The chicken HMG-17 gene is dispensable for cell growth in vitro

A vertebrate N-end rule degron reveals that Orc6 is required in mitosis for daughter cell abscission

In addition to its function as an initiator of DNA replication, vertebrate Orc6 is also required for the final step of cytokinesis.

Orc6, an evolutionarily conserved component of the origin recognition complex, is essential for deoxyribonucleic acid (DNA) replication initiation from yeast to humans. Whether vertebrate Orc6 has a mitotic function remains unresolved. In vertebrates, but not yeast, its depletion causes centrosome amplification and multinucleate division, but replication stress indirectly causes similar abnormalities. In this paper, we exploit Varshavsky’s N-end rule to create a temperature-sensitive degron form of avian Orc6. Orc6 depletion during the S phase triggers centrosome amplification suppressed by G2 checkpoint inhibition, reflecting an indirect consequence of aberrant DNA replication. However, Orc6 depletion during mitosis suffices to cause asymmetric division and failure in cytokinesis, with a delay in daughter cell abscission revealed by a fluorescence-bleaching assay. A mutant lacking the C-terminal 25 residues cannot rescue these defects. Thus, vertebrate Orc6 is necessary during mitosis for the abscission stage of cytokinesis. Our findings exemplify N-end rule degrons as tools to unravel functions of a single protein during different phases of the vertebrate cell cycle.

The nucleosome-binding protein HMGN2 modulates global genome repair

The HMGN family comprises nuclear proteins that bind to nucleosomes and alter the structure of chromatin. Here, we report that DT40 chicken cells lacking either HMGN2 or HMGN1a, or lacking both HMGN1a and HMGN2, are hypersensitive to killing by UV irradiation. Loss of both HMGN1a and HMGN2 or only HMGN2 increases the extent of UV-induced G(2)-M checkpoint arrest and the rate of apoptosis. HMGN null mutant cells showed slower removal of UV-induced DNA lesions from native chromatin, but the nucleotide excision repair remained intact, as measured by host cell reactivation assays. These results identify HMGN2 as a component of the global genome repair subpathway of the nucleotide excision repair pathway, and may indicate that HMGN2 facilitates the ability of the DNA repair proteins to access and repair UV-induced DNA lesions in chromatin. Our finding that HMGNs play a role in global DNA repair expands the role of these proteins in the maintenance of genome integrity.

HMGN1 is dispensable for myogenesis and adipogenesis

Expression of key regulatory and tissue specific proteins necessary for myogenesis and adipogenesis are dependent on functional SWI/SNF enzymes that hydrolyze ATP to remodel chromatin and allow factors access to chromatinized DNA. Functional chromatin structural changes also can be facilitated by the high mobility group-N1 (HMGN1) protein. HMGN1 is a chromatin architectural protein that specifically interacts with nucleosomes and has been shown to facilitate the reversal of repressive chromatin structure, thereby making it more conducive for transcription. To determine if HMGN1 functions in myogenesis or adipogensis, two SWI/SNF-dependent processes, we used RNA interference to created stable cell lines with reduced HMGN1 protein levels and differentiated them along the myogenic and adipogenic pathways. We show that neither myogenesis nor adipogenesis was affected by reduced HMGN1 protein levels. We further demonstrate that HMGN1 levels naturally decrease as a function of contact-mediated cell cycle arrest, thereby explaining the lack of requirement for HMGN1 in these cellular differentiation processes.

Reverse genetic studies of the DNA damage response in the chicken B lymphocyte line DT40

In the 'post-genome' era, reverse genetics is one of the most informative and powerful means to investigate protein function. The chicken B lymphocyte line DT40 is widely used for reverse genetics because the cells have a number of advantages, including efficient gene targeting as well as a remarkably stable phenotype. Furthermore, the absence of functional p53 in DT40 cells enables identification of DNA damage using chromosome analysis by suppressing damage-induced apoptosis during interphase. This review summarizes the contribution of DT40 cells to reverse genetic studies of DNA damage response pathways in higher eukaryotic cells.

Construction and analysis of cells lacking the HMGA gene family

The high mobility group A (HMGA) family of non-histone chromosomal proteins is encoded by two related genes, HMGA1 and HMGA2. HMGA proteins are architectural transcription factors that have been found to regulate the transcription of a large number of genes. They are also some of the most commonly dysregulated genes in human neoplasias, highlighting a role in growth control. HMGA1 and HMGA2 have also been found to stimulate retroviral integration in vitro. In this study, we have cloned chicken HMGA1, and used the chicken DT40 B-cell lymphoma line to generate cells lacking HMGA1, HMGA2 and both in combination. We tested these lines for effects on cellular growth, gene control and retroviral integration. Surprisingly, we found that the HMGA gene family is dispensable for growth in DT40 cells, and that there is no apparent defect in retroviral integration in the absence of HMGA1 or HMGA2. We also analyzed the activity of approximately 4000 chicken genes, but found no significant changes. We conclude that HMGA proteins are not strictly required for growth control or retroviral integration in DT40 cells and may well be redundant with other factors.

The chicken B cell line DT40: a novel tool for gene disruption experiments

The use of the chicken DT40 B cell line is increasing in popularity due to the ease with which it can be manipulated genetically. It offers a targeted to random DNA integration ratio of more than 1:2, by far exceeding that of any mammalian cell line. The facility with which knockout cell lines can be generated, combined with a short generation time, makes the DT40 cell line attractive for phenotype analysis of single and multiple gene disruptions. Advantage has been taken of this to investigate such diverse fields as B cell antigen receptor (BCR) signaling, cell cycle regulation, gene conversion and apoptosis. In this review, we give a historical introduction and a practical guide to the use of the DT40 cell line, along with an overview of the main topics being researched using the DT40 cell line as a model system. These topics include B cell-specific subjects such as B cell signaling and Ig rearrangement, and subjects common to all cell types such as apoptosis, histones, mRNA modification, chromosomal maintenance and DNA repair. Attention is in each case brought to peculiarities of the DT40 cell line that are of relevance for the subject. Novel applications of the cell line, e.g., as a vector for gene targeting of human chromosomes, are also discussed in this review.

Use of gene knockouts in cultured cells to study apoptosis

The avian DT40 cell system represents a novel method to generate loss of function mutations in vertebrate cells. These chicken B lymphoma cells undergo homologous recombination at very high frequencies and can thus be used to "knock out" genes believed to function in apoptotic processes. The knockout cells can then be used to determine how the cell death process is modulated after induction of apoptosis and to order components in cell death pathways. The system can be further modified, using tetracycline-responsive promoters, to allow expression of wild-type cDNAs to rescue "knockout cells" if the gene of interest is essential. Alternatively, cDNA expression constructs containing mutations or deletions in the cDNA encoding the absent protein can be used to delineate functional domains. cDNA expression libraries or known proteins believed to function downstream of the target in a signal transduction pathway could also be transfected into the knockout cell line, and the resultant cells could be assayed for complementation and/or rescue of the apoptotic alteration/defect. Finally, the system has recently been adapted to allow disruption of human genes in DT40/human hybrid cell lines thereby potentially extending this system for use in studying human genes.

Neither HMG-14a nor HMG-17 gene function is required for growth of chicken DT40 cells or maintenance of DNaseI-hypersensitive sites

HMG-14 and HMG-17 form a family of ubiquitous non-histone chromosomal proteins and have been reported to bind preferentially to regions of active chromatin structure. Our previous studies demonstrated that the chicken HMG-17 gene is dispensable for normal growth of the DT40 chicken lymphoid cell line. Here it is shown that the major chicken HMG-14 gene,HMG-14a, is also dispensable and, moreover, that DT40-derived cells lacking both HMG-17 and HMG-14a proteins show no obvious change in phenotype with respect to the parental DT40 cells. Furthermore, no compensatory changes in HMG-14b or histone protein levels were observed in cells lacking both HMG-14a and HMG-17, nor were any alterations detected in such hallmarks of chromatin structure as DNaseI-hypersensitive sites or micrococcal nuclease digestion patterns. It is concluded that the HMG-14a and HMG-17 proteins are not required for normal growth of avian cell linesin vitro, nor for the maintenance of DNaseI-hypersensitive sites in chromatin.

Targeted disruption of an essential vertebrate gene: ASF/SF2 is required for cell viability

Alternative splicing factor/splicing factor 2 (ASF/SF2) is the prototype of a family of nuclear proteins highly conserved throughout metazoa, the SR (serine/arginine) proteins. Based largely on in vitro studies, SR proteins have been suggested to play important roles in constitutive and alternative splicing of pre-mRNAs. Here we describe the development of a genetic system employing the chicken B-cell line DT40 to study the function of ASF/SF2 in vivo. The high level of homologous recombination and rapid growth rate of these cells allowed us to show first that ASF/SF2 is an essential gene, and then to perform targeted disruption of both ASF/SF2 alleles, by creating a cell line in which the only source of ASF/SF2 is a human cDNA controlled by a tetracycline (tet)-repressible promoter. We show that addition of tet to these cells results in rapid depletion of ASF/SF2, concomitant accumulation of incompletely processed pre-mRNA, and subsequent cell death. The tet-induced lethality could be rescued by plasmids expressing wild-type ASF/SF2, but not several mutant derivatives, or other SR proteins. Heterozygous cell lines overexpressing human ASF/SF2 displayed significant reductions of endogenous ASF/SF2 mRNA, suggesting that ASF/SF2 mRNA levels are controlled by an autoregulatory loop. This system provides a novel method for genetic analysis of factors that function in basic processes in vertebrate cells.