Expression and purification of moricin CM4 and human β-defensins 4 in Escherichia coli using a new technology

Different strategies have been developed to produce small antimicrobial peptides using recombinant techniques. Here we report a new technology of biosynthesis of moricin CM4 and human β-defensins 4 (HβD4) in the Escherichia coli. The CM4 and HβD4 gene were cloned into a vector containing the tags elastin-like peptide (ELP) and intein to construct the expression vector pET-EI-CM4 and pET-EI-HβD4. All the peptides, expressed as soluble fusions, were isolated from the protein debris by the method called inverse transition cycling (ITC) rather than traditional immobilized metal affinity chromatography (IMAC) and separated from the fusion leader by self-cleavage. Fully reduced peptides that were purified exhibited expected antimicrobial activity. The approach described here is a low-cost, convenient and potential way for generating small antimicrobial peptide.     

Simultaneous cultivation and disruption of Escherichia coli using glass beads to release recombinant α-amylase and other enzymes

An efficient and reproducible protein recovery procedure from Escherichia coli is presented. Recombinant strains overexpressing recombinant -amylase were cultured in shaken flasks containing small glass beads. Most of the cells underwent mechanical lysis and more than 90% of the -amylase content and also of other non-recombinant enzymes were released into the culture fluid after 24 h. The degree to which the enzymes were released depended on the enzymes and strains involved.     

Roles of ExoI and SbcCD Nucleases in “Reckless” DNA Degradation in recA Mutants of Escherichia coli

Exponentially growing recA mutant cells of Escherichia coli display pronounced DNA degradation that starts at the sites of DNA damage and depends on RecBCD nuclease (ExoV) activity. As a consequence of this “reckless” DNA degradation, populations of recA mutants contain a large proportion of anucleate cells. We have found that both DNA degradation and anucleate-cell production are efficiently suppressed by mutations in the xonA (sbcB) and sbcD genes. The suppressive effects of these mutations were observed in normally grown, as well as in UV-irradiated, recA cells. The products of the xonA and sbcD genes are known to code for the ExoI and SbcCD nucleases, respectively. Since both xonA and sbcD mutations are required for strong suppression of DNA degradation while individual mutations have only a weak suppressive effect, we infer that ExoI and SbcCD play partially redundant roles in regulating DNA degradation in recA cells. We suggest that their roles might be in processing (blunting) DNA ends, thereby producing suitable substrates for RecBCD binding.The RecA protein plays a central role in homologous recombination and recombinational DNA repair in Escherichia coli, as well as in other bacterial species. It catalyzes the key stages of the recombination process—homologous pairing and DNA strand exchange. Cells carrying null mutations in the recA gene are completely deficient for homologous recombination and are extremely sensitive to DNA-damaging agents (for a review, see references 21, 24, and 25). Populations of recA null mutants contain a large proportion (50 to 60%) of nonviable cells, reflecting the inability of these mutants to repair spontaneously occurring DNA damage (31). Also, exponentially growing recA cells display pronounced spontaneous DNA degradation that presumably starts at the sites of DNA damage and that depends on RecBCD nuclease (ExoV) activity (5, 48). This phenotype of recA cells is aggravated after DNA-damaging treatment, such as UV irradiation (48).According to the present data, the majority of RecA-catalyzed DNA transactions in E. coli start with binding of the RecA protein onto single-stranded DNA (ssDNA) substrates. This binding is mediated by the RecBCD and/or RecFOR protein, which helps RecA to overcome hindrance imposed by the SSB protein during competition for the DNA substrate. The RecBCD and RecFOR proteins begin RecA polymerization on ssDNA, giving rise to a nucleoprotein filament that is indispensable for further recombination reactions (3, 33; reviewed in reference 44).The RecBCD enzyme is crucial for initiation of recombinational processes at double-stranded DNA (dsDNA) ends (or breaks [DSBs]) in wild-type E. coli (a set of reactions known as the RecBCD pathway) (9, 43, 44). Upon recognizing a blunt or nearly blunt dsDNA end and binding to it, RecBCD acts as a combination of powerful helicase and nuclease, thus unwinding and simultaneously degrading both strands of the DNA duplex. After encountering a specific octanucleotide sequence designated Chi, the strong 3′-5′ nuclease activity of the enzyme is attenuated and a weaker 5′-3′ nuclease activity is upregulated (1). This Chi-dependent modification allows RecBCD to create a long 3′ ssDNA tail and to direct the loading of RecA protein onto it (2, 3). In vivo data suggest that this transition of RecBCD from a nuclease to a recombinase mode of action requires the presence of the RecA protein, suggesting that the two proteins might interact (27).In wild-type E. coli cells, the RecFOR protein complex works predominantly on DNA gaps, which may arise in chromosomes due to replication forks passing over the noncoding lesions (e.g., UV-induced pyrimidine dimers) or may be present in replication forks stalled at different obstacles in DNA (44). On the other hand, the RecFOR complex has an important role in recBC sbcBC(D) mutant cells, replacing the RecA-loading activity of RecBCD during recombination reactions starting from dsDNA ends. Recombination reactions mediated by RecFOR proteins are termed the RecF (or RecFOR) pathway (44).Cells mutated in the recB and/or recC gene exhibit strong deficiency in conjugational and transductional recombination, as well as in the repair of DSBs (8, 21). These defects can be rectified by extragenic sbcB and sbcC(D) suppressor mutations that inactivate two nucleases, thus enabling full efficiency of the RecF pathway on dsDNA ends (21, 44). The sbcB gene (also designated xonA) encodes exonuclease I (ExoI), the enzyme that digests ssDNA in the 3′-5′ direction (23). The sbcC and sbcD genes encode subunits of the SbcCD nuclease, which acts both as an endonuclease that cleaves hairpin structures and as an exonuclease that degrades linear dsDNA molecules (10, 11). Inactivation of either of the two subunits leads to the loss of SbcCD enzyme activity (18).The exact mechanism of activation of the RecF pathway by sbc mutations is not completely understood. A plausible explanation is that inactivation of ExoI and SbcCD nucleases is necessary to prevent the degradation of recombinogenic 3′ DNA ends created in a RecBCD-independent manner (8, 23, 38, 45, 46). It was recently shown that the sbcB15 mutant allele (encoding a protein without nucleolytic activity) (37) is a better suppressor of the RecBCD⁻ phenotype than an sbcB deletion (50), suggesting that some nonnucleolytic activity of ExoI may also contribute to the efficiency of the RecF pathway (46, 50).ExoI and SbcCD are usually viewed as enzymes with inhibitory roles in recombination due to their deleterious actions on the RecF pathway. However, some results suggest that these enzymes could also have stimulatory roles in recombination reactions proceeding on the RecBCD pathway. Genetic experiments with UV-irradiated E. coli cells indicated that ExoI and SbcCD might be involved in blunting radiation-induced DNA ends prior to RecBC(D) action (38, 45, 46). Such a role of ExoI and SbcCD seems to be particularly critical in recD recF mutants, in which the majority of DSB repair depends on the RecBC enzyme (38). It was also suggested that the blunting roles of the two nucleases may be required during conjugational recombination (16, 46).In this work, we studied the effects of sbcB (xonA) and sbcD mutations on DNA degradation occurring spontaneously in exponentially growing recA mutant cells, as well as on DNA degradation induced in recA mutants by UV irradiation. We have demonstrated that in both cases DNA degradation is strongly reduced in recA mutants that carry in addition a combination of xonA and sbcD null mutations. The results described in this paper suggest that ExoI and SbcCD play partially redundant roles in regulating DNA degradation in recA cells.     

Development and validation of a new method to measure walking speed in free-living environments using the actibelt® platform

Walking speed is a fundamental indicator for human well-being. In a clinical setting, walking speed is typically measured by means of walking tests using different protocols. However, walking speed obtained in this way is unlikely to be representative of the conditions in a free-living environment. Recently, mobile accelerometry has opened up the possibility to extract walking speed from long-time observations in free-living individuals, but the validity of these measurements needs to be determined. In this investigation, we have developed algorithms for walking speed prediction based on 3D accelerometry data (actibelt?) and created a framework using a standardized data set with gold standard annotations to facilitate the validation and comparison of these algorithms. For this purpose 17 healthy subjects operated a newly developed mobile gold standard while walking/running on an indoor track. Subsequently, the validity of 12 candidate algorithms for walking speed prediction ranging from well-known simple approaches like combining step length with frequency to more sophisticated algorithms such as linear and non-linear models was assessed using statistical measures. As a result, a novel algorithm employing support vector regression was found to perform best with a concordance correlation coefficient of 0.93 (95%CI 0.92-0.94) and a coverage probability CP1 of 0.46 (95%CI 0.12-0.70) for a deviation of 0.1 m/s (CP2 0.78, CP3 0.94) when compared to the mobile gold standard while walking indoors. A smaller outdoor experiment confirmed those results with even better coverage probability. We conclude that walking speed thus obtained has the potential to help establish walking speed in free-living environments as a patient-oriented outcome measure.     

Proline excretion in Escherichia coli: A comparison of an argD + strain and a proline-excreting argD − derivative

In an attempt to deduce the physiological basis of proline excretion in argD ^– strains of Escherichia coli K12, several properties of an argD ⁺ (nonexcreting) and an argD ^– (excreting) derivative were compared. No difference was found in the transport or in the utilization of either proline or its immediate precursor, ¹-pyrroline-5-carboxylate (PCA). Furthermore, no differences were found in the physical or kinetic properties of partially purified preparations of the enzyme mediating the final step in proline biosynthesis, PCA reductase. The specific activity of PCA reductase was, however, consistently higher in crude extracts prepared from the argD ^– mutant.This work was supported by grants from the National Institutes of Allergy and Infectious Diseases (Public Health Service No. AI-10862) and The University of Connecticut Research Foundation (to C. M. B.). J. J. R. was supported by an NDEA Predoctoral Fellowship.     

Local and global analysis of endocytic patch dynamics in fission yeast using a new “temporal superresolution” realignment method

Quantitative microscopy is a valuable tool for inferring molecular mechanisms of cellular processes such as clathrin-mediated endocytosis, but, for quantitative microscopy to reach its potential, both data collection and analysis needed improvement. We introduce new tools to track and count endocytic patches in fission yeast to increase the quality of the data extracted from quantitative microscopy movies. We present a universal method to achieve “temporal superresolution” by aligning temporal data sets with higher temporal resolution than the measurement intervals. These methods allowed us to extract new information about endocytic actin patches in wild-type cells from measurements of the fluorescence of fimbrin-mEGFP. We show that the time course of actin assembly and disassembly varies <600 ms between patches. Actin polymerizes during vesicle formation, but we show that polymerization does not participate in vesicle movement other than to limit the complex diffusive motions of newly formed endocytic vesicles, which move faster as the surrounding actin meshwork decreases in size over time. Our methods also show that the number of patches in fission yeast is proportional to cell length and that the variability in the repartition of patches between the tips of interphase cells has been underestimated.     

Ratiometric fluorescence imaging of dual bio-molecular events in single living cells using a new FRET pair mVenus/mKOκ-based biosensor and a single fluorescent protein biosensor

Genetically coded fluorescent protein (FP)-based biosensors are powerful tools for the non-invasive tracking of molecular events in living cells. Although a variety of FP biosensors are available, the simultaneous imaging of multiple biosensors (multi-parameter imaging) in single living cells remains a challenge and is far from routinely used to elucidate the intricate networks of molecular events. In this study, we established a novel combination of FP biosensors for dual-parameter ratiometric imaging, consisting of a new fluorescence resonance energy transfer (FRET) pair mVenus (yellow FP)/mKOκ (orange FP)-based (abbreviated as YO) biosensor and a single FP-based biosensor Grx1-roGFP2. Under our imaging condition, 1.4±0.05% of Grx1-roGFP2 signal contributes to the mVenus channel and 5.2±0.12% of the mVenus signal contributes to the Grx1-roGFP2 channel. We demonstrate that such low degree of cross-talk causes negligible distortion of the ratiometric signal of the YO-based FRET biosensor and Grx1-roGFP2. By using this dual-parameter ratiometric imaging approach, we achieved simultaneous imaging of Src/Ca(2+) signaling and glutathione (GSH) redox potential in a single cell, which was previously unattainable. Furthermore, we provided direct evidence that epidermal growth factor (EGF)-induced Src signaling was negatively regulated by H(2)O(2) via its effect on GSH-based redox system, demonstrating the power of this dual-parameter imaging approach for elucidating new connections between different molecular events that occur in a single cell. More importantly, the dual-parameter imaging approach described in this study is highly extendable.     

Organization and genomic distribution of “82H” alpha satellite DNA

Summary We have investigated the organization and genomic distribution of sequences homologous to p82H, a cloned human alpha satellite sequence purported, based on previous in situ hybridization experiments, to exist at the centromere of each human chromosome. We report here that, using Southern blotting analysis under conditions of high stringency, p82H hybridizes solely to a low-copy or single-copy alphoid domain located at or near the centromeric region of human chromosome 14. In contrast, conditions of reduced hybridization stringency permit extensive cross-hybridization with nonidentical, chromosome-specific alpha satellite subsets found elsewhere in the human genome. Thus, the previously described ubiquity of 82H human centromeric sequences reflects the existence of diverse alpha satellite subsets located at the centromeric region of each human chromosome.     

“Biosynthesis of psilocybin and its nonnatural derivatives by a promiscuous psilocybin synthesis pathway in Escherichia coli”

Traditional psychedelics are undergoing a transformation from recreational drugs, to promising pharmaceutical drug candidates with the potential to provide an alternative treatment option for individuals struggling with mental illness. Sustainable and economic production methods are thus needed to facilitate enhanced study of these drug candidates to support future clinical efforts. Here, we expand upon current bacterial psilocybin biosynthesis by incorporating the cytochrome P450 monooxygenase, PsiH, to enable the de novo production of psilocybin as well as the biosynthesis of 13 psilocybin derivatives. The substrate promiscuity of the psilocybin biosynthesis pathway was comprehensively probed by using a library of 49 single-substituted indole derivatives, providing biophysical insights to this understudied metabolic pathway and opening the door to the in vivo biological synthesis of a library of previously unstudied pharmaceutical drug candidates.     

The new method ‘micromapping’, a means to study species-specific associations and exclusions of ectomycorrhizae

Ectomycorrhizae (ECM) are obligate symbiotic associations between higher fungi and most tree species of the temperate and boreal forests, and of some tree families in tropical areas. As the anatomical features of these symbiotic organs are very diverse and suggested to improve tree growth differently efficient, their frequency and natural distribution in the soil, as well as the differentiation and amount of their substrate exploiting extramatrical mycelia, are of special ecological interest. The soil with its heterogeneous assemblage of micro-niches certainly provokes ectomycorrhizal fungi to compete for such microsites. We therefore applied the method ‘micromapping’ to record the ECM in their natural position with the following question in mind: Do indicators exist for an exclusion of or an association with other ectomycorrhizal species or not? Thoroughly excavated and carefully cleaned ectomycorrhizae of the O_F horizon of a Picea abies stand were drawn in their natural position on perspex plates of 5 × 5 cm mapping area (McMp) with ink of different colours. They were afterwards removed and specified. Following scanning of the McMp, a special computer program was applied to analyse their distribution. The spatial relations of the ECM were calculated according to the ‘growing grid method’. The preliminary results suggest that the ECM of Russula ochroleuca and Piceirhiza internicrassihyphis show no common occurrence within short distances. This possibly applies also for Russula ochroleuca in comparison to Piceirhiza cinnbadiosimilis, for Elaphomyces granulatus in comparison to Xerocomus badius, and Lactarius decipiens in comparison to Piceirhiza cinnbadiosimilis. Cortinarius obtusus with Piceirhiza internicrassihyphis, and Piceirhiza internicrassihyphis with Xerocomus badius, indicate, however, rather high values of common occurrence. Due to the small number of replications, the standard deviations are high. More detailed investigations are therefore necessary before definite conclusions can be made. This method, however, apparently provides a useful tool to analyse spatial relations of ECM in the soil. Possible reasons for exclusions and associations of ECM are briefly discussed.     

A new 10-min ligation method using a modified buffer system with a very low amount of T4 DNA ligase: the “Coffee Break Ligation” technique

The ligation reaction is widely used in molecular biology. There are several kits available that complete the ligation reaction very rapidly but they are rather expensive. In this study, we successfully modified the ligation buffer with much lower cost than existing kits. The ligation reaction can be completed in 10 min using very low activities such as 0.01 U T4 DNA ligase, and costs only $1 for 100 reactions of 20 μl scale. We name this ligation system the “Coffee Break Ligation” system; one can complete ligation reaction while drinking a cup of coffee, and perform 100 reactions by spending money equivalent to a cup of coffee.     

Identification and classification of cut-flower “Huangyinghua”using DNA marker techniques

rch Laboratory, Nanjing Agricultural University, Nanjing 210095, China) Abstract “Huangyinghua” is a popular cut-flower in China, but it is unclear as to whether “Huangyinghua” is an invasive Solidago canadensis or not. The genetic relationship of a total of 45 samples of “Huangyinghua” with S. canadensis, and S. decurrens were investigated using AFLP technique so as to determine the identity of “Huangyinghua”. Genomic DNA was digested with EcoRI and MseI enzymes and amplified with six E+3 and M+3 primer combinations. AFLP analysis produced 661 endonucleotide discernable bands, of which 639 (96.61%) were polymorphic. Cluster analysis through using UPGMA method indicated that “Huangyinghua” and S. canadensis were clustered into the same group that was different from S. decurrens. Sequence analysis based on the ITS regions showed that their sequences of 5.8S rDNA were the same, and the differences were found only in the ITS1 and ITS2 regions. ITS phylogenetic trees of the tested samples and closely-related species were reconstructed based on our sequence data in combination with those from GenBank. Based on the trees, “Huangyinghua” was found to belong to S. canadensis complex, but not to S. decurrens. Moreover, it was found that there were considerable genetic variation in both “Huangyinghua” and S. canadensis. Therefore, the cut-flower “Huangyinghua” may be invasive, and proper measures should be taken to control the further spread of its propagules.     

Identification of a cyclooxygenase gene from the red alga Gracilaria vermiculophylla and bioconversion of arachidonic acid to PGF(2α) in engineered Escherichia coli

Prostaglandins (PGs) are important local messenger molecules in many tissues and organs of animals including human. For applications in medicine and animal care, PGs are mostly purified from animal tissues or chemically synthesized. To generate a clean, reliable, and inexpensive source for PGs, we have now engineered expression of a suitable cyclooxygenase gene in Escherichia coli and achieved production levels of up to 2.7 mg l⁻¹ PGF_2α. The cyclooxygenase gene cloned from the red alga Gracilaria vermiculophylla appears to be fully functional without any eukaryotic modifications in E. coli. A crude extract of the recombinant E. coli cells is able to convert in vitro the substrate arachidonic acid (AA) to PGF_2α. Furthermore, these E. coli cells produced PGF_2α in a medium supplemented with AA and secreted the PGF_2α product. To our knowledge, this is the first report of the functional expression of a cyclooxygenase gene and concomitant production of PGF_2α in E. coli. The successful microbial synthesis of PGs with reliable yields promises a novel pharmaceutical tool to produce PGF_2α at significantly reduced prices and greater purity.     

Cost-effective and rapid (3 h) method for combined extraction of DNA,RNA and protein from a single tea leaf sample for genomic and proteomic analysis

This is the first report about the simultaneous extraction of nucleic acids and proteins from tea leaf tissue. Using the present protocol, the DNA, RNA and protein were simultaneously isolated from a single tea leaf sample. The method also maintained the quality and quantity of the isolated biomolecules. The method is cost-effective and takes only 3 h to isolate the starting molecules (DNA, RNA and protein) of central dogma of biology. It was also demonstrated that the isolated DNA, RNA and protein could be successfully used for genomics and proteomic analysis in tea plant which was verified by performing marker study, gene cloning, cDNA preparation, gene expression study and 2-DE.