Identification of Genomic Alterations Through Multilevel DNA Structural Analysis.

Current methods to identify genomic alterations using whole-genome sequencing (WGS) data are often limited to single nucleotide polymorphisms and insertions and deletions that are less than 10 bp in length. These limitations are largely due to challenges in accurately mapping short sequencing reads that significantly diverge from the reference genome. Newer sequencing-based methods have been developed to define and characterize larger DNA structural elements. This is achieved by enriching for and sequencing regions of the genome that contain a specific element, followed by identifying genomic regions with high densities of mapped short reads that designate the location of these elements. This process essentially aggregates short read data into larger structural units for further characterization. Here, we describe protocols for identifying various types of genomic alterations using differential analysis of these structural units. We focus on changes in DNA accessibility, protein-DNA interactions, and chromosomal contacts as measured by ATAC-Seq, ChIP-Seq, and Hi-C respectively. As many protocols have been published describing the generation and processing of these data, we focus on simple methods that can be used to identify mutations in these data, and can be executed by someone with limited computational expertise.

Agnostic detection of genomic alterations by holistic DNA structural interrogation.

There is an established relationship between primary DNA sequence, secondary and tertiary chromatin structure, and transcriptional activity, suggesting that observed differences in one of these properties may reflect changes in the others. Here, we exploit these relationships to show that variations in DNA structure can be used to identify a wide range of genomic alterations in mammalian samples. In this proof-of-concept study we characterized and compared genome-wide histone occupancy by ChIP-Seq, DNA accessibility by ATAC-Seq, and chromosomal conformation by Hi-C for five CRISPR/Cas9-modified mammalian cell lines and their unmodified parent strains, as well as in one modified tissue sample and its parent strain. The results showed that the impact of genomic alterations on each of the levels of DNA organization varied depending on mutation type (insertion or deletion), size, and genomic location. The largest genomic alterations we identified included chromosomal rearrangements and deletions (greater than 200 Kb) in four of the modified cell lines, which can be difficult to identify by standard whole genome sequencing analysis. This multi-level DNA organizational analysis provides a sensitive approach for identifying a wide range of genomic and epigenomic perturbations that can be utilized for biomedical and biosecurity applications.

Cell-Free Production of Protein Biologics Within 24 H.

Protein biologics have emerged as a safe and effective group of drug products that can be used in a variety of medical disorders and clinical settings, including treatment of orphan diseases, personalized medicine, and point-of-care applications. However, the full potential of protein biologics for such applications will not be realized until there are methods available for rapid and cost-effective production of small scale products for individual needs. Here, we describe a modular and scalable method for rapid and adaptable production of protein-based medical products at small doses. The method includes cell-free synthesis of the protein target in a reactor module followed by a fluidic process for protein purification. As a proof of concept, we describe the application of this method for expression and purification of a bioactive pharmaceutically relevant protein biologic, recombinant human erythropoietin, at a single dose within 24 h. This method can be applied toward the development of automated platforms for rapid and adaptive production of protein biologics at the point of care in response to specific medical needs.

A cell-free expression and purification process for rapid production of protein biologics.

Cell-free protein synthesis has emerged as a powerful technology for rapid and efficient protein production. Cell-free methods are also amenable to automation and such systems have been extensively used for high-throughput protein production and screening; however, current fluidic systems are not adequate for manufacturing protein biopharmaceuticals. In this work, we report on the initial development of a fluidic process for rapid end-to-end production of recombinant protein biologics. This process incorporates a bioreactor module that can be used with eukaryotic or prokaryotic lysates that are programmed for combined transcription/translation of an engineered DNA template encoding for specific protein targets. Purification of the cell-free expressed product occurs through a series of protein separation modules that are configurable for process-specific isolation of different proteins. Using this approach, we demonstrate production of two bioactive human protein therapeutics, erythropoietin and granulocyte-macrophage colony-stimulating factor, in yeast and bacterial extracts, respectively, each within 24 hours. This process is flexible, scalable and amenable to automation for rapid production at the point-of-need of proteins with significant pharmaceutical, medical, or biotechnological value.

Actin exposure upon tissue injury is a targetable wound site-specific protein marker.

BACKGROUND: Identification of wound-specific markers would represent an important step toward damaged tissue detection and targeted delivery of biologically important materials to injured sites. Such delivery could minimize the amount of therapeutic materials that must be administered and limit potential collateral damage on nearby normal tissues. Yet, biological markers that are specific for injured tissue sites remain elusive. METHODS: In this study, we have developed an immunohistological approach for identification of protein epitopes specifically exposed in wounded tissue sites. RESULTS: Using ex-vivo tissue samples in combination with fluorescently-labeled antibodies we show that actin, an intracellular cytoskeletal protein, is specifically exposed upon injury. The targetability of actin in injured sites has been demonstrated in vivo through the specific delivery of anti-actin conjugated particles to the wounded tissue in a lethal rat model of grade IV liver injury. CONCLUSIONS: These results illustrate that identification of injury-specific protein markers and their targetability for specific delivery is feasible. GENERAL SIGNIFICANCE: Identification of wound-specific targets has important medical applications as it could enable specific delivery of various products, such as expression vectors, therapeutic drugs, hemostatic materials, tissue healing, or scar prevention agents, to internal sites of penetrating or surgical wounds regardless of origin, geometry or location.

Simultaneous Extraction of Viral and Bacterial Nucleic Acids for Molecular Diagnostic Applications.

Molecular detection of microbial pathogens in clinical samples requires the application of efficient sample lysis protocols and subsequent extraction and isolation of their nucleic acids. Here, we describe a simple and time-efficient method for simultaneous extraction of genomic DNA from gram-positive and -negative bacteria, as well as RNA from viral agents present in a sample. This method compared well with existing bacterial- and viral-specialized extraction protocols, worked reliably on clinical samples, and was not pathogen specific. This method may be used to extract DNA and RNA concurrently from viral and bacterial pathogens present in a sample and effectively detect coinfections in routine clinical diagnostics.

Chromatin structure analysis enables detection of DNA insertions into the mammalian nuclear genome.

BACKGROUND: Genetically modified organisms (GMOs) have numerous biomedical, agricultural and environmental applications. Development of accurate methods for the detection of GMOs is a prerequisite for the identification and control of authorized and unauthorized release of these engineered organisms into the environment and into the food chain. Current detection methods are unable to detect uncharacterized GMOs, since either the DNA sequence of the transgene or the amino acid sequence of the protein must be known for DNA-based or immunological-based detection, respectively. METHODS: Here we describe the application of an epigenetics-based approach for the detection of mammalian GMOs via analysis of chromatin structural changes occurring in the host nucleus upon the insertion of foreign or endogenous DNA. RESULTS: Immunological methods combined with DNA next generation sequencing enabled direct interrogation of chromatin structure and identification of insertions of various size foreign (human or viral) DNA sequences, DNA sequences often used as genome modification tools (e.g. viral sequences, transposon elements), or endogenous DNA sequences into the nuclear genome of a model animal organism. CONCLUSIONS: The results provide a proof-of-concept that epigenetic approaches can be used to detect the insertion of endogenous and exogenous sequences into the genome of higher organisms where the method of genetic modification, the sequence of inserted DNA, and the exact genomic insertion site(s) are unknown. GENERAL SIGNIFICANCE: Measurement of chromatin dynamics as a sensor for detection of genomic manipulation and, more broadly, organism exposure to environmental or other factors affecting the epigenomic landscape are discussed.

Assays for the identification of inhibitors targeting specific translational steps.

While bacterial protein synthesis is the target of about half of the known antibiotics, the great structural-functional complexity of the translational machinery still offers remarkable opportunities for identifying novel and specific inhibitors of unexploited targets. We designed a knowledge-based in vitro translation assay to identify inhibitors selectively targeting the bacterial or the yeast translational apparatus, preferentially blocking the early steps of protein synthesis. Using a natural-like, "universal" model mRNA and cell-free extracts prepared from Eschericha coli, Saccharomyces cerevisiae, and HeLa cells, we were able to translate, with comparable yields in the three systems, the immunogenic peptide encoded by this "universal" mRNA. The immuno-enzymatic quantification of the translated peptide in the presence of a potential inhibitor can identify a selective bacterial or fungal inhibitor inactive in the human system. When applied to the high-throughput screening (HTS) of a library of approximately 25,000 natural products, this assay led to the identification of two novel and specific inhibitors of bacterial translation.

Analysis of ribosomal shunting during translation initiation in eukaryotic mRNAs.

In eukaryotes, translation initiation involves recruitment of ribosomal subunits at either the 5' m7G cap structure or at an internal ribosome entry site (IRES). For most mRNAs, the initiation codon is located some distance downstream, necessitating ribosomal movement to this site. Although the mechanistic details of this movement remain to be fully resolved, it appears to be nonlinear for some mRNAs (i.e., ribosomal subunits appear to bypass [shunt] segments of the 5' leader as they move to the initiation codon). This chapter describes various experimental approaches to assess ribosomal shunting and to identify mRNA elements (shunt sites) that facilitate shunting. In addition, we provide an overview of approaches that can be used to investigate the mechanism used by individual shunt sites, along with a detailed protocol for investigating putative base pairing interactions between shunt sites and 18S rRNA.

Death-associated protein kinase phosphorylates mammalian ribosomal protein S6 and reduces protein synthesis.

Death-associated protein kinase (DAPK) is a pro-apoptotic, calcium/calmodulin-regulated protein kinase that is a drug discovery target for neurodegenerative disorders. Despite the potential profound physiological role of DAPK in neuronal function and pathophysiology, the endogenous substrate(s) of this kinase and the mechanisms via which DAPK elicits its biological action remain largely unknown. We report here that the mammalian 40S ribosomal protein S6 is a DAPK substrate. Results from immunoprecipitation experiments are consistent with endogenous DAPK being associated with endogenous S6 in rat brain. When S6 is a component of the 40S ribosomal subunit complex, DAPK selectively phosphorylates it at serine 235, one of the five sites in S6 that are phosphorylated by the S6 kinase family of proteins. The amino acid sequence flanking serine 235 matches the established pattern for DAPK peptide and protein substrates. Kinetic analyses using purified 40S subunits revealed a K(m) value of 9 microM, consistent with S6 being a potential physiological substrate of DAPK. This enzyme-substrate relationship has functional significance. DAPK suppresses translation in rabbit reticulocyte lysate, and treatment of neuroblastoma cells with a stimulator of DAPK reduces protein synthesis. In both cases, suppression of translation correlates with increased phosphorylation of S6 at serine 235. These results demonstrate that DAPK is a S6 kinase and provide evidence for a novel role of DAPK in the regulation of translation.

Ribosomal shunting mediated by a translational enhancer element that base pairs to 18S rRNA.

In eukaryotes, 40S ribosomal subunits move from their recruitment site on the mRNA to the initiation codon by an as yet poorly understood process. One postulated mechanism involves ribosomal shunting, in which ribosomal subunits completely bypass regions of the 5' leader. For some mRNAs, shunting has been shown to require various mRNA elements, some of which are thought to base pair to 18S rRNA; however, the role of base pairing has not yet been tested directly. In earlier studies, we demonstrated that a short mRNA element in the 5' leader of the Gtx homeodomain mRNA functioned as a ribosomal recruitment site by base pairing to the 18S rRNA. Using a model system to assess translation in transfected cells, we now show that this intermolecular interaction also facilitates ribosomal shunting across two types of obstacles: an upstream AUG codon in excellent context or a stable hairpin structure. Highly efficient shunting occurred when multiple Gtx elements were present upstream of the obstacles, and a single Gtx element was present downstream. Shunting was less efficient, however, when the multiple Gtx elements were present only upstream of the obstacles. In addition, control experiments with mRNAs lacking the upstream elements showed that these results could not be attributed to recruitment by the single downstream element. Experiments in yeast in which the mRNA elements and 18S rRNA sequences were both mutated indicated that shunting required an intact complementary match. The data obtained by this model system provide direct evidence that ribosomal shunting can be mediated by mRNA-rRNA base pairing, a finding that may have general implications for mechanisms of ribosome movement.

Determination of the amino acids in yeast ribosomal protein YS11 essential for the recognition of nucleotides in 18 S ribosomal RNA.

The nucleotides in domain I of 18 S rRNA that are important for the binding of the essential yeast ribosomal protein YS11 are mainly in a kink-turn motif and the terminal loop of helix 11 (H11). In the atomic structure of the Thermus thermophilus 30 S subunit, 16 amino acids in S17, the homolog of YS11, are within hydrogen bonding distance of nucleotides in 16 S rRNA. The homologous or analogous 16 amino acids in YS11 were replaced with alanine; nine of the substitutions slowed the growth of yeast cells. The most severe effects were caused by mutations R103A, N106A, K133A, T134A, and K151A. The T. thermophilus analogs of Arg103, Asn106, Thr134, and Lys151 contact nucleotides in the kink-turn motif of 16 S rRNA, whereas Lys133 contacts nucleotides in the terminal loop of H11. These contacts are predominantly with backbone phosphate and sugar oxygens in regions that deviate from A-form geometry, suggesting that YS11 recognizes the shape of its rRNA-binding site rather than reading the sequence of nucleotides. The effect of the mutations on the binding of YS11 to a domain I fragment of 18 S rRNA accorded, in general, with their effect on growth. Mutations of seven YS11 amino acids (Ser77, Met80, Arg88, Tyr97, Pro130, Ser132, and Arg136) whose homologs or analogs in S17 are within hydrogen bonding distance of nucleotides in 16 S rRNA did not affect binding. Apparently, proximities alone do not define either the amino acids or the nucleotides that are important for recognition.

Eukaryotic ribosomal proteins lacking a eubacterial counterpart: important players in ribosomal function.

The ribosome is a macromolecular machine responsible for protein synthesis in all organisms. Despite the enormous progress in studies on the structure and function of prokaryotic ribosomes, the respective molecular details of the mechanism by which the eukaryotic ribosome and associated factors construct a polypeptide accurately and rapidly still remain largely unexplored. Eukaryotic ribosomes possess more RNA and a higher number of proteins than eubacterial ribosomes. As the tertiary structure and basic function of the ribosomes are conserved, what is the contribution of these additional elements? Elucidation of the role of these components should provide clues to the mechanisms of translation in eukaryotes and help unravel the molecular mechanisms underlying the differences between eukaryotic and eubacterial ribosomes. This article focuses on a class of eukaryotic ribosomal proteins that do not have a eubacterial homologue. These proteins play substantial roles in ribosomal structure and function, and in mRNA binding and nascent peptide folding. The role of these proteins in human diseases and viral expression, as well as their potential use as targets for antiviral agents is discussed.

A pathway for the transmission of allosteric signals in the ribosome through a network of RNA tertiary interactions.

There are a large number of tertiary contacts between nucleotides in 23S rRNA, but which are of functional importance is not known. Disruption of one between A2662 in the sarcin/ricin loop (SRL) and A2531 in the peptidyl-transferase center (PTC) has adverse effects on cell growth and on the ability of ribosomes to catalyze some but not other partial reactions of elongation. A lethal A2662C mutation is suppressed by a concomitant lethal A2531 mutation. Ribosomes with non-lethal A2531 mutations, treated with base-specific reagents, have alterations of nucleotides in the PTC (home of A2531) and, more significantly, in nucleotides in the SRL and in the GTPase center. The results suggest that the function of ribosomal centers is coordinated by a set of sequential conformational changes in rRNA that are a response to signals transmitted through a network of tertiary interactions.

An mRNA-rRNA base-pairing mechanism for translation initiation in eukaryotes.

Base-pairing of messenger RNA to ribosomal RNA is a mechanism of translation initiation in prokaryotes. Although analogous base-pairing has been suggested to affect the translation of various eukaryotic mRNAs, direct evidence has been lacking. To test such base-pairing, we developed a yeast system that uses ribosomes containing a mouse-yeast hybrid 18S rRNA. Using this system, we demonstrate that a 9-nucleotide element found in the mouse Gtx homeodomain mRNA facilitates translation initiation by base-pairing to 18S rRNA. Various point mutations in the Gtx element and in either the hybrid or wild-type yeast 18S rRNAs confirmed the requirement for an intact complementary match. The presence of the Gtx element in various mRNAs suggests that this element affects the translation of groups of mRNAs. We discuss the possibility that other mRNA elements affect translation by base-pairing to different sites in the 18S rRNA.

Cold stress-induced protein Rbm3 binds 60S ribosomal subunits, alters microRNA levels, and enhances global protein synthesis.

The expression of Rbm3, a glycine-rich RNA-binding protein, is enhanced under conditions of mild hypothermia, and Rbm3 has been postulated to facilitate protein synthesis at colder temperatures. To investigate this possibility, Rbm3 was overexpressed as a c-Myc fusion protein in mouse neuroblastoma N2a cells. Cells expressing this fusion protein showed a 3-fold increase in protein synthesis at both 37 degrees C and 32 degrees C compared with control cells. Although polysome profiles of cells expressing the fusion protein and control cells were similar, several differences were noted, suggesting that Rbm3 might enhance the association of 40S and 60S ribosomal subunits at 32 degrees C. Studies to assess a direct interaction of Rbm3 with ribosomes showed that a fraction of Rbm3 was associated with 60S ribosomal subunits in an RNA-independent manner. It appeared unlikely that this association could explain the global enhancement of protein synthesis, however, because cells expressing the Rbm3 fusion protein showed no substantial increase in the size of their monosome and polysome peaks, suggesting that similar numbers of mRNAs were being translated at approximately the same rates. In contrast, a complex that sedimented between the top of the gradient and 40S subunits was less abundant in cells expressing recombinant Rbm3. Further analysis showed that the RNA component of this fraction was microRNA. We discuss the possibility that Rbm3 expression alters global protein synthesis by affecting microRNA levels and suggest that both Rbm3 and microRNAs are part of a homeostatic mechanism that regulates global levels of protein synthesis under normal and cold-stress conditions.

A determination of the identity elements in yeast 18 S ribosomal RNA for the recognition of ribosomal protein YS11: the role of the kink-turn motif in helix 11.

A description of the site of interaction of YS11, the yeast homolog of eubacterial S17, with 18 S rRNA was obtained by assessing the binding of the ribosomal protein, in a filter retention assay, to oligoribonucleotides that reproduce regions of 18 S rRNA. YS11 binds predominantly to domain I; the Kd value is 113 nM. The dimensions of the YS11 binding site were refined, guided by chemical protection data and by the atomic structure of the Thermus thermophilus 30 S subunit, which has the S17 recognition site in 16 S rRNA. An oligoribonucleotide that mimics helix 11, a phylogenetically conserved region in domain I, binds YS11 with a Kd value of 230 nM; a second oligoribonucleotide that contains only the kink-turn motif in helix 11 binds YS11 with a Kd value of 528 nM. Thus, helix 11 has most of the nucleotides required for the recognition of YS11. To identify those nucleotides a set of 27 transversion mutations in H11 was constructed and their contribution to the binding of YS11 determined. Mutations of nine nucleotides (U313, C314, A316, G337, C338, G347, U348, U350, and C351) increased the Kd value for YS11 binding by at least eightfold; G325U and U349A mutations increased the Kd value fivefold. Eight of the 11 mutations are in the kink-turn in H11, confirming the critical importance of the motif for YS11 recognition. The other three nucleotides are in the lower stem and the terminal loop of H11, which makes a lesser, but still important, contribution to YS11 binding. The identity elements for YS11 recognition are: A316, G325, G337, G347, U348, U349, U350, and C351. The effect of the other nucleotides that decrease binding is probably indirect, presumably they affect the conformation of the binding site but do not have contacts to YS11 amino acid residues. The eight identity element nucleotides are in regions of H11 that deviate from A-form geometry and the contacts are predominantly, if not exclusively, to backbone phosphate and sugar oxygen atoms, indicating that YS11 recognizes the shape of the rRNA binding site rather than reading the sequence of nucleotides.

Biochemical evidence of translational infidelity and decreased peptidyltransferase activity by a sarcin/ricin domain mutation of yeast 25S rRNA.

A C-->U mutation (rdn5) in the conserved sarcin/ricin domain of yeast 25S rRNA has been shown to cause translational suppression and paromomycin resistance. It also separates the killing from the misreading effect of this antibiotic. We confirm these findings and provide in vitro evidence that rdn5 causes a 3-fold increase in translational errors and resistance to paromomycin. The role of this 25S rRNA domain in ribosome's decoding function was further demonstrated when 60S subunits from rdn5 cells were combined with 40S subunits from cells carrying an error-prone mutation in the eukaryotic accuracy center ribosomal protein S23, an homologue of Escherichia coli S12. These hybrids exhibited an error frequency similar to that of rdn5 alone, despite the error-prone mutation in S23. This was accompanied by extreme resistance to paromomycin, unlike the effects of the individual mutations. Furthermore, rdn5 lowers peptidyltransferase activity measured as a second-order rate constant (kcat/K(s)) corresponding to the rate of peptide bond formation. This mutation was also found to affect translocation. Elongation factor 2 (EF2)-dependent translocation of Ac-Phe-tRNA from the A- to P-site was achieved at an EF2 concentration 3.5 times lower than in wild type. In conclusion, the sarcin/ricin domain of 25S rRNA influences decoding, peptide bond formation and translocation.

A dispensable yeast ribosomal protein optimizes peptidyltransferase activity and affects translocation.

Yeast ribosomal protein L41 is dispensable in the yeast. Its absence had no effect on polyphenylalanine synthesis activity, and a limited effect on growth, translational accuracy, or the resistance toward the antibiotic paromomycin. Removal of L41 did not affect the 60:40 S ratio, but it reduced the amount of 80 S, suggesting that L41 is involved in ribosomal subunit association. However, the two most important effects of L41 were on peptidyltransferase activity and translocation. Peptidyltransferase activity was measured as a second-order rate constant (k(cat)/K(s)) corresponding to the rate of peptide bond formation; this k(cat)/K(s) was lowered 3-fold to 1.15 min(-1) mm(-1) in the L41 mutant compared with 3.46 min(-1) mm(-1) in the wild type. Translocation was also affected by L41. Elongation factor 2 (EF2)-dependent (enzymatic) translocation of Ac-Phe-tRNA from the A- to P-site was more efficient in the absence of L41, because 50% translocation was achieved at only 0.004 microm EF2 compared with 0.02 microm for the wild type. Furthermore, the EF2-dependent translocation was inhibited by 50% at 2.5 microm of the translocation inhibitor cycloheximide in the L41 mutant compared with 1.2 microm in the wild type. Finally, the rate of EF2-independent (spontaneous) translocation was increased in the absence of L41.

The role of the zinc finger motif and of the residues at the amino terminus in the function of yeast ribosomal protein YL37a.

YL37a is an essential yeast ribosomal protein that has a C(2)-C(2) zinc finger motif. Replacement of the cysteine residues had yielded variants that lacked the capacity to bind zinc but still supported cell growth. In a continuation of an examination of the relation of the structure of YL37a to its function, the contribution of amino acid residues in the intervening sequence between the internal cysteine residues of the motif was evaluated. Substitutions of alanine for the lysine residues at positions 44, 45, or 48, or for arginine 49 slowed cell growth. The most severe effect was caused by a double-mutation, K48A-R49A. A mutation of tryptophan 55 to alanine was lethal. Mutations to alanine of six conserved residues (K6, K7, K13, Y14, R17, and Y18) in the amino-terminal region decreased cell growth; the Y14 mutation was lethal. An in vitro assay for binding of YL37a to individual 26 S rRNA domains was developed. Binding of the recombinant fusion protein MBP-YL37a was to domains II and III; the K(d) for binding to domain II was 79 nM; for domain III it was 198 nM. There was a close correspondence between the effect of mutations in YL37a on cell growth and on binding to 26 S rRNA. In the atomic structure of the 50 S subunit of Haloarcula marismortui, the archaebacteria homolog of yeast YL37a, L37ae, coordinates a zinc atom and the finger motif is folded and interacts mainly with domain III of 23 S rRNA; whereas the amino-terminal region of L37ae interacts primarily with domain II. The biochemical and genetic experiments complement the three-dimensional structure and define for the first time the functional importance of a subset of the residues in close proximity to nucleotides.