c-ABL gene expression and spermatogenesis : investigations into the possible role of octamer transcription factors

The work described in this thesis aims at the elucidation of mechanisms that govern cellular differentiation events in male germ cell development (spermatogenesis), especially during the post-meiotic phase (spermiogenesis). and in embryonal carcinoma cells. Chapter II describes the molecular characterization of a variant c-abl mANA (TSabl) that is specifically expressed at high levels during spermiogenesis and was suggested to play an important role in this proces. The TSabl mANA is transcribed from the proximal of the two c-abl promoters and is alternatively processed resulting in a removal of most of the 3'UTA, without an effect on the coding capicity of the mANAs. The high levels of this shortened mANA in post-meiotic male germ cells could be due to two not mutually exclusive mechanisms, i.e. a higher mANA stability or/and continued transcription of the gene during the later phases of spermiogenesis. Chapter Ill describes experiments that tried to address the question whether the TSabl mANA has a longer half life as a consequence of the removal of most of the 3'UTA. In chapter IV a preliminary analysis of the c-abl promoter is presented, using DNAsel footprinting and gel retardation assays. The results of these experiments hinted at the possibility that there exists a testis specific octamer binding factor that could be involved in the haploid specific regulation of gene expression. This stimulated us to undertake the experiments described in chapter V that aimed at the cloning of testis specific cDNAs encoding octamer binding factors. We show that the POU domain gene Oct2 is highly expressed in spermatogenic cells, generating two transcripts through a mechanism of alternative processing and/or promoter usage. This chapter closes with a discussion of testis specific gene expression. The temporally regulated expression of a family of octamer binding factors during 'neuronal 'differentiation of P19 EC cells is described in chapter VI. One factor, Oct6, is expressed in a bi-phasic pattern, suggesting that it might play a role at different stages of development. This factor is further characterized by cloning of the cognate eDNA and was found to be the mouse homologue of the rat Tst-1 POU gene [29]. This gene is highly expressed in rat testis but not in mouse testis (this thesis). Chapter VII describes the functional mapping of the protein domains involved in transcriptional activation and DNA binding. In chapter VIII the genomic organization of the Oct6 gene is described. Furthermore, we present an initial characterization of the Oct6 promoter, to begin to address the important question of how this transcriptional regulator is regulated itself. In the last chapter some aspects of the Oct6 gene are discussed in relation to its possible function in differentiation, drawing on examples from other members of the POU domain gene famil

The restricted expression pattern of the POU factor Oct-6 during early development of the mouse nervous system

Oce-6 is a POU transcription factor that is thought to play a role in the differentiation of cells of neuroectodermal origin. To investigate whether the Oct-6 protein could play a role in the establishment of neuroectoderm in vivo we studied the expression of the Oct-6 protein during early mouse development. Expression is first observed in the primitive ectoderm of the egg cylinder stage embryo. In gastrulating embryos, Oct-6 protein is found in the extra-embryonic ectoderm of the chorion and the anterior ectoderm of the embryo proper. As development proceeds, Oct-6 expression becomes more restricted to the anterior medial part of the embryo until Oct-6 positive cells are observed only in the neural groove of the headfold stage embryo. In the late headfold stage embryo, Oct-6 expression is detected in the neuroepithelium of the entire brain and later is restricted to a more ventral and anterior position. As the anterior neuropore closes, Oct-6 protein is detected in a segment-like pattern in the mid- and forebrain. Thus, the expression pattern of the Oct-6 gene agrees with a role for the Oct-6 protein in the establishment and regional specification of the neuroectoderm in vivo. The two waves of widespread induction of the Oct-6 gene, one in the primitive ectoderm and another in the primitive brain, both followed by a progressive restriction in the expression patterns suggest a mechanism for the regulation of the gene

LGI proteins in the nervous system

The development and function of the vertebrate nervous system depend on specific interactions between different cell types. Two examples of such interactions are synaptic transmission and myelination. LGI1-4 (leucine-rich glioma inactivated proteins) play important roles in these processes. They are secreted proteins consisting of an LRR (leucinerich repeat) domain and a so-called epilepsy-associated or EPTP (epitempin) domain. Both domains are thought to function in protein-protein interactions. The first LGI gene to be identified, LGI1, was found at a chromosomal translocation breakpoint in a glioma cell line. It was subsequently found mutated in ADLTE (autosomal dominant lateral temporal (lobe) epilepsy) also referred to as ADPEAF (autosomal dominant partial epilepsy with auditory features). LGI1 protein appears to act at synapses and antibodies against LGI1 may cause the autoimmune disorder limbic encephalitis. A similar function in synaptic remodelling has been suggested for LGI2, which is mutated in canine Benign Familial Juvenile Epilepsy. LGI4 is required for proliferation of glia in the peripheral nervous system and binds to a neuronal receptor, ADAM22, to foster ensheathment and myelination of axons by Schwann cells. Thus, LGI proteins play crucial roles in nervous system development and function and their study is highly important, both to understand their biological functions and for their therapeutic potential. Here, we review our current knowledge about this important family of proteins, and the progress made towards understanding their functions

A tissue-specific knockout reveals that Gata1 is not essential for Sertoli cell function in the mouse

The transcription factor Gata1 is essential for the development of erythroid cells. Consequently, Gata1 null mutants die in utero due to severe anaemia. Outside the haematopoietic system, Gata1 is only expressed in the Sertoli cells of the testis. To elucidate the function of Gata1 in the testis, we made a Sertoli cell-specific knockout of the Gata1 gene in the mouse. We deleted a normally functioning 'floxed' Gata1 gene in pre-Sertoli cells in vivo through the expression of Cre from a transgene driven by the Desert Hedgehog promoter. Surprisingly, Gata1 null testes developed to be morphologically normal, spermatogenesis was not obviously affected and expression levels of putative Gata1 target genes, and other Gata factors, were not altered. We conclude that expression of Gata1 in Sertoli cells is not essential for testis development or spermatogenesis in the mouse

The rat androgen receptor gene promoter

The androgen receptor (AR) is activated upon binding of testosterone or dihydrotestosterone and exerts regulatory effects on gene expression in androgen target cells. To study transcriptional regulation of the rat AR gene itself, the 5' genomic region of this gene was cloned from a genomic library and the promoter was identified. S1-nuclease protection analysis showed two major transcription start sites, located between 1010 and 1023 bp upstream from the translation initiation codon. The area surrounding these start sites was cloned in both orientations in a CAT reporter plasmid. Upon transfection of the constructs into COS cells, part of the promoter stimulated transcription in an orientation-independent manner, but the full promoter showed a higher and unidirectional activity. In the promoter/reporter gene constructs, transcription initiated from the same positions as in the native gene. Sequence analysis showed that the promoter of the rat AR gene lacks typical TATA and CCAAT box elements, but one SP1 site is located at about 60 bp upstream from the major start site of transcription. Other possible promoter elements are TGTYCT sequences at positions -174 to -179, -434 to -439., -466 to -471, and -500 to -505, resembling half-sites of the glucocorticoid-responsive element (GRE). Furthermore, a homopurine stretch containing a total of 8 GGGGA elements and similar to sequences that are present in several other GC-rich promoters, is located between -89 and -146 bp upstream from the major start site of transcriptio

Evolution and mutagenesis of the mammalian excision repair gene ERCC-1

The human DNA excision repair protein ERCC-1 exhibits homology to the yeast RADIO repair protein and its longer C-terminus displays similarity to parts of the E.coli repair proteins uvrA and uvrC. To study the evolution of this 'mosaic' ERCC-1 gene we have isolated the mouse homologue. Mouse ERCC-1 harbors the same pattern of homology with RAD10 and has a comparable C-terminal extension as its human equivalent. Mutation studies show that the strongly conserved C-terminus is essential in contrast to the less conserved N-terminus which is even dispensible. The mouse ERCC-1 amino acid sequence is compatible with a previously postulated nuclear location signal and DNA-binding domain. The ERCC-1 promoter harbors a region which is highly conserved in mouse and man. Since the ERCC-1 promoter is devoid of all classical promoter elements this region may be responsible for the low constitutive level of expression in all mouse tissues and stages of embryogenesis examined

The structure of a human neurofilament gene (NF-L): A unique exon-intron organization in the intermediate filament gene family.

We have cloned and determined the nucleotide sequence of the human gene for the neurofilament subunit NF-L. The cloned DNA contains the entire transcriptional unit and generates two mRNAs of approx. 2.6 and 4.3 kb after transfection into mouse L-cells. The NF-L gene has an unexpected intron-exon organization in that it entirely lacks introns at positions found in other members of the intermediate filament gene family. It contains only three introns that do not define protein domains. We discuss possible evolutionary schemes that could explain these results

The human neurofilament gene (NEFL) is located on the short arm of chromosome 8.

We have localized the gene coding for the human neurofilament light chain (NEFL) to chromosome band 8p2.1 by Southern blotting of DNA from hybrid cell panels and in situ hybridization to metaphase chromosomes

The POU factor Oct-6 is required for the progression of Schwann cell differentiation in peripheral nerves.

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

ADAM22, a Kv1 channel-interacting protein, recruits membrane-associated guanylate kinases to juxtaparanodes of myelinated axons

Clustered Kv1 K+channels regulate neuronal excitability at juxtaparanodes of myelinated axons, axon initial segments, and cerebellar basket cell terminals (BCTs). These channels are part of a larger protein complex that includes cell adhesion molecules and scaffolding proteins. To identify proteins that regulate assembly, clustering, and/or maintenance of axonal Kv1 channel protein complexes, we immunoprecipitated Kv1.2 αsubunits, and then used mass spectrometry to identify interacting proteins.We found that a disintegrin and metalloproteinase 22 (ADAM22) is a component of the Kv1 channel complex and that ADAM22 coimmunoprecipitates Kv1.2 and the membrane-associated guanylate kinases (MAGUKs) PSD-93 and PSD-95. When coexpressed with MAGUKs in heterologous cells, ADAM22 and Kv1 channels are recruited into membrane surface clusters. However, coexpression of Kv1.2 with ADAM22 and MAGUKs does not alter channel properties. Among all the known Kv1 channel-interacting proteins, only ADAM22 is found at every site where Kv1 channels are clustered. Analysis of Caspr-null mice showed that, like other previously described juxtaparanodal proteins, disruption of the paranodal junction resulted in redistribution of ADAM22 into paranodal zones. Analysis of Caspr2-, PSD-93-, PSD-95-, and double PSD-93/PSD-95-null mice showed ADAM22 clustering at BCTs requires PSD-95, but ADAM22 clustering at juxtaparanodes requires neither PSD-93 nor PSD-95. In direct contrast, analysis of ADAM22-null mice demonstrated juxtaparanodal clustering of PSD-93 and PSD-95 requires ADAM22, whereas Kv1.2 and Caspr2 clustering is normal in ADAM22-null mice. Thus, ADAM22 is an axonal component of the Kv1 K+channel complex that recruits MAGUKs to juxtaparanodes. Copyrigh