Electrophoretic Transfer Research Articles

Western blotting of high and low molecular weight proteins using heat.

A method for the electrophoretic transfer of high and low molecular weight proteins to nitrocellulose membranes following sodium dodecyl sulfate (SDS) polyacrylamide gel is described here. The transfer was performed with heated (70-75 °C) normal transfer buffer from which methanol had been omitted. Complete transfer of high and low molecular weight antigens (molecular weight protein standards, a purified protein, and proteins from a human tissue extract) could be carried out in 10 min for a 7 % (0.75 mm) SDS polyacrylamide gel. For 10 and 12.5 % gels (0.75 mm) the corresponding time was 15 min. A complete transfer could be carried out in 20 min for 7, 10, and 12.5 % gels (1.5 mm gels). The permeability of the gel is increased by heat, such that the proteins trapped in the polyacrylamide gel matrix can be easily transferred to the membrane. The heat mediated transfer method was compared with a conventional transfer protocol, under similar conditions. The conventional method transferred minimal low molecular weight proteins while retaining most of the high molecular weight proteins in the gel. In summary, this procedure is particularly useful for the transfer of high molecular weight proteins, very rapid, and avoids the use of methanol.

SDS-PAGE to Immunoblot in One Hour.

An ultra-rapid method for electrophoresing proteins on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transfer of proteins to nitrocellulose membranes, and immunoblotting is described here. Electrophoresis of the autoantigens La and Ro60, as well as molecular weight standards on a 4-20 % gradient gel, was performed in about 10 min using heated (70-75 °C) normal Laemmli running buffer. Electrophoretic transfer of these proteins was achieved in 7 min using a semidry transfer method. Finally, immunoblotting of La and Ro60 was carried out in 30 min. Thus, the entire process of electrophoresis, electrotransfer, and immunoblotting could be carried out in 1 h.

Detection of antimicrobial (poly)peptides with acid urea polyacrylamide gel electrophoresis followed by Western immunoblot.

Antimicrobial (poly)peptides (AMPs) are ancient key effector molecules of innate host defense and have been identified in mammals, insects, plants, and even fungi (Nakatsuji and Gallo, J Invest Dermatol, 132: 887-895, 2012). They exhibit a cationic net charge at physiological pH and are rich in hydrophobic amino acids (Dufourc et al., Curr Protein Pept Sci, 13: 620-631, 2012). Their mode of action has been best investigated in bacteria. When assuming secondary structure the cationic and hydrophobic amino acids are sequestered creating a bipartitioned molecule in which the cationic amino acids mediate initial electrostatic interaction with the negatively charged bacterial surface and the hydrophobic amino acids mediate embedding into the bacterial membranes followed by a multitude of effects interfering with bacterial viability (Nicolas, FEBS J, 276: 6483-6496, 2009; Padovan et al., Curr Protein Pept Sci, 11: 210-219, 2010). However, immunomodulatory, antitumor, and other effects have been added to the ever increasing list of AMP functions (Pushpanathan et al., Int J Pept, 2013: 675391, 2013). Several classes of AMPs have been distinguished based on structure, namely anti-parallel beta-sheet, alpha-helical, circular, as well as disulfide bridge connectivity (Bond and Khalid, Protein Pept Lett, 17: 1313-1327, 2010). Many of the AMPs undergo posttranslational modification including further proteolysis. Biochemical analysis at the protein level is of great interest for a wide range of scientists and important when studying host-pathogen interaction, for example Salmonella invasion of the small intestine. Acid-urea polyacrylamide gel electrophoresis (AU-PAGE) followed by Western immunoblotting is an important tool for the identification and quantification of cationic AMPs. The protocol for these procedures outlined here describes, in detail, the necessary steps; including pouring the AU-gels, preparing the test samples, performing the electrophoretic separation and protein transfer to the membrane, and conducting the immunodetection using an alkaline phosphatase/NBT/BCIP system. A standard SDS-PAGE in comparison with AU-PAGE and the corresponding Western immunoblot are depicted in Fig. 1.

Northern blots for small RNAs and microRNAs.

This protocol describes the detection of small RNAs (~10-200 nucleotides) by blot hybridization. The RNA samples, denatured in formamide, are separated by denaturing polyacrylamide gel electrophoresis. Because high-percentage polyacrylamide gels are required to separate RNAs in this size range, it is necessary to perform electrophoretic transfer to positively charged nylon membranes. After transfer, the immobilized RNAs are subjected to hybridization with a (32)P-radiolabeled DNA or RNA probe and detected by phosphorimaging or autoradiography. This procedure is commonly used to detect small, U-rich spliceosomal small nuclear RNAs (snRNAs) and miRNAs. It should be possible also to detect most miRNAs using high-percentage (e.g., 15%) urea-polyacrylamide gel electrophoresis.

Electrophoretic Transfer Buffer (20×)

Electrophoretic Transfer Buffer (20×)

Simultaneous semi-dry electrophoretic transfer of a wide range of differently sized proteins for immunoblotting.

Simultaneous semi-dry electrophoretic transfer of a wide range of differently sized proteins for immunoblotting.

Amino Acid Region 1000–1008 of Factor V Is a Dynamic Regulator for the Emergence of Procoagulant Activity

Single chain factor V (fV) circulates as an Mr 330,000 quiescent pro-cofactor. Removal of the B domain and generation of factor Va (fVa) are vital for procoagulant activity. We investigated the role of the basic amino acid region 1000-1008 within the B domain of fV by constructing a recombinant mutant fV molecule with all activation cleavage sites (Arg(709)/Arg(1018)/Arg(1545)) mutated to glutamine (fV(Q3)), a mutant fV molecule with region 1000-1008 deleted (fV(ΔB9)), and a mutant fV molecule containing the same deletion with activation cleavage sites changed to glutamine (fV(ΔB9/Q3)). The recombinant molecules along with wild type fV (fV(WT)) were transiently expressed in COS-7L cells, purified, and assessed for their ability to bind factor Xa (fXa) prior to and following incubation with thrombin. The data showed that fV(Q3) was severely impaired in its interaction with fXa before and after incubation with thrombin. In contrast, KD(app) values for fV(ΔB9) (0.9 nM), fVa(ΔB9) (0.4 nM), and fV(ΔB9/Q3) (0.7 nM) were similar to the affinity of fVa(WT) for fXa (0.3 nM). Two-stage clotting assays revealed that although fV(Q3) was deficient in its clotting activity, fV(ΔB9/Q3) had clotting activity comparable with fVa(WT). The kcat value of prothrombinase assembled with fV(ΔB9/Q3) was minimally affected, whereas the Km value of the reaction was increased 57-fold compared with the Km value obtained with prothrombinase assembled with fVa(WT). These findings strongly suggest that amino acid region 1000-1008 of fV is a regulatory sequence protecting the organisms from spontaneous binding to fXa and unnecessary prothrombinase complex formation, which in turn results in catastrophic physiological consequences.

Nucleic Acid Blotting: Southern and Northern

AbstractE.M. Southern invented blotting of DNA in 1975; the method was extended to RNA and named northern blotting in 1977. Southern blotting includes limited depurination, denaturation, and neutralization of the DNA in gels (where they have been separated in size by electrophoresis) and capillary transfer of the DNA onto nitrocellulose or nylon blotting membranes. For northern blotting, RNA is guarded from basic pH and RNase, denatured, separated by electrophoresis, and then blotted on to nylon blotting membranes. Either type of blot is then blocked to prevent nonspecific binding, hybridized with probe, and washed. Next, the sequences of interest are located by detecting labeled probes. One alternative method involves dot/slot blotting when the size of the nucleic acid being probed is not of interest. Also, electrophoretic transfer from polyacrylamide gels can be used when the nucleic acid fragments of interest are too small to be resolved on agarose gels. Artifacts in Southern blot can result from incomplete digestion, overloading the blotting membrane, incomplete blocking, damaged blot media, and air bubbles. In northern blotting, RNA quality must be monitored, and RNA that is degraded or contaminated with excess DNA should be avoided. Curr. Protoc. Essential Lab. Tech. 6:8.2.1‐8.2.26. © 2012 by John Wiley & Sons, Inc.

An electrochemically enhanced solid-phase microextraction approach based on molecularly imprinted polypyrrole/multi-walled carbon nanotubes composite coating for selective extraction of fluoroquinolones in aqueous samples

In this study, an electrochemically enhanced solid-phase microextraction (EE-SPME) approach based on molecularly imprinted polypyrrole/multi-walled carbon nanotubes (MIPPy/MWCNTs) composite coating on Pt wire was developed for selective extraction of fluoroquinolone antibiotics (FQs) in aqueous samples. During the extraction, a direct current potential was applied to the MIPPy/MWCNTs/Pt fiber as working electrode in a standard three-electrode system, FQ ions suffered electrophoretic transfer to the coating surface and then entered into the shape-complimentary cavities by hydrogen-bonding and ion-exchange interactions. After EE-SPME extraction, the fiber was desorbed with desorption solvent for high-performance liquid chromatography (HPLC) analysis. Some parameters influencing EE-SPME extraction such as applied potential, extraction time, solution pH, ionic strength, and desorption solvent were optimized. EE-SPME showed good selectivity and higher extraction efficiency to FQs compared with that of traditional solid-phase microextraction. EE-SPME coupled with HPLC to determine FQs in water samples, the limits of detection (S/N=3) for the selected FQs are 0.5–1.9μgL−1. The proposed method was successfully used to the analysis of FQs spiked urine and soil samples, with recoveries of 85.1–94.2% for the urine samples and 89.8–95.5% for the soil samples.

Western Blotting via Proximity Ligation for High Performance Protein Analysis

Western blotting is a powerful and widely used method, but limitations in detection sensitivity and specificity, and dependence upon high quality antibodies to detect targeted proteins, are hurdles to overcome. The in situ proximity ligation assay, based on dual antibody recognition and powerful localized signal amplification, offers increased detection sensitivity and specificity, along with an ability to identify complex targets such as phosphorylated or interacting proteins. Here we have applied the in situ proximity ligation assay mechanism in Western blotting. This combination allowed the use of isothermal rolling circle amplification of DNA molecules formed in target-specific ligation reaction, for 16-fold or greater increase in detection sensitivity. The increased specificity because of dual antibody recognition ensured highly selective assays, detecting the specific band when combinations of two cross-reactive antitubulin antibodies were used (i.e. both producing distinct nonspecific bands in traditional Western blotting). We also demonstrated detection of phosphorylated platelet-derived growth factor receptor β by proximity ligation with one antibody directed against the receptor and another directed against the phosphorylated tyrosine residue. This avoided the need for stripping and re-probing the membrane or aligning two separate traditional blots. We demonstrate that the high-performance in situ proximity ligation-based Western blotting described herein is compatible with detection via enhanced chemiluminescence and fluorescence detection systems, and can thus be readily employed in any laboratory.

Lon Peptidase 1 (LONP1)-dependent Breakdown of Mitochondrial 5-Aminolevulinic Acid Synthase Protein by Heme in Human Liver Cells

5-Aminolevulinic acid synthase (ALAS-1) is the first rate controlling enzyme that controls cellular heme biosynthesis. Negative feedback regulation of ALAS-1 by the end product heme is well documented and provides the foundation for heme treatment of acute porphyrias, a group of diseases caused by genetic defects in the heme biosynthesis pathway and exacerbated by controlled up-regulation of ALAS-1. Heme is known to affect ALAS-1 activity by repressing gene transcription, accelerating mRNA degradation, and impeding pre-ALAS-1 mitochondrial translocation. In the current study, we examined the effect of heme on the rate of mature ALAS-1 protein turnover in human cells and tissues and explored the mediator involved in this new regulatory mechanism. We found that heme and other metalloporphyrins such as CoPP and CrPP decreased mitochondrial ALAS-1 protein through proteolysis. This degradative effect cannot be emulated by iron or free protoporphyrin, two major chemical components of the heme ring, and is independent of oxidative stress. Down-regulating the activity of mitochondrial LONP1, an ATP-dependent protease that controls the selective turnover of mitochondrial matrix proteins, with potent inhibitors and specific siRNA diminished the negative effect of heme on mitochondrial ALAS-1. Therefore, our data support the existence of a conserved heme feedback regulatory mechanism that functions on the mature form of ALAS-1 protein through the activity of a mitochondrial proteolytic system.

A laboratory exercise illustrating the sensitivity and specificity of Western blot analysis

Western blot analysis, commonly known as "Western blotting," is a standard tool in every laboratory where proteins are analyzed. It involves the separation of polypeptides in polyacrylamide gels followed by the electrophoretic transfer of the separated polypeptides onto a nitrocellulose or polyvinylidene fluoride membrane. A replica of the separated polypeptides from the gel is created on the membrane, which is then probed with antibodies or other ligands to identify specific polypeptide(s). Here, we report an undergraduate laboratory exercise involving Western blotting. During the 3-week laboratory exercise, students investigated the likelihood of the presence of a serum albumin in fruit fly (Drosophila melanogaster) homogenate, bovine calf serum (BCS), and fetal bovine serum (FBS). Students isolate proteins from fruit fly larvae and perform sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE), electrophoretic blotting, and immunoassay comparing those proteins with BCS and FBS proteins. Their results indicate that serum albumin is present in BCS and FBS but is absent in fruit flies. In the process, the specificity and sensitivity of Western blot analysis is demonstrated. The laboratory exercise can be easily incorporated into any college-level biochemistry or molecular techniques laboratory. The procedure used can be easily adapted to study other proteins.

Inositol Hexakisphosphate Kinases Induce Cell Death in Huntington Disease

Inositol pyrophosphate diphosphoinositol pentakisphosphate is ubiquitously present in mammalian cells and contains highly energetic pyrophosphate bonds. We have previously reported that inositol hexakisphosphate kinase type 2 (InsP(6)K2), which converts inositol hexakisphosphate to inositol pyrophosphate diphosphoinositol pentakisphosphate, mediates apoptotic cell death via its translocation from the nucleus to the cytoplasm. Here, we report that InsP(6)K2 is localized mainly in the cytoplasm of lymphoblast cells from patients with Huntington disease (HD), whereas this enzyme is localized in the nucleus in control lymphoblast cells. The large number of autophagosomes detected in HD lymphoblast cells is consistent with the down-regulation of Akt in response to InsP(6)K2 activation. Consistent with these observations, the overexpression of InsP(6)Ks leads to the depletion of Akt phosphorylation and the induction of cell death. These results suggest that InsP(6)K2 activation is associated with the pathogenesis of HD.

Effects of Ultraviolet-A and Riboflavin on the Interaction of Collagen and Proteoglycans during Corneal Cross-linking

Corneal cross-linking using riboflavin and ultraviolet-A (RFUVA) is a clinical treatment targeting the stroma in progressive keratoconus. The stroma contains keratocan, lumican, mimecan, and decorin, core proteins of major proteoglycans (PGs) that bind collagen fibrils, playing important roles in stromal transparency. Here, a model reaction system using purified, non-glycosylated PG core proteins in solution in vitro has been compared with reactions inside an intact cornea, ex vivo, revealing effects of RFUVA on interactions between PGs and collagen cross-linking. Irradiation with UVA and riboflavin cross-links collagen α and β chains into larger polymers. In addition, RFUVA cross-links PG core proteins, forming higher molecular weight polymers. When collagen type I is mixed with individual purified, non-glycosylated PG core proteins in solution in vitro and subjected to RFUVA, both keratocan and lumican strongly inhibit collagen cross-linking. However, mimecan and decorin do not inhibit but instead form cross-links with collagen, forming new high molecular weight polymers. In contrast, corneal glycosaminoglycans, keratan sulfate and chondroitin sulfate, in isolation from their core proteins, are not cross-linked by RFUVA and do not form cross-links with collagen. Significantly, when RFUVA is conducted on intact corneas ex vivo, both keratocan and lumican, in their natively glycosylated form, do form cross-links with collagen. Thus, RFUVA causes cross-linking of collagen molecules among themselves and PG core proteins among themselves, together with limited linkages between collagen and keratocan, lumican, mimecan, and decorin. RFUVA as a diagnostic tool reveals that keratocan and lumican core proteins interact with collagen very differently than do mimecan and decorin.

Layered electrophoretic transfer – A method for pre‐analytic processing of histological sections

Current technologies for measuring protein expression across a tissue section are based on MS or in situ detection such as immunohistochemistry. However, due to the inherent molecular complexity of tissue samples and the large dynamic range of protein expression in cells, current approaches are often unable to measure moderate- and low-abundant proteins. In addition, they do not provide information on the physico-chemical properties of the proteins studied. To address these problems, we are developing a new pre-analytic methodology termed layered electrophoretic transfer (LET) that selectively separates and processes proteins from an intact tissue section without compromising important two-dimensional histological information. LET offers two potential advantages over standard techniques: (i) A reduced complexity of the tissue proteome for subsequent analysis; (ii) An opportunity to assess the biochemical status of proteins as they exist in situ. As an initial proof-of-concept, we demonstrate here that the protein content from a mixture of molecular weight standards, human tissue lysates, and tissue sections can be successfully transferred and separated using LET, and further demonstrate that the method can be coupled with immunoblotting or MS for downstream measurements. LET technology represents a new pre-analytic tool for interrogating the proteome in tissue sections while preserving valuable spatial information.

Electrophoretic transfer protein zymography

Zymography detects and characterizes proteolytic enzymes by electrophoresis of protease-containing samples into a nonreducing sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) gel containing a copolymerized protein substrate. The usefulness of zymography for molecular weight determination and proteomic analysis is hampered by the fact that some proteases exhibit slower migration through a gel that contains substrate protein. This article introduces electrophoretic transfer protein zymography as one solution to this problem. In this technique, samples containing proteolytic enzymes are first resolved in nonreducing SDS–PAGE on a gel without protein substrate. The proteins in the resolving gel are then electrophoretically transferred to a receiving gel previously prepared with a copolymerized protein substrate. The receiving gel is then developed as a zymogram to visualize clear or lightly stained bands in a dark background. Band intensities are linearly related to the amount of protease, extending the usefulness of the technique so long as conditions for transfer and development of the zymogram are kept constant. Conditions of transfer, such as the pore sizes of resolving and receiving gels and the transfer time relative to the molecular weight of the protease, are explored.

Western Blotting

Featured Article: Burnette WN. “Western blotting”: electrophoretic transfer of proteins from sodium dodecyl sulfate–polyacrylamide gels to unmodified nitrocellulose and radiographic detection with antibody and radioiodinated protein A. Anal Biochem 1981;112:195–203. Three decades have flown by, and it is now difficult to imagine a world of biological science in which graphic representations of antigen reactions with specific antibodies did not exist. Nevertheless, the need for facilitated screening of antibody-producing hybridomas in the late 1970s gave rise to Western blotting, again validating the Swiftian dictum of necessity leading to invention. As a new member of Bob Nowinski’s laboratory at the Fred Hutchinson Cancer Research Center, I was interested in RNA tumor virus (now called “retrovirus”) protein–RNA interactions. The main thrust of the laboratory, however, was using the then-recent innovation of monoclonal antibodies to assess antigenic epitopes of retrovirus structural proteins. Contributing to this effort, I volunteered to find a means to simplify the tedious RIAs being used, which were very low–throughput methods of screening. That the invention of Western blotting was not blindingly intuitive to someone like me, who was performing Southern and Northern blots (1, 2 ) on a regular basis, perhaps seems incomprehensible now, but struggle I did. In defense of my rather amusing early efforts to develop something useful, I did quickly focus on antibody reactivity with proteins resolved by SDSPAGE. The problem inherent in melding RIAs with SDS-PAGE was that no suitable means existed to bind antibodies to antigens “fixed” (to avoid diffusion) in a porous gel matrix; elution of individual proteins from the gel still meant performing RIAs, rendering SDSPAGE nothing more than another laborious antigenpurification method. There were several “eureka moments” that occurred in rapid succession. The first—in the category of “the solution is right in front of you, stupid”—was the realization that, just like Southern and Northern blots, producing a replica of the gel-resolved proteins would facilitate handling and antibody binding. Some quick experiments suggested that conditions favoring passive capillary transfer of proteins from a gel to a nitrocellulose paper replica were slow, were inefficient, and produced unacceptable band spreading. Like Kekule’s apocryphal dream of the tail-biting serpent and the benzene ring (3 ), I was overcome, so to speak, by a flash of clarity that I might electromotively transport proteins out of an unfixed gel directly onto nitrocellulose sheets in a protein gel– destaining chamber I used almost every day. Unaware of the work of Renart et al. (4 ), I initially used diazobenzyloxymethyl-treated nitrocellulose sheets as the replica medium, as with nucleic acid blots, but soon found that unmodified sheets were more satisfactory and, moreover, required no time-consuming derivatization. Various buffer compositions, electrophoretic transfer conditions, nitrocellulose pore sizes, “blocking” agents for protein-adsorptive sites on the replica paper, antibody incubation and replica washing conditions, and the substitution of radioiodinated Staphylococcus aureus protein A for second-antibody detection of antigen–antibody complexes by radiography all were assessed in a couple of weeks. Gratifyingly, the new technique worked exactly as hoped for the specificity screening of hybridomas. It dawned on me that this methodology had potential for much greater applicability, both as a broadly applicable laboratory technique for detection of protein antigens in complex (e.g., cellular) mixtures and as a general immunodiagnostic tool. About this time, there appeared the report of Towbin et al. (5 ), describing an immunoblotting technique very similar to mine. There were, however, substantial enabling differences between the 2 methods, and I believed that Western blotting greatly simplified antigen transfer, antibody detection, and complex visualization. Undaunted, I therefore submitted my manuscript to Analytical Biochemistry, only to have it dismissed— not on the basis of the Towbin publication but because the technique was transparently obvious, made no fundamental contribution to the scientific literature, and, most damning, had been given the flippant name of “Western blotting” in honor, of course, of Edwin Southern and of the West Coast location of its invention. Word of the method continued to spread widely as a consequence of multiplicative expansion of the preprints sent to numerous colleagues. Thus, within a year of countenancing nonattributable references to my work, Analyti1 Molecular Pharmaceutics Consulting, Chapel Hill, NC. 2 This paper has been cited more than 7300 times since publication. * Address correspondence to the author at: Molecular Pharmaceutics Consulting, 85423 Dudley, Chapel Hill, NC 27517. E-mail burnetten@iname.com. Received June 3, 2010; accepted June 8, 2010. Previously published online at DOI: 10.1373/clinchem.2010.149765 Clinical Chemistry 57:2 000 – 000 (2011) Citation Classic

Angiopoietin-1 Gene Therapy Attenuates Hypertension and Target Organ Damage in Nitric Oxide Synthase Inhibited Spontaneously Hypertensive Rats

Background and ObjectivesIn our previous study, we found that the gene transfer of a potent derivative of cartilage oligomeric matrix protein Angiopoietin-1 (COMP-Ang-1) substantially prevented hypertension, microvascular rarefaction, and target organ damage in spontaneously hypertensive rats (SHRs). The purpose of the present study was to examine the role of nitric oxide (NO) in the therapeutic effects observed after COMP-Ang-1 gene transfer.Materials and MethodsTo exclude the NO-mediated effects in COMP-Ang-1 gene therapy, the SHRs were treated with an NO synthase (NOS) inhibitor, Nw-nitro-L-arginine methyl ester (L-NAME) before the electrophoretic gene transfer.ResultsThe pretreatment with L-NAME induced a severe and sustained increase in systolic blood pressure (BP) in a LacZ plasmid transferred control SHR. However, the electrophoretic transfer of a COMP-Ang-1 plasmid instead of LacZ plasmid in L-NAME-pretreated SHRs substantially blocked the development of hypertension without any significant difference in comparison with L-NAME-untreated COMP-Ang-1 plasmid transferred groups. In addition, the COMP-Ang-1 plasmid transfer substantially attenuated microvascular rarefaction and arteriole remodeling in the heart and kidney, which might account for the mild histological alterations observed in the COMP-Ang-1 plasmid transferred group, in contrast to the severe fibrosis and necrosis seen in the LacZ plasmid controls.ConclusionThese therapeutic outcomes of COMP-Ang-1 gene transfer even in NOS inhibited SHRs suggested that the antihypertensive effect of COMP-Ang-1 was not merely secondary to NO-mediated vasorelaxation, but it may be associated with its ability to protect the vascular endothelium probably via an NO-independent mechanism which serves to attenuate microvascular rarefaction and target organ damage, and also to prevent hypertension by reducing peripheral vascular resistance.

Claudin-11 expression increased in spermatogenic defect in human testes

Expression of claudin-11, which builds up blood-testis barrier (BTB), was increased in decreased spermatogenesis, including in hypospermatogenesis, spermatocytic and maturation arrest, and Sertoli cell only (SCO) testes. Increased claudin-11 immunoreactivity was observed at the inter-Sertoli tight junctions in maturation arrest and in the cytoplasm of Sertoli cells in SCO. The late spermatogenic wave may negatively regulate claudin-11 gene activation and the subcellular localization of claudin-11 in Sertoli cells, thus altering the BTB in the human testis.

Polyacrylamide Gel Photopatterning Enables Automated Protein Immunoblotting in a Two-Dimensional Microdevice

We demonstrate a two-dimensional microfluidic architecture that integrates polyacrylamide gel electrophoresis (PAGE) with immunoblotting in a fully automated format. This assay is designed to overcome performance limitations of conventional slab-gel immunoblotting, including multiple manual interventions, low-throughput transfer and blotting, and substantial consumption of reagents and sample. To unify PAGE with blotting in one device, this microfluidic approach makes use of high-resolution regional photopatterning of multiple polyacrylamide gel elements, and automated electrophoretic transport. A complete native immunoblot of free prostate specific antigen from human seminal fluid is demonstrated in less than 5 min. Further, the characterization of post-PAGE electrophoretic transfer showed high efficiency and minimal sample dispersion.