tRNA-derived small RNA changes in bone marrow stem cells under hypoxia and osteogenic conduction.

BACKGROUND: Tissue engineering using bone mesenchymal stem cells (BMSCs) transplantation is a promising therapeutic for bone regeneration. However, the effect of bone regeneration remains unsatisfactory due to the BMSCs' functional abnormality influenced by hypoxia. In this study, we attempt to explore the mechanism of osteogenic differentiation of BMSCs under hypoxic conditions from the perspective of non-coding RNA regulation. METHODS: The study employed BMSCs obtained from healthy donors and simulated hypoxia using CoCl2 stimulation. High-throughput sequencing technique was used to identify differential expression profiles of tRNA-derived small RNA (tsRNA) in three experimental groups: BMSCs-0d, BMSCs-7d and BMSCs-0d-CoCl2 . TargetScan and miRanda algorithms were used to determine tsRNA target genes, while Gene Ontology and Kyoto Encyclopedia of Genes and Genomes analysis were employed for the prediction of biological functions. Real-time reverse transcriptase-polymerase chain reaction (Real-time RT-PCR) was carried out on four selected differentially expressed tsRNAs. RESULTS: After the osteogenic induction and CoCl2 stimulated separately, there were 19 tsRNAs differentially expressed in BMSCs, including 14 upregulated and five downregulated. According to the analysis of biological information, these tsRNAs may regulate 311 potential target genes and mainly enrich the pathways such as metabolic pathways, Wnt signalling pathway, osteoclast differentiation, cellular senescence and mTOR signalling pathway. The results of Real-time RT-PCR for 3'tiRNA-41-GlnTTG-6, 3'tiRNA-42-LysTTT-8, 5'tiRNA-35-CysACA-1 and tRF3a-AsnGTT-9 were consistent with small RNA sequencing data. CONCLUSION: We discovered the tsRNA that changes the process of osteogenesis and hypoxia, which provides new targets for promoting survival and regeneration functions after BMSCs transplantation.

Integrated analysis of tRNA-derived small RNAs in proliferative human aortic smooth muscle cells.

BACKGROUND: Abnormal proliferation of vascular smooth muscle cells (VSMCs) contributes to vascular remodeling diseases. Recently, it has been discovered that tRNA-derived small RNAs (tsRNAs), a new type of noncoding RNAs, are related to the proliferation and migration of VSMCs. tsRNAs regulate target gene expression through miRNA-like functions. This study aims to explore the potential of tsRNAs in human aortic smooth muscle cell (HASMC) proliferation. METHODS: High-throughput sequencing was performed to analyze the tsRNA expression profile of proliferative and quiescent HASMCs. Quantitative real-time polymerase chain reaction (qRT-PCR) was performed to validate the sequence results and subcellular distribution of AS-tDR-001370, AS-tDR-000067, AS-tDR-009512, and AS-tDR-000076. Based on the microRNA-like functions of tsRNAs, we predicted target promoters and mRNAs and constructed tsRNA-promoter and tsRNA-mRNA interaction networks. Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analyses were performed to reveal the function of target genes. EdU incorporation assay, Western blot, and dual-luciferase reporter gene assay were utilized to detect the effects of tsRNAs on HASMC proliferation. RESULTS: Compared with quiescent HASMCs, there were 1838 differentially expressed tsRNAs in proliferative HASMCs, including 887 with increased expression (fold change > 2, p < 0.05) and 951 with decreased expression (fold change < ½, p < 0.05). AS-tDR-001370, AS-tDR-000067, AS-tDR-009512, and AS-tDR-000076 were increased in proliferative HASMCs and were mainly located in the nucleus. Bioinformatics analysis suggested that the four tsRNAs involved a variety of GO terms and pathways related to VSMC proliferation. AS-tDR-000067 promoted HASMC proliferation by suppressing p53 transcription in a promoter-targeted manner. AS-tDR-000076 accelerated HASMC proliferation by attenuating mitofusin 2 (MFN2) levels in a 3'-untranslated region (UTR)-targeted manner. CONCLUSIONS: During HASMC proliferation, the expression levels of many tsRNAs are altered. AS-tDR-000067 and AS-tDR-000076 act as new factors promoting VSMC proliferation.

Inhibition of HIV-1 Gag-membrane interactions by specific RNAs.

HIV-1 particle assembly, which occurs at the plasma membrane (PM) of cells, is driven by the viral polyprotein Gag. Gag recognizes phosphatidylinositol-(4,5)-bisphosphate [PI(4,5)P2], a PM-specific phospholipid, via the highly basic region (HBR) in its N-terminal matrix (MA) domain. The HBR is also known to bind to RNA. We have previously shown, using an in vitro liposome binding assay, that RNA inhibits Gag binding to membranes that lack PI(4,5)P2 If this RNA block is removed by RNase treatment, Gag can bind nonspecifically to other negatively charged membranes. In an effort to identify the RNA species that confer this inhibition of Gag membrane binding, we have tested the impact of purified RNAs on Gag interactions with negatively charged liposomes lacking PI(4,5)P2 We found that some tRNA species and RNAs containing stem-loop 1 of the psi region in the 5' untranslated region of the HIV-1 genome impose inhibition of Gag binding to membranes lacking PI(4,5)P2 In contrast, a specific subset of tRNAs, as well as an RNA sequence previously selected in vitro for MA binding, failed to suppress Gag-membrane interactions. Furthermore, switching the identity of charged residues in the HBR did not diminish the susceptibility of Gag-liposome binding for each of the RNAs tested, while deletion of most of the NC domain abrogates the inhibition of membrane binding mediated by the RNAs that are inhibitory to WT Gag-liposome binding. These results support a model in which NC facilitates binding of RNA to MA and thereby promotes RNA-based inhibition of Gag-membrane binding.

In vivo modification of tRNA with an artificial nucleobase leads to full disease remission in an animal model of multiple sclerosis.

Queuine is a modified pyrrolopyrimidine nucleobase derived exclusively from bacteria. It post-transcriptionally replaces guanine 34 in transfer RNA isoacceptors for Asp, Asn, His and Tyr, in almost all eukaryotic organisms, through the activity of the ancient tRNA guanine transglycosylase (TGT) enzyme. tRNA hypomodification with queuine is a characteristic of rapidly-proliferating, non-differentiated cells. Autoimmune diseases, including multiple sclerosis, are characterised by the rapid expansion of T cells directed to self-antigens. Here, we demonstrate the potential medicinal relevance of targeting the modification of tRNA in the treatment of a chronic multiple sclerosis model­murine experimental autoimmune encephalomyelitis. Administration of a de novo designed eukaryotic TGT substrate (NPPDAG) led to an unprecedented complete reversal of clinical symptoms and a dramatic reduction of markers associated with immune hyperactivation and neuronal damage after five daily doses. TGT is essential for the therapeutic effect, since animals deficient in TGT activity were refractory to therapy. The data suggest that exploitation of the eukaryotic TGT enzyme is a promising approach for the treatment of multiple sclerosis.

G-quadruplex structures contribute to the neuroprotective effects of angiogenin-induced tRNA fragments.

Angiogenin (ANG) is a stress-activated ribonuclease that promotes the survival of motor neurons. Ribonuclease inactivating point mutations are found in a subset of patients with ALS, a fatal neurodegenerative disease with no cure. We recently showed that ANG cleaves tRNA within anticodon loops to produce 5'- and 3'-fragments known as tRNA-derived, stress-induced RNAs (tiRNAs). Selected 5'-tiRNAs (e.g., tiRNA(Ala), tiRNA(Cys)) cooperate with the translational repressor Y-box binding protein 1 (YB-1) to displace the cap-binding complex eIF4F from capped mRNA, inhibit translation initiation, and induce the assembly of stress granules (SGs). Here, we show that translationally active tiRNAs assemble unique G-quadruplex (G4) structures that are required for translation inhibition. We show that tiRNA(Ala) binds the cold shock domain of YB-1 to activate these translational reprogramming events. We discovered that 5'-tiDNA(Ala) (the DNA equivalent of 5'-tiRNA(Ala)) is a stable tiRNA analog that displaces eIF4F from capped mRNA, inhibits translation initiation, and induces the assembly of SGs. The 5'-tiDNA(Ala) also assembles a G4 structure that allows it to enter motor neurons spontaneously and trigger a neuroprotective response in a YB-1-dependent manner. Remarkably, the ability of 5'-tiRNA(Ala) to induce SG assembly is inhibited by G4 structures formed by pathological GGGGCC repeats found in C9ORF72, the most common genetic cause of ALS, suggesting that functional interactions between G4 RNAs may contribute to neurodegenerative disease.

A vast collection of microbial genes that are toxic to bacteria.

In the process of clone-based genome sequencing, initial assemblies frequently contain cloning gaps that can be resolved using cloning-independent methods, but the reason for their occurrence is largely unknown. By analyzing 9,328,693 sequencing clones from 393 microbial genomes, we systematically mapped more than 15,000 genes residing in cloning gaps and experimentally showed that their expression products are toxic to the Escherichia coli host. A subset of these toxic sequences was further evaluated through a series of functional assays exploring the mechanisms of their toxicity. Among these genes, our assays revealed novel toxins and restriction enzymes, and new classes of small, non-coding toxic RNAs that reproducibly inhibit E. coli growth. Further analyses also revealed abundant, short, toxic DNA fragments that were predicted to suppress E. coli growth by interacting with the replication initiator DnaA. Our results show that cloning gaps, once considered the result of technical problems, actually serve as a rich source for the discovery of biotechnologically valuable functions, and suggest new modes of antimicrobial interventions.

Ascophyllum nodosum polysaccharide regulates gut microbiota metabolites to protect against colonic inflammation in mice.

Ascophyllum nodosum polysaccharide (ANP) can protect against colonic inflammation but the underlying mechanism is still unclear. This study has determined the metabolites of gut microbiota regulated by ANP to reveal the mechanism of the anti-inflammation effect of ANP. Using an in vitro colonic fermentation model, the results indicate that gut microbiota could utilize a proportion of ANP to increase the concentrations of short-chain fatty acids (SCFAs) and decrease ammonia content. Metabolomics revealed that 46 differential metabolites, such as betaine, L-carnitine, and aminoimidazole carboxamide ribonucleotide (AICAR), could be altered by ANP. Metabolic pathway analysis showed that ANP mainly up-regulated the phenylalanine, tyrosine, and tryptophan biosynthesis and aminoacyl-tRNA biosynthesis, which were negatively correlated with inflammation progression. Interestingly, these metabolites associated with inflammation were also up-regulated by ANP in colitis mice, including betaine, L-carnitine, AICAR, N-acetyl-glutamine, tryptophan, and valine, which were mainly associated with amino acid metabolism and aminoacyl-tRNA biosynthesis. Furthermore, the metabolites modulated by ANP were associated with the relative abundances of Akkermansia, Bacteroides, Blautia, Coprobacillus, Enterobacter, and Klebsiella. Additionally, based on VIP values, betaine is a key metabolite after the ANP supplement in vitro and in vivo. As indicated by these findings, ANP can up-regulate the production of SCFAs, betaine, L-carnitine, and AICAR and aminoacyl-tRNA biosynthesis to protect against colonic inflammation and maintain intestinal health.

Tavaborole-Induced Inhibition of the Aminoacyl-tRNA Biosynthesis Pathway against Botrytis cinerea Contributes to Disease Control and Fruit Quality Preservation.

The inhibitory effect of tavaborole on the invasion of Botrytis cinerea in grapes and tomatoes, as well as the potential mechanism involved, was discovered in this study. Our findings showed that tavaborole inhibited Botrytis cinerea spore germination and mycelial expansion in vitro and that the control efficiency in vivo on fruit decay was dose-dependent, which was effective in reducing disease severity and maintaining the organoleptic quality of the fruit, such as reducing weight loss and retaining fruit hardness and titratable acid contents during storage. Furthermore, the precise mechanism of action was investigated further. Propidium iodide staining revealed that Botrytis cinerea treated with tavaborole lost membrane integrity. For further validation, cytoplasmic malondialdehyde accumulation and leakage of cytoplasmic constituents were determined. Notably, the inhibitory effect was also dependent on inhibiting the activities of aminoacyl-tRNA synthetases involved in the aminoacyl-tRNA biosynthesis pathway in Botrytis cinerea. The above findings concluded that tavaborole was effective against Botrytis cinerea infection in postharvest fruit, and a related mechanism was also discussed, which may provide references for the drug repurposing of tavaborole as a postharvest fungicide.

Phenotype microarray analysis reveals the biotransformation of Fusarium oxysporum f.sp. lycopersici influenced by Bacillus subtilis PBE-8 metabolites.

Herein, Bacillus subtilis PBE-8's biocontrol efficacy was evaluated through physiological and metabolic approaches against Fusarium oxysporum f.sp. lycopersici (FOL). The study elaborates on PBE-8's cell-free filtrate (CFF) antifungal activity through mycelial growth inhibition, metabolite profiling, and substrates utilization patterns. Additionally, under different CFF concentrations, reduction in spore count (94%-55%), biomass (50%), and cytoplasmic bulbous protrusions in mycelia were also observed. Furthermore, the effect of bacterial CFF on FOL metabolism was confirmed through GC-MS. CFF suppresses the concentration of aliphatic amino acids like L-valine, L-leucine, L-Isoleucine, glycine, and fatty acids such as linoleic acid and α- linolenic acid during the co-culturing conditions, which are essential for pathogenicity and resistance against host's systemic acquired resistance. The phenotype microarray assay revealed that CFF-treated FOL shows phenotype loss in 507 (56.58%) out of 896 substrates. Among 507, twenty-seven substrates showed significant phenotype loss, among which four substrates such as L-glutamic acid, L-glutamine, ammonia, and L-arginine are common in different crucial metabolic pathways of FOL, like alanine, aspartate, and glutamate metabolism, arginine and proline, carbon metabolism, arginine biosynthesis, nitrogen metabolism, amino-acyl tRNA synthesis, and biosynthesis of amino acids. The results suggest that PBE-8 CFF has certain antifungal metabolites that hinder the fungal metabolic pathways.

Effects of polystyrene microplastics acute exposure in the liver of swordtail fish (Xiphophorus helleri) revealed by LC-MS metabolomics.

As global pollution, microplastics pollution has aroused growing concerns. In our experiment, the effect of microplastics acute exposure on the liver of swordtail fish was investigated by using LC-MS metabolomics. Fishes treated with high concentration polystyrene microspheres (1 µm) for 72 h were divided into three concentration groups: (A) no microplastics, (B): 1 × 106 microspheres L-1, (C): 1 × 107 microspheres L-1. Metabolomic analysis indicated that exposure to microplastics caused alterations of metabolic profiles in swordtail fish, including 37 differential metabolites were identified in B vs. A, screened out ten significant metabolites, which involved 14 metabolic pathways. One hundred three differential metabolites were identified in C vs. A, screened out 16 significant metabolites, which involved 30 metabolic pathways. Six significant metabolites were overlapping in group B vs. A and C vs. A; they are 3-hydroxyanthranilic acid, l-histidine, citrulline, linoleic acid, pantothenate, and xanthine. In addition, four metabolic pathways are overlapping in group B vs. A and C vs. A; they are beta-alanine metabolism, biosynthesis of amino acids, linoleic acid metabolism, and aminoacyl-tRNA biosynthesis. These differential metabolites were involved in oxidative stress, immune function, energy metabolism, sugar metabolism, lipid metabolism, molecule transport, and weakened feed utilization, growth performance, nutrient metabolism, and animal growth. Furthermore, we found that the number of interfered amino acids and microplastics showed a dose-effect. In summary, great attention should be paid to the potential impact of microplastics on aquatic organisms.

A Ran-independent pathway for export of spliced mRNA.

All major nuclear export pathways so far examined follow a general paradigm. Specifically, a complex is formed in the nucleus, containing the export cargo, a member of the importin-beta family of transporters and RanGTP. This complex is translocated across the nuclear pore to the cytoplasm, where hydrolysis of the GTP on Ran is stimulated by the GTPase-activating protein RanGAP. The activity of RanGAP is increased by RanBP1, which also promotes disassembly of RanGTP-cargo-transporter complexes. Here we investigate the role of RanGTP in the export of mRNAs generated by splicing. We show that nuclear injection of a Ran mutant (RanT24N) or the normally cytoplasmic RanGAP potently inhibits the export of both tRNA and U1 snRNA, but not of spliced mRNAs. Moreover, nuclear injection of RanGAP together with RanBP1 blocks tRNA export but does not affect mRNA export. These and other data indicate that export of spliced mRNA is the first major cellular transport pathway that is independent of the export co-factor Ran.

Improvement of in vitro-transcribed amber suppressor tRNAs toward higher suppression efficiency in wheat germ extract.

In vitro-transcribed, unmodified, and non-aminoacylated amber suppressor tRNAs that are recognized by natural aminoacyl-tRNA synthetase were improved toward higher suppression efficiency in batch-mode cell-free translation in wheat germ extract. The suppression efficiency of the suppressor obtained through four sequence optimization steps (anticodon alteration of natural tRNAs (the first generation); chimerization of the efficient suppressors in the first generation; investigation and optimization of the effective parts in the second generation; combination of the optimized parts in the third generation) and by the terminal tuning was approximately 60%, which was 2.4-fold higher than that of the best suppressor in the first generation. In addition, an eRF1 aptamer further increased the efficiency up to 85%. This highly efficient suppression system also functioned well in a dialysis-based large-scale protein synthesis.

A genetically engineered microRNA-34a prodrug demonstrates anti-tumor activity in a canine model of osteosarcoma.

Osteosarcoma (OSA) represents the most common primary bone tumor in humans and pet dogs. Little progress has been made with regard to viable treatment options in the past three decades and patients presenting with metastatic disease continue to have a poor prognosis. Recent mouse studies have suggested that microRNA-34a (miR-34a) may have anti-tumor activities in human OSA models. Due to the conservation of microRNA across species, we hypothesized that a bioengineered miR-34a prodrug (tRNA/miR-34a) would have similar effects in canine OSA, providing a valuable preclinical model for development of this therapeutic modality. Using a panel of canine OSA cell lines, we found that tRNA/miR-34a reduced viability, clonogenic growth, and migration and invasion while increasing tumor cell apoptosis. Furthermore, canine OSA cells successfully process the tRNA/miR-34a into mature miR-34a which reduces expression of target proteins such as platelet derived growth factor receptor alpha (PDGFRα), Notch1 and vascular endothelial growth factor (VEGF). Additionally, our subcutaneous OSA xenograft model demonstrated in vivo tumor growth delay, increased necrosis and apoptosis by tRNA/miR-34a, and decreased cellular proliferation ability. Taken together, these data support that this novel microRNA-based therapy may possess clinical utility in a spontaneously-occurring large animal model of OSA, which can then serve to inform the clinical development of this therapy for human OSA patients.

The limiting effect of transfer RNA's on the rate of protein synthesis in cell extracts of rapidly growing tumors.

Using crude cell extracts from rapidly growing animal and human tumors, we found that (a) the addition of homologous transfer RNA (tRNA) to these extracts stimulated polypeptide synthesis two-to threefold, while addition of heterologous tRNA did not have a similar effect; (b) addition of homologous as well as heterologous ribosomal RNA was also stimulatory; and (c) both stimulatory effects were additive. The possibility that the effect of homologous tRNA could be mediated by contaminating material (such as the "translational control" RNA) seems to be rulted out by experiments with highly purified tRNA preparations, which did not contain even traces of 18 S, 7 S, 5 S, and smaller than 4S RNA's. Control experiments showed that no loss of tRNA occurred either during preparation of the cell extracts or under the conditions of in vitro protein synthesis. The results obtained suggest possible occurrence of a deficiency in specific isoaccepting tRNA's in rapidly growing solid tumors.

The influence of rRNA and tRNA on the translation of avian globin mRNA in cell-free systems of protein synthesis.

Cell-free synthesis of globin chains in the presence of globin mRNA in an Ehrlich ascites-cell-free system is further stimulated by addition of 18- and 28-S rRNA but not of 4-S tRNA and 5-S rRNA. This stimulation can not be observed in the wheat germ cell-free system. When 125I-labelled globin mRNA was incubated in the two systems we have found after 60 min a 75% decrease of trichloroacetic acid precipitable polynucleotides in the ascites but only a 20% decrease in the wheat germ system. The RNAase action on mRNA can be reduced by the addition of 18- and 28-S rRNA but not by 5-S rRNA and 4-S tRNA. We suggest that the stimulating effect of the two rRNA species in the ascites cell-free system is due to a higher activity of a specific RNAase in this system and a competitive protection of mRNA from RNAase action.

Regulation of RNA synthesis in Escherichia coli. III. Degradation of guanosine 5'-diphosphate 3'-diphosphate in cold-shocked cells.

Cold-shocked cells of Escherichia coli can degrade intracellularly accumulated guanosine 5'-diphosphate 3'-diphosphate (ppGpp). The rate of ppGpp degradation is governed, as in whole cells, by the spoT gene; a rapid breakdown reaction is associated with the presence of the spoT+ allele and at least a five-fold slower decay occurs in spoT-minus mutants. The two degradation reactions in shocked cells display the following similarities: (i) the rates of degradation are equivalent to whole cell estimates, (ii) both require a full complement of activated amino acids, (iii) both are dependent upon supplements in the reaction mixture which stimulate the availability of energy-rich compounds and (iv) neither is inhibited by concentrations of ribosomal antibiotics which severely restrict protein synthesis. Apart from characteristic rate differences, decay of ppGpp in shocked cells derived from spoT-minus strains is discerned from spoT+ mediated decay in shocked cells by sensitivity to high concentrations of tetracycline and by manganese ion dependence.

Factors causing release of ribosomal subunits from isolated nuclei of regenerating rat liver in vitro.

Incubation medium II causes release of ribosomal subunits from isolated prelabeled nuclei of regenerating rat liver in vitro (Sato, T., Ishikawa, K. and Ogato, K. (1976) Biochim. Biophys. Acta 000, 000-000). The effects of individual components of this medium on release of subunits were studied and the following results were obtained. 1. Dialyzed cytosol was effective in causing release of total labeled RNA, but its effect on release of labeled ribosomal subunits was rather lower than that of low molecular yeast RNA. Spermidine inhibited the release of total labeled RNA as well as that of labeled ribosomal subunits. 2. Low molecular yeast RNA was the most effective component for inducing release of labeled ribosomal subunits. Homologous ribosomal RNA was as effective as yeast RNA. Cytoplasmic ribosomes, prepared by washing with solution of high salt concentration, and their subunits were also effective. 3. Transfer RNA was not so effective as yeast RNA and ribosomal RNA and even after heat treatment it had little effect. 4. Among the homopolyribonucleotides tested, polyuridylic acid had a strong effect but polyadenylic acid, polycytidylic acid and polyinosinic acid had no effect. 5. The effects of yeast RNA and polyuridylic acid in causing release of labeled ribosomal subunits were dependent upon their concentrations in the reaction mixture. The characteristics of the factors which cause release of labeled ribosomal subunits in vitro are discussed on the basis of the results.

Effects of polyamines and polyanions on a cyclic nucleotide-independent and a cyclic AMP-dependent protein kinase.

The phosphorylation of phosvitin in vitro by a cyclic nucleotide-independent protein kinase (phosvitin kinase) derived from rooster liver is markedly stimulated by the divalent cation, Mg2+. In addition, the activity is further stimulated by low concentrations of the polyamines putrescine, spermidine and spermine leading to higher rates of phosphate incorporation than could be obtained at any concentration of Mg2+. Spermine is inhibitory at higher concentrations. The polyamines shift the Mg2+ requirement for maximal activity to lower concentrations. The activity of a cyclic AMP-dependent histone kinase from beef heart is not altered by the presence of polyamines. Heparin is a potent inhibitor of phosvitin kinase but has no effect on histone kinase. Polyribonucleotides (polyadenylic acid and transfer RNA) inhibit both types of kinases, but the degree of inhibition of phosvitin kinase is variable and depends upon the type of the polyanion present. Sermidine and spermine, but not Mg2+, efficiently counteract the inhibitory action of heparin and tRNA. The results suggest that, also in vivo, naturally occurring polyamines and polyanions such as tRNA may have a regulatory function on protein kinases.

Chymotrypsin treatment of glucocorticoid receptor attenuates RNA-dependent inhibition of DNA binding. Evidence for a distinct RNA-binding site.

Certain types of RNA can prevent the association of the rat liver glucocorticoid receptor with DNA. This inhibition of receptor binding to DNA cannot be mitigated by increasing amounts of DNA, suggesting that the RNA is not merely acting as a competitive inhibitor. Treatment of partially purified receptor with low concentrations of chymotrypsin eliminates the inhibitory effects of some RNAs without negatively affecting the DNA-binding ability of the receptor. Potent inhibitors of the receptor-DNA association, such as poly(G) and poly(X), still inhibit DNA binding of the treated receptor, although to a lesser extent than the untreated controls. However, moderate inhibitors, such as tRNA and poly(U), no longer inhibit the receptor-DNA association at low concentrations. We take these findings to suggest that RNA inhibition of DNA binding is due to the interaction of the RNA at a distinct RNA-binding site. This site may serve as a regulator site for the receptor-DNA association.