Photoaffinity labeling of functionally different lysine-binding sites in human plasminogen and plasmin

Photoaffinity labeling of human plasmin using 4-azidobenzoylglycyl-L-lysine inhibits clot lysis activity, while the activity toward the active-site titrant, p-nitrophenyl-p'-guanidinobenzoate, or alpha-casein are maintained. Photoaffinity labeling of native Glu-plasminogen with the same reagent causes incorporation of approximately 1.5 mol label per mol plasminogen. This labeled plasminogen can be activated to plasmin by either urokinase or streptokinase. The resulting plasmin has full clot lysis activity and can be subsequently photoaffinity labeled with a loss of clot lysis activity. The rate of activation of labeled plasminogen by urokinase is increased relative to that of native plasminogen. epsilon-Aminocaproic acid blocks incorporation of photoaffinity label into both plasminogen and plasmin, indicating that the labeling is specific to the lysine-binding sites. The labels are located in the kringle 1+2+3 fragment in either photoaffinity-labeled plasminogen or plasmin. These results indicate that the specific lysine-binding site blocked in plasmin acts in concert with the active-site in binding and using fibrin as a substrate. This clot lysis regulating site is not available for labeling in plasminogen, but is exposed or changed upon activation to plasmin. The different lysine-binding sites labeled in plasminogen may regulate the conformation of the molecule as evidence by an enhanced rate of activation to plasmin.     

Nicking enzyme-based internal labeling of DNA at multiple loci

The labeling of biomolecules has become standard practice in molecular biosciences. Modifications are used for detection, sorting and isolation of small molecules, complexes and entire cells. We have recently reported a method for introducing internal chemical and structural modifications into kbp-sized DNA target substrates that are frequently used in single-molecule experiments. It makes use of nicking enzymes that create single-stranded DNA gaps, which can be subsequently filled with labeled oligonucleotides. Here we provide a detailed protocol and further expand this method. We show that modifications can be introduced at distant loci within one molecule in a simple one-pot reaction. In addition, we achieve labeling on both strands at a specific locus, as demonstrated by F?rster resonance energy transfer (FRET) experiments. The protocol requires an initial cloning of the target substrate (3-5 d), whereas the labeling itself takes 4-6 h. More elaborate purification and verification of label incorporation requires 2 h for each method.     

Bovine spermatozoa incorporate 32Pi into ADP by an unknown pathway.

Intact ejaculated bovine sperm incorporate 32Pi into ADP to a specific activity two to three times higher than into ATP. This contrasts with other cell types where ATP specific activity is higher than that of ADP. Predominant labeling of ADP may be partially due to compartmentation of ATP, but removal of cytosolic ATP does not change the relative labeling of ADP and ATP. Dilution of extracellular 32Pi following labeling resulted in loss of 70% of label from ADP but only 50% loss from gamma-ATP at 26 min. ADP was labeled in the absence of detectable ATP in the presence of rotenone plus antimycin. Fractionation of ejaculated sperm yielded midpieces that are depleted of adenylate kinase and have coupled respiration. ATP was labeled with 32Pi, but ADP was not in midpieces. Evidence for mitochondrial substrate level phosphorylation-supported incorporation of 32Pi into nucleotides was observed for intact sperm incubated with pyruvate and inhibitors of oxidative phosphorylation, but this activity did not occur in midpieces and does not appear to explain disproportionate labeling of ADP. We conclude that labeling of ADP in intact and permeabilized cells occurs by two pathways; one involves adenylate kinase, and the other is an unknown pathway which may be independent of ATP.     

Development of a microarray assay that measures hybridization stoichiometry in moles

Microarray data is most useful when it can be compared with other genetic detection technologies. In this report, we designed a microarray assay format that transforms raw data into a defined scientific unit (i.e., moles) by measuring the amount of array feature present and the cDNA sequence hybridized. This study profiles a mouse reference universal RNA sample on a microarray consisting of PCR products. In measuring array features, a labeled DNA sequence was designed that hybridizes to a conserved sequence that is present in every array feature. To measure the amount of cDNA sample hybridized, the RNA sample was processed to ensure consistent dye to DNA ratio for every labeled target cDNA molecule, using labeled branched dendrimers rather than by incorporation. A dye printing assay was then performed in order to correlate molecules of cyanine dye to signal intensity. We demonstrate that by using this microarray assay design, raw data can be transformed into defined scientific units, which will facilitate interpretation of other experiments, such as data deposited at the Gene Expression Omnibus and ArrayExpress.     

Comparison of different labeling methods for the production of labeled target DNA for microarray hybridization

Different labeling methods were studied to compare various approaches to the preparation of labeled target DNA for microarray experiments. The methods under investigation included a post-PCR labeling method using the Klenow fragment and a DecaLabel DNA labeling kit, the use of a Cy3-labeled forward primer in the PCR, generating either double-stranded or single-stranded PCR products, and the incorporation of Cy3-labeled dCTPs in the PCR. A microarray that had already been designed and used for the detection of microorganisms in compost was used in the study. PCR products from the organisms Burkholderia cepacia and Staphylococcus aureus were used in the comparison study, and the signals from the probes for these organisms analyzed. The highest signals were obtained when using the post-PCR labeling method, although with this method, more non-specific hybridizations were found. Single-stranded PCR products that had been labeled by the incorporation of a Cy3-labeled forward primer in the PCR were found to give the next highest signals upon hybridization for a majority of the tested probes, with less non-specific hybridizations. Hybridization with double-stranded PCR product labeled with a Cy3-labeled forward primer, or labeled by the incorporation of Cy3-labeled dCTPs resulted in acceptable signal to noise ratios for all probes except the UNIV 1389a and Burkholderia genus probes, both located toward the 3' end of the 16S rRNA gene. The comparison of the different DNA labeling methods revealed that labeling via the Cy3-forward primer approach is the most appropriate of the studied methods for the preparation of labeled target DNA for our purposes.     

PCR amplification and simultaneous digoxigenin incorporation of long DNA probes for fluorescence in situ hybridization.

Nonradioactive in situ hybridization has found widespread applications in cytogenetics. Basic requirements are DNA probes in sufficient amounts and of high specificity as well as a labeling protocol of good reproducibility. The PCR has been of fundamental importance for the amplification of DNA sequences and thus for the production of DNA probes. Meanwhile, PCR protocols for amplification of DNA have reached a high degree of automation. So far, incorporation of labeled nucleotides into these DNA probes has normally been done by nick translation. Here we show that in using the PCR, amplification of a DNA probe larger than one kilobase accompanied by simultaneous incorporation of digoxigenin-11-dUTP can be performed for in situ hybridization experiments. As an example, the DNA probe pUC 1.77 specific for the subcentromeric region q12 of chromosome number 1 was used and hybridized against metaphase chromosomes from human lymphocytes. The labeled chromosome region was detected by anti-digoxigenin-fluorescein, Fab fragments. The experiments were evaluated by digital image analysis of microphotographs.     

Comparison of fluorescent tag DNA labeling methods used for expression analysis by DNA microarrays

Gene expression profiling by DNA microarrays has found wide application in many fields of biomedical research. The protocols for this technique are not yet standardized, and for each given step in microarray analysis a number of different protocols are in use. As a consequence, results obtained in different laboratories can be difficult to compare. Of particular importance in this respect are the methods for the preparation of fluorescent cDNA probes that should quantitatively reflect the abundance of different mRNAs in the two samples to be compared. Here we systematically evaluate and compare five different published and/or commercial principles for the synthesis offluorescently labeled probes for microarray analysis (direct labeling, 77 RNA polymerase amplification, aminoallyl labeling, hapten-antibody enzymatic labeling, and 3-D multi-labeled structures). We show that individual labeling methods can significantly influence the expression pattern obtained in a microarray experiment and discuss the respective benefits and limitations of each method.     

一种标记cDNA芯片探针的新方法

探讨mRNA长片段反转录PCR技术(RT-LDPCR)在cDNA芯片微量探针标记和信号放大中的应用.首先提取BEP2D细胞的总RNA,然后用两种不同的方法进行标记,一种为RT-LDPCR,用荧光素Cy3-dCTP进行标记;另一种为传统的RNA反转录,用荧光素Cy5-dCTP进行标记.将两种方法标记好的探针等量混合后与含有440个点(44个基因)的cDNA芯片同时杂交,发现二者具有很高的一致性(0.5＜Cy3/Cy5＞2.0).由于RNA反转录法为cDNA芯片探针标记的传统方法,从而验证了RT-LDPCR用于cDNA芯片探针标记的可行性.RT-LDPCR具有对样品总RNA的需要量少和可对样品中信号进行放大的优点,特别适合于对材料来源受到限制的RNA进行标记.     

Single molecule linear analysis of DNA in nano-channel labeled with sequence specific fluorescent probes

An array of nano-channels was fabricated from silicon based semiconductor materials to stretch long, native dsDNA. Here we present a labeling scheme in which it is possible to identify the location of specific sequences along the stretched DNA molecules. The scheme proceeds by first using the strand displacement activity of the Vent (exo-) polymerase to generate single strand flaps on nicked dsDNA. These single strand flaps are hybridized with sequence specific fluorophore-labeled probes. Subsequent imaging of the DNA molecules inside a nano-channel array device allows for quantitative identification of the location of probes. The highly efficient DNA hybridization on the ss-DNA flaps is an excellent method to identify the sequence motifs of dsDNA as it gives us unique ability to control the length of the probe sequence and thus the frequency of hybridization sites on the DNA. We have also shown that this technique can be extended to a multi color labeling scheme by using different dye labeled probes or by combining with a DNA- polymerase-mediated incorporation of fluorophore-labeled nucleotides on nicking sites. Thus this labeling chemistry in conjunction with the nano-channel platform can be a powerful tool to solve complex structural variations in DNA which is of importance for both research and clinical diagnostics of genetic diseases.     

Application of fed-batch fermentation to the preparation of isotopically labeled or selenomethionyl-labeled proteins.

An increasing demand for isotopically labeled samples for spectroscopic and crystallographic studies has led to a corresponding need for effective and efficient methods for producing these samples. The present work is based on the strategy of using an isotopically labeled compound as the growth-limiting nutrient during protein expression in Escherichia coli (DE3) strains. By using dissolved O2 and agitation rate data, the cell growth, feeding of the isotopic label, induction of protein expression, and the harvest of cells can be coordinated in a feedback controlled fermenter in a simple, easily defined manner. This approach is demonstrated for the nutrient-limited production of [U-15N]- and [U-13C, U-15N]-labeled toluene 4-monooxygenase effector protein in E. coli BL21(DE3) with isotopic abundance identical to that of the labeled precursors. For selective labeling, demonstrated with selenomethionine using methionine auxotroph E. coli B834(DE3), approximately 80-85% incorporation was obtained from methionine-dependent growth of the auxotroph followed by selenomethionine feeding and protein induction upon methionine depletion. This selective labeling is accomplished in a single culture, does not require washing or resuspension, minimizes costly incorporation of label into host cell mass prior to induction, and can be easily adapted to selective labeling with other amino acids. Moreover, cell mass yield from these experiments can be readily optimized to provide the desired level of protein for a given investigation from a single growth and purification. This combination provides an efficient, controllable option for isotopic labeling experiments.     

Labeling of proteins with [35S]methionine and/or [35S]cysteine in the absence of cells

Incubation of [35S]methionine and [35S]cysteine with bovine albumin, globulin, catalase, hemoglobin, or human globulin resulted in incorporation of the 35S label into each of these proteins. Trichloroacetic acid (TCA) precipitation revealed that the percentage of label incorporated ranged from 1 to 15%. The 35S labeling was resistant to dissociation by reducing SDS-PAGE, prolonged dialysis against 4 M urea, heating, TCA precipitation, and dilution by gel filtration. The labeling effect was more efficient with [35S]cysteine than [35S]methionine. Incubation of 35S label with proteins differing in methionine and cysteine content revealed no requirement for sulfur-containing amino acids in the target protein. Protein carboxymethylation reduced but did not prevent 35S label incorporation. Amino acid analysis of labeled proteins revealed that the radioactive label was not consistently associated with an individual amino acid. Differences in the ability of various proteins to spontaneously label with these amino acids suggest caution in the interpretation of metabolic labeling experiments and the necessity for inclusion of additional controls. Alternatively, our experience indicates a potentially useful method for labeling proteins in the absence of cells.     

cDNA Labeling Strategies for Microarrays Using Fluorescent Dyes

Microarray analysis has become a key experimental tool in the study of genome‐wide patterns of gene expression. The labeling step of target molecules such as cDNA or cRNA plays a key role in a microarray experiment because the amount of mRNA is measured indirectly by the labeled molecules. In this paper, the most widely used cDNA labeling strategies in microarray experiments are reviewed in detail, including direct labeling and indirect labeling methods along with a discussion of the merits and disadvantages of these methods. Furthermore, various RNA amplification approaches were surveyed to obtain a target nucleic acid sufficient for microarray experiments from minute amounts of mRNA. Finally, the labeling strategies of commonly used microarray platforms (e.g., Affymetrix GeneChip®, CodeLink? Bioarray, Agilent and spotted microarrays) were compared.     

Rapid mass spectrometric analysis of 15N-Leu incorporation fidelity during preparation of specifically labeled NMR samples

Advances in NMR spectroscopy have enabled the study of larger proteins that typically have significant overlap in their spectra. Specific (15)N-amino acid incorporation is a powerful tool for reducing spectral overlap and attaining reliable sequential assignments. However, scrambling of the label during protein expression is a common problem. We describe a rapid method to evaluate the fidelity of specific (15)N-amino acid incorporation. The selectively labeled protein is proteolyzed, and the resulting peptides are analyzed using MALDI mass spectrometry. The (15)N incorporation is determined by analyzing the isotopic abundance of the peptides in the mass spectra using the program DEX. This analysis determined that expression with a 10-fold excess of unlabeled amino acids relative to the (15)N-amino acid prevents the scrambling of the (15)N label that is observed when equimolar amounts are used. MALDI TOF-TOF MS/MS data provide additional information that shows where the "extra" (15)N labels are incorporated, which can be useful in confirming ambiguous assignments. The described procedure provides a rapid technique to monitor the fidelity of selective labeling that does not require a lot of protein. These advantages make it an ideal way of determining optimal expression conditions for selectively labeled NMR samples.     

The Efficiency of DNA Labeling with Near-Infrared Fluorescent Dyes

The efficiency of DNA labeling was assessed for 2'-deoxyuridine 5'-triphosphate (dUTP) derivatives containing the Cy7 cyanine dye as a fluorophore. Two fluorescent Cy7-labeled dUTP analogs differed in the chemical structure of the linker between the fluorophore and nucleotide moieties. The efficiency of the polymerase chain reaction (PCR) and inhibition with modified nucleotides were estimated by real-time PCR. The efficiency of labeled nucleotide incorporation in PCR products was measured by quantitative electrophoresis. The efficiency of target DNA labeling was evaluated by binding the fluorescently labeled PCR products to a microarray of oligonucleotide probes immobilized in hydrogel drops (a biochip). The near-infrared hybridization signal was detected by digital luminescence microscopy. An increase in linker length was found to provide more efficient incorporation of the labeled nucleotide. Both of the compounds provided high sensitivity and high specificity of DNA testing via allele-specific hybridization on a biochip.