Rates of asymptomatic respiratory virus infection across age groups.

Respiratory viral infections are a leading cause of disease worldwide. A variety of respiratory viruses produce infections in humans with effects ranging from asymptomatic to life-treathening. Standard surveillance systems typically only target severe infections (ED outpatients, hospitalisations, deaths) and fail to track asymptomatic or mild infections. Here we performed a large-scale community study across multiple age groups to assess the pathogenicity of 18 respiratory viruses. We enrolled 214 individuals at multiple New York City locations and tested weekly for respiratory viral pathogens, irrespective of symptom status, from fall 2016 to spring 2018. We combined these test results with participant-provided daily records of cold and flu symptoms and used this information to characterise symptom severity by virus and age category. Asymptomatic infection rates exceeded 70% for most viruses, excepting influenza and human metapneumovirus, which produced significantly more severe outcomes. Symptoms were negatively associated with infection frequency, with children displaying the lowest score among age groups. Upper respiratory manifestations were most common for all viruses, whereas systemic effects were less typical. These findings indicate a high burden of asymptomatic respiratory virus infection exists in the general population.

Regulation of the 75-kDa subunit of mitochondrial complex I by iron.

Iron homeostasis is tightly regulated, as cells work to conserve this essential but potentially toxic metal. The translation of many iron proteins is controlled by the binding of two cytoplasmic proteins, iron regulatory protein 1 and 2 (IRP1 and IRP2) to stem loop structures, known as iron-responsive elements (IREs), found in the untranslated regions of their mRNAs. In short, when iron is depleted, IRP1 or IRP2 bind IREs; this decreases the synthesis of proteins involved in iron storage and mitochondrial metabolism (e.g. ferritin and mitochondrial aconitase) and increases the synthesis of those involved in iron uptake (e.g. transferrin receptor). It is likely that more iron-containing proteins have IREs and that other IRPs may exist. One obvious place to search is in Complex I of the mitochondrial respiratory chain, which contains at least 6 iron-sulfur (Fe-S) subunits. Interestingly, in idiopathic Parkinson's disease, iron homeostasis is altered, and Complex I activity is diminished. These findings led us to investigate whether iron status affects the Fe-S subunits of Complex I. We found that the protein levels of the 75-kDa subunit of Complex I were modulated by levels of iron in the cell, whereas mRNA levels were minimally changed. Isolation of a clone of the 75-kDa Fe-S subunit with a more complete 5'-untranslated region sequence revealed a novel IRE-like stem loop sequence. RNA-protein gel shift assays demonstrated that a specific cytoplasmic protein bound the novel IRE and that the binding of the protein was affected by iron status. Western blot analysis and supershift assays showed that this cytosolic protein is neither IRP1 nor IRP2. In addition, ferritin IRE was able to compete for binding with this putative IRP. These results suggest that the 75-kDa Fe-S subunit of mitochondrial Complex I may be regulated by a novel IRE-IRP system.

The top3(+) gene is essential in Schizosaccharomyces pombe and the lethality associated with its loss is caused by Rad12 helicase activity.

The topoisomerase III gene ( top3 (+)) from Schizosaccharomyces pombe was isolated and a targeted gene disruption ( top3 :: kan (R)) was used to make a diploid strain heterozygous for top3 (+). The diploid was sporulated and the top3 :: kan (R)spores went through four to eight cell divisions before arresting as elongated, predominantly binucleated cells with incompletely segregated chromosomes. This demonstrates that top3 (+)is essential for vegetative growth in fission yeast. The aberrant chromosomal segregation seen in top3 :: kan (R)cells is unlike the 'cut' phenotype seen in mitosis-defective mutants and so we refer to this phenotype as 'torn'. A deletion mutant, rad12-hd ( rad12 is a homolog of Saccharomyces cerevisiae SGS1), partially suppressed the lethality of top3 mutants. A point mutant, rad12-K547I, which presumably eliminates helicase activity, also suppresses the lethality of top3 mutants, demonstrating that the lethality seen in top3 (-)cells is most likely caused by the helicase activity of Rad12. This double mutant grows very slowly and has much lower viability compared to rad12-hd top3 :: kan (R)cells, implying that the helicase activity of Rad12 is not the only cause of top3 (-)lethality. The low viability of rad12 (-) top3 (-)mutants compared with rad12 single mutants suggests that Top3 also functions independently of Rad12.

A Uve1p-mediated mismatch repair pathway in Schizosaccharomyces pombe.

UV damage endonuclease (Uve1p) from Schizosaccharomyces pombe was initially described as a DNA repair enzyme specific for the repair of UV light-induced photoproducts and proposed as the initial step in an alternative excision repair pathway. Here we present biochemical and genetic evidence demonstrating that Uve1p is also a mismatch repair endonuclease which recognizes and cleaves DNA 5' to the mispaired base in a strand-specific manner. The biochemical properties of the Uve1p-mediated mismatch endonuclease activity are similar to those of the Uve1p-mediated UV photoproduct endonuclease. Mutants lacking Uve1p display a spontaneous mutator phenotype, further confirming the notion that Uve1p plays a role in mismatch repair. These results suggest that Uve1p has a surprisingly broad substrate specificity and may function as a general type of DNA repair protein with the capacity to initiate mismatch repair in certain organisms.

Fission yeast rad12+ regulates cell cycle checkpoint control and is homologous to the Bloom's syndrome disease gene.

The human BLM gene is a member of the Escherichia coli recQ helicase family, which includes the Saccharomyces cerevisiae SGS1 and human WRN genes. Defects in BLM are responsible for the human disease Bloom's syndrome, which is characterized in part by genomic instability and a high incidence of cancer. Here we describe the cloning of rad12+, which is the fission yeast homolog of BLM and is identical to the recently reported rhq1+ gene. We showed that rad12 null cells are sensitive to DNA damage induced by UV light and gamma radiation, as well as to the DNA synthesis inhibitor hydroxyurea. Overexpression of the wild-type rad12+ gene also leads to sensitivity to these agents and to defects associated with the loss of the S-phase and G2-phase checkpoint control. We showed genetically and biochemically that rad12+ acts upstream from rad9+, one of the fission yeast G2 checkpoint control genes, in regulating exit from the S-phase checkpoint. The physical chromosome segregation defects seen in rad12 null cells combined with the checkpoint regulation defect seen in the rad12+ overproducer implicate rad12+ as a key coupler of chromosomal integrity with cell cycle progression.

The post-incision steps of the DNA base excision repair pathway in Escherichia coli: studies with a closed circular DNA substrate containing a single U:G base pair.

The DNA base excision repair pathway is responsible for removal of oxidative and endogenous DNA base damage in both prokaryotes and eukaryotes. This pathway involves formation of an apurinic/apyrimidinic (AP) site in the DNA, which is further processed to restore the integrity of the DNA. In Escherichia coli it has been suggested that the major mode of repair involves replacement of a single nucleotide at the AP site, based on repair synthesis studies using oligonucleotide substrates containing a unique uracil base. The mechanism of the post-incision steps of the bacterial base excision repair pathway was examined using a DNA plasmid substrate containing a single U:G base pair. Repair synthesis carried out by repair-proficient ung, recJ and xon E.coli cell extracts was analyzed by restriction endonuclease cleavage of the DNA containing the uracil lesion. It was found that replacement of the uracil base was always accompanied by replacement of several nucleotides ( approximately 15) 3' of the uracil and this process was absolutely dependent on initial removal of the uracil base by the action of uracil-DNA glycosylase. In contrast to findings with oligonucleotide substrates, replacement of just a single nucleotide at the lesion site was not detected. These results suggest that repair patch length may be substrate dependent and a re-evaluation of the post-incision steps of base excision repair is suggested.

The fission yeast UVDR DNA repair pathway is inducible.

In addition to nucleotide excision repair (NER), the fission yeast Schizosaccharomyces pombe possesses a UV damage endonuclease (UVDE) for the excision of cyclobutane pyrimidine dimers and 6-4 pyrimidine pyrimidones. We have previously described UVDE as part of an alternative excision repair pathway, UVDR, for UV damage repair. The existence of two excision repair processes has long been postulated to exist in S.pombe, as NER-deficient mutants are still proficient in the excision of UV photoproducts. UVDE recognizes the phosphodiester bond immediately 5'of the UV photoproducts as the initiating event in this process. We show here that UVDE activity is inducible at both the level of uve1+ mRNA and UVDE enzyme activity. Further, we show that UVDE activity is regulated by the product of the rad12 gene.

Neoplastic transformation of mouse C3H10T1/2 cells following exposure to neutrons does not involve mutation of ras gene as analyzed by SSCP and cycle sequencing.

About 25% of human tumors contain a mutated member of the ras gene family. Neutron exposure is an occupational risk in several work places and while we know that cells exposed to neutrons can become transformed, the molecular basis of this process is not understood. To determine whether neutron-induced cellular transformation involves ras mutation, C3H10T1/2 cells were exposed to a single dose of 5.9 MeV neutrons. Type II and type III foci were isolated and established as cell lines. A total of 34 foci were selected and expanded for analysis of tumorigenicity, chromosomal aberrations and mutations in members of the ras gene family. The presence of mutations in genomic DNA in N-ras or K-ras of each focus was examined by either single-strand conformational polymorphism (SSCP) analysis or by asymmetric PCR coupled cell cycle sequence analysis. Although chromosomal aberrations were detected at metaphase, no alterations in either ras gene were detected. We conclude that in vitro neutron-induced transformation must occur through a mechanism other than ras mutation.

An alternative eukaryotic DNA excision repair pathway.

DNA lesions induced by UV light, cyclobutane pyrimidine dimers, and (6-4)pyrimidine pyrimidones are known to be repaired by the process of nucleotide excision repair (NER). However, in the fission yeast Schizosaccharomyces pombe, studies have demonstrated that at least two mechanisms for excising UV photo-products exist; NER and a second, previously unidentified process. Recently we reported that S. pombe contains a DNA endonuclease, SPDE, which recognizes and cleaves at a position immediately adjacent to cyclobutane pyrimidine dimers and (6-4)pyrimidine pyrimidones. Here we report that the UV-sensitive S. pombe rad12-502 mutant lacks SPDE activity. In addition, extracts prepared from the rad12-502 mutant are deficient in DNA excision repair, as demonstrated in an in vitro excision repair assay. DNA repair activity was restored to wild-type levels in extracts prepared from rad12-502 cells by the addition of partially purified SPDE to in vitro repair reaction mixtures. When the rad12-502 mutant was crossed with the NER rad13-A mutant, the resulting double mutant was much more sensitive to UV radiation than either single mutant, demonstrating that the rad12 gene product functions in a DNA repair pathway distinct from NER. These data directly link SPDE to this alternative excision repair process. We propose that the SPDE-dependent DNA repair pathway is the second DNA excision repair process present in S. pombe.

A new ATP-independent DNA endonuclease from Schizosaccharomyces pombe that recognizes cyclobutane pyrimidine dimers and 6-4 photoproducts.

We have discovered a new DNA endonuclease in the fission yeast Schizosaccharomyces pombe which recognizes cyclobutane pyrimidine dimers and (6-4) pyrimidine-pyrimidone photoproducts. S. pombe DNA endonuclease (SPDE) catalyzes a single ATP-independent incision immediately 5' to the UV photoproduct and generates termini containing 3' hydroxyl and 5' phosphoryl groups. Based on these properties, we propose that SPDE may function in a DNA repair capacity, representing the initial recognition/cleavage step of a DNA excision repair pathway.

Repair of DNA damaged by UV light and ionizing radiation by cell-free extracts prepared from Schizosaccharomyces pombe.

A whole cell extract prepared from Schizosaccharomyces pombe was shown to be active in an assay for repair of plasmid DNA damaged by either ultraviolet (UV) light or gamma-radiation. The assay allows for analysis of repair synthesis at single-strand nicks generated by gamma-rays and analysis of the incision step and repair synthesis in UV-light-damaged DNA. Repair synthesis of DNA damaged by either UV light or gamma-rays was shown to depend on the presence of ATP in the reaction mixture. However, incision at pyrimidine dimers did not require the addition of exogenous ATP. These studies showed that plasmid DNA containing a single pyrimidine dimer or one single-strand nick is a suitable substrate in this assay system. S. pombe is a genetically well-defined eukaryotic organism and many radiation-sensitive mutant derivatives have already been described, making this a powerful system in which to study DNA excision repair.

The molecular biology of radiation carcinogenesis.

Major new insights into carcinogenesis have come from recent advances in cellular and molecular biology. The concept of oncogenes provides a simple explanation for how agents as diverse as radiation, chemicals or retroviruses can induce tumors that are indistinguishable one from another. Oncogenes may be activated by a point mutation, by a chromosome translocation, or by amplification. Ionizing radiations are efficient at the first two mechanisms. While oncogenes are frequently associated with leukemias and lymphomas, they are associated with only 10 to 15% of human solid cancers. The importance of the loss of suppressor genes was suggested first from studies with human-hamster hybrid cells, but has since been shown to be of importance in an increasing number of human solid tumors, from rare tumors such as retinoblastoma to more common tumors such as small cell lung cancer and colorectal cancer. The mechanism of somatic homozygosity clearly involves several steps, some of which, such as a deletion, could be readily produced by ionizing radiation. The multi-step nature of carcinogenesis can be demonstrated in the petri dish, where the transfection of multiple oncogenes is required to transform normal cells from short-term explants. It can be shown, too, in colorectal cancer in the human, where the activation of an oncogene and the loss of more than one suppressor gene may be involved in the progression from normal epithelium to a frank malignancy.

Alterations in the polypyrimidine sequence affect the in vitro splicing reactions catalyzed by HeLa cell-free preparations.

The polypyrimidine tract, located at the 3' end of intron 1 of the adenovirus major late transcript, was studied for its role in splicing using cell-free preparations isolated from HeLa cells. A plasmid (pIz) was constructed in which seven purine bases were substituted for pyrimidine bases within the 14-nucleotide polypyrimidine sequence. Runoff transcripts extending to the middle of intron 2 were tested for their ability to support in vitro splicing. The efficiency of these reactions was compared with pre-mRNA transcripts made from the wild-type nonmutated plasmid (p1-2). Neither spliced products nor splicing intermediates were detected in reactions with the pIz pre-mRNA. The formation of the nucleoprotein complexes involved in splicing was examined with this altered pre-mRNA. No 55 S splicing complex was detected and only low levels of the 30 S presplicing complex formed (30-fold less than with wild-type pre-mRNA). However, when a longer runoff transcript was prepared from the polypyrimidine mutated plasmid pIz, spliced RNA was formed. This activity required specific downstream sequences, since transcripts produced from pIz which contained substituted downstream sequences were not spliced. Although intron 2 of the adenovirus major late transcript does not contain a discernible 3' polypyrimidine sequence, pre-mRNA (p2-3) containing this intron was efficiently spliced. However, when the 3' region of intron 2 was substituted for the polypyrimidine sequence of intron 1, the resulting pre-mRNA did not support efficient splicing in vitro. However, when the polypyrimidine sequence of intron 1 was substituted for the sequence at the 3' end of intron 2, efficient splicing occurred, and the rate of formation of splicing intermediates and the accumulation of nucleoprotein complexes was greater than with the wild-type pre-mRNA (p2-3).

In vitro formation of a lariat structure containing a G2'-5'G linkage.

We have examined the effects of base changes at the lariat branch site of a modified adenovirus major late precursor mRNA (pre-mRNA). Replacement of the A residue at the lariat attachment site with a G residue was studied. Incubation of this altered pre-mRNA with nuclear extracts of HeLa cells yielded less spliced mRNA (10-fold) than similar reactions with the wild type pre-mRNA. The intron lariat formed during the reaction with the mutant transcript contained the predominant branch (2'-5' phosphodiester linkage) to an upstream A residue. In contrast, the intron/exon 2 lariat contained the predominant branch to the substituted G residue. These results indicated that detectable spliced RNA was formed when the lariat was attached at the A residue but not when the lariat was attached to the substituted G residue. A second mutation was introduced into the transcript by substituting an additional G residue at the alternative A branch site. When transcript derived from this plasmid was incubated with nuclear extract, cleavage occurred at the 5' splice site, and an intron/exon 2 lariat was produced, but spliced RNA was not detected. T1 RNase digestion and primer extension analyses of this intron/exon 2 lariat revealed that all of the lariat formed on the G residue at the normal attachment site.

Two soybean seed lipoxygenase nulls accumulate reduced levels of lipoxygenase transcripts.

Soybean (Glycine max L. [Merrill]) seed lipoxygenase cDNA clones were recovered from two cDNA libraries: a size-selected library in pBR322 and an expression library in pUC8. The pUC8 library was made with total poly(A)(+) embryo RNA and was screened with antiserum to lipoxygenase-1, one of 3 seed lipoxygenase isozymes. Three lipoxygenase antigen-producing clones were identified: two with identical cDNA inserts of 977 nucleotides representing an open-reading frame and a third truncated clone bearing a 3' end common to the longer clones. A long clone, pAL-134, was chosen for further study and was used to screen the size-selected cDNA library from which sixteen clones were identified. They fall into two homology classes represented by pLX-10 (ca. 1360 bp) and pLX-65 (2047 bp).The lipoxygenase expression clone pAL-134 hybridized much more strongly to pLX-65 than to pLX-10. pAL-134 and pLX-65 share 89% nucleotide homology and 75% deduced amino acid homology along their common sequence. Their deduced amino acid sequences each show 80% homology to sequences determined for isolated peptides of the lipoxygenase-1 isozyme.pAL-134 hybridizes poorly with a 3.8 kb RNA from LOX-1 null (lx1) embryos while pLX-65 hybridizes more strongly, but still to a lesser extent than its hybridization to standard embryo RNA or to RNA from embryos lacking lipoxygenase-2 (lx2) or lipoxygenase-3 (lx3) protein.The lx3 null lacks almost all embryo 3.8 kb RNA homologous to pLX-10. This hybridization pattern suggests that pLX-10 encodes LOX-3. Thus, the lx1 and lx3 genotypes accumulate little, if any, mRNA for the lipoxygenase-1 and lipoxygenase-3 isozymes, respectively.

Isolation and characterization of two fractions from HeLa cells required for mRNA splicing in vitro.

A nuclear extract from HeLa cells has been separated by DEAE-cellulose chromatography into two fractions, both of which are required for mRNA splicing in vitro. Both fractions are heat labile and sensitive to N-ethylmaleimide. The activity of one of the fractions was abolished by preincubation with micrococcal nuclease, while the other fraction was unaffected by this treatment. This abolition indicates an essential nucleic acid component. Fractions I and II are required for the in vitro splicing of human beta-globin and adenovirus transcripts.

Characterization of the major mRNAs from adenovirus 2 early region 4 by cDNA cloning and sequencing.

The sequences at the splice junctions of many early region 4 (E4) mRNAs from adenovirus 2 (Ad2) were determined by analysis of cDNA clones. The cDNAs were synthesized from poly(A)+ mRNA isolated from HeLa cells early during Ad2 infection. A standard library was constructed, in pBR322, from double stranded cDNAs initiated by oligo-dT priming. Approximately 1% of total recombinants contained E4 sequences, however among eighty clones analyzed in detail, only four contained the 5' leader sequence. A second library was prepared using a new method that led to a greatly increased representation of desired clones. This method employed oligo-dT to prime the synthesis of the first strand and an oligonucleotide ligated to pBR322, whose sequence was present in the 5' leader, to prime the synthesis of the second strand. With this method the percentage of recombinants containing E4 sequences ranged between 15 and 50% of the total colonies. Virtually all of these E4 cDNA clones contained the 5' leader sequence and several hundred were analyzed by comparing the results from single channel dideoxy sequencing reactions. Nine unique sequence patterns were identified and representative clones were completely sequenced.

The analysis of a chicken myosin heavy chain cDNA clone.

A cDNA library has been constructed in the plasmid pBR322 using a large size class of RNA derived from chicken embryonic leg muscle as the template material. A clone containing a 2350-base pair insert was selected and identified as coding for the myosin heavy chain sequence, based upon its ability to hybridize to genomic myosin heavy chain clones, and by direct nucleotide sequencing. Cross-hybridization experiments with myosin heavy chain genomic clones, and mRNAs derived from different muscle types were used to explore the heterogeneity of the various myosin heavy chain isoforms at the level of the coding sequences. Although extensive sequence homology with the other isoforms was observed, a fast white isoform-specific subclone was constructed, and used to demonstrate that different genes code for the adult and embryonic fast white myosin heavy chain proteins.

Isolation of multiple genomic sequences coding for chicken myosin heavy chain protein.

A genomic bank has been constructed using DNA isolated from a dystrophic strain of chickens. The library was screened for myosin heavy chain (MHC) sequences using a cDNA probe and 11 positive recombinants isolated. Identity of the clones was confirmed by positive RNA selection via hybridization of the clones with muscle RNA and subsequent translation of the hybridizable RNA in vitro. Restriction maps indicate that the clones can be divided into 7 distinct groups; some of these groups do, however, share similar or homologous sequences. Hydridization of the clones to RNA derived from leg, breast, heart, and brain reveals that all of the clones code for the muscle-specific MHC isoforms. These experiments also show that there are at least 3 size classes of MHC mRNA sequences, whose relative amounts appear to be modulated in a tissue- and developmental stage-specific manner.