T4 mRNA Research Articles

Mixture effect of parental exposure to triazophos and fenvalerate on the early development of zebrafish offspring

Triazophos (TRI) and fenvalerate (FEN) have been extensively used in the world and frequently coexist in the water environments, might pose health risk to aquatic species. However, investigations of their mixture toxic effects on offspring after parental exposure have been neglected, especially for aquatic vertebrates such fish. To address this knowledge gap, parental zebrafish (F0 generation) were exposed to TRI, FEN and their mixture for 60 days, as well as the embryos (F1 generation) were hatched without or with continued corresponding exposures at the same concentrations until 7 days post fertilization. The results exhibited that exposure to TRI and FEN altered the expression levels of biomarkers associated with several biological processes, such as apoptosis and inflammatory response. Compared to individual exposure in the F1 generation, the co-exposure to TRI and FEN resulted in increased the expression of T4 and cc-chem mRNA and decreased the expression of ROS, trα, il-8, and gpx mRNA when the F0 generation was similarly exposed. These results revealed that the co-exposure to TRI and FEN has detrimental effects on fish progeny following parental exposure, even if the progeny are not directly exposed to the pesticides, and such negative effects may be intensified if the offspring continue to be exposed. This study enhances the understanding of the harmful impacts of parental exposure to the pesticide mixture on descendants and holds implications for the ecological risk assessment of pesticide mixtures in aquatic vertebrates. Further mechanistic studies are necessary to gain a deeper insight into the mixture effects of pesticides and other kinds of pollutants on subsequent offspring following parental exposure.

Versatile fluorescence detection of T4 PNK and mRNA based on unique DNA nanomachine amplification

The development of DNA nanomachines provides a new strategy for the detection of tumor markers. In this work, an intelligent three-dimensional (3D) DNA walking machine with polynucleotide kinase (PNK) activator was designed, which was coupled with unique nanomachine formed by DNA nanowire cascade amplification reaction for versatile fluorescence detection of T4 PNK activity and messenger RNA (mRNA). When PNK exists, the free DNA walker was formed by hydrolysis cleavage of exonuclease, then the fluorophore-labeled report probe on the Au nanoparticles (NPs) was sheared during cycling cleavage reaction, thus the fluorescence signal was recovered for detection of PNK. Moreover, the DNA nanowires were produced by rolling ring amplification, then target mRNA sequentially initiated interval hybridization of hairpin probes through DNA nanowire, thus realizing DNA cascade reaction (DCR) with high “on” signal of DNA nanomachine for mRNA assay. This developed novel fluorescence nanomachine reported a new assay method with promising application for versatile targets and showed great potential for molecular-target therapies, and clinic diagnostics.

Thermodynamic Cost, Speed, Fluctuations, and Error Reduction of Biological Copy Machines.

Due to large fluctuations in cellular environments, transfer of information in biological processes without regulation is error-prone. The mechanistic details of error-reducing mechanisms in biological copying processes have been a subject of active research; however, how error reduction of a process is balanced with its thermodynamic cost and dynamical properties remain largely unexplored. Here, we study the error reducing strategies in light of the recently discovered thermodynamic uncertainty relation (TUR) that sets a physical bound to the cost-precision trade-off for dissipative processes. We found that the two representative copying processes, DNA replication by the exonuclease-deficient T7 DNA polymerase and mRNA translation by the E. coli ribosome, reduce the error rates to biologically acceptable levels while also optimizing the processes close to the physical limit dictated by TUR.

RnlB Antitoxin of the Escherichia coli RnlA-RnlB Toxin-Antitoxin Module Requires RNase HI for Inhibition of RnlA Toxin Activity.

The Escherichia coli RnlA-RnlB toxin–antitoxin system is related to the anti-phage mechanism. Under normal growth conditions, an RnlA toxin with endoribonuclease activity is inhibited by binding of its cognate RnlB antitoxin. After bacteriophage T4 infection, RnlA is activated by the disappearance of RnlB, resulting in the rapid degradation of T4 mRNAs and consequently no T4 propagation when T4 dmd encoding a phage antitoxin against RnlA is defective. Intriguingly, E. coli RNase HI, which plays a key role in DNA replication, is required for the activation of RnlA and stimulates the RNA cleavage activity of RnlA. Here, we report an additional role of RNase HI in the regulation of RnlA-RnlB system. Both RNase HI and RnlB are associated with NRD (one of three domains of RnlA). The interaction between RnlB and NRD depends on RNase HI. Exogenous expression of RnlA in wild-type cells has no effect on cell growth because of endogenous RnlB and this inhibition of RnlA toxicity requires RNase HI and NRD. These results suggest that RNase HI recruits RnlB to RnlA through NRD for inhibiting RnlA toxicity and thus plays two contrary roles in the regulation of RnlA-RnlB system.

Structural characterizations of phage antitoxin Dmd and its interactions with bacterial toxin RnlA

Toxin–antitoxin (TA) loci are widespread in bacteria plasmids and chromosomes, and target various cellular functions to regulate cell growth and death. A type II TA system RnlA–RnlB from Escherichia coli is associated with phage-resistance. After the infection of bacteriophage T4 with Dmd defection, RnlA is activated by the disappearance of RnlB, resulting in the rapid degradation of T4 mRNAs. Dmd can bind to RnlA directly and neutralize RnlA toxicity to allow phage reproduction. Dmd represent a heterogenous antitoxin of RnlA replacing antitoxin RnlB. Here, we reported two structures of Dmd from T4 phage and RB69 phage. Both Dmd structures are high similar with a compacted domain composed of a four-stranded anti-parallel β-sheet and an α-helix. Chromatography and SAXS suggest Dmd forms a dimer in solution consistent with that in crystal. Structure-based mutagenesis of Dmd reveals key residues involved in RnlA-binding. Possibility cavities in Dmd used for compounds design were modeled. Our structural study revealed the recognition and inhibition mechanism of RnlA by Dmd and providing a potential laboratory phage prevention target for drug design.

Coupling of mRNA Structure Rearrangement to Ribosome Movement during Bypassing of Non-coding Regions

Nearly half of the ribosomes translating a particular bacteriophage T4 mRNA bypass a region of 50 nt, resuming translation 3' of this gap. How this large-scale, specific hop occurs and what determines whether a ribosome bypasses remain unclear. We apply single-molecule fluorescence with zero-mode waveguides to track individual Escherichia coli ribosomes during translation of T4's gene 60 mRNA. Ribosomes that bypass are characterized by a 10- to 20-fold longer pause in a non-canonical rotated state at the take-off codon. During the pause, mRNA secondary structure rearrangements are coupled to ribosome forward movement, facilitated by nascent peptide interactions that disengage the ribosome anticodon-codon interactions for slippage. Close to the landing site, the ribosome then scans mRNA in search of optimal base-pairing interactions. Our results provide a mechanistic and conformational framework for bypassing, highlighting a non-canonical ribosomal state to allow for mRNA structure refolding to drive large-scale ribosome movements.

Improvement of kidney yang syndrome by icariin through regulating hypothalamus-pituitary-adrenal axis.

To investigate whether Epimedium brevicornu Maxim (EB) and icariin could exert their protective effects on hydrocortisone induced (HCI) rats by regulating the hypothalamus-pituitary-adrenal (HPA) axis and endocrine system and the possible mechanism. Male 10-week-old Sprague Dawley (SD) rats were allotted to 6 groups (A-F) with 12 each, group A was injected normal saline (NS) 3 mL/kg day intraperitoneally, group A and B were given NS 6 mL/kg day by gastrogavage, group B-F were injected hydrocortisone 15 mg/kg intraperitoneally, group C and D were given EB 8 or 5 g/(kg day) by gastrogavage, group E and F were given icariin 25 or 50 mg/(kg day) by gastrogavage. Gene expressions of hypothalamus corticotropin releasing hormone (CRH) and pituitary proopiomelanocortin (POMC) were detected by reverse transcription-polymerase chain reaction (RT-PCR), and protein of pituitary POMC by Western-blot. The serum T4, testosterone, cortisol and POMC mRNA expression were increased after treatment with EB or icariin in HCI rats, the serum CRH and the hypothalamus CRH mRNA expression released from hypothalamus corticotropin decreased compared with group B (P<0.05).The treatment with only icariin increased serum adrenocorticotropic hormone (ACTH) compared with group B (P<0.05). EB and icariin might be therapeutically beneficial in the treatment of HCI rats through attuning the HPA axis and endocrine system which was involved in the release of CRH in hypothalamic, and the production of POMC-derived peptide ACTH in anterior pituitary, the secretion of corticosteroids in adrenal cortex.

Hsp90, hsp60 and hsf‐1 genes expression in muscle, heart and brain of thermal manipulated chicken (539.12)

The aim of this study was to investigate the effect of thermal manipulation (TM during embryonic days ED12 ‐ 18) on the gene expressions of Hsp90 and Hsp60 and HSF‐1 on hatchability, growth performance and thermotolerance acquisition during thermal challenge (TC) in three different thermal manipulated groups and also to investigate their ability to cope with thermal challenged (TC) during post hatching days (10 and 28) by using real time RT‐PCR and ELISA techniques. One thousand five hundred fertile chicken eggs were divided randomly into four groups: control group (37.8°C), TM1 (39°C for 9h), TM2 (39°C for 12h) and TM3 (39°C for 18h). Chicks from each treatment group were then randomly divided into 2 sub‐treatment groups (Naive and TC). Chicks in TC groups were subjected to thermal challenge at 43.0°C for 6h on days 10 and 28 of age while naïve chicks were kept under regular conditions. Chick’s response to TC was evaluated by determination of body temperature, plasma T3 and T4 levels and mRNA levels of Hsp90, Hsp60 &amp; Hsf‐1 of muscle, heart and brain. There was a significant differences in muscle, heart and brain mRNA levels of Hsp90, Hsp60 &amp; Hsf‐1 during embryogenesis and during TC in post‐hatch chicks that indicates tissue responds differently to heat stress. While hatchability was adversely affected, the body weight in TM3 chicks was significantly higher at the end of the study period (35 days). Results of this study indicated a long‐term enhancement of Hsp90, Hsp60 &amp; Hsf‐1 gene expressions associated with thermotolerance acquisition in treated chicks without adversely affecting body parameters.

RNase HI stimulates the activity of RnlA toxin in Escherichia coli

A type II toxin-antitoxin system in Escherichia coli, rnlA-rnlB, functions as an anti-phage mechanism. RnlA is a toxin with an endoribonuclease activity and the cognate RnlB inhibits RnlA toxicity in E. coli cells. After bacteriophage T4 infection, RnlA is activated by the disappearance of RnlB, resulting in the rapid degradation of T4 mRNAs and consequently no T4 propagation, when T4 dmd is defective: Dmd is an antitoxin against RnlA for promoting own propagation. Previous studies suggested that the activation of RnlA after T4 infection was regulated by multiple components. Here, we provide the evidence that RNase HI is an essential factor for activation of RnlA. The dmd mutant phage could grow on ΔrnhA (encoding RNase HI) cells, in which RnlA-mediated mRNA cleavage activity was defective. RNase HI bound to RnlA in vivo and enhanced the RNA cleavage activity of RnlA in vitro. In addition, ectopic expression of RnlA in ΔrnlAB ΔrnhA cells has less effect on cell toxicity and RnlA-mediated mRNA degradation than in ΔrnlAB cells. This is the first example of a direct factor for activation of a toxin.

Development of a broad-host synthetic biology toolbox for ralstonia eutropha and its application to engineering hydrocarbon biofuel production

BackgroundThe chemoautotrophic bacterium Ralstonia eutropha can utilize H2/CO2 for growth under aerobic conditions. While this microbial host has great potential to be engineered to produce desired compounds (beyond polyhydroxybutyrate) directly from CO2, little work has been done to develop genetic part libraries to enable such endeavors.ResultsWe report the development of a toolbox for the metabolic engineering of Ralstonia eutropha H16. We have constructed a set of broad-host-range plasmids bearing a variety of origins of replication, promoters, 5’ mRNA stem-loop structures, and ribosomal binding sites. Specifically, we analyzed the origins of replication pCM62 (IncP), pBBR1, pKT (IncQ), and their variants. We tested the promoters PBAD, T7, Pxyls/PM, PlacUV5, and variants thereof for inducible expression. We also evaluated a T7 mRNA stem-loop structure sequence and compared a set of ribosomal binding site (RBS) sequences derived from Escherichia coli, R. eutropha, and a computational RBS design tool. Finally, we employed the toolbox to optimize hydrocarbon production in R. eutropha and demonstrated a 6-fold titer improvement using the appropriate combination of parts.ConclusionWe constructed and evaluated a versatile synthetic biology toolbox for Ralstonia eutropha metabolic engineering that could apply to other microbial hosts as well.

Escherichia coli rnlA and rnlB Compose a Novel Toxin–Antitoxin System

RNase LS was originally identified as a potential antagonist of bacteriophage T4 infection. When T4 dmd is defective, RNase LS activity rapidly increases after T4 infection and cleaves T4 mRNAs to antagonize T4 reproduction. Here we show that rnlA, a structural gene of RNase LS, encodes a novel toxin, and that rnlB (formally yfjO), located immediately downstream of rnlA, encodes an antitoxin against RnlA. Ectopic expression of RnlA caused inhibition of cell growth and rapid degradation of mRNAs in ΔrnlAB cells. On the other hand, RnlB neutralized these RnlA effects. Furthermore, overexpression of RnlB in wild-type cells could completely suppress the growth defect of a T4 dmd mutant, that is, excess RnlB inhibited RNase LS activity. Pull-down analysis showed a specific interaction between RnlA and RnlB. Compared to RnlA, RnlB was extremely unstable, being degraded by ClpXP and Lon proteases, and this instability may increase RNase LS activity after T4 infection. All of these results suggested that rnlA-rnlB define a new toxin-antitoxin (TA) system.

IscR regulates RNase LS activity by repressing rnlA transcription.

The Escherichia coli endoribonuclease LS was originally identified as a potential antagonist of bacteriophage T4. When the T4 dmd gene is defective, RNase LS cleaves T4 mRNAs and antagonizes T4 reproduction. This RNase also plays an important role in RNA metabolisms in E. coli. rnlA is an essential gene for RNase LS activity, but the transcriptional regulation of this gene remains to be elucidated. An Fe-S cluster protein, IscR, acts as a transcription factor and controls the expression of genes that are necessary for Fe-S cluster biogenesis. Here, we report that overexpression of IscR suppressed RNase LS activity, causing the loss of antagonist activity against phage T4. This suppressive effect did not require the ligation of Fe-S cluster into IscR. beta-Galactosidase reporter assays showed that transcription from an rnlA promoter increased in iscR-deleted cells compared to wild-type cells, and gel-mobility shift assays revealed specific binding of IscR to the rnlA promoter region. RT-PCR analysis demonstrated that endogenous rnlA mRNA was reduced by overexpression of IscR and increased by deletion of iscR. From these results, we conclude that IscR negatively regulates transcription of rnlA and represses RNase LS activity.

Prenatal thyroxine treatment disparately affects peripheral and amygdala thyroid hormone levels

A prenatal hypothyroid state is associated with behavioral abnormalities in adulthood. Wistar Kyoto (WKY) rats exhibit hypothyroidism and increased depressive and anxiety-like behaviors. Thus, the WKY could illuminate the mechanisms by which the reversal of developmental hypothyroidism in humans and animals results in adult behavioral improvement. We examined the outcome of maternal thyroxine (T4) treatment on thyroid hormone-regulated functions and adult behavior of the WKY offspring. Pregnant WKY dams completed gestation with and without T4 administration and their adult male offspring were tested. Measures included depressive and anxiety-like behaviors, and thyroid hormone (TH) concentrations in both plasma and specific brain regions. In addition, the expression of two proteins affecting thyroid hormone trafficking and metabolism, monocarboxylate transporter 8 (MCT-8) and iodothyronine deiodinase type III (Dio3), and of several behavior-altering molecules, glucocorticoid receptor (GR), prepro-thyrotropin releasing hormone (prepro-TRH) and corticotrophin releasing hormone (CRH), were determined in the hippocampus and amygdala of the offspring. Prenatal T4 treatment of WKYs did not affect adult depressive behavior but increased anxiety-like behavior and decreased plasma levels of THs. In the hippocampus of males treated with T4 in utero, Dio3 and MCT-8 protein levels were increased, while in the amygdala, there were increases of free T4, MCT-8, GR, prepro-TRH protein and CRH mRNA levels. These results show that T4 administration in utero programs adult peripheral and amygdalar thyroid hormone levels divergently, and that the resulting upregulation of anxiety-related genes in the amygdala could be responsible for the exacerbated anxiety-like behavior seen in WKYs after prenatal T4 treatment.

Reversal of Physiological Deficits Caused by Diminished Levels of Peptidylglycine α-Amidating Monooxygenase by Dietary Copper

Amidated peptides are critically involved in many physiological functions. Genetic deletion of peptidylglycine alpha-amidating monooxygenase (PAM), the only enzyme that can synthesize these peptides, is embryonically lethal. The goal of the present study was the identification of physiological functions impaired by haploinsufficiency of PAM. Regulation of the hypothalamic-pituitary-thyroid axis and body temperature, functions requiring contributions from multiple amidated peptides, were selected for evaluation. Based on serum T(4) and pituitary TSH-beta mRNA levels, mice heterozygous for PAM (PAM(+/-)) were euthyroid at baseline. Feedback within the hypothalamic-pituitary-thyroid axis was impaired in PAM(+/-) mice made hypothyroid using a low iodine/propylthiouracil diet. Despite their normal endocrine response to cold, PAM(+/-) mice were unable to maintain body temperature as well as wild-type littermates when kept in a 4 C environment. When provided with additional dietary copper, PAM(+/-) mice maintained body temperature as well as wild-type mice. Pharmacological activation of vasoconstriction or shivering also allowed PAM(+/-) mice to maintain body temperature. Cold-induced vasoconstriction was deficient in PAM(+/-) mice. This deficit was eliminated in PAM(+/-) mice receiving a diet with supplemental copper. These results suggest that dietary deficiency of copper, coupled with genetic deficits in PAM, could result in physiological deficits in humans.

Involvement of the Escherichia coli endoribonucleases G and E in the secondary processing of RegB-cleaved transcripts of bacteriophage T4

Sequence-specific endoribonuclease RegB of bacteriophage T4 cleaves early phage mRNAs and facilitates the transition between early and subsequent phases of T4 gene expression. The great majority of RegB targets have been identified in the intergenic regions of T4 transcripts, frequently in the Shine–Dalgarno sequences. Here we show that localization of RegB targets is not restricted to intergenic regions of mRNA. We detected 30 intragenic RegB sites in T4 transcripts that are differently susceptible to cleavage. Four RegB-processed mRNAs were previously shown to undergo further processing at so-called “secondary sites”. We have found three additional transcripts carrying clear targets for both RegB and another endoribonuclease. We show that secondary cuts within RegB-processed T4 mRNAs are generated mainly by Escherichia coli RNase G, but that in some cases RNase E can recognize the same targets. Using plasmid-phage systems we demonstrate that T4 infection favours cleavage by the host endoribonucleases at these sites.

A role of RnlA in the RNase LS activity from Escherichia coli

Escherichia coli ribonuclease LS is a potential antagonist of bacteriophage T4. When the T4 dmd gene is defective, RNase LS cleaves T4 mRNAs and antagonizes T4 reproduction. Our previous work demonstrated that E. coli rnlA is essential for RNase LS activity. Here we show that His-tagged RnlA cleaves T4 soc RNA at one of the sites also cleaved by RNase LS in a cell extract. The cleavage activities of His-tagged RnlA and the RNase LS activity in a cell extract were inhibited by Dmd encoded by T4 phage. Fractionation of the RNase LS activity in a cell extract showed that it sedimented through a sucrose density gradient as a 1000-kDa complex that included RnlA. Pull-down experiments revealed more than 10 proteins associated with His-tagged RnlA. Among these, triose phosphate isomerase exhibited a remarkable affinity to RnlA. These results suggest that RnlA plays a central role in RNase LS activity and that its activity is regulated by multiple components.

RNA Cleavage Linked With Ribosomal Action

Ribonuclease LS in Escherichia coli is a potential antagonist of bacteriophage T4. When T4 dmd is mutated, this RNase efficiently cleaves T4 mRNAs and leads to the silencing of late genes, thus blocking T4 growth. We previously found that, when two consecutive ochre codons were placed in the open reading frame of T4 soc, RNase LS cleaved soc mRNA at a specific site downstream of the ochre codons. Here, we demonstrate that RNase LS cleaves soc RNA at the same site even when only a single ochre codon is present or is replaced with either an amber or an opal codon. On the other hand, disruption of the Shine-Dalgarno sequence, a ribosome-binding site required for the initiation of translation, eliminates the cleavage. These results strongly suggest that RNase LS cleaves in a manner dependent on translation termination. Consistent with this suggestion, the cleavage dependency on an amber codon was considerably reduced in the presence of amber-codon-suppressing tRNA. Instead, two other cleavages that depend on translation of the region containing the target sites occurred farther downstream. Additional analysis suggests that an interaction of the ribosome with a stop codon might affect the site of cleavage by RNase LS in an mRNA molecule. This effect of the ribosome could reflect remodeling of the high-order structure of the mRNA molecule.

The absB Gene Encodes a Double Strand-specific Endoribonuclease That Cleaves the Read-through Transcript of the rpsO-pnp Operon in Streptomyces coelicolor

The absB locus of Streptomyces coelicolor encodes a homolog of bacterial RNase III. We cloned and overexpressed the absB gene product and purified a decahistidine-tagged version of the protein. We show here that AbsB is active against double-stranded RNA transcripts derived from synthetic DNAs but is inactive with single-stranded homopolymers. We thus designate the absB product RNase IIIS. Using T7 RNA polymerase and a cloned template containing the rpsO-pnp intergenic region, we synthesized an RNA substrate representing a portion of the read-through transcript normally produced in S. coelicolor. This transcript contains the sequences that form the putative rpsO terminator and those that form an intergenic stem-loop structure thought to be the site for RNase IIIS processing of the read-through transcript. We show that RNase IIIS does cleave that model transcript, with primary and secondary cleavage sites in an internal loop in the stem-loop structure. We have identified the primary and secondary cleavage sites by primer extension and demonstrate the further processing of the initial cleavage products. Thus, as is the case in Escherichia coli, the read-through transcript from rpsO-pnp is cleaved by RNase IIIS in S. coelicolor. However, the cleavage sites are different in the two systems. The positions of the cleavage sites in the stem-loop of the S. coelicolor transcript are more akin to those identified in the processing of bacteriophage T7 mRNAs. A kinetic assay for RNase IIIS was developed, and kinetic parameters for the reaction utilizing the model transcript from rpsO-pnp were determined.

Association between Expression Levels of CA 19-9 and N-Acetylglucosamine-β1,3-Galactosyltransferase 5 Gene in Human Pancreatic Cancer Tissue

Objective: CA 19-9, equivalent to Sialyl Lewis^a antigen, is a well-known tumor marker in pancreatic cancer. At the initial step of the biosynthesis of CA 19-9, N-acetylglucosamine-β1,3-galactosyltransferase (β3Gal-T) transfers galactose to N-acetylglucosamine (GlcNAc). Recently, β3Gal-T5 has been presumed to be related to the formation of the type 1 chain in an in vitro experiment in terms of kinetic enzyme characterization. The purpose of this study was to investigate which β3Gal-T is related to the synthesis of CA 19-9 in human pancreatic cancer tissues. Methods: We examined β3Gal-T1, T2, T3, T4, and β3Gal-T5 mRNA expressions in 13 noncancerous and cancerous tissues of the human pancreas using real-time polymerase chain reaction, and compared those gene expression levels with the immunoreactivity of CA 19-9 and its precursor DUPAN-2 in cancerous tissues. Results:β3Gal-T5 gene expression significantly augmented in cancerous tissues, when compared with the adjacent noncancerous tissues. Additionally, there was a good correlation between β3Gal-T5 gene transcription levels and immunohistochemical grades of CA 19-9 or its precursor DUPAN-2 in cancerous tissues. However, no correlation was observed between β3Gal-T1, T2, T3, and β3Gal-T4 gene expression levels and CA 19-9 or DUPAN-2 immunoreactive grades in cancerous tissue. Conclusion: β3Gal-T5 is presumed to be responsible for the synthesis of CA 19-9 in pancreatic cancer tissue.

Escherichia coli endoribonucleases involved in cleavage of bacteriophage T4 mRNAs.

The dmd mutant of bacteriophage T4 has a defect in growth because of rapid degradation of late-gene mRNAs, presumably caused by mutant-specific cleavages of RNA. Some such cleavages can occur in an allele-specific manner, depending on the translatability of RNA or the presence of a termination codon. Other cleavages are independent of translation. In the present study, by introducing plasmids carrying various soc alleles, we could detect cleavages of soc RNA in uninfected cells identical to those found in dmd mutant-infected cells. We isolated five Escherichia coli mutant strains in which the dmd mutant was able to grow. One of these strains completely suppressed the dmd mutant-specific cleavages of soc RNA. The loci of the E. coli mutations and the effects of mutations in known RNase-encoding genes suggested that an RNA cleavage activity causing the dmd mutant-specific mRNA degradation is attributable to a novel RNase. In addition, we present evidence that 5'-truncated soc RNA, a stable form in T4-infected cells regardless of the presence of a dmd mutation, is generated by RNase E.