Banking of biological fluids for studies of disease-associated protein biomarkers

With the increasing demand of providing personalized medicine the need for biobanking of biological material from individual patients has increased. Such samples are essential for molecular research aimed at characterizing diseases at several levels ranging from epidemiology and diagnostic and prognostic classification to prediction of response to therapy. Clinically validated biomarkers may provide information to be used for diagnosis, screening, evaluation of risk/predisposition, assessment of prognosis, monitoring (recurrence of disease), and prediction of response to treatment and as a surrogate response marker. Many types of biological fluids or tissues can be collected and stored in biorepositories. Samples of blood can be further processed into plasma and serum, and tissue pieces can be either frozen or fixed in formalin and then embedded into paraffin. The present review focuses on biological fluids, especially serum and plasma, intended for study of protein biomarkers. In biomarker studies the process from the decision to take a sample from an individual to the moment the sample is safely placed in the biobank consists of several phases including collection of samples, transport of the samples, and handling and storage of samples. Critical points in each step important for high quality biomarker studies are described in this review. Failure to develop and adhere to robust standardized protocols may have significant consequences as the quality of the material stored in the biobank as well as conclusions and clinical recommendations based on analysis of such material may be severely affected.     

Major histocompatibility complex class II polymorphisms in Macaca mulatta: factors influencing comprehensive genotyping of Macaca mulatta (Mamu)-DQA1 alleles by PCR-RFLP in archival samples.

In the last 5 years, HLA class II genotyping methods have been adapted for genotyping of class II loci in rhesus macaques. Since previously published typing protocols were used on samples that were collected and stored under ideal conditions, it was of interest to determine if these methods were adequate for genotyping a large collection of archival samples from which DNA had been isolated and stored under various conditions. Established macaque DQA1 typing protocols were modified to optimize the typing procedure and enhance the ability to successfully genotype DNA from samples that were of poor quality and/or quantity. Long-term storage of whole-blood buffy coats or stored DNA extracted from whole-blood buffy coats did not affect typing success; however, amplification and typing of DNA extracted from archival samples of plasma were difficult and resulted in a low success rate. This suggests that amplification and DQA1-genotyping of archival samples is possible with a modified protocol, but is influenced by the age and source of the sample, and to a lesser extent, the method used to extract DNA from sample substrates.     

Paper-based archiving of mammalian and plant samples for RNA analysis

The ability to archive biological samples for subsequent nucleic acid analysis is essential for tissue specimens and forensic samples. FTA Card is a chemically treated filter paper designed for the collection and room temperature storage of biological samples for subsequent DNA analysis. Its usefulness for the preservation of biological samples for subsequent RNA analysis was tested. Here, we demonstrate that RNA in biological samples stored on FTA Cards is stable and can be used successfully for RT-PCR and northern blot analysis. RNA stability depends on the storage temperature and the type of biological specimen. RNA in mammalian cells stored on FTA Cards is stable for over one year at temperatures at or below -20 degrees C and for two to three months in samples stored at room temperature. For plant leaf, longer storage times (> 5 days) require temperatures at or below -70 degrees C following sample application. FTA Cards may constitute a method not only for convenient collection and storage of biological samples but also for rapid RT-PCR analysis of tissue and cell samples.     

Visualizing Proteins and Macromolecular Complexes by Negative Stain EM: from Grid Preparation to Image Acquisition

Single particle electron microscopy (EM), of both negative stained or frozen hydrated biological samples, has become a versatile tool in structural biology ¹. In recent years, this method has achieved great success in studying structures of proteins and macromolecular complexes ^{2, 3}. Compared with electron cryomicroscopy (cryoEM), in which frozen hydrated protein samples are embedded in a thin layer of vitreous ice ⁴, negative staining is a simpler sample preparation method in which protein samples are embedded in a thin layer of dried heavy metal salt to increase specimen contrast ⁵. The enhanced contrast of negative stain EM allows examination of relatively small biological samples. In addition to determining three-dimensional (3D) structure of purified proteins or protein complexes ⁶, this method can be used for much broader purposes. For example, negative stain EM can be easily used to visualize purified protein samples, obtaining information such as homogeneity/heterogeneity of the sample, formation of protein complexes or large assemblies, or simply to evaluate the quality of a protein preparation.In this video article, we present a complete protocol for using an EM to observe negatively stained protein sample, from preparing carbon coated grids for negative stain EM to acquiring images of negatively stained sample in an electron microscope operated at 120kV accelerating voltage. These protocols have been used in our laboratory routinely and can be easily followed by novice users.     

An improved semiautomated rapid method of extracting genomic DNA for molecular marker analysis in cocoa,<Emphasis Type="Italic">Theobroma cacao</Emphasis> L

DNA extraction is a time-consuming and expensive component of molecular marker analysis, constituting about 30–60% of the total time required for sample processing. Furthermore, the procedure for extracting high-quality DNA from tree species such as cocoa differs from extraction protocols suitable for other crop plants. This is accompanied by problems in collecting leaf tissues from field-grown cocoa trees, where storage facilities are not available and where transporting samples to laboratory for immediate refrigeration is usually impossible. We preserved cocoa leaf tissues in the field in an NaCl-CTAB-azide solution (as described in Rogstad, 1992), which did not require immediate refrigeration. This method also allowed preservation of leaf tissues for a few days during transportation and protected leaf tissues from bacterial and fungal attacks. Once transported to the laboratory, the samples were stored at 4°C for almost 1 y. To isolate good-quality DNA from stored leaf tissues, a rapid semiautomated and relatively high-throughput protocol was established. The procedure followed a modified CTAB/β-mercaptoethanol method of DNA extraction in a 96-well plate, and an automated system (i.e., GenoGrinder 2000) was used to grind the leaf tissues. The quality of DNA was not affected by long storage, and the quantity obtained per sample was adequate for about 1000 PCR reactions. Thus, this method allowed isolation of about 200 samples per day at a cost of $0.60 per sample and is a relatively high-throughput, low-cost extraction compared with conventional methods that use manual grinding and/or expensive kits.     

PCR-based methylation testing for Prader-Willi or Angelman syndromes using archived fixed-cell suspensions

All Prader-Willi syndrome (PWS) and 75% of Angelman syndrome (AS) patients have specific DNA methylation pattern alterations that can be used for diagnostic evaluation. The methylation testing identifies a significantly higher proportion of patients as compared to fluorescence in situ hybridization (FISH)-based microdeletion analysis and is thus a useful diagnostic evaluation for clinically suspect, but FISH-negative, patients. We used two independent PCR-based protocols for methylation testing on fixed cell specimens archived after FISH analyses. Changes in DNA methylation due to the procedure of cell fixation were ruled out by testing control specimens before and after fixation. Then methylation testing was carried out on 20 standard fixed-cell supsensions from people suspected for PWS or AS. These fixed specimens were stored after negative FISH analysis for up to 4 years at 4 degrees C in 3:1 methanol/acetic acid. Methylation patterns associated with AS (one specimen) and with PWS (one specimen) were identified for both protocols. The observed methylation patterns were concordant with the phenotypes of the positive individuals and for the two protocols used. We have, thus, shown that archived fixed-cell suspensions from individuals suspected as PWS or AS that were negative for cytogenetic/FISH microdeletions, can now be re-evaluated with PCR-based methylation testing without the need for additional blood samples from the previously studied individuals.     

Peptidomic analysis of human blood specimens: comparison between plasma specimens and serum by differential peptide display

The human Plasma Proteome Project pilot phase aims to analyze serum and plasma specimens to elucidate specimen characteristics by various proteomic techniques to ensure sufficient sample quality for the HUPO main phase. We used our proprietary peptidomics technologies to analyze the samples distributed by HUPO. Peptidomics summarizes technologies for visualization, quantitation, and identification of the low-molecular-weight proteome (<15 kDa), the "peptidome." We analyzed all four HUPO specimens (EDTA plasma, citrate plasma, heparin plasma, and serum) from African- and Asian-American donors and compared them to in-house collected Caucasian specimens. One main finding focuses on the most suitable method of plasma specimen collection. Gentle platelet removal from plasma samples is beneficial for improved specificity. Platelet contamination or activation of platelets by low temperature prior to their removal leads to distinct and multiple peptide signals in plasma samples. Two different specimen collection protocols for platelet-poor plasma are recommended. Further emphasis is placed on the differences between plasma and serum on a peptidomic level. A large number of peptides, many of them in rather high abundance, are only present in serum and not detectable in plasma. This ex vivo generation of multiple peptides hampers discovery efforts and is caused by a variety of factors: the release of platelet-derived peptides, other peptides derived from cellular components or the clot, enzymatic activities of coagulation cascades, and other proteases. We conclude that specimen collection is a crucial step for successful peptide biomarker discovery in human blood samples. For analysis of the low-molecular-weight proteome, we recommend the use of platelet-depleted EDTA or citrate plasma.     

Differences in the ability of spermatozoa from individual boar ejaculates to withstand different semen-processing techniques

The present study aimed to evaluate the ability of spermatozoa from individual boar ejaculates to withstand different semen-processing techniques. Eighteen sperm-rich ejaculate samples from six boars (three per boar) were diluted in Beltsville Thawing Solution and split into three aliquots. The aliquots were (1) further diluted to 3×10(7) sperm/mL and stored as a liquid at 17°C for 72 h, (2) frozen-thawed (FT) at 1×10(9) sperm/mL using standard 0.5-mL straw protocols, or (3) sex-sorted with subsequent liquid storage (at 17°C for 6 h) or FT (2×10(7) sperm/mL using a standard 0.25-mL straw protocol). The sperm quality was evaluated based on total sperm motility (the CASA system), viability (plasma membrane integrity assessed using flow cytometry and the LIVE/DEAD Sperm Viability Kit), lipid peroxidation (assessed via indirect measurement of the generation of malondialdehyde (MDA) using the BIOXYTECH MDA-586 Assay Kit) and DNA fragmentation (sperm chromatin dispersion assessed using the Sperm-Sus-Halomax(?) test). Data were normalized to the values assessed for the fresh (for liquid-stored and FT samples) or the sorted semen samples (for liquid stored and the FT sorted spermatozoa). All of the four sperm-processing techniques affected sperm quality (P<0.01), regardless of the semen donor, with reduced percentages of motile and viable sperm and increased MDA generation and percentages of sperm with fragmented DNA. Significant (P<0.05) inter-boar (effect of boars within each semen-processing technique) and intra-boar (effect of semen-processing techniques within each boar) differences were evident for all of the sperm quality parameters assessed, indicating differences in the ability of spermatozoa from individual boars to withstand the semen-processing techniques. These results are the first evidence that ejaculate spermatozoa from individual boars can respond in a boar-dependent manner to different semen-processing techniques.     

AN EMPIRICAL PROTOCOL FOR WHOLE-CELL IMMUNOFLUORESCENCE OF MARINE PHYTOPLANKTON1

An immunofluorescence protocol for intracellular antigens of phytoplankton was developed empirically. Paraformaldehyde (4%) was used to fix samples for 6 h at 4° C; fixed samples can be stored in cold (–20°C) methanol for at least 1 month. We used Triton X-100, Nonidet P-40, and dimethyl sulfoxide to permeabilize the cells for antibody penetration across the cell wall and plasma membrane. After immunolabeling at room temperature, the samples were mounted on slides and could be stored at 4° C for up to 6 months without significant decay of the fluorescence. The staining was examined with an epifluorescence microscope; semiquantitative (percentage of cells with positive staining) and quantitative (staining intensity measured with an imaging system) analyses were performed. Reproducible staining was achieved for nuclear, chloroplastic, cytoplasmic, and cell surface antigens in species of Chlorophyceae, Prymnesiophyceae, Bacillariophyceae, and Dinophyceae including some field-collected samples. This protocol is advantageous to previously published protocols in that it allows relatively simple and long-term storage of fixed samples and allows staining of multiple antigens for the same sample. Although improvement on cell permeabilization is required for some species, the present protocol could prove useful for physiological or ecological studies when frequent sampling is required and immediate processing of the samples is not possible.     

Factors that drive the increasing use of FFPE tissue in basic and translational cancer research

The decision to use 10% neutral buffered formalin fixed, paraffin embedded (FFPE) archival pathology material may be dictated by the cancer research question or analytical technique, or may be governed by national ethical, legal and social implications (ELSI), biobank, and sample availability and access policy. Biobanked samples of common tumors are likely to be available, but not all samples will be annotated with treatment and outcomes data and this may limit their application. Tumors that are rare or very small exist mostly in FFPE pathology archives. Pathology departments worldwide contain millions of FFPE archival samples, but there are challenges to availability. Pathology departments lack resources for retrieving materials for research or for having pathologists select precise areas in paraffin blocks, a critical quality control step. When samples must be sourced from several pathology departments, different fixation and tissue processing approaches create variability in quality. Researchers must decide what sample quality and quality tolerance fit their specific purpose and whether sample enrichment is required. Recent publications report variable success with techniques modified to examine all common species of molecular targets in FFPE samples. Rigorous quality management may be particularly important in sample preparation for next generation sequencing and for optimizing the quality of extracted proteins for proteomics studies. Unpredictable failures, including unpublished ones, likely are related to pre-analytical factors, unstable molecular targets, biological and clinical sampling factors associated with specific tissue types or suboptimal quality management of pathology archives. Reproducible results depend on adherence to pre-analytical phase standards for molecular in vitro diagnostic analyses for DNA, RNA and in particular, extracted proteins. With continuing adaptations of techniques for application to FFPE, the potential to acquire much larger numbers of FFPE samples and the greater convenience of using FFPE in assays for precision medicine, the choice of material in the future will become increasingly biased toward FFPE samples from pathology archives. Recognition that FFPE samples may harbor greater variation in quality than frozen samples for several reasons, including variations in fixation and tissue processing, requires that FFPE results be validated provided a cohort of frozen tissue samples is available.     

Optimal molecular profiling of tissue and tissue components

Isolation of well-preserved pure cell populations is a prerequisite for sound studies of the molecular basis of any tissue-based biological phenomenon. This article reviews current methods for obtaining anatomically specific signals from molecules isolated from tissues, a basic requirement for productive linking of phenotype and genotype. The quality of samples isolated from tissue and used for molecular analysis is often glossed over or omitted from publications, making interpretation and replication of data difficult or impossible. Fortunately, recently developed techniques allow life scientists to better document and control the quality of samples used for a given assay, creating a foundation for improvement in this area. Tissue processing for molecular studies usually involves some or all of the following steps: tissue collection, gross dissection/identification, fixation, processing/embedding, storage/archiving, sectioning, staining, microdissection/annotation, and pure analyte labeling/identification and quantification. We provide a detailed comparison of some current tissue microdissection technologies, and provide detailed example protocols for tissue component handling upstream and downstream from microdissection. We also discuss some of the physical and chemical issues related to optimal tissue processing, and include methods specific to cytology specimens. We encourage each laboratory to use these as a starting point for optimization of their overall process of moving from collected tissue to high quality, appropriately anatomically tagged scientific results. In optimized protocols is a source of inefficiency in current life science research. Improvement in this area will significantly increase life science quality and productivity. The article is divided into introduction, materials, protocols, and notes sections. Because many protocols are covered in each of these sections, information relating to a single protocol is not contiguous. To get the greatest benefit from this article, readers are advised to read through the entire article first, identify protocols appropriate to their laboratory for each step in their workflow, and then reread entries in each section pertaining to each of these single protocols.     

Influence of storage conditions on MALDI‐TOF MS profiling of gingival crevicular fluid: Implications on the role of S100A8 and S100A9 for clinical and proteomic based diagnostic investigations

Gingival crevicular fluid (GCF) may be a source of diagnostic biomarkers of periodontitis/gingivitis. However, peptide fingerprints may change, depending on GCF collection, handling and storage. We evaluated how storage conditions affect the quality and the reproducibility of MALDI‐TOF profiles of this fluid. GCF was collected on paper strips from four subjects with healthy gingiva. Our findings demonstrated that sample storage conditions significantly affect GCF peptide pattern over time. Specifically, the storage of GCF immediately extracted from paper strips generates less variations in molecular profiles compared to the extraction performed after the storage. Significant spectral changes were detected for GCF samples stored at –20°C directly on the paper strips and extracted after three months, in comparison to the freshly extracted control. Noteworthy, a significant decrease in the peak area of HNP‐3, S100A8, full‐length S100A9 and its truncated form were detected after 3 months at –80°C. The alterations found in the “stored GCF” profile not only may affect the pattern‐based biomarker discovery but also make its use not adequate for in vitro diagnostic test targeting S100A8, S100A9 proposed as potential diagnostic biomarkers for periodontal disease. In summary, this study shows that the best preserved signatures were obtained for the GCF samples eluted in trifluoroacetic acid and then immediately stored at –80°C for 1 month. The wealth of information gained from our data on protein/patterns stability after storage might be helpful in defining new protocols which enable optimal preservation of GCF specimen.     

A practical guide to sample preservation and pre‐PCR processing of aquatic environmental DNA

Environmental DNA (eDNA) is rapidly growing in popularity as a tool for community assessments and species detection. While eDNA approaches are now widely applied, there is not yet agreement on best practices for sample collection and processing. Investigators looking to integrate eDNA approaches into their research programme are required to examine a growing collection of disparate studies to make an often uncertain decision about which protocols best fit their needs. To promote the application of eDNA approaches and to encourage the generation of high‐quality data, here we review the most common techniques for the collection, preservation and extraction of metazoan eDNA from water samples. Specifically, we focus on experimental studies that compare various methods and outline the numerous challenges associated with eDNA. While the diverse applications of eDNA do not lend themselves to a one‐size‐fits‐all recommendation, in most cases, capture/concentration of eDNA on cellulose nitrate filters (with pore size determined by water turbidity), followed by storage of filters in Longmire's buffer and extraction with a DNeasy Blood & Tissue Kit (or similar) has been shown to provide sufficient, high‐quality DNA. However, we also emphasize the importance of testing and optimizing protocols for the system of interest.     

Comprehensive evaluation of solution nuclear magnetic resonance spectroscopy sample preparation for helical integral membrane proteins

The preparation of high quality samples is a critical challenge for the structural characterization of helical integral membrane proteins. Solving the structures of this diverse class of proteins by solution nuclear magnetic resonance spectroscopy (NMR) requires that well-resolved 2D ¹H/¹⁵N chemical shift correlation spectra be obtained. Acquiring these spectra demands the production of samples with high levels of purity and excellent homogeneity throughout the sample. In addition, high yields of isotopically enriched protein and efficient purification protocols are required. We describe two robust sample preparation methods for preparing high quality, homogeneous samples of helical integral membrane proteins. These sample preparation protocols have been combined with screens for detergents and sample conditions leading to the efficient production of samples suitable for solution NMR spectroscopy. We have examined 18 helical integral membrane proteins, ranging in size from approximately 9 kDa to 29 kDa with 1–4 transmembrane helices, originating from a number of bacterial and viral genomes. 2D ¹H/¹⁵N chemical shift correlation spectra acquired for each protein demonstrate well-resolved resonances, and >90% detection of the predicted resonances. These results indicate that with proper sample preparation, high quality solution NMR spectra of helical integral membrane proteins can be obtained greatly enhancing the probability for structural characterization of these important proteins.     

Comparison of DNA extraction methods for PCR amplification of mitochondrial cytochrome c oxidase subunit II (COII) DNA from primate fecal samples

Mitochondrial COII DNA was amplified by PCR from total DNA extracted from field collected primate fecal samples (n=24) which had been stored without refrigeration for over 30 days. High molecular weight DNA total DNA was obtained from samples stored in 70% (v/v) ethanol, SDS lysis buffer (LB) and guanidine isothiocyanate buffer (GTB) than from samples stored in 10% formalin. Fecal DNA quality and COII amplification varied according to storage solution (formalin, ethanol, LB and GTB), extraction method (LB-based and GTB-based) and primate species (chimpanzee, baboon, human). It is recommended that fecal samples be collected in LB for DNA analysis. However, GTB-based protocols are suitable when total RNA is needed for epidemiological studies of viral diseases or gene expression analysis.     

Contaminated liquid nitrogen vapour as a risk factor in pathogen transfer

Liquid nitrogen in storage containers will gather particulate matter from the atmosphere, or the surfaces of containers placed into it, with time. Some of these accumulating particles may be pathogenic organisms and it can be demonstrated that their viability may be conserved by immersion in the liquid nitrogen. This contamination constitutes a risk to the status of stored samples that can, largely, be avoided by the use of appropriate techniques for sealing sample containers and sterilizing their outer surfaces. The present study uses fungal spores and organic crystals to demonstrate that such particles contained in liquid nitrogen are released back into the environment when nitrogen vapour cools programmable freezers or dry shippers. This demonstrates that storage in the vapour phase above liquid nitrogen still carries a real risk of sample, or facility, contamination. Regardless of the safety of the stored sample, this is a potential source of cross-contamination between repositories or experimental sites, both locally and internationally, that could have serious consequences in clinical and agricultural situations. This study provides evidence to suggest that this possibility, as yet unquantified, should be included in risk analysis of storage protocols for reproductive materials. The risk becomes diverse when, for example, semen and embryos are frozen at an agricultural site and the dry shipper can co-transport spores of contaminating crop plant pathogens to the destination site.     

Genome-Wide Massively Parallel Sequencing of Formaldehyde Fixed-Paraffin Embedded (FFPE) Tumor Tissues for Copy-Number- and Mutation-Analysis

Background

Cancer re-sequencing programs rely on DNA isolated from fresh snap frozen tissues, the preparation of which is combined with additional preservation efforts. Tissue samples at pathology departments are routinely stored as formalin-fixed and paraffin-embedded (FFPE) samples and their use would open up access to a variety of clinical trials. However, FFPE preparation is incompatible with many down-stream molecular biology techniques such as PCR based amplification methods and gene expression studies.

Methodology/Principal Findings

Here we investigated the sample quality requirements of FFPE tissues for massively parallel short-read sequencing approaches. We evaluated key variables of pre-fixation, fixation related and post-fixation processes that occur in routine medical service (e.g. degree of autolysis, duration of fixation and of storage). We also investigated the influence of tissue storage time on sequencing quality by using material that was up to 18 years old. Finally, we analyzed normal and tumor breast tissues using the Sequencing by Synthesis technique (Illumina Genome Analyzer, Solexa) to simultaneously localize genome-wide copy number alterations and to detect genomic variations such as substitutions and point-deletions and/or insertions in FFPE tissue samples.

Conclusions/Significance

The application of second generation sequencing techniques on small amounts of FFPE material opens up the possibility to analyze tissue samples which have been collected during routine clinical work as well as in the context of clinical trials. This is in particular important since FFPE samples are amply available from surgical tumor resections and histopathological diagnosis, and comprise tissue from precursor lesions, primary tumors, lymphogenic and/or hematogenic metastases. Large-scale studies using this tissue material will result in a better prediction of the prognosis of cancer patients and the early identification of patients which will respond to therapy.     

Survival of Xiphinema index in clay loam soil

A sample of clay loam vineyard soil, containing the nematode Xiphinema index, was divided into equal portions and stored in plastic bags. Nematodes were extracted immediately or remained in fridge for a short time or at room temperature for longer periods. The number of extracted nematodes did not differ significantly between treatments, indicating that X. index in soil samples collected for diagnostic purposes could remain viable for a period up to six months. Four other samples, of similar soil type, were collected from different vineyards and kept stored in plastic bags at room temperature. Variable periods of nematode survival recorded, ranging from less than two years in one sample, up to five years in another one. It is concluded that a long fallow period of at least five years may be required between successive grapevine crops to eliminate the nematode from clay loam soils.     

On detection of pseudo-nitzschia (bacillariophyceae) species using whole cell hybridization: sample fixation and stability

Some species within the genus Pseudo‐nitzschia H. Peragallo are associated with production of domoic acid, the agent responsible for amnesic shellfish poisoning (ASP). Identification and enumeration of particular Pseudo‐nitzschia in natural populations is often difficult and time consuming because of the need for detailed morphological observations, which often require scanning or transmission electron microscopy. In earlier publications we described the development of large subunit ribosomal RNA (LSU rRNA)‐targeted fluorescent DNA probes for discriminating among a variety of Pseudo‐nitzschia species collected from Monterey Bay, California. Probes are applied using whole cell hybridization and a custom filtration manifold, enabling rapid identification and quantification of target species in cultured as well as field samples. In this work we compared a variety of preservation techniques and assessed the stability of stored samples with respect to their reactivity towards the probes. Of the preservatives tested, a saline ethanol‐based treatment gave the best results in terms of probes yielding a bright and uniform cell label. Culture samples treated with this fixative continued to react well with the probes for at least 6 weeks post‐fixation whether stored in the preservative or dried post‐preservation, with samples being kept at either room temperature or ?20° C. Likewise, field samples containing a variety of diatoms and dinoflagellate species stored in the saline ethanol solution at room temperature were also stable for at least 4–6 weeks, reacting brilliantly towards a positive control probe. After prolonged storage, however, cell reactivity towards the probes diminished dramatically. Post‐hybridization, samples stored at 4° C were found to retain their fluorescence for at least 1 week. These results indicate a wider window of opportunity for Pseudo‐nitzschia analysis using whole cell hybridization than previously reported. Sample collection, preservation, and probing protocols optimized for Pseudo‐nitzschia are also applicable to a wide range of phytoplankton species. The time required to execute the whole cell hybridization protocol was reduced by premixing probe with hybridization buffer. The premixed probe solutions as well as fixative and wash solutions are all stable at room temperature for at least 6 weeks. Application of two different species‐specific probes, each labeled with a different fluorochrome, allowed detection of two species on a single filter. The latter could be adopted in the future to increase the rate of sample processing and decrease the cost of sample analysis.     

Probing chromatin with the scanning force microscope

With the scanning force microscope (SFM), one can image the topography of biological material adsorbed at air-solid or liquid-solid interfaces with up to nanometer resolution. In principle, fixation, contrast enhancement, and labeling are not required. We have adapted specimen preparation techniques of conventional electron microscopy for visualizing chromatin ultra-structures in the SFM. A beaded substructure of the nucleoprotein filament was obtained after hypotonic lysis of chicken erythrocytes and air drying. The beads-on-astring morphology of the basic nucleosomal assembly was well delineated. The nucleosomes appeared as round protrusions with an apparent height of 4–6 nm. The histogram of center-to-center distances between adjacent nucleosome cores along the filament axis had a peak at 30 nm. Reversible changes in the three-dimensional structure were observed upon exposure of airdried samples of metaphase chromosomes to solutions of different ionic strengths.