Technical advance in fungal biotechnology: development of a miniaturized culture method and an automated high-throughput screening

Aims:  The goal of the study was to develop a reliable, reproducible and rapid method of culture in order to screen a large number of fungal transformants.
Methods and Results:  The method is based upon miniaturized cell cultures and automated expression screening in microwell plates. For the method development, 50 recombinant Aspergillus vadensis clones producing feruloyl esterase B (FaeB) from Aspergillus niger were screened in 6 days. Then a panel of clones showing various behaviours was checked in flasks in order to demonstrate the reproducibility of the method. Using this method, a transformant of A. vadensis producing 1·2 g l⁻¹ of FaeB was selected (12-fold more than the A. niger overproducing strain).
Conclusions:  This miniaturized culture method allows to obtain reliable and reproducible results. The procedure has the advantages of being efficient, time-saving and more efficient than conventional in-flask culture screening as it can screen 800 clones per day after a culture of 3 days.
Significance and Impact of the Study:  This method could be applied to any other fungal strain culture, enzyme activity or biodiversity screening.     

Development of a cost-effective production process for Halomonas levan

Bioprocess and Biosystems Engineering - Levan polysaccharide is an industrially important natural polymer with unique properties and diverse high-value applications. However, current bottlenecks...     

High-resolution melting analysis of cDNA-derived PCR amplicons for rapid and cost-effective identification of novel alleles in barley

An original method has been established for the identification of novel alleles of eukaryotic translation initiation factor 4E (eIF4E) gene, which is required for resistance to agronomically important bymoviruses, in barley germplasm. This method involves scanning for sequence variations in cDNA-derived PCR amplicons using High-resolution melting (HRM) followed by direct Sanger sequencing of only those amplicons which were predicted to carry nucleotide changes. HRM is a simple, cost-effective, rapid and high-throughput assay, which so far has only been widely used in clinical pathology for molecular diagnostic of diseases and patient genotyping. Application of HRM allowed significant reduction in the amount of expensive Sanger sequencing required for allele mining in plants. The method described here involved an investigation of total cDNA rather than genomic DNA, thus permitting the analyses of shorter (up to 300-bp) and fewer overlapping amplicons to cover the coding sequence. This strategy further reduced the allele mining costs. The sensitivity and accuracy of HRM for predicting genotypes carrying a wide range of nucleotide polymorphisms in eIF4E approached 100%. Results of the current study are promising and suggest that this method could also potentially be applied to the discovery of superior alleles controlling other important traits in barley as well in other model and crop plant species. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Development and multiplex PCR amplification of microsatellite markers in the commercial clam Venerupis rhomboides (Mollusca: Bivalvia)

Venerupis rhomboides is a commercial clam whose production could be enhanced through effective management of natural and hatchery stocks. This study provides the first panel of microsatellite markers for the exploitation of this species according to genetic criteria. A total of 22 polymorphic microsatellite loci were isolated and characterized from two genomic libraries enriched for different motifs. The number of alleles per locus ranged from 2 to 14 in a sample of 20 clams from Spain, and the observed and expected heterozygosity from 0 to 0.95 and 0.05–0.901, respectively. Sixteen loci were in agreement with Hardy–Weinberg equilibrium after sequential Bonferroni correction and linkage disequilibrium between loci pairs was not detected. To reduce the cost of the genotyping process, tri- and pentaplex PCRs, amplifying a total of 13 microsatellites loci were optimized. The microsatellites developed here represent the first nuclear markers described in V. rhomboides and will be useful tools for genetic studies involving assessment of genetic variation and population structure of natural and cultivated populations, assignment testing, construction of genetic linkage maps and dissection of production traits.     

Development and multiplex PCR amplification of new microsatellite markers for the freshwater fish,ayu (Plecoglossus altivelis)

Multiplex polymerase chain reaction (PCR) technique has recently been applied to gain many advantages in molecular genetics. The present study focused on the development of 15 new microsatellite markers with multiplex PCR systems in ayu, Plecoglossus altivelis, an important freshwater fish in Japan. All loci were followed Mendelian inheritance in 27 F1 progeny except for the one locus. The number of alleles per locus ranged from nine to 44 and the observed heterozygosities ranged from 0.680 to 0.980 in 50 unrelated individuals. The results indicate that these new microsatellite markers are useful for studies of linkage mapping and population genetics for the species.     

PCR amplification and analysis of yeast artificial chromosomes

A strategy for the analysis of yeast artificial chromosome (YAC) clones that relies on polymerase chain reaction (PCR) amplification of small restriction fragments from isolated YACs following adapter ligation was developed. Using this method, termed YACadapt, we have amplified several YACs from a human Xq24-qter library and have used the PCR products for physical mapping by somatic cell hybrid deletion analysis and fluorescent in situ hybridization. One YAC, RS46, was mapped to band Xq27.3, near the fragile X mutation. The PCR product is an excellent renewable source of YAC DNA for analyses involving hybridization of YAC inserts to a variety of DNA/RNA sources.     

Molecular identification of pufferfish species using PCR amplification and restriction analysis of a segment of the 16S rRNA gene

This study amplified the mitochondrial 16S rRNA gene using polymerase chain reaction (PCR) with a template of total DNA from muscle tissues of nine pufferfish species collected from the coastal area of Okinawa Islands in Japan: Pleuranacanthus sceleratus, Triodon macropterus, Chelonodon patoca, Sphoeroides pachygaster, Arothron hispidus, A. stellatus, A. manilensis, A. mappa, and A. nigropunctatus. Then nucleotide sequence encoding a partial region of the 16S rRNA gene was compared among species. The sequenced fragment was also used to select restriction enzymes, yielding species-specific restriction fragment length polymorphisms (RFLP). The sequence of the segment of the 16S rRNA gene consisted of about 615 nucleotides and showed interspecies variations in the targeted region. After calculation of corresponding RFLP-patterns of nine species investigated with suitable restriction enzymes, three restriction enzymes – BanII, DdeI, and NlaIII – were found to be sufficient for identification of all nine species. Successful testing of this methodology in frozen and heated food samples suggests its utility for pufferfish species authentication in food products.     

Isolation and identification of methanogen-specific DNA from blanket bog peat by PCR amplification and sequence analysis.

The presence of methanogenic bacteria was assessed in peat and soil cores taken from upland moors. The sampling area was largely covered by blanket bog peat together with small areas of red-brown limestone and peaty gley. A 30-cm-deep core of each soil type was taken, and DNA was extracted from 5-cm transverse sections. Purified DNA was subjected to PCR amplification with primers IAf and 1100Ar, which specifically amplify 1.1 kb of the archaeal 16S rRNA gene, and ME1 and ME2, which were designed to amplify a 0.75-kb region of the alpha-subunit gene for methyl coenzyme M reductase (MCR). Amplification with both primer pairs was obtained only with DNA extracted from the two deepest sections of the blanket bog peat core. This is consistent with the notion that anaerobiosis is required for activity and survival of the methanogen population. PCR products from both amplifications were cloned, and the resulting transformants were screened with specific oligonucleotide probes internal to the MCR or archaeal 16S rRNA PCR product. Plasmid DNA was extracted from probe-positive clones of both types and the insert was sequenced. The DNA sequences of 8 MCR clones were identical, as were those of 16 of the 17 16S rRNA clones. One clone showed marked variation from the remainder in specific regions of the sequence. From a comparison of these two different 16S rRNA sequences, an oligonucleotide was synthesized that was 100% homologous to a sequence region of the first 16 clones but had six mismatches with the variant. This probe was used to screen primary populations of PCR clones, and all of those that were probe negative were checked for the presence of inserts, which were then sequenced. By using this strategy, further novel methanogen 16S rRNA variants were identified and analyzed. The sequences recovered from the peat formed two clusters on the end of long branches within the methanogen radiation that are distinct from each other. These cannot be placed directly with sequences from any cultured taxa for which sequence information is available.     

Development of a miniaturized nitrate reduction test for the identification of oral bacteria

A miniaturized nitrate reduction test (MNRT) for oral bacteria was developed and its reliability compared with a conventional nitrate reduction test (CNRT). In the MNRT 100 μl aliquots of freshly grown heavy suspension of various oral bacterial species, in physiological saline, were added to equal volumes of 0.1% filter-sterilized KNO₃ solution in distilled water in wells of transparent plastic plates. Duplicate plates were incubated aerobically or anaerobically at 35°C for 12–15 h. At the end of the incubation period the test was performed by adding either a trace amount of a non-liquid reagent (mixture of l-(+)-tartaric acid, sulfanilic acid and 1-naphthylenediamine dihydrochloride, 10:1:1, wt/wt) or conventional liquid reagents A and B (sulfanilic acid and N,N-dimethyl-1-naphthylamine). In the conventional nitrate reduction test (CNRT), tubes of a basal anaerobic broth were inoculated with the same bacterial species used for MNRT, and the nitrate reduction tests performed after anaerobic incubation of the cultures for 4–6 days. Several hundred anaerobic and facultative bacterial isolates belonging to genera Veillonella, Bacteroides, Fusobacterium, Selenomonas, Actinomyces and Capnocytophaga were characterized by MNRT and CNRT. Analysis of the data showed that MNRT and CNRT systems were comparable. In the MNRT system Veillonella parvula and Selenomonas sputigena were capable of reducing nitrate only under anaerobic conditions. Actinomycetes reduced the nitrates under aerobic and anaerobic conditions, while all black-pigmented Bacteroides, Fusobacterium and Capnocytophaga species did not reduce nitrate. These findings suggest that the MNRT is reliable, rapid and may be conveniently used in clinical or research laboratories with a heavy microbiological work load.     

Development of a high-throughput process for detection and screening of genetic polymorphisms

A method is described that uses the ABI PRISM 310 genetic analyzer in conjunction with custom-designed software to identify and classify RAPD products. This methodology will also work well with AFLPs and microsatellite analyses. The methodology uses the ABI PRISM 310's high-throughput (> 500 samples per week) capabilities and in-lane molecular weight standards to efficiently separate and size DNA products. Peak detection, locus classification and export of the data in a form accessible by several genetic analysis programs were accomplished through a custom-written software program (Peaks). Various criteria used by the program to identify and classify loci are described, and their effect on population analyses is examined. Criteria providing an effective, robust determination of population structure are presented.     

Rapid and cost-effective screening of newly identified microsatellite loci by high-resolution melting analysis

This study describes a new method for identifying microsatellite loci that will reliably amplify and show high degree of polymorphism in a given species. Microsatellites are the most powerful codominant markers available today, but the development of novel loci remains a labour-intensive and expensive process. In de novo isolation, approaches using next generation sequencing (NGS) are gradually replacing ones using Escherichia coli libraries, resulting in unparalleled numbers of candidate loci available. We present a systematic review of published microsatellite primer notes and show that, on average, about half of all candidate loci are lost due to insufficient PCR amplification, monomorphism or multicopy status in the genome, no matter what isolation strategy is used. Thus, the screening of candidate loci remains a major step in marker development. Re-assessing capillary-electrophoresis genotyped loci via high-resolution melting analysis (HRM), we evaluate the usefulness of HRM for this step. We demonstrate its applicability in a genotyping case study and introduce a fast, HRM-based workflow for the screening of microsatellite loci. This workflow may readily be applied to NGS-based marker development and has the potential to cut the costs of traditional testing by half to three quarters.     

Isolation of microsatellite markers in the Emys orbicularis complex and development of multiplex PCR amplification

We report the development of 15 new microsatellite markers for Emys orbicularis and Emys trinacris. A survey of 20 individuals showed that all loci are highly polymorphic with 3–14 alleles per locus. Additionally, 22 Glyptemys muhlenbergii primers were checked for cross-species amplification, with 14 being amplified successfully and polymorphic (2–14 alleles). A set of eight markers was selected and combined into two multiplex PCRs. Levels of genetic diversity were assessed in 648 individuals covering the complete distribution area. The number of alleles ranged from 13 to 24 and observed heterozygosity varied between 0.515 and 0.852.     

Development and evaluation of real competitive PCR for high-throughput quantitative applications

Real competitive PCR (rcPCR) has been shown to have high sensitivity, reproducibility, and high-throughput potential. We describe further development and evaluation of this methodology as a tool for measuring nucleic acid abundance within a cell. Modifications to the original protocol allow analysis of gene expression levels using standard conditions regardless of mRNA abundance and assay type, thereby increasing throughput and ease of reaction setup while decreasing optimization time. In addition, we have developed a software package, TITAN, to automatically analyze the results. The details are relevant to researchers performing competitive PCR using any detection technique. The effectiveness of the described developments is demonstrated using 12 genes known to have differential expression in cell lines grown under normal and hypoxic conditions. Quantitative and qualitative comparisons to real-time PCR are presented. It is also demonstrated that the technique is capable of detecting submicroscopic chromosomal DNA deletions.     

Protein–protein‐interactions in a multiplexed,miniaturized format a functional analysis of Rho GTPase activation and inhibition

A miniaturized, bead‐based protein–protein‐interaction assay was developed to study the interaction of Rho GTPases with regulatory proteins. The setup, which uses only minute amounts of sample, was used to analyze small molecules that inhibit the interaction between Rho GTPases and RhoGDIα. Prenylcysteine analogues and the replacement of GDP by non‐hydrolysable GTP analogues prevented the formation of Rho GTPase‐RhoGDIα complexes in a concentration‐dependent manner.     

1株源于人体的双歧杆菌的PCR扩增和鉴定

目的从佳木斯大学健康学生体内分离出1株双歧杆菌。方法利用引物设计软件设计双歧杆菌的引物,通过PCR进行扩增,进行序列分析和鉴定。结果通过BLAST序列比对分析,与GenBank中相应基因同源性为99%。结论确定此菌株为青春双歧杆菌。     

Development of a highly automated and multiplexed targeted proteome pipeline and assay for 112 rat brain synaptic proteins

We present a comprehensive workflow for large scale (>1000 transitions/run) label‐free LC‐MRM proteome assays. Innovations include automated MRM transition selection, intelligent retention time scheduling that improves S/N by twofold, and automatic peak modeling. Improvements to data analysis include a novel Q/C metric, normalized group area ratio, MLR normalization, weighted regression analysis, and data dissemination through the Yale protein expression database. As a proof of principle we developed a robust 90 min LC‐MRM assay for mouse/rat postsynaptic density fractions which resulted in the routine quantification of 337 peptides from 112 proteins based on 15 observations per protein. Parallel analyses with stable isotope dilution peptide standards (SIS), demonstrate very high correlation in retention time (1.0) and protein fold change (0.94) between the label‐free and SIS analyses. Overall, our method achieved a technical CV of 11.4% with >97.5% of the 1697 transitions being quantified without user intervention, resulting in a highly efficient, robust, and single injection LC‐MRM assay.     

Development and application of a miniaturized gel electrophoresis device for protein analysis

The present article describes a miniaturized polyacrylamide slab gel electrophoresis-chip (PASGE-Chip) that can rapidly separate a set of predefined samples as well as cell lysate samples for clinical diagnosis. The chip consists of a polymethyl methacrylate (PMMA) upper unit (25 x 30 x 10 mm, width x length x depth) with integrated buffer chambers, running electrodes and loading wells and a bottom unit comprising a silicon dioxide-coated silicon plate with embossed gel chamber (11 x 15 x 0.37 mm). This miniaturized device was designed to be fast, easy to use and cheap to produce. The polyacrylamide slab gel electrophoresis can be performed in less than 10 min with low voltage. The gel-to-gel repeatability is around 3.8%. The limit of detection is approx. 10 ng as determined by Coomassie staining of selected standard proteins, and corresponds to a 10-fold increase in sensitivity as compared with a common size PAGE analysis device (e.g. 10 x 7 cm). The device was successfully applied to peptide mass fingerprint analysis, protein sequencing and ultra-sensitive immunodetection, and the performance was compared to a commonly used regular PAGE device.     

Primer design for PCR and sequencing in high-throughput analysis of SNPs

To achieve high-throughput analysis of allele frequencies in human SNPs, we have developed automated methodsfor designing PCR and DNA sequencing primers. We found we could run the PCR assays at quite stringent, uniform conditions. The design process used freely available databases, including dbSNP, SNPper, and TSC, and publicly available software including RepeatMasker and Primer3. We describe parameters for the software and other considerations that increase experimental success. As anticipated. some assays filed at the design stage due primarily to the genomic locations of repetitive sequences, extreme GC content regions, or lack of sufficient sequence. However, over 23,000 assays, including 96% of those recently analyzed, have been experimentally successfuL Similar design methods could be usedfor PCR assays in any organism with substantial available sequence.     

Gene expression analysis of Escherichia coli grown in miniaturized bioreactor platforms for high-throughput analysis of growth and genomic data

Combining high-throughput growth physiology and global gene expression data analysis is of significant value for integrating metabolism and genomics. We compared global gene expression using 500 ng of total RNA from Escherichia coli cultures grown in rich or defined minimal media in a miniaturized 50-μl bioreactor. The microbioreactor was fabricated out of poly(dimethylsiloxane) (PDMS) and glass and equipped to provide on-line, optical measurements. cDNA labeling for microarray hybridizations was performed with the GeniconRLS system. From these experiments, we found that the expression of 232 genes increased significantly in cells grown in minimum medium, including genes involved in amino acid biosynthesis and central metabolism. The expression of 275 genes was significantly elevated in cells grown in rich medium, including genes involved in the translational and motility apparatuses. In general, these changes in gene expression levels were similar to those observed in 1,000-fold larger cultures. The increasing rate at which complete genomic sequences of microorganisms are becoming available offers an unprecedented opportunity for investigating these organisms. Our results from microscale cultures using just 500 ng of total RNA indicate that high-throughput integration of growth physiology and genomics will be possible with novel biochemical platforms and improved detection technologies.