Janna Enderich

Cooperative Function of POU Proteins and SOX Proteins in Glial Cells

Glial cells of the oligodendrocyte lineage express several highly related POU proteins including Tst-1/Oct6/SCIP and Brn-1. Tst-1/Oct6/SCIP, but not Brn-1 efficiently cooperated with Sox10, the only SRY box protein so far identified in oligodendrocytes. Here we show that, in addition to Sox10, cells of the oligodendrocyte lineage contain significant amounts of the related SRY box proteins Sox4 and Sox11. During development, Sox11 was strongly expressed in the central nervous system. It was first detected in neural precursors throughout the neuroepithelium. During later stages of neural development, Sox11 was additionally expressed in areas of the brain in which neurons undergo differentiation. In agreement with its expression in neural precursors, Sox11 levels in cells of the oligodendrocyte lineage were high in precursors and down-regulated during terminal differentiation. Outside the nervous system, expression of Sox11 was also detected in the developing limbs, face, and kidneys. Structure function analysis revealed that Sox11 has a strong intrinsic transactivation capacity which is mediated by a transactivation domain in its carboxyl-terminal part. In addition, Sox11 efficiently synergized with Brn-1. Synergy was dependent on binding of both proteins to adjacent DNA elements, and required the presence of the respective transactivation domain in each protein. Our data suggest the existence of a specific code in which POU proteins require specific Sox proteins to exhibit cooperative effects in glial cells.

Gene Targeting Reveals a Widespread Role for the High-Mobility-Group Transcription Factor Sox11 in Tissue Remodeling

ABSTRACT The high-mobility-group domain-containing transcription factor Sox11 is expressed transiently during embryonic development in many tissues that undergo inductive remodeling. Here we have analyzed the function of Sox11 by gene deletion in the mouse. Sox11-deficient mice died at birth from congenital cyanosis, likely resulting from heart defects. These included ventricular septation defects and outflow tract malformations that ranged from arterial common trunk to a condition known as double outlet right ventricle. Many other organs that normally express Sox11 also exhibited severe developmental defects. We observed various craniofacial and skeletal malformations, asplenia, and hypoplasia of the lung, stomach, and pancreas. Eyelids and the abdominal wall did not close properly in some Sox11-deficient mice. This phenotype suggests a prime function for Sox11 in tissue remodeling and identifies SOX11 as a potentially mutated gene in corresponding human malformation syndromes.

Placental Failure in Mice Lacking the Mammalian Homolog of Glial Cells Missing, GCMa

ABSTRACT The GCM family of transcription factors consists ofDrosophila melanogaster GCM, an important regulator of gliogenesis in the fly, and its two mammalian homologs, GCMa and GCMb. To clarify the function of these mammalian homologs, we deleted GCMa in mice. Genetic ablation of murine GCMa (mGCMa) is embryonic lethal, with mice dying between 9.5 and 10 days postcoitum. At the time of death, no abnormalities were apparent in the embryo proper. Nervous system development, in particular, was not impaired, as might have been expected in analogy to Drosophila GCM. Instead, placental failure was the cause of death. In agreement with the selective expression of mGCMa in labyrinthine trophoblasts, mutant placentas did not develop a functional labyrinth layer, which is necessary for nutrient and gas exchange between maternal and fetal blood. Only a few fetal blood vessels entered the placenta, and these failed to thrive and branch normally. Labyrinthine trophoblasts did not differentiate. All other layers of the placenta, including spongiotrophoblast and giant cell layer, formed normally. Our results indicate that mGCMa plays a critical role in trophoblast differentiation and the signal transduction processes required for normal vascularization of the placenta.

Muscarinic Acetylcholine Receptors Activate Expression of the Egr Gene Family of Transcription Factors

In order to search for genes that are activated by muscarinic acetylcholine receptors (mAChRs), we used an mRNA differential display approach in HEK293 cells expressing m1AChR. The zinc-finger transcription factor genes Egr-1,Egr-2, and Egr-3 were identified. Northern blot analyses confirmed that mRNA levels of Egr-1, Egr-2, and Egr-3 increased readily after m1AChR stimulation and that a maximum was attained within 50 min. At that time, Egr-4 mRNA was also detectable. Western blots and electromobility shift assays demonstrated synthesis of EGR-1 and EGR-3, as well as binding to DNA recognition sites in response to m1AChR activation. Activation of m1AChR increased transcription from EGR-dependent promoters, including the acetylcholinesterase gene promoter. Activity-dependent regulation of Egr-1 mRNA expression and EGR-1 protein synthesis was also observed in cells expressing m2, m3, or m4AChR subtypes. Increased EGR-1 synthesis was mimicked by phorbol myristate acetate, but not by forskolin, and receptor-stimulated EGR-1 synthesis was partially inhibited by phorbol myristate acetate down-regulation. Together, our results demonstrate that muscarinic receptor signaling activates the EGR transcription factor family and that PKC may be involved in intracellular signaling. The data suggest that transcription of EGR-dependent target genes, including the AChE gene, can be under the control of extracellular and intracellular signals coupled to muscarinic receptors.

Identification of the Nuclear Localization Signal of the POU Domain Protein Tst-1/Oct6

POU domain proteins are important regulators of development and terminal differentiation based upon their transcriptional activity in the nucleus. Here, we analyzed the mechanism underlying the nuclear localization of Tst-1/Oct6, a member of this family that regulates events during neurogenesis and myelination. Nuclear localization of Tst-1/Oct6 was dependent on the POU domain, as its deletion prevented access to the nucleus, whereas its transfer to the amino terminus of β-galactosidase was sufficient to prompt nuclear accumulation of this normally cytosolic protein. Interestingly, nuclear localization and high affinity DNA binding were two independent functions of the POU domain and could be separated in several mutants. While specific high affinity binding to DNA required the presence of both the POU-specific and the POU homeodomain, the POU-specific domain was dispensable for nuclear localization of Tst-1/Oct6. Rather, the nuclear localization function was selectively contained within the POU homeodomain. Specifically, a basic cluster (GRKRKKRT) preceding helix 1 of the homeodomain was shown by deletion mutagenesis to be involved in the nuclear localization of Tst-1/Oct6. This sequence, which is highly conserved among POU domain proteins, was by itself capable of translocating β-galactosidase to the nucleus defining it as the bona fide nuclear localization signal of Tst-1/Oct6 and presumably other POU domain factors.

Redundancy of Class III POU Proteins in the Oligodendrocyte Lineage

Class III POU proteins are prominent regulators of neural development. Tst-1/Oct6/SCIP, for instance, is essential for terminal differentiation of myelinating Schwann cells in the peripheral nervous system. Although Tst-1/Oct6/SCIP is also expressed in the myelin forming oligodendrocytes of the central nervous system, targeted deletion of Tst-1/Oct6/SCIP failed to reveal a gross alteration of myelination in the central nervous system. To better understand this apparent discrepancy, we examined the expression of POU proteins in both cultured primary oligodendrocytes and in the oligodendrocyte-like CG-4 cell line. These cells expressed Tst-1/Oct6/SCIP, Brn-1, and Brn-2 in significant amounts, indicating that Brn-1 and Brn-2 might have the capacity to compensate loss of Tst-1/Oct6/SCIP. We show that Tst-1/Oct6/SCIP, Brn-1, and Brn-2 were all down-regulated during the early phases of oligodendrocyte development both on RNA and protein level. All three POU proteins exhibited similar DNA binding characteristics. When promoters consisting of a single POU protein-binding site adjacent to a TATA box were used as reporters in transient transfections, Brn-1 proved to be a weaker transcriptional activator than Tst-1/Oct6/SCIP. In agreement with this, we found the transactivation domain of Brn-1, which we mapped between amino acids 119 and 237, significantly weaker than the transactivation domain of Tst-1/Oct6/SCIP. Taken together, our data imply a partial, but not complete redundancy between POU proteins in oligodendrocytes.

Muscarinic acetylcholine receptors activate the acetylcholinesterase gene promoter

The acetylcholinesterase (AChE) gene promoter contains several overlapping binding sites for Sp1 and Egr-1 transcription factors. Cotransfection experiments and promoter assays showed that Egr-1 can potently activate transcription from the human AChE promoter. Muscarinic acetylcholine receptors (mAChR) rapidly activate, via protein kinase C-mediated signaling, expression of the Egr-1 gene, leading to dramatically increased nuclear concentrations of Egr-1 protein, and to increased binding of Egr-1 to specific DNA recognition sequences. These mAChR-induced increases are followed by increased transcription from the human AChE promoter. In vivo studies with intraventricular infusions of the cholinergic immunotoxin 192 IgG saporin showed more than 80% decrease of AChE activity in cholinergic target areas of the hippocampus and brain cortex. The results are compatible with a combination of decreased AChE activity in degenerating subcortical cholinergic projections, and additional decreases in postsynaptic AChE gene expression. Together our data show that mAChR can activate transcription from the AChE promoter via increased synthesis of Egr-1. The results suggest a feedback mechanism by which the AChE gene is activated by cholinergic neurotransmission, possibly leading to increased formation of AChE protein and accelerated degradation of acetylcholine at cholinergic synapses. This possibility suggests testing of cholinomimetic compounds currently in development for the treatment of Alzheimers disease for their potential ability to increase AChE gene expression.

Expression of Krox Proteins During Differentiation of the O‐2A Progenitor Cell Line CG‐4

Abstract: Krox proteins are important regulators of development and terminal differentiation. Using the rat glial progenitor cell line CG‐4 as a model system for oligodendrocyte differentiation, we show that on the RNA level Krox‐24 is the predominant member of the Krox family in these cells. Similar results were also obtained on the protein level as the major Krox protein from CG‐4 cell extracts reacted specifically with an antibody against Krox‐24. Whereas Krox‐24 RNA and protein were abundant in undifferentiated CG‐4 cells, a dramatic decrease in expression was detected after a 3–5‐day period of differentiation during which we observed a reciprocal increase in the levels of myelin basic protein expression. Importantly, regulation of Krox‐24 expression was very similar in CG‐4 cells and primary oligodendrocyte cultures. When expression of Krox‐24 in differentiating CG‐4 cells was followed on a closer time scale, we observed a sharp and transient increase in Krox‐24 RNA, protein, and DNA binding activity immediately after the onset of differentiation followed by an equally rapid decrease. This expression pattern implicates Krox‐24 both in maintenance of the undifferentiated state and in the immediate early phase of differentiation of CG‐4 cells and possibly oligodendrocytes.

The J Domain of Papovaviral Large Tumor Antigen Is Required for Synergistic Interaction with the POU-Domain Protein Tst-1/Oct6/SCIP

ABSTRACT Large T antigens from polyomaviruses are multifunctional proteins with roles in transcriptional regulation, viral DNA replication, and cellular transformation. They have been shown to enhance the activity of various cellular transcription factors. In the case of the POU protein Tst-1/Oct6/SCIP, this enhancement involves a direct physical interaction between the POU domain of the transcription factor and the amino-terminal region of large T antigen. Here we have analyzed the structural requirements for synergistic interaction between the two proteins in greater detail. Tst-1/Oct6/SCIP and the related POU protein Brn-1 were both capable of direct physical interaction with large T antigen. Nevertheless, only Tst-1/Oct6/SCIP functioned synergistically with large T antigen. This differential behavior was due to differences in the amino-terminal regions of the proteins, as evident from chimeras between Tst-1/Oct6/SCIP and Brn-1. Synergy was specifically observed for constructs containing the amino-terminal region of Tst-1/Oct6/SCIP. Large T antigen, on the other hand, functioned synergistically with Tst-1/Oct6/SCIP only when the integrity of its J-domain-containing amino terminus was maintained. Mutations that disrupted the J domain concomitantly abolished the ability to enhance the function of Tst-1/Oct6/SCIP. The J domain of T antigen was also responsible for the physical interaction with Tst-1/Oct6/SCIP and could be replaced in this property by other J domains. Intriguingly, a heterologous J domain from a human DnaJ protein partially substituted for the amino terminus of T antigen even with regard to the synergistic enhancement of Tst-1/Oct6/SCIP function. Given the general role of J domains, we propose chaperone activity as the underlying mechanism for synergy between Tst-1/Oct6/SCIP and large T antigens.