A human Alu RNA-binding protein whose expression is associated with accumulation of small cytoplasmic Alu RNA

7SL RNA and signal recognition particle orchestrate a global cellular response to acute thermal stress

Non-coding 7SL RNA is an ancestor to mammalian Alu and B1 SINE RNAs and is thought to function exclusively within the Signal Recognition Particle (SRP), aiding in the translocation of secretory proteins into the endoplasmic reticulum for export. Here, we discover a function of 7SL/SRP unrelated to protein secretion. Under acute heat shock, 7SL and SRP together selectively arrest cellular transcription and translation machineries during early response to stress. Under thermal stress, 7SL is upregulated, accumulates in the nucleus, and binds to target genes repressed by heat shock. Concurrently, in the cytosol, SRP binds to ribosomes and inhibits new protein synthesis. Translational suppression occurs independently of the signal peptide and is abrogated by depleting SRP. Translation inhibition extends to the mitochondria, as nuclear-encoded genes with mitochondrial functions are enriched among SRP targets. Thus, apart from its role in protein export, 7SL/SRP orchestrates a global response to acute stress that encompasses the nucleus, cytosol, and mitochondria across transcription and translation.

Transposable elements, circular RNAs and mitochondrial transcription in age-related genomic regulation

Our understanding of the molecular regulation of aging and age-related diseases is still in its infancy, requiring in-depth characterization of the molecular landscape shaping these complex phenotypes. Emerging classes of molecules with promise as aging modulators include transposable elements, circRNAs and the mitochondrial transcriptome. Analytical complexity means that these molecules are often overlooked, even though they exhibit strong associations with aging and, in some cases, may directly contribute to its progress. Here, we review the links between these novel factors and age-related phenotypes, and we suggest tools that can be easily incorporated into existing pipelines to better understand the aging process.

Alu RNA regulates the cellular pool of active ribosomes by targeted delivery of SRP9/14 to 40S subunits

The human genome contains about 1.5 million Alu elements, which are transcribed into Alu RNAs by RNA polymerase III. Their expression is upregulated following stress and viral infection, and they associate with the SRP9/14 protein dimer in the cytoplasm forming Alu RNPs. Using cell-free translation, we have previously shown that Alu RNPs inhibit polysome formation. Here, we describe the mechanism of Alu RNP-mediated inhibition of translation initiation and demonstrate its effect on translation of cellular and viral RNAs. Both cap-dependent and IRES-mediated initiation is inhibited. Inhibition involves direct binding of SRP9/14 to 40S ribosomal subunits and requires Alu RNA as an assembly factor but its continuous association with 40S subunits is not required for inhibition. Binding of SRP9/14 to 40S prevents 48S complex formation by interfering with the recruitment of mRNA to 40S subunits. In cells, overexpression of Alu RNA decreases translation of reporter mRNAs and this effect is alleviated with a mutation that reduces its affinity for SRP9/14. Alu RNPs also inhibit the translation of cellular mRNAs resuming translation after stress and of viral mRNAs suggesting a role of Alu RNPs in adapting the translational output in response to stress and viral infection.

Identification of a recently active mammalian SINE derived from ribosomal RNA

Complex eukaryotic genomes are riddled with repeated sequences whose derivation does not coincide with phylogenetic history and thus is often unknown. Among such sequences, the capacity for transcriptional activity coupled with the adaptive use of reverse transcription can lead to a diverse group of genomic elements across taxa, otherwise known as selfish elements or mobile elements. Short interspersed nuclear elements (SINEs) are nonautonomous mobile elements found in eukaryotic genomes, typically derived from cellular RNAs such as tRNAs, 7SL or 5S rRNA. Here, we identify and characterize a previously unknown SINE derived from the 3'-end of the large ribosomal subunit (LSU or 28S rDNA) and transcribed via RNA polymerase III. This new element, SINE28, is represented in low-copy numbers in the human reference genome assembly, wherein we have identified 27 discrete loci. Phylogenetic analysis indicates these elements have been transpositionally active within primate lineages as recently as 6 MYA while modern humans still carry transcriptionally active copies. Moreover, we have identified SINE28s in all currently available assembled mammalian genome sequences. Phylogenetic comparisons indicate that these elements are frequently rederived from the highly conserved LSU rRNA sequences in a lineage-specific manner. We propose that this element has not been previously recognized as a SINE given its high identity to the canonical LSU, and that SINE28 likely represents one of possibly many unidentified, active transposable elements within mammalian genomes.

Multiple Roles of Alu-Related Noncoding RNAs

Repetitive Alu and Alu-related elements are present in primates, tree shrews (Scandentia), and rodents and have expanded to 1.3 million copies in the human genome by nonautonomous retrotransposition. Pol III transcription from these elements occurs at low levels under normal conditions but increases transiently after stress, indicating a function of Alu RNAs in cellular stress response. Alu RNAs assemble with cellular proteins into ribonucleoprotein complexes and can be processed into the smaller scAlu RNAs. Alu and Alu-related RNAs play a role in regulating transcription and translation. They provide a source for the biogenesis of miRNAs and, embedded into mRNAs, can be targeted by miRNAs. When present as inverted repeats in mRNAs, they become substrates of the editing enzymes, and their modification causes the nuclear retention of these mRNAs. Certain Alu elements evolved into unique transcription units with specific expression profiles producing RNAs with highly specific cellular functions.

LINEs, SINEs and processed pseudogenes: parasitic strategies for genome modeling

Two major classes of retrotransposons have invaded eukaryotic genomes: the LTR retrotransposons closely resembling the proviral integrated form of infectious retroviruses, and the non-LTR retrotransposons including the widespread, autonomous LINE elements. Here, we review the modeling effects of the latter class of elements, which are the most active in humans, and whose enzymatic machinery is subverted to generate a large series of "secondary" retroelements. These include the processed pseudogenes, naturally present in all eukaryotic genomes possessing non-LTR retroelements, and the very successful SINE elements such as the human Alu sequences which have evolved refined parasitic strategies to efficiently bypass the original "protectionist" cis-preference of LINEs for their own retrotransposition.

Potential for retroposition by old Alu subfamilies

Alu elements sharing sequence characteristics of the "old" subfamilies are thought to currently be retrotranspositionally inactive. We analyzed one of these old subfamilies of Alu elements, Sx, for sequence conservation relative to the consensus and the length of the "A-tail" as parameters to define the presence of potential Alu Sx source genes in the human genome. Sequence identity to the left half or the right half of the Alu Sx consensus sequence was evaluated for 4424 complete elements obtained from the human genome draft sequence. A small subset of Alu Sx left halves were found to be more conserved than any of the Alu Sx right halves. Selection for promoter function in active elements may explain the slightly higher conservation of the left half. In order to determine whether this sequence identity was the result of recent activity, or simply sequence conservation for older elements, PCR amplification of some of the loci containing Sx elements with conserved left/right halves from different primate genomes was carried out. Several of these Sx Alus were found to have amplified at a later evolutionary period (<35 mya) than expected based on previous studies of Sx elements. Analysis of "A-tail" length, a feature correlated with current retroposition activity, varied between Alu Sx element loci in different primates, where the length increased in specific Alu elements in the human genome. The presence of few conserved Alu Sx elements and the dynamic expansion/contraction of the A-tail suggests that some of these older subfamilies may still be active at very low levels or in a few individuals.

Mobile elements and the human genome

Genomic DNA is often thought of as the stable template of heredity, largely dormant and unchanging, apart from perhaps the occasional point mutation. But it has become increasingly clear that DNA is dynamic rather than static, being subjected to rearrangements, insertions and deletions. Much of this plasticity can be attributed to transposable elements and their genomic relatives.

Suppression subtractive hybridization to identify gene expressions in variant and classic small cell lung cancer cell lines

Small Cell Lung Cancer (SCLC), a clinically aggressive cancer, accounts for approximately 25% of primary lung cancers. We carried out suppression subtractive hybridization (SSH), a PCR-based method for cDNA subtraction, between the human classic, NCI-H69 and variant, more aggressive NCI-N417 SCLC cell lines to isolate and characterize variable expression of genes, which may be responsible for differential degree of tumorigenicity of SCLC. Using NCI-N417 as a tester, we obtained 28 differentially expressed cDNA clones from a total of 60 arbitrarily picked clones. Among the 28 cDNA clones, 4 were unknown genes, 2 were fatty acid binding protein (FABP) with specific identification of mRNA for mammary-derived growth inhibitor (MDGI), 1 was human alpha-enolase, 4 were ribosomal proteins, 2 were structural genes, vimentin and moesin (membrane-organizing extension spike protein), and 9 were homologous with murine leukemia viruses, whereas 2 others had enhanced expression in NCI-H69 and A549 cell lines, and 4 were cell surface proteins and murine type C retrovirus. Expression of FABP/MDGI was significantly high in NCI-H417, which may influence mitosis and cell growth as implicated in other tissues, contrary to the conclusion drawn for the role of MDGI in human breast cancer. Higher expression of ribosomal proteins in NCI-N417 compared to NCI-H69 may have a role in differential tumorigenicity and metastatic ability. Further, we obtained 14 differentially expressed cDNA clones by reversing the tester and driver, using NCI-H69 as a tester. Of these 14 differential cDNAs, 5 were unknown genes, 2 were specific for keratins, others had similarities with protease inhibitor, human BAC clone, Alu RNA binding protein, and tumor expression-enhanced gene. Characterization of these differentially expressed cDNA clones will provide useful information in understanding of the genes responsible for differential tumorigenicity of SCLC.

Alu-DNA repeat-binding protein p68 is a part of Alu-RNA containing alpha-RNP

An Alu-DNA repeat-binding protein with a molecular mass of 68 kDa (p68) is identified in the somatic human cell nucleoplasm. Gel mobility shift assay (GMSA), South-western blotting and affinity purification on DNA attached to the carrier were used in the identification. GMSA revealed multiple complexes with the exponential dependence of their relative mobility. A narrow binding site of the p68 was revealed using synthetic oligonucleotides. It is located between the A-box and B-box of the RNA polymerase III promoter and is identical to that reported for the Alu-binding protein from human spermatozoids. The same narrow binding site, the similarity of the isolation procedure from germ and somatic cells, and similar binding properties and molecular masses suggest homology of the two proteins. Antibodies raised against Alu-protein complexes led to hypershift of the complexes in GMSA and stained p68 in active fractions in human spermatozoids and in Alu-RNA-containing alpha-RNP particles. Immunofluorescence of a HeLa cell monolayer revealed an intranuclear dot pattern with the dots corresponding to euchromatin areas and some dots located at the cell periphery in the cytoplasm. alpha-RNP particles bound Alu-DNA in vitro and contained p68 as shown using the immunogold procedure. Alu-DNA binding activity was revealed in cytoplasm as well as in nucleoplasm. The possible nature of the main Alu-DNA binding protein and its involvement in the particle structure are discussed.

The impact of L1 retrotransposons on the human genome

The 'master' human mobile element, the L1 retrotransposon, has come of age as a biological entity. Knowledge of how it retrotransposes in vivo, how its proteins act to retrotranspose other poly A elements and the extent of its role in shaping the human genome should emerge rapidly over the next few years. We review the impact of retrotransposons and how new insight is likely to lead to important practical applications for these intriguing mobile elements.

Triplet repeat-containing ribosomal protein L14 gene in immortalized human endothelial cell line (t-HUE4)

A cDNA encoding human 60S ribosomal subunit protein L14 (hRL14) was isolated from a human immortal endothelial cell line, t-HUE4. This cell line was established via a series of cell lines cultured in a serum-free and a protein-free medium, and a directional cDNA library has been constructed and screened in search for the genes modulating protein synthesis machinery in cell proliferation. A putative full-length clone with an open reading frame of 220 amino acids; predicted molecular weight of 23.6 kDa. A significant identity for hRL14 was observed with rat RL14 (85% identity), with exception of COOH-terminal region, but not with any eukaryote amino acid sequences so far deposited to database. The typical features of ribosomal proteins were observed in hRL14, as seen in nuclear targeting sequences necessary for the transport from cytoplasm to nucleolus, a bZIP like (basic region-leucine zipper) element for the binding to rRNA, and the internal repeat sequences; the pentapeptide QKA(A/S)X. The COOH-terminal region of the transcripts contained fifteen triplet repeats (GCT; alanine) at nucleotide 465 to 509, which is significantly expanded compared to the rat RL14. However, the repeat number was all the same among the normal human endothelial cell line and the cell lines established in the course of t-HUE4 establishment. A single band with about 800 bases was identified by Northern blot analysis without tissue specificity. This GCT repeat was found to be one of the longest uninterrupted repeats in a coding sequence, which were associated with the highest degree of polymorphism.

Characterization and sequence of an additional 15-lipoxygenase transcript and of the human gene

15-lipoxygenase is a lipid-peroxidating enzyme that oxidizes fatty acids, such as those esterified to cellular membranes. It has been implicated in the oxidative modification of low-density lipoprotein and is thus thought to contribute to the development of atherosclerosis. The enzyme has also been shown to be specifically induced by interleukin-4 in human blood monocytes. Two 15-lipoxygenase-hybridizing messages were detected in these cells; one (2.7 kb) corresponds to the previously isolated cDNA for 15-lipoxygenase, while the other (4 kb) was of unknown origin. We have isolated and characterized this 4 kb transcript. Our experiments show that it has 1.2 kb additional sequence in its 3' untranslated region, and that it is generated from genomic sequences through differential polyA site selection. We present studies to address the functional significance of the extended 3'UTR. Selection of an upstream polyadenylation signal results in production of the 2.7 kb transcript. In addition, we present here for the first time the cloning and sequence of the human 15-lipoxygenase gene, as well as the identification of regulatory elements in the promoter region of this gene.

The signal recognition particle and related small cytoplasmic ribonucleoprotein particles

Recently, a number of novel small cytoplasmic ribonucleoprotein particles have been identified that comprise RNA and protein subunits related to the signal recognition particle (SRP). Here we discuss the latest results on the structure and functions of SRP together with the structures and putative functions of the novel SRP-related ribonucleoprotein particles.

Crystallization and preliminary crystallographic analysis of the signal recognition particle SRPphi14-9 fusion protein

The SRPphi14-9 fusion protein, which can functionally replace the SRP9/14 heterodimer in the mammalian signal recognition particle (SRP), has been crystallized using the vapor diffusion method. Four different crystal forms were grown. SRPphi14-9 form IV crystals belong to the space group P4(1)22/ P4(3)22 with cell parameters a = b = 69.7 Angstroms, c = 95.7 Angstroms, alpha = beta = gamma = 90 degrees. A complete data set to 2.8 Angstroms resolution with an Rsym on intensities of 7.0% was collected on a single flash-frozen crystal.

Characterization of the HeLa cell 35 kDa Alu-element binding protein

Human Alu-elements are short interspersed DNA sequences that comprise approximately 5% of the human genome. The physiological role of Alu-elements are unknown, although they are proposed to be involved in DNA replication, transcriptional regulation and nuclear transport of signal recognition particle RNA. Proteins that bind to Alu-element and Alu RNA have been identified in human cells. In HeLa cells, two proteins of 120 kDa and 35 kDa specifically bind to Alu-elements. We find that the 35 kDa protein is localized exclusively to the nucleus, while the 120 kDa protein is distributed between nucleus and cytoplasm. The 35 kDa protein is regulated by phosphorylation. Upon dephosphorylation, its DNA binding activity is significantly enhanced. Contrary to the recent identification of the smaller Alu-element binding protein as annexin II, we find that annexin II is not an Alu-element binding protein. Using a variety of techniques, we demonstrate that the 35 kDa Alu-element binding protein is distinct from annexin II.

Human signal recognition particle (SRP) Alu-associated protein also binds Alu interspersed repeat sequence RNAs. Characterization of human SRP9

Nearly 1 million interspersed Alu elements reside in the human genome. Alu retrotransposition is presumably mediated by full-length Alu transcripts synthesized by RNA polymerase III, while some polymerase III-synthesized Alu transcripts undergo 3'-processing and accumulate as small cytoplasmic (sc) RNAs of unknown function. Interspersed Alu sequences also reside in the untranslated regions of some mRNAs. The Alu sequence is related to a portion of the 7SL RNA component of signal recognition particle (SRP). This region of 7SL RNA together with 9- and 14-kDa polypeptides (SRP9/14) regulates translational elongation of ribosomes engaged by SRP. Here we characterize human (h) SRP9 and show that it, together with hSRP14 (SRP9/14), forms the activity previously identified as Alu RNA-binding protein (RBP). The primate-specific C-terminal tail of hSRP14 does not appreciably affect binding to scAlu RNA. Kd values for three Alu-homologous scRNAs were determined using Alu RBP (SRP9/14) purified from HeLa cells. The Alu region of 7SL, scAlu, and scB1 RNAs exhibited Kd values of 203 pM, 318 pM, and 1.8 nM, respectively. Finally, Alu RBP can bind with high affinity to synthetic mRNAs that contain interspersed Alus in their untranslated regions.

Signal recognition particle (SRP), a ubiquitous initiator of protein translocation

In higher eukaryotes, most secretory and membrane proteins are synthesised by ribosomes which are attached to the membrane of the rough endoplasmic reticulum (RER). This allows the proteins to be translocated across that membrane already during their synthesis. The ribosomes are directed to the RER membrane by a cytoplasmic ribonucleoprotein particle, the signal recognition particle (SRP). SRP fulfills its task by virtue of three distinguishable activities: the binding of a signal sequence which, being part of the nascent polypeptide to be translocated, is exposed on the surface of a translating ribosome; the retardation of any further elongation; and the SRP-receptor-mediated binding of the complex of ribosome, nascent polypeptide and SRP to the RER membrane which results in the detachment of SRP from the signal sequence and the ribosome and the insertion of the nascent polypeptide into the membrane. Evidence is accumulating that SRP is not restricted to eukaryotes: SRP-related particles and SRP-receptor-related molecules are found ubiquitously and may function in protein translocation in every living organism. This review focuses on the mammalian SRP. A brief discussion of its overall structure is followed by a detailed description of the structures of its RNA and protein constituents and the requirements for their assembly into the particle. Homologues of SRP components from organisms other than mammals are mentioned to emphasize the components' conserved or less conserved features. Subsequently, the functions of each of the SRP constituents are discussed. This sets the stage for a presentation of a model for the mechanism by which SRP cyclically assembles and disassembles with translating ribosomes and the RER membrane. It may be expected that similar mechanisms are used by SRP homologues in organisms other than mammals. However, the mammalian SRP-mediated translocation mechanism may not be conserved in its entirety in organisms like Escherichia coli whose SRP lack components required for the function of the mammalian SRP. Possible translocation pathways involving the rudimentary SRP are discussed in view of the existence of alternative, chaperone-mediated translocation pathways with which they may intersect. The concluding two sections deal with open questions in two areas of SRP research. One formulates basic questions regarding the little-investigated biogenesis of SRP. The other gives an outlook over the insights into the mechanisms of each of the known activities of the SRP that are to be expected in the short and medium-term future.