RNA Splice Variants Research Articles

Proteins with neomorphic moonlighting functions in disease

One gene can encode multiple protein functions because of RNA splice variants, gene fusions during evolution, promiscuous enzyme activities, and moonlighting protein functions. In addition to these types of multifunctional proteins, in which both functions are considered "normal" functions of a protein, some proteins have been described in which a mutation or conformational change imparts a second function on a protein that is not a "normal" function of the protein. We propose to call these new functions "neomorphic moonlighting functions". The most common examples of neomorphic moonlighting functions are due to conformational changes that impart novel protein-protein interactions resulting in the formation of protein aggregates in Alzheimers, Parkinsons disease, and the systemic amyloidoses. Other changes that can result in a neomorphic moonlighting function include a mutation in SMAD4 that causes the protein to bind to new promoters and thereby alter gene transcription patterns, mutations in two isocitrate dehydrogenase isoforms that impart a new catalytic activity, and mutations in dihydrolipoamide dehydrogenase that activate a hidden protease activity. These neomorphic moonlighting functions were identified because of their connection to disease. In the cases described herein, the new functions cause cancers or severe neurological impairment, although in most cases the mechanism by which the new function leads to disease is unknown.

Bgp1/Vezf1 couples RNA Pol II activity and maintenance of genomic methylation

The protein Vezf1 plays multiple roles within the nucleus. Vezf1−/− mouse embryonic stem (MES) cells show widespread changes in gene expression profiles, including genome wide reduction in DNA methylation, which can be ascribed to a change in abundance of the RNA splice variant coding for the DNA methyltransferase Dnmt3b. We show here that the elongating form of RNA polymerase II accumulates at a Vezf1 binding site within a Dnmt3b intron in Wt MES cells, but not in Vezf1−/− cells. Vezf1 dependent Pol II pausing was seen at several intragenic and promoter‐associated Vezf1 binding sites in mouse ES cells. We carried out a genome wide ChIP‐seq study in HeLa cells of the distribution of both Vezf1 and Ser2P‐Pol II. There is a strong correlation between Vezf1 binding and peaks in abundance of elongating polymerase. Given the known relationship between RNA elongation rates, pausing, and splice variant choice, these results suggest that Vezf1, when bound at introns, may play a significant role in splicing outcomes.

A comparison of analog and Next-Generation transcriptomic tools for mammalian studies

This review focuses on tools for studying a cell's transcriptome, the collection of all RNA transcripts produced at a specific time, and the tools available for determining how these changes in gene expression relate to the functional changes in an organism. While the microarray-based (analog) gene-expression profiling technology has dominated the 'omics' era, Next-Generation Sequencing based gene-expression profiling (RNA-Seq) is likely to replace this analog technology in the future. RNA-Seq shows much promise for transcriptomic studies as the genes of interest do not have to be known a priori, new classes of RNA, SNPs and alternative splice variants can be detected, and it is also theoretically possible to detect transcripts from all biologically relevant abundance classes. However, the technology also brings with it new issues to resolve: the specific technical properties of RNA-Seq data differ to those of analog data, leading to novel systematic biases which must be accounted for when analysing this type of data. Additionally, multireads and splice junctions can cause problems when mapping the sequences back to a genome, and concepts such as cloud computing may be required because of the massive amounts of data generated.

Reversible upregulation of tropomyosin-related kinase receptor B by geranylgeranoic acid in human neuroblastoma SH-SY5Y cells

All-trans retinoic acid (ATRA) plays crucial roles in cell survival and differentiation of neuroblastoma cells. In the present study, we investigated the effects of geranylgeranoic acid (GGA), an acyclic retinoid, on differentiation and tropomyosin-related kinase receptorB (TrkB) gene expression in SH-SY5Y human neuroblastoma cells in comparison with ATRA. GGA induced growth suppression and neural differentiation to the same extent as ATRA. Two variants (145 and 95 kD) of the TrkB protein were dramatically increased by GGA treatment, comparable to the effect of ATRA. Following 6- to 8-day GGA treatment, the effect of GGA on TrkB was reversed after 2-4 days of its removal, whereas the effect of ATRA was irreversible under the same conditions. Both GGA and ATRA upregulated the cellular levels of three major TrkB messenger RNA splice variants in a time-dependent manner. Time-dependent induction of cell cycle-related genes, such as cyclinD1 and retinoblastoma protein, and amplification of the neural progenitor cell marker, brain lipid binding protein, were suppressed by GGA treatment and were completely abolished by ATRA. ATRA and GGA induced retinoic acid receptorβ (RARβ) expression, whereas the time-dependent expression of both RARα and RARγ was abolished by ATRA, but not by GGA. Our results suggest that GGA may be able to restore neuronal properties of SH-SY5Y human neuroblastoma cells in a similar but not identical way to ATRA.

Association analysis of RGS7BP gene polymorphisms with aspirin intolerance in asthmatic patients

Signal-regulated palmitoylation of RGS7BP(regulator of G-protein-signaling 7-binding protein) initiates the activation of G-protein-coupled receptors (GPCRs), including muscarinic receptors, which contribute to the development of asthma and its subphenotypes. To determine the association of RGS7BP gene polymorphisms with the development of aspirin-exacerbated respiratory disease (AERD). We evaluated the association of RGS7BP gene polymorphisms with response to oral aspirin challenge and with responsiveness to methacholine challenge. RGS7BP messenger RNA splice variants in peripheral blood platelets from patients with different single-nucleotide polymorphisms were analyzed by reverse-transcription polymerase chain reaction. Logistic regression analysis of RGS7BP gene polymorphisms in patients with AERD (n = 102) and aspirin-tolerant asthma (n = 429) revealed that a haplotype of block 3 consisting of rare alleles +98092 C>G, +98853 C>T, and +104450 T>G of the RGS7BP gene was associated with AERD. Multiple linear regression analysis showed that asthmatic patients carrying ht2/ht2 in block 3 were more responsive to aspirin challenge than those not carrying ht2 (P = .008 in a codominant model). The log-transformed provocation concentration that caused a decrease in forced expiratory volume in 1 second of 20% for methacholine was significantly dependent on the BL3-ht2 haplotype. No significant differences in platelet expression of different RGS7BP messenger RNA splice variants were detected between those with and without the BL3-ht2 haplotype. BL3-ht2 of RGS7BP may be an important genetic variant associated with AERD. The haplotype of block 3 may play a protective role against aspirin hypersensitivity in asthma, perhaps by altering the responsiveness of muscarinic receptors.

Frontiers in Molecular Neuroscience – Résumé and Perspective

The open access journal Frontiers in Molecular Neuroscience has existed since 2008. Publications started with an inaugural Research Topic centered on molecular mechanisms of the regulation of excitatory and inhibitory synapses in the brain – also known as E–I balance. This topic addressed the necessity of excitation and inhibition for cognitive function and how both types of transmission need to be co-regulated in order to avoid synaptic dysfunction. De-regulation of the E–I balance is associated with a number of neurological disorders including epilepsy and intellectual disability (Eichler and Meier, 2008; Fritschy, 2008; Harvey et al., 2008; Kehrer et al., 2008). Hence, an understanding of regulatory mechanisms at systemic, network, cellular, and molecular levels is a prerequisite for the development of novel and effective pharmacological therapies. However, we still need to learn and understand how the highly interconnected signaling networks function on a temporal basis, which is required to orchestrate proper brain function. Thus, it is also important to understand synaptic transmission at the level of individual receptors, such as GABAA, glycine, and glutamate receptors (Keith and El-Husseini, 2008; Tretter and Moss, 2008). In addition to synaptic mechanisms, the role of non-synaptic neurotransmitter receptor signaling can also play a fundamental role (Stell and Mody, 2002; Sierra-Paredes and Sierra-Marcuno, 2007; Zhang et al., 2007; Muller et al., 2008; Legendre et al., 2009). In order to understand how disease-related changes in molecular and cellular mechanisms impact on cognitive processing and brain function in general, it is important to invent experimental tools for targeted manipulation of neuronal activity. In this context, papers focusing on advanced techniques for visualization and manipulation of neuronal activity have helped address unmet needs, placing the journal at the cutting edge of this molecular revolution (Wisden and Meier, 2010). In particular, cell type-selective manipulations of neuronal activity can be achieved with light (Alilain and Silver, 2009; Han et al., 2009; Adamantidis et al., 2010), ligand–receptor combinations (Nichols and Roth, 2009; Wisden et al., 2009), K+ channels (Hodge, 2009), and tethered toxins (Holford et al., 2009). Gene targeting and virally mediated gene expression in mice continues to yield gains (Heldt and Ressler, 2009; Reijmers and Mayford, 2009; Weber et al., 2009). Moreover, model organisms such as Drosophila and zebrafish are increasingly valuable, as they allow rapid generation of transgenic animals or targeted knockdowns and investigation of the systemic changes that result from targeted manipulation of neuronal activity (Kasuya et al., 2009; Tessier and Broadie, 2009; White and Peabody, 2009; Hirata et al., 2010). Molecular systems for monitoring ion flux across the neuronal plasma membrane as well as high-throughput drug screening approaches will also help to develop novel pharmacological tools for treating neurological disorders (Bregestovski et al., 2009; Gilbert et al., 2009; Perron et al., 2009). Advanced sequencing technologies will play an increasing role in neuroscience, providing us with important information about exomic, genomic, and RNA splice variants. Epigenetic modulation via genomic DNA methylation, regulating gene transcription, is also a rapidly emerging field (Eid et al., 2009; Li et al., 2009; Flusberg et al., 2010). However, it is important to determine whether these polymorphisms, variants, and modifications are relevant to disease. Thus, functional studies that link DNA/RNA polymorphisms or DNA methylation to specific disease states will be required for years to come. A holistic approach involving genomics, RNomics, and proteomics in combination with bioinformatics and computational neuroscience will help create corresponding databases and constitute the basis for multimodal and interdisciplinary views of disease mechanisms. Understanding these multimodal relationships via a multidisciplinary approach should be our primary goal (Engmann and Giese, 2009; Harvey et al., 2009; Legendre et al., 2009; Liebl et al., 2009; Phuket and Covarrubias, 2009; Rivera-Arconada et al., 2009; Poulter et al., 2010). In summary, the first 3 years of Frontiers in Molecular Neuroscience have been a resounding success, with over 100 articles and 18 Research Topics published to date. The long-term goal of Frontiers in Molecular Neuroscience is to continue publishing the latest findings and conceptual advances in neurobiology (see for example Albrecht, 2011; Carulli et al., 2011; Hideyama and Kwak, 2011; Kaidanovich-Beilin and Woodgett, 2011; Li et al., 2011; Tonges et al., 2011; Weiss, 2011; Zhang et al., 2011). We therefore encourage researchers to submit novel and stimulating findings to Frontiers in Molecular Neuroscience in 2012 and warmly thank all authors and editors for their invaluable support of Frontiers in Molecular Neuroscience.

A novel T cell cytokine, secreted osteoclastogenic factor of activated T cells, induces osteoclast formation in a RANKL-independent manner.

Chronic T cell activation is central to the etiology of rheumatoid arthritis (RA), an inflammatory autoimmune disease that leads to severe focal bone erosions and generalized systemic osteoporosis. Previous studies have shown novel cytokine-like activities in medium containing activated T cells, characterized by potent induction of the osteoblastic production of interleukin-6 (IL-6), an inflammatory cytokine and stimulator of osteoclastogenesis, as well as induction of an activity that directly stimulates osteoclast formation in a manner independent of the key osteoclastogenic cytokine RANKL. This study was undertaken to identify the factors secreted by T cells that are responsible for these activities. Human T cells were activated using anti-human CD3 and anti-human CD28 antibodies for 72 hours in AIM V serum-free medium to obtain T cell-conditioned medium, followed by concentration and fractionation of the medium by fast-protein liquid chromatography. Biologically active fractions were resolved using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Major bands were analyzed by mass spectrometry, and a major candidate protein was identified. This novel cytokine was cloned, and its expression was analyzed using recombinant DNA technologies. A single novel cytokine that could induce both osteoblastic IL-6 production and functional osteoclast formation in the absence of osteoblasts or RANKL and that was insensitive to the effects of the RANKL inhibitor osteoprotegerin was identified in the activated T cell-conditioned medium; this cytokine was designated secreted osteoclastogenic factor of activated T cells (SOFAT). Further analysis of SOFAT revealed that it was derived from an unusual messenger RNA splice variant coded by the threonine synthase-like 2 gene homolog, which is a conserved gene remnant coding for threonine synthase, an enzyme that functions only in microorganisms and plants. SOFAT may act to exacerbate inflammation and/or bone turnover under inflammatory conditions such as RA or periodontitis and in conditions of estrogen deficiency.

A Putative Splice Variant of Anti-Mullerian Hormone Receptor Missing the Transmembrane Domain in Hamsters and Mice.

In female mammals, the size of the ovarian follicular pool decreases with age. However, in Siberian hamsters (Phodopus sungorus) the age-associated attrition of primordial follicles is modulated by day length. Short photoperiod profoundly inhibits hamster reproductive physiology and the number of ovarian primordial follicles was at least two-fold greater at 3, 6, and 12 months of age in females that were raised and maintained in short days as compared to hamsters that were held in long days. The levels of anti-Mullerian hormone (AMH) in the serum and ovary are also modulated by photoperiod in Siberian hamsters, and AMH was investigated because it has been found to inhibit primordial follicle activation in mice. To further elucidate the effects of AMH in reproductive activity and quiescence and its relationship with age, we examined expression of AMH receptor (Amhr2), a serine-threonine kinase membrane receptor. Early in the course of that investigation we found a putative Amhr2 mRNA splice variant lacking exon 4, which encodes the vast majority of the transmembrane domain. Ovarian RNA expression levels of both variants were measured in young and old animals. The level of the Amhr2 splice variant containing exon 4 was significantly higher in the ovaries from 12-month-old females than from 3-month-old hamsters, whereas levels of the splice variant lacking exon 4 were not statistically different in the two age groups. These data suggest age-specific differential regulation of these two RNA species in the ovary. In contrast to its receptor, the levels of ovarian Amh RNA trended in the opposite direction: lower in 12-month-old hamsters than in 3-month-old hamsters (P = 0.06). Hamster uterus and testis were also found to express the putative Amhr2 RNA splice variant, as was mouse ovary. The latter finding will facilitate a more thorough characterization of this splice variant, because the molecular tools for investigations in mice far exceed the availability for hamsters. (poster)

Identification and characterisation of a novel antisense non-coding RNA from the RBM5 gene locus

Previous work from our lab identified a 326 base-pair (bp) cDNA, termed Je2, which mapped to the antisense strand of intron 6 of the putative tumour suppressor gene RBM5/LUCA-15/H37, and functioned as an apoptosis suppressor. The purpose of the work described herein was to determine if Je2 is part of a larger transcript, to clone that transcript and to examine its ability to modulate RBM5 expression. Northern blot analyses in conjunction with strand-specific reverse transcription and PCR revealed two novel transcripts, one antisense and one sense, that included Je2 as well as RBM5 intron 4 sequence. Using rapid amplification of cDNA ends (RACE), a novel 1.4 kb product including Je2 and intron 4 was cloned. In vitro transcription/translation did not result in the production of any protein product, from either strand. Genomic DNA analysis revealed the presence of a putative promoter region 5′ to Je2, suggesting that the cloned 1.4 kb RACE product represents an antisense transcript that initiates within intron 6 and terminates within intron 4 of the RBM5 gene. This novel antisense, non-coding RNA was termed LUST, for LUCA-15- specific transcript. Ectopic overexpression of LUST coincided with elevated expression of the full-length RBM5+5+6 alternative RBM5 RNA splice variant, and reduced expression of the truncated, cytotoxic RBM5+5+6t/Clone 26 alternative RBM5 RNA splice variant. A model is proposed whereby LUST functions co-transcriptionally to mask a sense-strand regulatory sequence, common to both RBM5+5+6 and RBM5+5+6t/Clone 26 transcripts, that when unmasked results in premature termination of RBM5+5+6, thereby generating the cytotoxic truncated product, RBM5+5+6t/Clone 26. These results suggest that LUST is a novel, functional, non-coding RNA that plays a role in determining the apoptotic fate of a cell by regulating the expression of RBM5 splice variants.

Expression analysis of a novel pyridoxal kinase messenger RNA splice variant, PKL, in oil rape suffering abiotic stress and phytohormones

Pyridoxal kinase is key enzyme for the biosynthesis of pyridoxal 5'-phosphate, the biologically active form of vitamin B6, in the salvage pathway. A pyridoxal kinase gene, BnPKL (GenBank accession No. DQ463962), was isolated from oilseed rape (Brassica napus L.) following water stress through rapid amplification of complementary DNA (cDNA) ends. The results showed that the gene had two splice variants: PKL and PKL2. PKL, the long cDNA, encodes a 334 amino acid protein with a complete ATP-binding site, pyridoxal kinase-binding site and dimer interface site of a pyridoxal kinase, while PKL2, the short cDNA, lacked a partial domain. Southern blot showed that there were two copies in Brassica napus. The expression of BnPKL cDNA could rescue the mutant phenotype of Escherichia coli defective in pyridoxal kinase. Real-time reverse transcription-polymerase chain reaction revealed that the relative abundance of two transcripts are modulated by development and environmental stresses. Abscisic acid and NaCl were inclined to decrease PKL expression, but H2O2 and cold temperatures induced the PKL expression. In addition, the PKL expression could be transiently induced by jasmonate acid at an early stage, abscisic acid, salicylic acid and jasmonate acid enhanced the PKL expression in roots. Our results demonstrated that BnPKL was a pyridoxal kinase involved in responses to biotic and abiotic stresses.

Functional Diversity of Human Protection of Telomeres 1 Isoforms in Telomere Protection and Cellular Senescence

Protection of telomeres 1 (POT1) proteins in various organisms bind telomeres and regulate their structure and function. In contrast to mice carrying two distinct POT1 genes encoding two POT1 proteins (POT1a and POT1b), humans have the single POT1 gene. In addition to full-length POT1 protein (variant v1), the human POT1 gene encodes four other variants due to alternative RNA splicing (variants v2, v3, v4, and v5), whose functions are poorly understood. The functional analyses of the NH(2)-terminally and COOH-terminally truncated POT1 variants in this study showed that neither the single-stranded telomere-binding ability of the NH(2)-terminal oligonucleotide-binding (OB) folds nor the telomerase-dependent telomere elongation activity mediated by the COOH-terminal TPP1-interacting domain was telomere protective by itself. Importantly, a COOH-terminally truncated variant (v5), which consists of the NH(2)-terminal OB folds and the central region of unknown function, was found to protect telomeres and prevent cellular senescence as efficiently as v1. Our data revealed mechanistic and functional differences between v1 and v5: (a) v1, but not v5, functions through the maintenance of telomeric 3' overhangs; (b) p53 is indispensable to v5 knockdown-induced senescence; and (c) v5 functions at only a fraction of telomeres to prevent DNA damage signaling. Furthermore, v5 was preferentially expressed in mismatch repair (MMR)-deficient cells and tumor tissues, suggesting its role in chromosome stability associated with MMR deficiency. This study highlights a human-specific complexity in telomere protection and damage signaling conferred by functionally distinct isoforms from the single POT1 gene.

CMTM5 Exhibits Tumor Suppressor Activities and Is Frequently Silenced by Methylation in Carcinoma Cell Lines

CMTM5 (CKLF-like MARVEL transmembrane domain containing member 5) is located at 14q11.2, a locus associated with multiple cancers. It has six RNA splicing variants with CMTM5-v1 as the major one. We explored its expression pattern in normal tissues and tumor cell lines, as well as its functions in carcinoma cells. We evaluated CMTM5 expression by semiquantitative reverse transcription-PCR (RT-PCR) in normal tissues and carcinoma cell lines of cervical, breast, nasopharyngeal, lung, hepatocellular, esophageal, gastric, colon, and prostate. We further examined CMTM5 promoter methylation in these cell lines. We also analyzed CMTM5 expression after 5-aza-2'-deoxycytidine treatment and genetic demethylation and the functional consequences of restoring CMTM5 in HeLa and PC-3 cells. CMTM5-v1 is broadly expressed in human normal adult and fetal tissues, but undetectable or down-regulated in most carcinoma cell lines. Its promoter methylation was detected in virtually all the silenced or down-regulated cell lines. The silencing of CMTM5 could be reversed by pharmacologic demethylation or genetic double-knockout of DNMT1 and DNMT3B, indicating methylation-mediated mechanism. Restoration of CMTM5-v1 suppressed carcinoma cell proliferation, migration, and invasion. These results indicate that CMTM5 exhibits tumor suppressor activities, but with frequent epigenetic inactivation in carcinoma cell lines.

Human Fibroblast Growth Factor Receptor 1-IIIb Is a Functional Fibroblast Growth Factor Receptor Expressed in the Pancreas and Involved in Proliferation and Movement of Pancreatic Ductal Cells

The possible functions of the human IIIb-messenger RNA splice variant of fibroblast growth factor (FGF) receptor 1 (FGFR-1 IIIb) are yet to be delineated. In this study, the expression and functionality of the human FGFR-1 IIIb were characterized in the pancreas. In situ hybridization with a specific FGFR-1 IIIb probe in human pancreatic tissues demonstrated that FGFR-1 IIIb localized in normal pancreatic acinar and in ductal-like pancreatic cancer cells. To further assess the potential role of this receptor, a full-length human FGFR-1 IIIb was stably expressed in TAKA-1 pancreatic ductal cells not expressing endogenous FGFR-1. The FGFR-1 IIIb-expressing TAKA-1 cells synthesized a glycosylated 110-kd protein capable of inducing proliferation on incubation with exogenous FGF-1, -2, and -4. These effects were paralleled by tyrosine phosphorylation of FGFR substrate 2 and association of FGFR substrate 2 with FGFR-1 IIIb. The FGF-1, -2, and -10 induced the activation of p44/42 mitogen-activated protein kinase (MAPK), p38 MAPK, and c-Jun N-terminal kinase. Pharmacological inhibition revealed that FGF-induced proliferation was dependent on the concomitant activation of p44/42 MAPK and c-Jun N-terminal kinase. The FGFR-1 IIIb expression enhanced single-cell movement and plating efficacy. Our results demonstrate that the human FGFR-1 IIIb variant is a functional FGFR expressed in the pancreas that can alter pancreatic functions that regulate proliferation, adhesion, and movement.

Proinsulin is encoded by an RNA splice variant in human blood myeloid cells

Genes for peripheral tissue-restricted self-antigens are expressed in thymic and hematopoietic cells. In thymic medullary epithelial cells, self-antigen expression imposes selection on developing autoreactive T cells and regulates susceptibility to autoimmune disease in mouse models. Less is known about the role of self-antigen expression by hematopoietic cells. Here we demonstrate that one of the endocrine self-antigens expressed by human blood myeloid cells, proinsulin, is encoded by an RNA splice variant. The surface expression of immunoreactive proinsulin was significantly decreased after transfection of monocytes with small interfering RNA to proinsulin. Furthermore, analogous to proinsulin transcripts in the thymus, the abundance of the proinsulin RNA splice variant in blood cells corresponded with the length of the variable number of tandem repeats 5' of the proinsulin gene, known to be associated with type 1 diabetes susceptibility. Self-antigen expression by peripheral myeloid cells extends the umbrella of "immunological self" and, by analogy with the thymus, may be implicated in peripheral immune tolerance.

Multichannel Reverse Transcription-Polymerase Chain Reaction Microdevice for Rapid Gene Expression and Biomarker Analysis

A microdevice is developed for RNA analysis that integrates one-step reverse transcription and 30 cycles of PCR (RT-PCR) amplification with capillary electrophoresis (CE) separation and fluorescence detection of the amplicons. The four-layer glass-PDMS-glass-glass hybrid microdevice integrates microvalves, on-chip heaters and temperature sensors, nanoliter reaction chambers (380 nL), and 5-cm-long CE separation channels. The direct integration of these processes results in attomolar detection sensitivity (<11 template RNA molecules or approximately 0.1 cellular equiv) and rapid 45-min analysis, while minimizing sample waste and eliminating contamination. Size-based electrophoretic product analysis provides definitive amplicon-size verification and multiplex analysis. Multiplexed differential gene expression analysis is demonstrated on mdh and gyrB E. coli transcripts. RNA splice variant analysis of the RBBP8 gene is used to identify tumorigenic tissue. RT-PCR microdevice analysis of normal breast tissue RNA generates the expected 202-bp normal splice isoform; tumor breast tissue RNA samples generate a 151-bp amplicon signifying the presence of the tumorigenic splice variant. The ability to perform RNA transcript and splice variant biomarker analysis establishes our RT-PCR microdevice as a versatile gene expression platform.

Identification of the Expressed Form of Human Cytosolic Phospholipase A2β (cPLA2β): cPLA2β3 IS A NOVEL VARIANT LOCALIZED TO MITOCHONDRIA AND EARLY ENDOSOMES

In this study, we identify the principal splice variant of human cytosolic phospholipase A(2)beta (cPLA(2)beta) (also known as Group IVB cPLA(2)) present in cells. In human lung, spleen, and ovary and in a lung epithelial cell line (BEAS-2B), cPLA(2)beta is expressed as a 100-kDa protein, not the 114-kDa form originally predicted. Using RNA interference, the 100-kDa protein in BEAS-2B cells was confirmed to be cPLA(2)beta. BEAS-2B cells contain three different RNA splice variants of cPLA(2)beta (beta1, beta2, and beta3). cPLA(2)beta1 is identical to the previously cloned cPLA(2)beta, predicted to encode a 114-kDa protein. However, cPLA(2)beta2 and cPLA(2)beta3 splice variants are smaller and contain internal deletions in the catalytic domain. The 100-kDa cPLA(2)beta in BEAS-2B cells is the translated product of cPLA(2)beta3. cPLA(2)beta3 exhibits calcium-dependent PLA(2) activity against palmitoyl-arachidonyl-phosphatidylethanolamine and low level lysophospholipase activity but no activity against phosphatidylcholine. Unlike Group IVA cPLA(2)alpha, cPLA(2)beta3 is constitutively bound to membrane in unstimulated cells, localizing to mitochondria and early endosomes. cPLA(2)beta3 is widely expressed in tissues, suggesting that it has a generalized function at these unique sites.

Molecular characterization and expression of maternally expressed gene 3 (Meg3/Gtl2) RNA in the mouse inner ear

The pathways responsible for sound perception in the cochlea involve the coordinated and regulated expression of hundreds of genes. By using microarray analysis, we identified several transcripts enriched in the inner ear, including the maternally expressed gene 3 (Meg3/Gtl2), an imprinted noncoding RNA. Real-time PCR analysis demonstrated that Meg3/Gtl2 was highly expressed in the cochlea, brain, and eye. Molecular studies revealed the presence of several Meg3/Gtl2 RNA splice variants in the mouse cochlea, brain, and eye. In situ hybridizations showed intense Meg3/Gtl2 RNA staining in the nuclei of type I spiral ganglion cells and in cerebellum near the dorsal vestibular region of the cochlea. In embryonic mouse head sections, Meg3/Gtl2 RNA expression was observed in the otocyst, brain, eye, cartilage, connective tissue, and muscle. Meg3/Gtl2 RNA expression increased in the developing otocyst and localized to the spiral ganglion, stria vascularis, Reissner's membrane, and greater epithelial ridge (GER) in the cochlear duct. RT-PCR analysis performed on cell lines derived from the organ of Corti, representing neural, supporting, and hair cells, showed significantly elevated levels of Meg3/Gtl2 expression in differentiated neural cells. We propose that Meg3/Gtl2 RNA functions as a noncoding regulatory RNA in the inner ear and that it plays a role in pattern specification and differentiation of cells during otocyst development, as well as in the maintenance of a number of terminally differentiated cochlear cell types.

Cooperativity of paired oligonucleotide probes for microarray hybridization assays

Synthetic DNA probes attached to microarrays usually range in length from 25 to 70 nucleotides. There is a compromise between short probes with lower sensitivity, which can be accurately synthesized in higher yields, and long probes with greater sensitivity but lower synthesis yields. Described here are microarrays printed with spots containing a mixture of two short probes, each designed to hybridize at noncontiguous sites in the same targeted sequence. We have shown that, for a printed microarray, mixed probe spots containing a pair of 30mers show significantly greater hybridization than spots containing a single 30mer and can approach the amount of hybridization to spots containing a 60mer or a 70mer. These spots with mixed oligonucleotide probes display cooperative hybridization signals greater than those that can be achieved by either probe alone. Both the higher synthesis yields of short probes and the greater sensitivity of long oligonucleotides can be utilized. This strategy provides new design options for microarray hybridization assays to detect RNA abundance, RNA splice variants, or sequence polymorphisms.

TRPV1b, a Functional Human Vanilloid Receptor Splice Variant

Transient receptor potential (TRP) genes encode a family of related ion-channel subunits. This family consists of cation-selective, calcium-permeable channels that include a group of vanilloid receptor channels (TRPV) implicated in pain and inflammation. These channels are activated by diverse stimuli, including capsaicin, lipids, membrane deformation, heat, and protons. Six members of the TRPV family have been identified that differ predominantly in their activation properties. However, in neurons, TRPV channels do not account for the observed diversity of responses to activators. By probing human and rat brain cDNA libraries to identify TRPV subunits, we identified a novel human TRPV1 RNA splice variant, TRPV1b, which forms functional ion channels that are activated by temperature (threshold, approximately 47 degrees C), but not by capsaicin or protons. Channels with similar activation properties were found in trigeminal ganglion neurons, suggesting that TRPV1b receptors are expressed in these cells and contribute to thermal nociception.

LUCA-15/RBM5, a putative tumour suppressor, enhances multiple receptor-initiated death signals.

LUCA-15/RBM5 is a putative tumour suppressor. The gene encodes a number of alternative RNA splice variants with differing abilities to either enhance or suppress apoptosis, and it is likely that this ability to modulate apoptosis is central to the putative tumour suppressor activity of LUCA-15. This report demonstrates for the first time that expression from the LUCA-15 locus modulates apoptosis triggered by the death-inducing ligand TRAIL. Using Jurkat T lymphoblastic leukemia cells, LUCA-15 expression was shown to enhance not only TRAIL but TNF-alpha- and Fas-mediated apoptosis. LUCA-15, therefore, has the ability to lower the apoptotic threshold of multiple receptor-initiated death-inducing signals. Of note, sensitisation of the Jurkat cells to TRAIL was shown to depend on new protein synthesis, since no enhancement of apoptosis was observed when cells were exposed to both TRAIL and the protein synthesis inhibitor cycloheximide. This result suggests that LUCA-15 does not act independently to regulate apoptosis, but modulates a process that requires additional, newly synthesized protein. These results may explain the putative role of LUCA-15 as a tumour suppressor, suggesting that lack of functional LUCA-15 could provide the means by which malignant T cells escape receptor-initiated apoptotic signals.