Negative regulation of the RLH signaling by the E3 ubiquitin ligase RNF114.

The retinoic acid-inducible gene-I (RIG-I)-like helicases (RLH)s are cytoplasmic pattern recognition receptors expressed in both immune and non-immune cells that are essential for detection of intracellular RNA products, primarily of viral origin. Upon binding to viral RNA, RLHs interact with mitochondrial antiviral signaling protein (MAVS) to activate interferon (IFN)-mediated antiviral responses. The RLH/MAVS signaling pathway is regulated by ubiquitination/deubiquitination, in which several ubiquitin-editing proteins play critical roles. The really interesting new gene (RING) finger protein 114 (RNF114) was originally identified as a psoriasis susceptibility gene broadly expressed in human tissues. Earlier studies implicated RNF114 in regulating cellular dsRNA responses, cell cycle progression, NF-κB activity and T-cell activation. We found that RNF114 inhibited cellular dsRNA responses and RLH-mediated IFN production. RNF114 functioned as an E3 ubiquitin ligase, and MAVS was identified as a potential target for RNF114-mediated polyubiquitination and degradation. Splenocytes and blood harvested from RNF114 KO showed increased basal IFN level and sensitized responses to dsRNA. However, RNF114 knockout mice failed to exhibit enhance resistance to infection by two acute RNA viruses. These data suggested the potential physiological function of RNF114 in inflammation and host antiviral responses, but demonstrate complexity in the regulation of innate immunity by ubiquitin ligases.

The Maize TFome--development of a transcription factor open reading frame collection for functional genomics.

Establishing the architecture of the gene regulatory networks (GRNs) responsible for controlling the transcription of all genes in an organism is a natural development that follows elucidation of the genome sequence. Reconstruction of the GRN requires the availability of a series of molecular tools and resources that so far have been limited to a few model organisms. One such resource consists of collections of transcription factor (TF) open reading frames (ORFs) cloned into vectors that facilitate easy expression in plants or microorganisms. In this study, we describe the development of a publicly available maize TF ORF collection (TFome) of 2034 clones corresponding to 2017 unique gene models in recombination-ready vectors that make possible the facile mobilization of the TF sequences into a number of different expression vectors. The collection also includes several hundred co-regulators (CoREGs), which we classified into well-defined families, and for which we propose here a standard nomenclature, as we have previously done for TFs. We describe the strategies employed to overcome the limitations associated with cloning ORFs from a genome that remains incompletely annotated, with a partial full-length cDNA set available, and with many TF/CoREG genes lacking experimental support. In many instances this required the combination of genome-wide expression data with gene synthesis approaches. The strategies developed will be valuable for developing similar resources for other agriculturally important plants. Information on all the clones generated is available through the GRASSIUS knowledgebase (http://grassius.org/).

Multiple Mechanisms Contribute To Telomere Maintenance.

The unlimited growth potential of tumors depends on telomere maintenance and typically depends on telomerase, an RNA-dependent DNA polymerase, which reverse transcribes the telomerase RNA template, synthesizing telomere repeats at the ends of chromosomes. Studies in various model organisms genetically deleted for telomerase indicate that several recombination-based mechanisms also contribute to telomere maintenance. Understanding the molecular basis of these mechanisms is critical since some human tumors form without telomerase, yet the sequence is maintained at the telomeres. Recombination-based mechanisms also likely contribute at some frequency to telomere maintenance in tumors expressing telomerase. Preventing telomere maintenance is predicted to impact tumor growth, yet inhibiting telomerase may select for the recombination-based mechanisms. Telomere recombination mechanisms likely involve altered or unregulated pathways of DNA repair. The use of some DNA damaging agents may encourage the use of these unregulated pathways of DNA repair to be utilized and may allow some tumors to generate resistance to these agents depending on which repair pathways are altered in the tumors. This review will discuss the various telomere recombination mechanisms and will provide rationale regarding the possibility that L1 retrotransposition may contribute to telomere maintenance in tumors lacking telomerase.