Splicing regulation in neurologic disease

The importance of alternative splicing in the regulation of diverse biological processes is reflected in the growing list of human diseases associated with known or suspected splicing defects. It is becoming evident that alternative splicing plays a particularly important role in neurologic disease, which is perhaps not surprising given the important role splicing plays in generating complexity and function in the brain. This review considers the evidence that defects in regulation of splicing may underlie many types of human neurologic diseases.     

Identification of Stk25 as a genetic modifier of Tau phosphorylation in Dab1-mutant mice

Hyperphosphorylation of the microtubule binding protein Tau is a feature of a number of neurodegenerative diseases, including Alzheimer's disease. Tau is hyperphosphorylated in the hippocampus of dab1-null mice in a strain-dependent manner; however, it has not been clear if the Tau phosphorylation phenotype is a secondary effect of the morbidity of these mutants. The dab1 gene encodes a docking protein that is required for normal brain lamination and dendritogenesis as part of the Reelin signaling pathway. We show that dab1 gene inactivation after brain development leads to Tau hyperphosphorylation in anatomically normal mice. Genomic regions that regulate the phospho Tau phenotype in dab1 mutants have previously been identified. Using a microarray gene expression comparison between dab1-mutants from the high-phospho Tau expressing and low-phospho Tau expressing strains, we identified Stk25 as a differentially expressed modifier of dab1-mutant phenotypes. Stk25 knockdown reduces Tau phosphorylation in embryonic neurons. Furthermore, Stk25 regulates neuronal polarization and Golgi morphology in an antagonistic manner to Dab1. This work provides insights into the complex regulation of neuronal behavior during brain development and provides insights into the molecular cascades that regulate Tau phosphorylation.     

The splicing machinery is a genetic modifier of disease severity

Disease severity correlates with the level of correctly spliced RNA transcribed from genes carrying splicing mutations and with the ratio of alternatively spliced isoforms. Hence, a role for splicing regulation as a genetic modifier has been suggested. Here we discuss recent experiments that provide direct evidence that changes in the level of splicing factors modulate the splicing pattern of disease-associated genes. Importantly, modulation of the splicing pattern led to regulation of the protein function and modification of disease severity.     

A mouse model of Alagille syndrome: Notch2 as a genetic modifier of Jag1 haploinsufficiency

Alagille syndrome is a human autosomal dominant developmental disorder characterized by liver, heart, eye, skeletal, craniofacial and kidney abnormalities. Alagille syndrome is caused by mutations in the Jagged 1 (JAG1) gene, which encodes a ligand for Notch family receptors. The majority of JAG1 mutations seen in Alagille syndrome patients are null alleles, suggesting JAG1 haploinsufficiency as a primary cause of this disorder. Mice homozygous for a Jag1 null mutation die during embryogenesis and Jag1/+ heterozygous mice exhibit eye defects but do not exhibit other phenotypes characteristic of Alagille syndrome patients ( Xue, Y., Gao, X., Lindsell, C. E., Norton, C. R., Chang, B., Hicks, C., Gendron-Maguire, M., Rand, E. B., Weinmaster, G. and Gridley, T. (1999) HUM: Mol. Genet. 8, 723-730). Here we report that mice doubly heterozygous for the Jag1 null allele and a Notch2 hypomorphic allele exhibit developmental abnormalities characteristic of Alagille syndrome. Double heterozygous mice exhibit jaundice, growth retardation, impaired differentiation of intrahepatic bile ducts and defects in heart, eye and kidney development. The defects in bile duct epithelial cell differentiation and morphogenesis in the double heterozygous mice are similar to defects in epithelial morphogenesis of Notch pathway mutants in Drosophila, suggesting that a role for the Notch signaling pathway in regulating epithelial morphogenesis has been conserved between insects and mammals. This work also demonstrates that the Notch2 and Jag1 mutations interact to create a more representative mouse model of Alagille syndrome and provides a possible explanation of the variable phenotypic expression observed in Alagille syndrome patients.     

MicroRNA-mediated gene regulation: potential applications for plant genetic engineering

Food security is one of the most important issues challenging the world today. Any strategies to solve this problem must include increasing crop yields and quality. MicroRNA-based genetic modification technology (miRNA-based GM tech) can be one of the most promising solutions that contribute to agricultural productivity directly by developing superior crop cultivars with enhanced biotic and abiotic stress tolerance and increased biomass yields. Indirectly, the technology may increase usage of marginal soils and decrease pesticide use, among other benefits. This review highlights the most recent progress of transgenic studies utilizing various miRNAs and their targets for plant trait modifications, and analyzes the potential of miRNA-mediated gene regulation for use in crop improvement. Strategies for manipulating miRNAs and their targets in transgenic plants including constitutive, stress-induced, or tissue-specific expression of miRNAs or their targets, RNA interference, expressing miRNA-resistant target genes, artificial target mimic and artificial miRNAs were discussed. We also discussed potential risks of utilizing miRNA-based GM tech. In general, miRNAs and their targets not only provide an invaluable source of novel transgenes, but also inspire the development of several new GM strategies, allowing advances in breeding novel crop cultivars with agronomically useful characteristics.     

PRTFDC1 is a genetic modifier of HPRT-deficiency in the mouse

Lesch-Nyhan disease (LND) is a severe X-linked neurological disorder caused by a deficiency of hypoxanthine phosphoribosyltransferase (HPRT). In contrast, HPRT-deficiency in the mouse does not result in the profound phenotypes such as self-injurious behavior observed in humans, and the genetic basis for this phenotypic disparity between HPRT-deficient humans and mice is unknown. To test the hypothesis that HPRT deficiency is modified by the presence/absence of phosphoribosyltransferase domain containing 1 (PRTFDC1), a paralog of HPRT that is a functional gene in humans but an inactivated pseudogene in mice, we created transgenic mice that express human PRTFDC1 in wild-type and HPRT-deficient backgrounds. Male mice expressing PRTFDC1 on either genetic background were viable and fertile. However, the presence of PRTFDC1 in the HPRT-deficient, but not wild-type mice, increased aggression as well as sensitivity to a specific amphetamine-induced stereotypy, both of which are reminiscent of the increased aggressive and self-injurious behavior exhibited by patients with LND. These results demonstrate that PRTFDC1 is a genetic modifier of HPRT-deficiency in the mouse and could therefore have important implications for unraveling the molecular etiology of LND.     

Synthetic polymers and their potential as genetic materials

DNA and RNA are the only known natural genetic materials. Systematic modification of each of their chemical building blocks (nucleobase, sugar, and phosphate) has enabled the study of the key properties that make those nucleic acids genetic materials. All three moieties contribute to replication and, significantly, all three moieties can be replaced by synthetic analogs without loss of function. Synthetic nucleic acid polymers capable of storing and propagating information not only expand the central dogma, but also highlight that DNA and RNA are not unique chemical solutions for genetic information storage. By considering replication as a question of information transfer, we propose that any polymer that can be replicated could serve as a genetic material. Editor's suggested further reading in BioEssays Xenobiology: A new form of life as the ultimate biosafety tool Abstract     

Endothelin 1 gene as a modifier in dilated cardiomyopathy

Dilated cardiomyopathy (DCM) is a myocardial disease of unknown etiology with left ventricular dilatation and impaired myocardial contractility leading to heart failure. It is considered to be a multifactorial disorder with the interplay of both genetic and environmental factors. One of the possible genes implicated in DCM is endothelin 1 (EDN1). The genetic variants of EDN1 may be involved in the pathophysiology of DCM hence the entire EDN1 gene was screened to examine for the possible genotypic associations with DCM. A total of 115 DCM patients and 250 control subjects were included in the present study. PCR based SSCP analysis was carried out followed by commercial sequencing. Screening of EDN1 revealed two common and two rare polymorphisms. Allelic and genotypic frequencies were estimated in patient and control groups by appropriate statistical tests. The heterozygotes of insertion variation (+ 138A) were found to exhibit four-fold increase risk to DCM (OR = 4.12, 95% CI 2.10–8.08; p = 0.0001). The two rare variants (G>A transition (rs150035515) at c.90 and C>T transition (rs149399492) at c.119) observed in the present study were found to be unique in DCM. The secondary mRNA structures of these variations were found to have less free energy than wild type. The haplotype analysis revealed 4A–T to be risk haplotype for DCM (OR 5.90, 95% CI 2.29–15.25, p = 0.0001). In conclusion, EDN1 polymorphisms (+ 138A, A30A, T40I) appear to play a significant role in the pathogenesis of DCM, as they influence the stability of protein. The increased EDN1 production may lead to constriction of coronary arteries, reducing coronary blood flow which may in turn increase the load on left ventricle, impairing contractility of the heart resulting in a DCM phenotype, an end stage of heart failure.     

The CFTR M470V gene variant as a potential modifier of COPD severity: study of Serbian population

Chronic obstructive pulmonary disease (COPD) is a complex disease influenced by genetic and environmental factors. Cystic fibrosis transmembrane conductance regulator (CFTR) protein is an important component of the lung tissue homeostasis, involved in the regulation of the rate of mucociliary clearance. As it is known that certain CFTR variants have consequences on the function of CFTR protein, the aim of this study was to examine the possible role of F508del, M470V, Tn locus, and R75Q variants in COPD development and modulation. Total number of 86 COPD patients and 102 control subjects were included in the study. Possible association between COPD susceptibility, severity, and onset of the disease and allele or genotype of four analyzed CFTR variants was examined. No associations were detected between COPD development, onset of the disease and tested CFTR alleles and genotypes. However, VV470 genotype was associated with mild/moderate COPD stages in comparison to severe/very severe ones (OR = 0.29, 95%CI = 0.11-0.80, p = 0.016). Our study showed that patients with VV470 genotype had a 3.4-fold decreased risk for the appearance of severe/very severe COPD symptoms, and the obtained results indicate that this genotype may have a protective role. These results also suggest the importance of studying CFTR gene as a modifier of this disease.     

转录辅调节因子在剪接过程中的作用

细胞通过基因表达调控来应对外界刺激,其中对基因转录起始和pre-mRNA剪接的调控是基因表达调控的重要环节。越来越多的实验显示基因转录和pre-mRNA剪接这两个过程在时空上密切相关。基因转录能调节剪接模式的选择性,反之剪接过程也影响基因转录。近年来研究发现转录辅调节因子在联系转录和剪接过程中扮演着重要角色。转录辅调节因子对基因表达的调控不仅在于影响转录产物的量,还可以调控pre-mRNA的选择性剪接并产生不同的剪接体,从而翻译出具有不同生物学功能的蛋白质。本文主要阐述了基因转录与剪接之间的关系以及它们之间相互作用的机制,有利于更深入理解基因表达调控的过程。