Avoiding false positives in colony PCR

Bacteria and Yeast Colony PCR

The bacteria Escherichia coli and the yeast Saccharomyces cerevisiae are currently the two most important organisms in synthetic biology. E. coli is almost always used for fundamental DNA manipulation, while yeast is the simplest host system for studying eukaryotic gene expression and performing large-scale DNA assembly. Yeast expression studies may also require altering the chromosomal DNA by homologous recombination. All these studies require the verification of the expected DNA sequence, and the fastest method of screening is colony PCR, which is direct PCR of DNA in cells without prior DNA purification. Colony PCR is hampered by the difficulty of releasing DNA into the PCR mix and by the presence of PCR inhibitors. We hereby present one protocol for E. coli and two protocols for S. cerevisiae differing in efficiency and complexity as well as an overview of past and possible future developments of efficient S. cerevisiae colony PCR protocols.

Evolutionary coincidence of adaptive changes in exuperantia and the emergence of bicoid in Cyclorrhapha (Diptera)

The great radiation in the infraorder Cyclorrhapha involved several morphological and molecular changes, including important changes in anterior egg development. During Drosophila oogenesis, exuperantia (exu) is critical for localizing bicoid (bcd) messenger RNA (mRNA) to the anterior region of the oocyte. Because it is phylogenetically older than bcd, which is exclusive to Cyclorrhapha, we hypothesize that exu has undergone adaptive changes to enable this new function. Although exu has been well studied in Drosophila, there is no functional or transcriptional information about it in any other Diptera. Here, we investigate exu in the South American fruit fly Anastrepha fraterculus, a Cyclorrhapha of great agricultural importance that have lost bcd, aiming to understand the evolution of exu in this infraorder. We assessed its pattern of gene expression in A. fraterculus by analyzing transcriptomes from cephalic and reproductive tissues. A combination of next-generation data with classical sequencing procedures enabled identification of the structure of exu and its alternative transcripts in this species. In addition to the sex-specific isoforms described for Drosophila, we found that not only exu is expressed in heads, but this is mediated by two transcripts with a specific 5′UTR exon—likely a result from usage of a third promoter. Furthermore, we tested the hypothesis that exu is evolving under positive selection in Cyclorrhapha after divergence from lower Diptera. We found evidence of positive selection at two important exu domains, EXO-like and SAM-like, both involved with mRNA binding during bcd mRNA localization in Drosophila, which could reflect its cooptation for the new function of bcd mRNA localization in Cyclorrhapha.

Colony PCR

Escherichia coli and Saccharomyces cerevisiae are currently the two most important organisms in synthetic biology. E.coli is almost always used for fundamental DNA manipulation while yeast is the simplest host system for studying eukaryotic gene expression and performing large scale DNA assembly. Yeast expression studies may also require altering of the chromosomal DNA by homologous recombination. All these studies require the verification of the expected DNA sequence and the fastest method of screening is colony PCR, which is direct PCR of DNA in cells without prior DNA purification. Colony PCR is hampered by the difficulty of releasing DNA into the PCR mix and the presence of PCR inhibitors. We hereby present one protocol for E. coli and two protocols for S. cerevisiae differing in efficiency and complexity as well as an overview of past and possible future developments of efficient S. cerevisiae colony PCR protocols.

Why Johnny can't clone: Common pitfalls and not so common solutions

The demand for cloned genes has increased incessantly over the past 32 years, but some who need recombinant plasmids struggle to produce them. While the pitfalls of traditional ligation-dependent cloning are non-trivial, most can be avoided with sufficient effort and attention to detail. Here, the chemical properties of enzymes and reagents used to clone genes into plasmids are reviewed to draw attention to the most pertinent details. In particular, the virtues of agarose gel electrophoresis monitoring, the nature of the interactions between DNA and silica, and challenges associated with thermostable DNA polymerases, restriction endonucleases, and T4 DNA ligase are explored. Common pitfalls associated with Escherichia coli transformation and DNA modifying enzymes are also described. A thorough understanding of established methods is essential for troubleshooting, implementing alternative approaches, and inventing new techniques in response to changes in technology and demand.

Detection of human herpesvirus 8 by quantitative polymerase chain reaction: development and standardisation of methods

Background

Human herpesvirus 8 (HHV-8), the aetiological agent of Kaposi’s sarcoma (KS), multicentric Castleman’s disease (MCD), and primary effusion lymphoma (PEL) is rare in Australia, but endemic in Sub-Saharan Africa, parts of South-east Asia and Oceania. While the treatment of external KS lesions can be monitored by clinical observation, the internal lesions of KS, MCD and PEL require extensive and expensive internal imaging, or autopsy. In patients with MCD and PEL, if HHV-8 viraemia is not reduced quickly, ~50% die within 24 months. HHV-8 qPCR is a valuable tool for monitoring HHV-8 viraemia, but is not available in many parts of the world, including those with high prevalence of KS and HHV-8.

Methods

A new molecular facility with stringent three-phase workflow was established, adhering to NPAAC and CLSI guidelines. Three fully validated quantitative assays were developed: two for detection and quantification of HHV-8; one for GAPDH, necessary for normalisation of viral loads in tissue and peripheral blood.

Results

The HHV-8 ORF73 and ORF26 qPCR assays were 100% specific. All qPCR assays, displayed a broad dynamic range (10² to 10¹⁰ copies/μL TE Buffer) with a limit of detection of 4.85x10³, 5.61x10², and 2.59x10² copies/μL TE Buffer and a limit of quantification of 4.85x10³, 3.01x10², and 1.38x10² copies/μL TE Buffer for HHV-8 ORF73, HHV-8 ORF26, and GAPDH respectively.

The assays were tested on a panel of 35 KS biopsies from Queensland. All were HHV-8 qPCR positive with average viral load of 2.96x10⁵ HHV-8 copies/μL DNA extract (range: 4.37x10³ to 1.47x10⁶ copies/μL DNA extract): When normalised these equate to an average viral load of 2.44x10⁴ HHV-8 copies/10³ cells (range: 2.20x10² to 7.38x10⁵ HHV-8 copies/10³ cells).

Conclusions

These are the first fully optimised, validated and MIQE compliant HHV-8 qPCR assays established in Australia. They worked well for qualitative detection of HHV-8 in archival tissue, and are well-suited for quantitative detection in whole blood. They are now available for research, for clinical diagnosis of HHV-8 infection, and for monitoring treatment efficacy.

Identification of small molecule regulators of the nuclear receptor HNF4alpha based on naphthofuran scaffolds

Nuclear receptors are ligand-activated transcription factors involved in all major physiological functions of complex organisms. In this respect, they are often described as drugable targets for a number of pathological states including hypercholesterolemia and atherosclerosis. HNF4alpha (NR2A1) is a recently 'deorphanized' nuclear receptor which is bound in vivo by linoleic acid, although this natural ligand does not seem to promote transcriptional activation. In mouse, HNF4alpha is a major regulator of liver development and hepatic lipid metabolism and mutations in human have been linked to diabetes. Here, we have used a yeast one-hybrid system to identify small molecule activators of HNF4alpha in a library of synthetic compounds and found one hit bearing a methoxy group branched on a nitronaphthofuran backbone. A collection of molecules deriving from the discovered hit was generated and tested for activity toward HNF4alpha in yeast one-hybrid system. It was found that both the nitro group and a complete naphthofuran backbone were required for full activity of the compounds. Furthermore, adding a hydroxy group at position 7 of the minimal backbone led to the most active compound of the collection. Accordingly, a direct interaction of the hydroxylated compound with the ligand binding domain of HNF4alpha was detected by NMR and thermal denaturation assays. When used in mammalian cell culture systems, these compounds proved to be highly toxic, except when methylated on the furan ring. One such compound was able to modulate HNF4alpha-driven transcription in transfected HepG2C3A cells. These data indicate that HNF4alpha activity can be modulated by small molecules and suggest new routes for targeting the receptor in humans.

Contaminating insert degradation by preincubation colony PCR: a method for avoiding false positives in transformant screening

Colony PCR is a convenient alternative to conventional plasmid isolation and restriction digestion for high-throughput screening of recombinant colonies. However, an insert carryover from the ligation mix, adhered to colony or agar plate, generates a substantial number of false positives. To avoid this, a simple single-tube technique involving pre-PCR nuclease incubation has been developed by optimizing a buffer system that provides nuclease action and PCR amplification sequentially. Results presented in this work provide a technique that is amenable for high-throughput screening of recombinant colonies.

Chapter 3. Assays of adenylate uridylate-rich element-mediated mRNA decay in cells

The abundance of a cytoplasmic mRNA in eukaryotes often determines the level of the encoded protein product. The rates at which an mRNA is synthesized, exported, and degraded collectively contribute to its abundance in all cell types. Numerous mRNAs, particularly those encoding structural proteins, are very stable, with half-lives in the order of many hours. In contrast, mRNAs encoding regulatory proteins, including oncoproteins, cytokines, and signaling proteins, are relatively unstable with half-lives of an hour or less. As a result, modest changes in their decay rates affect their levels over a relatively short time period. This is particularly important to ensure rapid responses to extracellular signaling events. Messenger RNAs often harbor sequence elements that dictate their degradation rates. Adenylate uridylate (A+U)-rich elements (AREs), first identified in 1986, are perhaps the best characterized sequences that promote rapid mRNA degradation. These elements, localized within 3'-untranslated regions, sometimes contain AUUUA pentamers within an overall U-rich sequence, but this does not always define a bona fide ARE. Thus, experimental validation is essential before bestowing upon a suspected A+U-rich sequence the title of "ARE." This chapter describes a reporter gene system that permits quantitative assessment of the effects of candidate A+U-rich sequences on mRNA half-life. This system employs tetracycline-controlled transcriptional silencing of the reporter gene, isolation of total-cell RNA at selected time points, quantitative reverse transcriptase polymerase chain reaction analysis of reporter mRNA levels, and nonlinear regression analysis of mRNA level as a function of time to quantitatively define parameters describing mRNA decay kinetics. Finally, this chapter describes more specialized assays to characterize ARE-mediated mRNA decay pathways, including deadenylation, and discusses decapping.

Sequential gene integration for the engineering of Kluyveromyces marxianus

The attributes of the yeast Kluyveromyces marxianus (rapid growth rate at high temperature, utilization of a wide range of inexpensive carbon sources) make it a promising industrial host for the synthesis of protein and non-protein products. However, no stable multicopy plasmids are currently available for long-term culture of K. marxianus. To allow the stable genetic/metabolic engineering of K. marxianus, a method for integrating precise numbers of the same or different genes was developed for this yeast. A K. marxianus URA3 deletion mutant was constructed and the URA3 blaster (UB) reusable selection cassette from Saccharomyces cerevisiae was used to select sequential, untargeted chromosomal insertions of the Bacillus megaterium lactate dehydrogenase (LDH) gene. Following excision of the UB cassette from the chromosomes, the integrating vector was retransformed into the strain and a second copy of LDH was inserted, demonstrating the success of this method for sequential gene integrations in K. marxianus. LDH activity and lactic acid concentration increased with each gene insertion, further illustrating the success of this method.

Effects of interactions of hepatocyte nuclear factor 4alpha isoforms with coactivators and corepressors are promoter-specific

The gene encoding hepatocyte nuclear factor 4alpha (HNF4alpha) possesses two alternative promoters responsible for developmental and tissue-specific expression of HNF4alpha1 and HNF4alpha7. The two isoforms possess different N-termini and exhibit distinct transactivation properties. We show here for the first time that the effects mediated by HNF4alpha isoforms in concert with three different coregulators result in promoter-specific responses. Transcript levels of silencing mediator for retinoid and thyroid receptors and glucocorticoid receptor interacting protein-1 in the liver are reduced at birth, a time point when many genes are strongly activated, suggesting that the effects of coregulators on HNF4alpha activity in vivo could be determined by the levels of their expression as well as by the target promoter.

Competitive cofactor recruitment by orphan receptor hepatocyte nuclear factor 4alpha1: modulation by the F domain

For most ligand-dependent nuclear receptors, the status of endogenous ligand modulates the relative affinities for corepressor and coactivator complexes. It is less clear what parameters modulate the switch between corepressor and coactivator for the orphan receptors. Our previous work demonstrated that hepatocyte nuclear factor 4alpha1 (HNF4alpha1, NR2A1) interacts with the p160 coactivator GRIP1 and the cointegrators CBP and p300 in the absence of exogenously added ligand and that removal of the F domain enhances these interactions. Here, we utilized transient-transfection analysis to demonstrate repression of HNF4alpha1 activity by the corepressor silencing mediator of retinoid and thyroid receptors (SMRT) in several cell lines and on several HNF4alpha-responsive promoter elements. Glutathione S-transferase pulldown assays confirmed a direct interaction between HNF4alpha1 and receptor interaction domain 2 of SMRT. Loss of the F domain resulted in marked reduction of the ability of SMRT to interact with HNF4alpha1 in vitro and repress HNF4alpha1 activity in vivo, although the isolated F domain itself failed to interact with SMRT. Surprisingly, loss of both the A/B and F domains restored full repression by SMRT, suggesting involvement of both domains in the SMRT interaction. Finally, we show that when coexpressed along with HNF4alpha1 and GRIP1, CBP, or p300, SMRT can titer out HNF4alpha1-mediated transactivation in a dose-dependent manner and that this competition derives from mutually exclusive binding. Collectively, these results suggest that HNF4alpha can functionally interact with both a coactivator and a corepressor without altering the status of any putative ligand and that the presence of the F domain may play a role in discriminating between the different coregulators.