Total Syntheses of Prenylated Isoflavones from Erythrina sacleuxii and Their Antibacterial Activity: 5-Deoxy-3'-prenylbiochanin A and Erysubin F.

The prenylated isoflavones 5-deoxyprenylbiochanin A (7-hydroxy-4'-methoxy-3'-prenylisoflavone) and erysubin F (7,4'-dihydroxy-8,3'-diprenylisoflavone) were synthesized for the first time, starting from mono- or di-O-allylated chalcones, and the structure of 5-deoxy-3'-prenylbiochanin A was corroborated by single-crystal X-ray diffraction analysis. Flavanones are key intermediates in the synthesis. Their reaction with hypervalent iodine reagents affords isoflavones via a 2,3-oxidative rearrangement and the corresponding flavone isomers via 2,3-dehydrogenation. This enabled a synthesis of 7,4'-dihydroxy-8,3'-diprenylflavone, a non-natural regioisomer of erysubin F. Erysubin F (8), 7,4'-dihydroxy-8,3'-diprenylflavone (27), and 5-deoxy-3'-prenylbiochanin A (7) were tested against three bacterial strains and one fungal pathogen. All three compounds are inactive against Salmonella enterica subsp. enterica (NCTC 13349), Escherichia coli (ATCC 25922), and Candida albicans (ATCC 90028), with MIC values greater than 80.0 µM. The diprenylated natural product erysubin F (8) and its flavone isomer 7,4'-dihydroxy-8,3'-diprenylflavone (27) show in vitro activity against methicillin-resistant Staphylococcus aureus (MRSA, ATCC 43300) at MIC values of 15.4 and 20.5 µM, respectively. In contrast, the monoprenylated 5-deoxy-3'-prenylbiochanin A (7) is inactive against this MRSA strain.

A recombinase polymerase amplification assay for the diagnosis of atypical pneumonia.

Pneumonia is one of the most common and potentially lethal infectious conditions worldwide. Streptococcus pneumoniae is the pathogen most frequently associated with bacterial community-acquired pneumonia, while Legionella pneumophila is the major cause for local outbreaks of legionellosis. Both pathogens can be difficult to diagnose since signs and symptoms are nonspecific and do not differ from other causes of pneumonia. Therefore, a rapid diagnosis within a clinically relevant time is essential for a fast onset of the proper treatment. Although methods based on polymerase chain reaction significantly improved the identification of pathogens, they are difficult to conduct and need specialized equipment. We describe a rapid and sensitive test using isothermal recombinase polymerase amplification and detection on a disposable test strip. This method does not require any special instrumentation and can be performed in less than 20 min. The analytical sensitivity in the multiplex assay amplifying specific regions of S. pneumoniae and L. pneumophila simultaneously was 10 CFUs of genomic DNA per reaction. In cross detection studies with closely related strains and other bacterial agents the specificity of the RPA was confirmed. The presented method is applicable for near patient and field testing with a rather simple routine and the possibility for a read out with the naked eye.

Identification of antimicrobial peptides and immobilization strategy suitable for a covalent surface coating with biocompatible properties.

Bacterial accumulation on solid material displays a major source of biomaterial associated infections, cross contamination, and spreading. To overcome these problems, different investigations on surface modifications for the containment of bacterial adhesion have been done. The aim of this research is the development of a rapid and efficient screening procedure to identify and investigate biologically active peptides in an immobilized state in order to produce an antimicrobial surface coating. We figured out that the antimicrobial mode of action is the most important parameter because only peptides with pronounced membrane disruption abilities displayed meaningful activity in an immobilized state. In addition, we highlighted the influence of the coupling reaction chemistry on the activity and amount of the immobilized peptide. Thereupon we developed an optimized antimicrobial surface coating with unrestricted antimicrobial properties by adjusting the immobilization strategy in combination with lowering the necessary peptide amount. Moreover we demonstrated that this antimicrobial surface coating displayed no cytotoxic activity against a eukaryotic cell line and thereby indicates a promising biocompatibility. Furthermore, different antimicrobial peptides obtained either by chemical peptide synthesis or by recombinant DNA technology were used in this study and their activities as well as their potential applications were discussed.

Rational design of artificial ß-strand-forming antimicrobial peptides with biocompatible properties.

Because the intensive use of antibiotics has led to a large variety of resistant bacterial strains, therapeutic measures have become increasingly challenging. In order to ensure reliable treatment of diseases, alternative antimicrobial agents need to be explored. In this context, antimicrobial peptides have been discussed as novel bioactive molecules, which, however, may be limited in their applicability due to their high manufacturing costs and poor pharmacokinetic properties. Consequently, the design of artificial antimicrobial peptides featuring two flanking cationic regions and a hydrophobic center is presented. These sequences led to distinct antimicrobial activity on the same order of magnitude as that of naturally occurring reference peptides but with less cytotoxic or cytostatic drawbacks. Furthermore, a deletion and substitution library revealed the minimal sequence requirements. By analysis of the computed 3D structures of these peptides, a single characteristic ß-strand was identified. This structural motif was pivotal for antimicrobial activity. Consequently, an optimized peptide sequence with antimicrobial and biocompatible properties was derived, and its application was demonstrated in a mixed culture experiment. Thus, it was shown that the optimized artificial antimicrobial peptide is suitable as a therapeutic agent and may be used as template for the development of new antimicrobial peptides with unique secondary structures.

Rapid detection of Plasmodium falciparum with isothermal recombinase polymerase amplification and lateral flow analysis.

BACKGROUND: Nucleic acid amplification is the most sensitive and specific method to detect Plasmodium falciparum. However the polymerase chain reaction remains laboratory-based and has to be conducted by trained personnel. Furthermore, the power dependency for the thermocycling process and the costly equipment necessary for the read-out are difficult to cover in resource-limited settings. This study aims to develop and evaluate a combination of isothermal nucleic acid amplification and simple lateral flow dipstick detection of the malaria parasite for point-of-care testing. METHODS: A specific fragment of the 18S rRNA gene of P. falciparum was amplified in 10 min at a constant 38°C using the isothermal recombinase polymerase amplification (RPA) method. With a unique probe system added to the reaction solution, the amplification product can be visualized on a simple lateral flow strip without further labelling. The combination of these methods was tested for sensitivity and specificity with various Plasmodium and other protozoa/bacterial strains, as well as with human DNA. Additional investigations were conducted to analyse the temperature optimum, reaction speed and robustness of this assay. RESULTS: The lateral flow RPA (LF-RPA) assay exhibited a high sensitivity and specificity. Experiments confirmed a detection limit as low as 100 fg of genomic P. falciparum DNA, corresponding to a sensitivity of approximately four parasites per reaction. All investigated P. falciparum strains (n=77) were positively tested while all of the total 11 non-Plasmodium samples, showed a negative test result. The enzymatic reaction can be conducted under a broad range of conditions from 30-45°C with high inhibitory concentration of known PCR inhibitors. A time to result of 15 min from start of the reaction to read-out was determined. CONCLUSIONS: Combining the isothermal RPA and the lateral flow detection is an approach to improve molecular diagnostic for P. falciparum in resource-limited settings. The system requires none or only little instrumentation for the nucleic acid amplification reaction and the read-out is possible with the naked eye. Showing the same sensitivity and specificity as comparable diagnostic methods but simultaneously increasing reaction speed and dramatically reducing assay requirements, the method has potential to become a true point-of-care test for the malaria parasite.

Microarray-based method for screening of immunogenic proteins from bacteria.

BACKGROUND: Detection of immunogenic proteins remains an important task for life sciences as it nourishes the understanding of pathogenicity, illuminates new potential vaccine candidates and broadens the spectrum of biomarkers applicable in diagnostic tools. Traditionally, immunoscreenings of expression libraries via polyclonal sera on nitrocellulose membranes or screenings of whole proteome lysates in 2-D gel electrophoresis are performed. However, these methods feature some rather inconvenient disadvantages. Screening of expression libraries to expose novel antigens from bacteria often lead to an abundance of false positive signals owing to the high cross reactivity of polyclonal antibodies towards the proteins of the expression host. A method is presented that overcomes many disadvantages of the old procedures. RESULTS: Four proteins that have previously been described as immunogenic have successfully been assessed immunogenic abilities with our method. One protein with no known immunogenic behaviour before suggested potential immunogenicity.We incorporated a fusion tag prior to our genes of interest and attached the expressed fusion proteins covalently on microarrays. This enhances the specific binding of the proteins compared to nitrocellulose. Thus, it helps to reduce the number of false positives significantly. It enables us to screen for immunogenic proteins in a shorter time, with more samples and statistical reliability. We validated our method by employing several known genes from Campylobacter jejuni NCTC 11168. CONCLUSIONS: The method presented offers a new approach for screening of bacterial expression libraries to illuminate novel proteins with immunogenic features. It could provide a powerful and attractive alternative to existing methods and help to detect and identify vaccine candidates, biomarkers and potential virulence-associated factors with immunogenic behaviour furthering the knowledge of virulence and pathogenicity of studied bacteria.

Construction of an artificial cell membrane anchor using DARC as a fitting for artificial extracellular functionalities of eukaryotic cells.

The need to functionalize cell membranes in a directed way for specific applications as single cell arrays or to force close cell-to-cell contact for artificial intercellular interaction and/or induction concerning stem cell manipulation or in general to have a tool for membrane and cell surface-associated processes, we envisaged a neutral inactive membrane anchor for extracellular entities to facillitate the above mentioned functionalities. The silent Duffy antigen/receptor for chemokines (DARC) is a receptor-like membrane protein of erythrocytes and mediates no cell transduction not at least regarding a missing or truncated G-loop and therefore it seemed to be the candidate for our cell membrane anchor. We isolated the genetic information of DARC from human genomic DNA and cloned it in a mammalian cell line as a fusion protein via a suitable plasmid vector. In this report we demonstrate that the human plasma membrane protein DARC can be used as an artificial anchor molecule in cell surface engineering applications. We constructed the fusion protein SNAP-tag-DARC, consisting of DARC and the self-labeling protein tag SNAP-tag® (Covalys). The SNAP-tag® served as an example for a molecular-technological developed protein that is artificially attached to the extracellular side of the plasma membrane through our DARC-anchor. SnapTag should serve as an example for any extracellular entity and was easy to detect by a commercial detection system. The synthesis of SNAP-tag-DARC, its correct incorporation into the cell membrane and the functionality of the SNAP-tag® were verified by RT-PCR, Western blotting and confocal fluorescence microscopy and showed the desired functionality as an membrane anchor for an extracellular application entity.

Detection of Trichinella spiralis, T. britovi and T. pseudospiralis in muscle tissue with real-time PCR.

Infections caused by Trichinella species occur throughout the world in many wild and domestic animals resulting in trichinellosis in men. In Europe, domestic pigs are predominantly infected by three Trichinella species: T. spiralis, T. britovi and T. pseudospiralis. Present methods for detection of Trichinella spp. (compressorium method, artificial digestion) do not always sufficiently recognize Trichinella larvae and these techniques are labor-intensive, time consuming and do not differentiate isolates on the species level since there are no distinguishing morphological features. Additionally, conventional PCRs cannot quantify numbers of larvae in infectious material. In order to better meet these requirements, we developed a real-time PCR assay for the accurate, rapid and specific identification of the three common European species of the genus Trichinella. The assay targets the large subunit of the mitochondrial rRNA (rrnL) and enables sensitive determination and discrimination of larvae in muscle tissue samples. The real-time PCR assay was developed and validated using reference and field strains from T. spiralis, T. britovi and T. pseudospiralis. In the described real-time PCR assay, the melting points of specific amplificates were always discernable via the melting curve from melting points of unspecific amplificates. This is important for the methods workflow because only C(T) values connected with the additional melting curve analysis allow a distinction of the individual species with confidence. The sensitivity of the technique enabled detection down to 0.1 Trichinella larva per gram meat sample. High disruption levels of tissues by mincing generally resulted in higher sensitivities than protocols without mincing. With its short completion time as well as accurate and specific detection of selected species this assay could become a convenient tool for the fast detection of Trichinella larvae in meat.

Reverse transcription-polymerase chain reaction on a microarray: the integrating concept of "active arrays".

In this report we describe the proof of principle of a reverse transcription polymerase chain reaction (RT-PCR) but on-chip, with immobilized specific primers using a transcriptome of mouse-muscle fibroblasts for detection of muscle-specific expression products of these cells. The isolated total mRNA was directly incubated on an array of immobilized and solubilized specific primers, which allow the amplification of certain muscle-specific RNAs via its immobilized cDNAs. In contrast to others, the immobilized cDNA-products were directly synthesized on the chip by applying covalently bound specific primers. The products were detected by the incorporated and fluorophore-modified specific primers of the subsequently synthezised second strand. In addition, this second-strand served as a further template (like the basically used mRNA) in the subsequent solid-phase-PCR to amplify first-strand cDNA copies at the remaining immobilized specific primer-probes. This is the intrinsic factor of the amplification of certain signals of this application. The specific cDNA templates of genes coding for subunits of the mouse muscle acetylcholine receptor (Chrna1, Chrnb1, Chrnd) and the genes coding for myogenin (Myog), muscle creatine kinase (Ckmm), and ATPase (Atp2a2) were amplified on a biochip by RT-PCR directly from freshly isolated mRNA. The resulting procedure allows the detection of mRNA sequences from less than 5 pg of total RNA preparations.

Epitope determination of immunogenic proteins of Neisseria gonorrhoeae.

Neisseria gonorrhoeae is the causative organism of gonorrhoea, a sexually transmitted disease that globally accounts for an estimated 80 to 100 million new infections per year. Increasing resistances to all common antibiotics used for N. gonorrhoeae treatment pose the risk of an untreatable disease. Further knowledge of ways of infection and host immune response are needed to understand the pathogen-host interaction and to discover new treatment alternatives against this disease. Therefore, detailed information about immunogenic proteins and their properties like epitope sites could advance further research in this area. In this work, we investigated immunogenic proteins of N. gonorrhoeae for linear epitopes by microarrays. Dominant linear epitopes were identified for eleven of the nineteen investigated proteins with three polyclonal rabbit antibodies from different immunisations. Identified linear epitopes were further examined for non-specific binding with antibodies to Escherichia coli and the closely related pathogen Neisseria meningitidis. On top of that, amino acids crucial for the antibody epitope binding were detected by microarray based alanine scans.

Identification of Novel Immunogenic Proteins of Neisseria gonorrhoeae by Phage Display.

Neisseria gonorrhoeae is one of the most prevalent sexually transmitted diseases worldwide with more than 100 million new infections per year. A lack of intense research over the last decades and increasing resistances to the recommended antibiotics call for a better understanding of gonococcal infection, fast diagnostics and therapeutic measures against N. gonorrhoeae. Therefore, the aim of this work was to identify novel immunogenic proteins as a first step to advance those unresolved problems. For the identification of immunogenic proteins, pHORF oligopeptide phage display libraries of the entire N. gonorrhoeae genome were constructed. Several immunogenic oligopeptides were identified using polyclonal rabbit antibodies against N. gonorrhoeae. Corresponding full-length proteins of the identified oligopeptides were expressed and their immunogenic character was verified by ELISA. The immunogenic character of six proteins was identified for the first time. Additional 13 proteins were verified as immunogenic proteins in N. gonorrhoeae.

In vitro transcription of a whole gene on a surface-coupled template.

An artificial gene was constructed combining the T7 promoter and terminator with the EGFP-gene from the plasmid pEGFP. The functionality of the construct was shown by in vitro translation. The gene-construct was immobilised on a planar glass surface. The transcription was performed on the immobilised gene and mRNA was determined by RT-PCR. Multiple use of the immobilised gene was demonstrated.

On-chip PCR amplification of very long templates using immobilized primers on glassy surfaces.

In this paper we describe a novel method for visualizing very long DNA fragments (for example >6 kb) which are difficult to spot with commonly used arrayers or capillary samplers with very small nanoliter volumes, using directly bound primers on "on-chip" polymerase chain reaction (PCR). We have used the genomes of the M13 bacteriophage (7.2 kb) the human mitochondrion (16.5 kb) as examples of long DNA templates to test the PCR and were able to elicit robust reactivity. Over 75% of the immobilized primers could be elongated to their fullest extent. In addition we were able to elicit the PCR reaction with double stranded templates in which one primer was immobilized and the other suspended in the reaction solution. These synthesized PCR products were visualized by either confocal microarray scanning or fluorescence microscopy using Cy5-dye fluorescence of the modified free primer, or the fluorescence of intercalating dyes.

Chemically synthesized zinc finger molecules as nano-addressable probes for double-stranded DNAs.

Our experiments describe an alternative method of dsDNA recognition using zinc finger (ZF) molecules which bind DNA specifically and with high affinity. Our aim was to develop zinc finger probes which are able to bind to dsDNA molecules at predetermined sites. In our basic approach we used pairs of complementary oligonucleotides to form dsDNAs, containing one of the three SP1-transcription factor motifs as a zinc finger recognition site. Two zinc finger probes of the SP1 motif were chemically synthesized and modified with a Dy-633 fluorophore. The SP1 peptides were folded into functional zinc fingers using zinc chloride. The addressable dsDNAs were immobilized on optical fibres, and the kinetics and binding rates of the artificial zinc finger probes were measured by a fluorescence detecting device (photomultiplying tube). The two zinc fingers and their corresponding DNA recognition sites served as specific probes and controls for the matching site and vice versa. Our experiments showed that a variety of dsDNA-binding probes may be created by modification of the amino acid sequence of natural zinc finger proteins. Our findings offer an alternative approach of addressing dsDNA molecules, for example for use in a nanoarray device.

Two-dye based arrayed primer extension for simultaneous multigene detection in lipid metabolism.

BACKGROUND: Cardiovascular disease (CVD) is one of the major causes of death worldwide. Numerous genetic risk factors in lipid metabolism, including mutations of LDLR, APOB, and PCSK9, as well as polymorphisms of CETP and APOE, have been found to associate with CVD. METHODS: In this study, a two-dye based arrayed primer extension (APEX) microarray assay for simultaneous multigene (LDLR, APOB, PCSK9, CETP, and APOE) detection was developed. The DNA templates, originating from 1 DNA sample of known genotype and 7 blind DNA samples, were amplified by uniplex PCR. RESULTS: Optimized conditions for the APEX reaction were determined to include a hybridization temperature of 55°C and a DNA template size of 50-150bp. The total assay including PCR, purification, fragmentation, APEX reaction, and image analysis could be performed in 6h. In total, 48 genotypes were identified among 8 individual DNA samples by APEX analysis. CONCLUSIONS: The data suggest that this APEX microarray offers a robust, fast, and versatile option for screening these genotypes in hypercholesterolemia patients.

Molecular confirmation of human alveolar echinococcosis in Poland.

Infections of humans with Echinococcus multilocularis, the causative agent of alveolar echinococcosis (AE), a zoonosis, have been described with increasing frequency in Poland since 1994. In the attempt to verify these reports, we analyzed specimens obtained from a representative group of Polish patients. Liver lesions in patients with AE that was diagnosed on the basis of results of histological and serological tests contained E. multilocularis DNA, as shown by the presence of specific microsatellite sequences and mitochondrial 12S rDNA. The same tests clearly distinguished between AE and cystic echinococcosis, which is caused by Echinococcus granulosus. These data are unequivocal proof that human infections with E. multilocularis occur in Poland.

Identification of antigenic proteins of the nosocomial pathogen Klebsiella pneumoniae.

The continuous expansion of nosocomial infections around the globe has become a precarious situation. Key challenges include mounting dissemination of multiple resistances to antibiotics, the easy transmission and the growing mortality rates of hospital-acquired bacterial diseases. Thus, new ways to rapidly detect these infections are vital. Consequently, researchers around the globe pursue innovative approaches for point-of-care devices. In many cases the specific interaction of an antigen and a corresponding antibody is pivotal. However, the knowledge about suitable antigens is lacking. The aim of this study was to identify novel antigens as specific diagnostic markers. Additionally, these proteins might be aptly used for the generation of vaccines to improve current treatment options. Hence, a cDNA-based expression library was constructed and screened via microarrays to detect novel antigens of Klebsiella pneumoniae, a prominent agent of nosocomial infections well-known for its extensive antibiotics resistance, especially by extended-spectrum beta-lactamases (ESBL). After screening 1536 clones, 14 previously unknown immunogenic proteins were identified. Subsequently, each protein was expressed in full-length and its immunodominant character examined by ELISA and microarray analyses. Consequently, six proteins were selected for epitope mapping and three thereof possessed linear epitopes. After specificity analysis, homology survey and 3d structural modelling, one epitope sequence GAVVALSTTFA of KPN_00363, an ion channel protein, was identified harboring specificity for K. pneumoniae. The remaining epitopes showed ambiguous results regarding the specificity for K. pneumoniae. The approach adopted herein has been successfully utilized to discover novel antigens of Campylobacter jejuni and Salmonella enterica antigens before. Now, we have transferred this knowledge to the key nosocomial agent, K. pneumoniae. By identifying several novel antigens and their linear epitope sites, we have paved the way for crucial future research and applications including the design of point-of-care devices, vaccine development and serological screenings for a highly relevant nosocomial pathogen.

Rapid identification of novel antigens of Salmonella Enteritidis by microarray-based immunoscreening.

We report on an approach to rapidly screen thousands of Salmonella Enteritidis proteins with the goal of identifying novel immunodominant proteins. We used a microarray-based system that warrants high throughput and easy handling. Seven immunogenic candidates were selected after screening. Comparative analyses by ELISA and microarrays manifested their immunodominant character. The large repetitive protein (SEN4030) that plays a role as a putative adhesin in initial cell surface interaction and is highly specific to Salmonella is considered to be the most suitable protein for a diagnostic approach. The results further demonstrate that the strategy applied herein is convenient for specifically identifying immunogenic proteins of pathogenic microorganisms. Consequently, it enables a sound assessment of promising candidates for diagnostic applications and vaccine development. Moreover, the elucidation of immunogenic proteins may assist in unveiling unknown virulence-associated factors, thus furthering the understanding of the underlying pathogenicity of Salmonella in general, and of S. Enteritidis, one of the most frequently detected serovars of this pathogen, in particular. FigureThe microarray-based approach was aimed at identifying novel immunodominant proteins of S. Enteritidis. Seven antigens were revealed by screening a cDNA expression library. SEN4030, a large repetitive protein specific for salmonella, is considered an optimal candidate for future applications.

Multiplex isothermal solid-phase recombinase polymerase amplification for the specific and fast DNA-based detection of three bacterial pathogens.

We report on the development of an on-chip RPA (recombinase polymerase amplification) with simultaneous multiplex isothermal amplification and detection on a solid surface. The isothermal RPA was applied to amplify specific target sequences from the pathogens Neisseria gonorrhoeae, Salmonella enterica and methicillin-resistant Staphylococcus aureus (MRSA) using genomic DNA. Additionally, a positive plasmid control was established as an internal control. The four targets were amplified simultaneously in a quadruplex reaction. The amplicon is labeled during on-chip RPA by reverse oligonucleotide primers coupled to a fluorophore. Both amplification and spatially resolved signal generation take place on immobilized forward primers bount to expoxy-silanized glass surfaces in a pump-driven hybridization chamber. The combination of microarray technology and sensitive isothermal nucleic acid amplification at 38 °C allows for a multiparameter analysis on a rather small area. The on-chip RPA was characterized in terms of reaction time, sensitivity and inhibitory conditions. A successful enzymatic reaction is completed in <20 min and results in detection limits of 10 colony-forming units for methicillin-resistant Staphylococcus aureus and Salmonella enterica and 100 colony-forming units for Neisseria gonorrhoeae. The results show this method to be useful with respect to point-of-care testing and to enable simplified and miniaturized nucleic acid-based diagnostics. FigureThe combination of multiplex isothermal nucleic acid amplification with RPA and spatially-resolved signal generation on specific immobilized oligonucleotides.

Rapid identification of novel immunodominant proteins and characterization of a specific linear epitope of Campylobacter jejuni.

Campylobacter jejuni remains one of the major gut pathogens of our time. Its zoonotic nature and wide-spread distribution in industrialized countries calls for a quick and reliable diagnostic tool. Antibody-based detection presents a suitable means to identify pathogenic bacteria. However, the knowledge about immunodominant targets is limited. Thus, an approach is presented, which allows for the rapid screening of numerous cDNA derived expression clones to identify novel antigens. The deeper understanding of immunodominant proteins assists in the design of diagnostic tools and furthers the insight into the bacterium's pathogenicity as well as revealing potential candidates for vaccination. We have successfully screened 1536 clones of an expression library to identify 22 proteins that have not been described as immunodominant before. After subcloning the corresponding 22 genes and expression of full-length proteins, we investigated the immunodominant character by microarrays and ELISA. Subsequently, seven proteins were selected for epitope mapping. For cj0669 and cj0920c linear epitopes were identified. For cj0669, specificity assays revealed a specific linear epitope site. Consequently, an eleven amino acid residue sequence TLIKELKRLGI was analyzed via alanine scan, which revealed the glycine residue to be significant for binding of the antibody. The innovative approach presented herein of generating cDNAs of prokaryotes in combination with a microarray platform rendering time-consuming purification steps obsolete has helped to illuminate novel immunodominant proteins of C.jejuni. The findings of a specific linear epitope pave the way for a plethora of future research and the potential use in diagnostic applications such as serological screenings. Moreover, the current approach is easily adaptable to other highly relevant bacteria making it a formidable tool for the future discovery of antigens and potential biomarkers. Consequently, it is desirable to simplify the identification of structural epitopes, as this would extend the spectrum of novel epitopes to be detected.