO compared with WT mice. In a compound mutant mouse, null for Runx3 and heterozygous for Runx1 (Runx3-/-;Runx1+/-), all peripheral CD8 T cells also expressed CD4, resulting in a complete lack of single-positive CD8+ T cells in the spleen. The results provide information on the role of Runx3 and Runx1 in thymopoiesis and suggest that both act as transcriptional repressors of CD4 expression during T cell lineage decisions.

Overproduction of human Cu/Zn-superoxide dismutase in transfected cells: extenuation of paraquat-mediated cytotoxicity and enhancement of lipid peroxidation.

The ‘housekeeping’ enzyme Cu/Zn‐superoxide dismutase (SOD‐1) is encoded by a gene residing on human chromosome 21, at the region 21q22 known to be involved in Downs syndrome. The SOD‐1 gene and the SOD‐1 cDNA were introduced into mouse L‐cells and human HeLa cells, respectively as part of recombinant plasmids containing the neoR selectable marker. Human and mouse transformants were obtained that expressed elevated levels (up to 6‐fold) of authentic, enzymatically active human SOD‐1. This enabled us to examine the consequences of hSOD‐1 gene dosage, apart from gene dosage effects contributed by other genes residing on chromosome 21. Human and mouse cell clones that overproduce the hSOD‐1 had altered properties; they were more resistant to paraquat than the parental cells and showed an increase in lipid peroxidation. The data are consistent with the possibility that gene dosage of hSOD‐1 contributes to some of the clinical symptoms associated with Downs syndrome.

Runx3 and T-box proteins cooperate to establish the transcriptional program of effector CTLs

Activation of naive CD8+ T cells with antigen induces their differentiation into effector cytolytic T lymphocytes (CTLs). CTLs lyse infected or aberrant target cells by exocytosis of lytic granules containing the pore-forming protein perforin and a family of proteases termed granzymes. We show that effector CTL differentiation occurs in two sequential phases in vitro, characterized by early induction of T-bet and late induction of Eomesodermin (Eomes), T-box transcription factors that regulate the early and late phases of interferon (IFN) γ expression, respectively. In addition, we demonstrate a critical role for the transcription factor Runx3 in CTL differentiation. Runx3 regulates Eomes expression as well as expression of three cardinal markers of the effector CTL program: IFN-γ, perforin, and granzyme B. Our data point to the existence of an elaborate transcriptional network in which Runx3 initially induces and then cooperates with T-box transcription factors to regulate gene transcription in differentiating CTLs.

Structure and regulated expression of mammalian RUNX genes

The RUNX are key regulators of lineage-specific gene expression in major developmental pathways. The expression of RUNX genes is tightly regulated, leading to a highly specific spatio/temporal expression pattern and to distinct phenotypes of gene knockouts. This review highlights the extensive structural similarities between the three mammalian RUNX genes and delineates how regulation of their expression at the levels of transcription and translation are orchestrated into the unique RUNX expression pattern.

Runx3 regulates mouse TGF-β-mediated dendritic cell function and its absence results in airway inflammation

Runx3 transcription factor regulates cell lineage decisions in thymopoiesis and neurogenesis. Here we report that Runx3 knockout (KO) mice develop spontaneous eosinophilic lung inflammation associated with airway remodeling and mucus hypersecretion. Runx3 is specifically expressed in mature dendritic cells (DC) and mediates their response to TGF‐β. In the absence of Runx3, DC become insensitive to TGF‐β‐induced maturation inhibition, and TGF‐β‐dependent Langerhans cell development is impaired. Maturation of Runx3 KO DC is accelerated and accompanied by increased efficacy to stimulate T cells and aberrant expression of β2‐integrins. Lung alveoli of Runx3 KO mice accumulate DC characteristic of allergic airway inflammation. Taken together, abnormalities in DC function and subset distribution may constitute the primary immune system defect, which leads to the eosinophilic lung inflammation in Runx3 KO mice. These data may help elucidate the molecular mechanisms underlying the pathogenesis of allergic airway inflammation in humans.

Architecture and anatomy of the chromosomal locus in human chromosome 21 encoding the Cu/Zn superoxide dismutase.

The SOD‐1 gene on chromosome 21 and approximately 100 kb of chromosomal DNA from the 21q22 region have been isolated and characterized. The gene which is present as a single copy per haploid genome spans 11 kb of chromosomal DNA. Heteroduplex analysis and DNA sequencing reveals five rather small exons and four introns that interrupt the coding region. The donor sequence at the first intron contains an unusual variant dinucleotide 5′‐G‐C, rather than the highly conserved 5′‐GT. The unusual splice junction is functional in vivo since it was detected in both alleles of the SOD‐1 gene, which were defined by differences in the length of restriction endonuclease fragments (RFLPs) that hybridize to the cDNA probe. Genomic blots of human DNA isolated from cells trisomic for chromosome 21 (Downs syndrome patients) show the normal pattern of bands. At the 5′ end of gene there are the ‘TATA’ and ‘CAT’ promoter sequences as well as four copies of the ‐GGCGGG‐ hexanucleotide. Two of these ‐GC‐ elements are contained within a 13 nucleotide inverted repeat that could form a stem‐loop structure with stability of ‐33 kcal. The 3′‐non coding region of the gene contains five short open reading‐frames starting with ATG and terminating with stop codons.

Down's syndrome: abnormal neuromuscular junction in tongue of transgenic mice with elevated levels of human Cu/Zn-superoxide dismutase

To investigate the possible involvement of Cu/Zn-superoxide dismutase (CuZnSOD) gene dosage in the neuropathological symptoms of Downs syndrome, we analyzed the tongue muscle of transgenic mice that express elevated levels of human CuZnSOD. The tongue neuromuscular junctions (NMJ) in the transgenic animals exhibited significant pathological changes, namely, withdrawal and destruction of some terminal axons and the development of multiple small terminals. The ratio of terminal axon area to postsynaptic membrane decreased, and secondary folds were often complex and hyperplastic. The morphological changes in the transgenic NMJ were similar to those previously seen in muscles of aging mice and rats as well as in tongue muscle of patients with Downs syndrome. The findings suggest that CuZnSOD gene dosage is involved in the pathological abnormalities of tongue NMJ observed in Downs syndrome patients.

Reversible impairment of long‐term potentiation in transgenic Cu/Zn‐SOD mice

Copper/zinc superoxide dismutase (CuZn‐SOD) is a key enzyme in the metabolism of oxygen free radicals. The gene encoding CuZn‐SOD resides on human chromosome 21 and is overexpressed in Down syndrome (DS) patients. Overexpression of CuZn‐SOD in transgenic (Tg) mice and cultured cells creates chronic oxidative stress leading to enhanced susceptibility to degeneration and apoptotic cell death. We have now found that three lines of Tg‐CuZn‐SOD mice, one of which also overexpresses S100β, a glial calcium binding protein, are deficient in spatial memory. Furthermore, hippocampal slices taken from these mice have an apparently normal synaptic physiology, but are impaired in the ability to express long‐term potentiation (LTP). This effect on hippocampal LTP was abrogated by treatment of slices with the H2O2 scavenger catalase or the antioxidant N‐t‐butyl‐phenylnitrone (BPN). It is proposed that elevated CuZnSOD causes an increase in tetanic stimulation‐evoked formation of H2O2 which leads to diminished LTP and cognitive deficits in these mice.

Human Gene-Centric Databases at the Weizmann Institute of Science: GeneCards, UDB, CroW 21 and HORDE

Recent enhancements and current research in the GeneCards (GC) (http://bioinfo.weizmann.ac.il/cards/) project are described, including the addition of gene expression profiles and integrated gene locations. Also highlighted are the contributions of specialized associated human gene-centric databases developed at the Weizmann Institute. These include the Unified Database (UDB) (http://bioinfo.weizmann.ac.il/udb) for human genome mapping, the human Chromosome 21 database at the Weizmann Insti-tute (CroW 21) (http://bioinfo.weizmann.ac.il/crow21), and the Human Olfactory Receptor Data Explora-torium (HORDE) (http://bioinfo.weizmann.ac.il/HORDE). The synergistic relationships amongst these efforts have positively impacted the quality, quantity and usefulness of the GeneCards gene compendium.