Involvement of cell surface TG2 in the aggregation of K562 cells triggered by gluten.

Gluten-induced aggregation of K562 cells represents an in vitro model reproducing the early steps occurring in the small bowel of celiac patients exposed to gliadin. Despite the clear involvement of TG2 in the activation of the antigen-presenting cells, it is not yet clear in which compartment it occurs. Herein we study the calcium-dependent aggregation of these cells, using either cell-permeable or cell-impermeable TG2 inhibitors. Gluten induces efficient aggregation when calcium is absent in the extracellular environment, while TG2 inhibitors do not restore the full aggregating potential of gluten in the presence of calcium. These findings suggest that TG2 activity is not essential in the cellular aggregation mechanism. We demonstrate that gluten contacts the cells and provokes their aggregation through a mechanism involving the A-gliadin peptide 31-43. This peptide also activates the cell surface associated extracellular TG2 in the absence of calcium. Using a bioinformatics approach, we identify the possible docking sites of this peptide on the open and closed TG2 structures. Peptide docks with the closed TG2 structure near to the GTP/GDP site, by establishing molecular interactions with the same amino acids involved in stabilization of GTP binding. We suggest that it may occur through the displacement of GTP, switching the TG2 structure from the closed to the active open conformation. Furthermore, docking analysis shows peptide binding with the ß-sandwich domain of the closed TG2 structure, suggesting that this region could be responsible for the different aggregating effects of gluten shown in the presence or absence of calcium. We deduce from these data a possible mechanism of action by which gluten makes contact with the cell surface, which could have possible implications in the celiac disease onset.

Peptide nucleic acids and biosensor technology for real-time detection of the cystic fibrosis W1282X mutation by surface plasmon resonance.

In this paper we demonstrate that peptide nucleic acids (PNAs) are excellent probes able to detect the W1282X point mutation of the cystic fibrosis (CF) gene when biospecific interaction analysis (BIA) by surface plasmon resonance (SPR) and biosensor technologies is performed. The results reported here suggest that BIA is an easy, fast, and automatable approach for detecting mutations of CF, allowing real-time monitoring of hybridization between 9-mer CF PNA probes and target biotinylated PCR products generated from healthy, heterozygous subjects and homozygous W1282X samples and immobilized on streptavidin-coated sensor chips. This method is, to our knowledge, the first application of PNAs, BIA, and SPR to a human hereditary mutation, and demonstrates the feasibility of these approaches for discriminating between normal and mutated target DNA. We like to point out that the procedure described in this paper is rapid and informative; results are obtained within a few minutes. This could be of great interest for molecular pre-implantation diagnosis to discriminate homozygous CF embryos from heterozygous and healthy embryos. Other advantages of the methodology described in the present paper are (a) that it is a nonradioactive methodology and (b) that gel electrophoresis and/or dot-spot analysis are not required. More importantly, the demonstration that SPR-based BIA could be associated with microarray technology allows us to hypothesize that the method described in the present paper could be used for the development of a protocol employing multispotting on SPR biosensors of many CF-PCR products and a real-time simultaneous analysis of hybridization to PNA probes. These results are in line with the concept that SPR could be an integral part of a fully automated diagnostic system based on the use of laboratory workstations, biosensors, and arrayed biosensors for DNA isolation, preparation of PCR reactions, and identification of point mutations.

Aromatic polyamidines inhibiting the Tat-induced HIV-1 transcription recognize structured TAR-RNA.

We have investigated the effects of aromatic polyamidines on HIV-1 transcription. We found a block to Tat-induced HIV-1 transcription assessed by inhibition of CAT activity in HL3T1 cells at a concentration lower than the IC50 value, suggesting that molecules with three (TAPB) and four (TAPP) benzamidine rings could be useful against HIV-1. In contrast, aromatic polyamidines with only two benzamidine rings (DAPP) did not block Tat-induced transcription. We reasoned that this effect could be due to binding of TAPB and TAPP to HIV-1 TAR RNA. By EMSA and filter binding assays, we studied possible interactions of aromatic polyamidines with HIV-1 TAR RNA. Wild-type TAR RNA or TAR RNA with mutations in the stem or bulge sequences, but retaining the stem-loop structure, was used to define the RNA-binding activities of these compounds. Our data suggest that aromatic polyamidines with two (DAPP) and four (TAPP) benzamidine rings, respectively, do not bind to TAR RNA or bind without sequence selectivity. Interestingly, an aromatic polyamidine with three benzamidine rings (TAPB) recognizes the wild-type TAR RNA in a specific manner. Furthermore, we found that introduction of one halogen atom into the benzamidine rings strongly increases the RNA-binding activity of these compounds.

Biosensor technology for real-time detection of the cystic fibrosis W1282X mutation in CFTR.

In the present paper, biospecific interaction analysis (BIA) was performed using surface plasmon resonance (SPR) and biosensor technologies to detect the Trp1282Ter mutation (W1282X) of the cystic fibrosis (CF) transmembrane conductance regulator (CFTR) gene. We first immobilized on a SA5 sensor chip a single-stranded biotinylated oligonucleotide containing the sequence involved in this mutation, and the efficiency of hybridization of oligonucleotide probes differing in length was determined. Second, we immobilized on different SA5 sensor chips biotinylated polymerase-chain reaction (PCR) products from a normal subject as well as from heterozygous and homozygous W1282X samples. The results obtained show that both allele-specific 10- and 12-mer oligonucleotides are suitable probes to detect W1282X mutations of the cystic fibrosis gene under standard BIA experimental conditions. During the association phase performed at 25 degrees C, discrimination between mismatched and full matched hybrids was readily and reproducibly observed by using the 10-mer W1282X probes. By contrast, when the 12-mer DNA probes were employed, discrimination between mismatched and full matched hybrids was observed during the dissociation phase. Taken together, the results presented suggest that BIA is an easy, speedy, and automatable approach to detect point mutations leading to cystic fibrosis. By this procedure, it is possible to perform real-time monitoring of hybridization between target single stranded PCR products obtained by using as substrates DNA isolated from normal or heterozygous subjects, and homozygous W1282X CF samples and oligonucleotide probes, therefore enabling a one-step, non-radioactive protocol to perform diagnosis.

[2,1-c][1,4]benzodiazepine (PBD)-distamycin hybrid inhibits DNA binding to transcription factor Sp1.

We designed and synthesized the hybrid 6, prepared combining the minor groove binders distamycin A and pyrrolo [2,1-c][1,4] benzodiazepine (PBD) 4, related to the natural occurring anthramycin (2) and DC-81 (3). In this paper, the effects of the compound 6 on molecular interactions between DNA and transcription factor Sp1 were studied. The results obtained demonstrate that PBD-distamycin hybrid is a powerful inhibitor of Sp1/DNA interactions.

Molecular cloning, expression, functional characterization, chromosomal localization, and gene structure of junctate, a novel integral calcium binding protein of sarco(endo)plasmic reticulum membrane.

Screening a cDNA library from human skeletal muscle and cardiac muscle with a cDNA probe derived from junctin led to the isolation of two groups of cDNA clones. The first group displayed a deduced amino acid sequence that is 84% identical to that of dog heart junctin, whereas the second group had a single open reading frame that encoded a polypeptide with a predicted mass of 33 kDa, whose first 78 NH(2)-terminal residues are identical to junctin whereas its COOH terminus domain is identical to aspartyl beta-hydroxylase, a member of the alpha-ketoglutarate-dependent dioxygenase family. We named the latter amino acid sequence junctate. Northern blot analysis indicates that junctate is expressed in a variety of human tissues including heart, pancreas, brain, lung, liver, kidney, and skeletal muscle. Fluorescence in situ hybridization analysis revealed that the genetic loci of junctin and junctate map to the same cytogenetic band on human chromosome 8. Analysis of intron/exon boundaries of the genomic BAC clones demonstrate that junctin, junctate, and aspartyl beta-hydroxylase result from alternative splicing of the same gene. The predicted lumenal portion of junctate is enriched in negatively charged residues and is able to bind calcium. Scatchard analysis of equilibrium (45)Ca(2+) binding in the presence of a physiological concentration of KCl demonstrate that junctate binds 21.0 mol of Ca(2+)/mol protein with a k(D) of 217 +/- 20 microm (n = 5). Tagging recombinant junctate with green fluorescent protein and expressing the chimeric polypeptide in COS-7-transfected cells indicates that junctate is located in endoplasmic reticulum membranes and that its presence increases the peak amplitude and transient calcium released by activation of surface membrane receptors coupled to InsP(3) receptor activation. Our study shows that alternative splicing of the same gene generates the following functionally distinct proteins: an enzyme (aspartyl beta-hydroxylase), a structural protein of SR (junctin), and a membrane-bound calcium binding protein (junctate).

Characterization of a major histocompatibility complex class II X-box-binding protein enhancing tat-induced transcription directed by the human immunodeficiency virus type 1 long terminal repeat.

The X-box element present within the promoter region of genes belonging to the major histocompatibility complex (MHC) plays a pivotal role in the expression of class II molecules, since it contains the binding sites for several well-characterized transcription factors. We have analyzed a randomly selected compilation of viral genomes for the presence of elements homologous to the X box of the HLA-DRA gene. We found that human immunodeficiency virus type 1 (HIV-1) shows the highest frequency of X-like box elements per 1,000 bases of genome. Within the HIV-1 genome, we found an X-like motif in the TAR region of the HIV-1 long terminal repeat (LTR), a regulative region playing a pivotal role in Tat-induced HIV-1 transcription. The use of a decoy approach for nuclear proteins binding to this element, namely, XMAS (X-like motif activator sequence), performed by transfection of multiple copies of this sequence into cells carrying an integrated LTR-chloramphenicol acetyltransferase construct, suggests that this element binds to nuclear proteins that enhance Tat-induced transcription. In this report we have characterized two proteins, one binding to the XMAS motif and the other to the flanking regions of XMAS. Mobility shift assays performed on crude nuclear extracts or enriched fractions suggest that similar proteins bind to XMAS from HIV-1 and the X box of the HLA-DRA gene. Furthermore, a UV cross-linking assay suggests that one protein of 47 kDa, termed FAX (factor associated with XMAS)-1, binds to the XMAS of HIV-1. The other protein of 56 kDa was termed FAX-2. In a decoy ex vivo experiment, it was found that sequences recognizing both proteins are required to inhibit Tat-induced HIV-1 LTR-driven transcription. Taken together, the data reported in this paper suggest that XMAS and nearby sequences modulate Tat-induced HIV-1 transcription by binding to the X-box-binding proteins FAX-1 and FAX-2. The sequence homology between XMAS and X box is reflected in binding of a common protein, FAX-1, and similar functional roles in gene expression. To our knowledge, this is the first report showing that transcription factors binding to the X box of the MHC class II genes enhance the transcription of HIV-1.

Liposomes as carriers for DNA-PNA hybrids.

Peptide nucleic acids (PNAs) are DNA mimics composed of N-(2-aminoethyl)glycine units. This structure gives to PNAs (a) resistance to DNases and proteinases, (b) capacity to hybridize with high affinity to complementary sequences of single-stranded RNA and DNA, and (c) capacity to form highly stable (PNA)(2)-RNA triplexes with RNA targets. Furthermore, DNA-PNA hybrid molecules are capable to reversibly interact with DNA-binding proteins, being therefore of interest for studies on regulation of gene expression by the decoy approach. The major conclusion of this paper is that cationic liposomes are able to efficiently complexate DNA-PNA hybrid molecules and mediate their binding to target cells. Our results are of some interest, since, unlike commonly used nucleic acids analogs, PNA oligomers are not taken up spontaneously into the cells. In addition, they are not suitable for an efficient delivery with commonly used liposomal formulations. Transfection of PNA-DNA hybrid molecules to in vitro cultured cells could be of great interest to determine the applications of these new reagents to experimental alteration of gene expression.

Biospecific interaction analysis (BIA) of low-molecular weight DNA-binding drugs.

DNA-binding drugs have been reported to be able to interfere with the activity of transcription factors in a sequence-dependent manner, leading to alteration of transcription. This and similar effects could have important practical applications in the experimental therapy of many human pathologies, including neoplastic diseases and viral infections. The analysis of the biological activity of DNA-binding drugs by footprinting, gel retardation, polymerase chain reaction, and in vitro transcription studies does not allow a real time study of binding to DNA and dissociation of the generated drugs/DNA complexes. The recent development of biosensor technologies for biospecific interaction analysis (BIA) enables monitoring of a variety of molecular reactions in real-time by surface plasmon resonance (SPR). In this study, we demonstrate that molecular interactions between DNA-binding drugs (chromomycin, mithramycin, distamycin, and MEN 10567) and biotinylated target DNA probes immobilized on sensor chips is detectable by SPR technology using a commercially available biosensor. The target DNA sequences were synthetic oligonucleotides mimicking the Sp1, NF-kB, and TFIID binding sites of the long terminal repeat of the human immunodeficiency type 1 virus. The results obtained demonstrate that mithramycin/DNA complexes are less stable than chromomycin/DNA complexes; distamycin binds to both NF-kB and TATA box oligonucleotides, but distamycin/(NF-kB)DNA complexes are not stable; the distamycin analog MEN 10567 binds to the NF-kB mer and the generated drug/DNA complexes are stable. The experimental approach described in this study allows fast analysis of molecular interactions between DNA-binding drugs and selected target DNA sequences. Therefore, this method could be used to identify new drugs exhibiting differential binding activities to selected regions of viral and eukaryotic gene promoters.

Computational procedures to explain the different biological activity of DNA/DNA, DNA/PNA and PNA/PNA hybrid molecules mimicking NF-kappaB binding sites.

Peptide nucleic acids (PNA) have recently been proposed as alternative reagents in experiments aimed to the control of gene expression. In PNAs, the pseudopeptide backbone is composed of N-(2-aminoethyl)glycine units and therefore is stable in human serum and cellular extracts. PNAs hybridize with high affinity to complementary sequences of single-stranded RNA and DNA, forming Watson-Crick double helices and giving rise to highly stable (PNA)2-RNA triplexes with RNA targets. Therefore, antisense and antigene PNAs have been synthetized and characterized. The major issue of the present paper is to describe some computational procedures useful to compare the behaviour of PNA double stranded molecules and PNA/DNA hybrids with the behaviour of regular DNA duplexes in generating complexes with DNA-binding proteins. The performed computational analyses clearly allow to predict that the lack of charged phosphate groups and the different shape of helix play a critical role in the binding efficiency of NF-kappaB transcription factors. These computational analyses are in agreement with competitive gel shift and UV-cross linking experiments. These experiments demonstrate that NF-kappaB PNA/PNA hybrids do not interact efficiently with proteins recognizing the NF-kappaB binding sites in genomic sequences. In addition, the data obtained indicate that the same NF-kappaB binding proteins recognize both the NF-kappaB DNA/PNA and DNA/DNA hybrids, but the molecular complexes generated with NF-kappaB DNA/PNA hybrids are less stable than those generated with NF-kappaB target DNA/DNA molecules.

Interaction of the human NF-kappaB p52 transcription factor with DNA-PNA hybrids mimicking the NF-kappaB binding sites of the human immunodeficiency virus type 1 promoter.

We determined whether peptide nucleic acids (PNAs) are able to interact with NF-kappaB p52 transcription factor. The binding of NF-kappaB p52 to DNA-DNA, DNA-PNA, PNA-DNA, and PNA-PNA hybrid molecules carrying the NF-kappaB binding sites of human immunodeficiency type 1 long terminal repeat was studied by (i) biospecific interaction analysis (BIA) using surface plasmon resonance technology, (ii) electrophoretic mobility shift, (iii) DNase I footprinting, and (iv) UV cross-linking assays. Our results demonstrate that NF-kappaB p52 does not efficiently bind to PNA-PNA hybrids. However, a DNA-PNA hybrid molecule was found to be recognized by NF-kappaB p52, although the molecular complexes generated exhibited low stability. From the theoretical point of view, our results suggest that binding of NF-kappaB p52 protein to target DNA motifs is mainly due to contacts with bases; interactions with the DNA backbone are, however, important for stabilization of the protein-DNA complex. From the practical point of view, our results suggest that DNA-PNA hybrid can be recognized by NF-kappaB p52 protein, although with an efficiency lower than DNA-DNA NF-kappaB target molecules; therefore, our results should encourage studies on modified PNAs in order to develop potential agents for the decoy approach in gene therapy.

Analysis of the human HLA-DRA gene upstream region: evidence for a stem-loop array directed by nuclear factors.

Sequence analysis of the far-upstream region of the human HLA-DRA gene has revealed the presence of Y' and X' boxes, highly homologous to the well characterized Y and X boxes present within the proximal-promoter region. Comparison of Y, Y', X, and X' box sequences present within different class II MHC genes of different species demonstrates that these boxes are conserved during evolution, suggesting an important role in regulation of gene expression. The far-upstream region and the proximal promoter region of the class II MHC genes could be organized in secondary structures, as suggested for the EA gene, the murine counterpart of the human HLA-DRA gene. The essential feature of this model is a dimerization of the proteins binding to X and X' and/or Y and Y' boxes resulting in a loop-out of the intervening DNA and a rapprochement of the far-upstream and proximal-promoter regions, and consequently of any proteins binding to them. We set up an in vitro approach in order to determine whether proteins bound to sequences present within far-upstream and proximal-promoter regions of the human HLA-DRA gene could direct a secondary structure assembly of regulative regions. Moreover, by gel retardation and DNase I footprinting assays, we demonstrate that similar proteins bind to Y and Y' boxes and, among these proteins, NF-Y was unambiguously identified by antibody-super shift experiments. Taken together, the data presented in this paper provide evidence supporting the hypothesis that a stem-loop array of the 5'-upstream region of the human HLA-DRA gene could be directed by nuclear factors. In this manner, additional nuclear factors bound to the far region could be driven in close proximity of the transcription initiation site.

Detection of the deltaF508 (F508del) mutation of the cystic fibrosis gene by surface plasmon resonance and biosensor technology.

In the present paper, we applied surface plasmon resonance (SPR) and biosensor technologies for biospecific interaction analysis (BIA) to detect deltaF508 mutation (F508del) of the cystic fibrosis transmembrane regulator (CFTR) gene in both homozygous as well as heterozygous human subjects. The proposed method is divided into three major steps. The first step is the immobilization on a SA5 sensor chip of two biotinylated oligonucleotide probes (one normal, N-508, and the other mutant, deltaF508) that are able to hybridize to the CFTR gene region involved in F508del mutation. The second step consists of the molecular hybridization between the oligonucleotide probes immobilized on the sensor chips and (1) wild-type or mutant oligonucleotides, as well as (2) single-stranded DNA obtained by asymmetric polymerase chain reaction (PCR), performed using genomic DNA from normal individuals and from F508del heterozygous and F508del homozygous patients. The third, and most important, step consists of the evaluation of differential stabilities of DNA/DNA molecular complexes generated after hybridization of normal and deltaF508 probes immobilized on the sensor chips. The results obtained strongly suggest that the proposed procedure employing SPR technology enables a one-step, nonradioactive protocol for the molecular diagnosis of F508del mutation of the CFTR gene. This approach could be of interest in clinical genetics, as the hybridization step is oftenly required to detect microdeletions present within PCR products.

The DNA-binding drugs mithramycin and chromomycin are powerful inducers of erythroid differentiation of human K562 cells.

The human leukaemic K562 cell line can be induced in vitro to undergo erythroid differentiation by a variety of chemical compounds, including haemin, butyric acid, 5-azacytidine and cytosine arabinoside. Differentiation of K562 cells is associated with an increased expression of embryo-fetal globin genes, such as the zeta, epsilon and gamma globin genes. Therefore the K562 cell line has been proposed as a useful in vitro model system to determine the therapeutic potential of new differentiating compounds as well as to study the molecular mechanism(s) regulating changes in the expression of embryonic and fetal human globin genes. Inducers of erythroid differentiation which stimulate gamma-globin synthesis could be considered for possible use in the experimental therapy of those haematological diseases associated with a failure in the expression of adult beta-globin genes. In this paper we demonstrated that the G + C selective DNA-binding drugs chromomycin and mithramycin were powerful inducers of erythroid differentiation of K562 cells. Erythroid differentiation was associated with an increase in the accumulation of (a) Hb Gower 1 and Hb Portland and (b) gamma-globin mRNA.

Surface plasmon resonance for real-time monitoring of molecular interactions between a triple helix forming oligonucleotide and the Sp1 binding sites of human Ha-ras promoter: effects of the DNA-binding drug chromomycin.

DNA-binding molecules have been recently proposed as potential inhibitors of molecular interactions between transcription factors and target DNA sequences. Among DNA-binding drugs, chromomycin binds to GC-rich sequences of the Sp1 binding sites of the Ha-ras oncogene. These sites are also molecular targets of a triple-helix forming oligonucleotide [Sp1(Ha-ras)TFO] which is able to inhibit Ha-ras oncogene transcription. We studied molecular interactions between triple-helix forming oligonucleotides and target Sp1 binding sites of the human Ha-ras promoter in the presence of the DNA-binding drug chromomycin. This study was performed by (a) surface plasmon resonance and biosensor technology, (b) gel retardation assay and (c) magnetic capturing of molecular complexes between TFO, chromomycin and target DNA. The main conclusion of our study is that low concentrations of chromomycin allow binding of the triplex-forming oligonucleotide to Sp1 target DNA sequences of the Ha-ras oncogene promoter. Higher concentrations of this DNA-binding drug fully suppress molecular interactions between the Sp1(Ha-ras)TFO and target DNA. Additionally, low concentrations of chromomycin potentiate the effects of the Sp1(Ha-ras)TFO in inhibiting the molecular interactions between purified Sp1 transcription factor and target DNA sequences.

Biosensor technology and surface plasmon resonance for real-time detection of HIV-1 genomic sequences amplified by polymerase chain reaction.

BACKGROUND: The recent development of biosensor technologies for biospecific interaction analysis enables the monitoring of a variety of molecular reactions in real time by surface plasmon resonance (SPR). If the ligand is a biotinylated single stranded DNA, this technology could monitor DNA-DNA hybridization. This approach could be of great interest in virology, since the hybridization step is oftenly required to confirm specificity of molecular diagnosis. OBJECTIVES: To determine whether real-time molecular diagnosis of human immunodeficiency virus type I (HIV-1) could be performed using biosensors and SPR technology. STUDY DESIGN: Specific hybridization of a biotinylated HIV-1 oligonucleotide probe immobilized on a sensor chip to single stranded DNA obtained by asymmetric polymerase-chain reaction (PCR) was determined using the BIAcore biosensor. RESULTS: Direct injection of asymmetric PCR to a sensor chip carrying an internal HIV-1 oligonucleotide probe allows detection of hybridization by SPR using biosensor technology. This enabled us to apply a real-time, one-step, non-radioactive protocol to demonstrate the specificity of amplification of HIV-1 genomic sequences by PCR. CONCLUSION: The procedure described in this study for HIV-1 detection is simple, fast (PCR and SPR analyses take 30 min), reproducible and could be proposed as an integral part of automated diagnostic systems based on the use of laboratory workstations and biosensors for DNA isolation, preparation of PCR reactions and analysis of PCR products.

Targeting of the HIV-1 long terminal repeat with chromomycin potentiates the inhibitory effects of a triplex-forming oligonucleotide on Sp1-DNA interactions and in vitro transcription.

We have studied the effects of chromomycin and of a triple-helix-forming oligonucleotide (TFO) that recognizes Sp1 binding sites on protein-DNA interactions and HIV-1 transcription. Molecular interactions between chromomycin, the Sp1 TFO and target DNA sequences were studied by gel retardation, triplex affinity capture using streptavidin-coated magnetic beads and biosensor technology. We also determined whether chromomycin and a TFO recognizing the Sp1 binding sites of the HIV-1 long terminal repeat (LTR) inhibit the activity of restriction enzyme HaeIII, which recognizes a sequence (5'-GGCC-3') located within these Sp1 binding sites. The effects of chromomycin and the TFO on the interaction between nuclear proteins or purified Sp1 and a double-stranded oligonucleotide containing the Sp1 binding sites of the HIV-1 LTR were studied by gel retardation. The effects of both chromomycin and TFO on transcription were studied by using an HIV-1 LTR-directed in vitro transcription system. Our results indicate that low concentrations of chromomycin potentiate the effects of the Sp1 TFO in inhibiting protein-DNA interactions and HIV-1-LTR-directed transcription. In addition, low concentrations of chromomycin do not affect binding of the TFO to target DNA molecules. The results presented here support the hypothesis that both DNA binding drugs and TFOs can be considered as sequence-selective modifiers of DNA-protein interactions, possibly leading to specific alterations of biological functions. In particular, the combined use of chromomycin and TFOs recognizing Sp1 binding sites could be employed in order to abolish the biological functions of promoters (such as the HIV-1 LTR) whose activity is potentiated by interactions with the promoter-specific transcription factor Sp1.

Conformation and surface expression of free HLA-CW1 heavy chains in the absence of beta 2-microglobulin.

A beta 2-microglobulin (beta 2m)-deficient kidney carcinoma cell line and three monoclonal antibodies to the alpha 1 (L31), alpha 2 (W6/32), and alpha 3 (Q1/28) domain of class I HLA molecules were selected to assess the role of beta 2m in regulating the conformation and surface expression of HLA-C molecules. HLA-A2, -B27, and -CW1 molecules synthesized by beta 2m-deficient cells were compared to heavy chains synthesized in transfectants expressing a large excess of beta 2m. As assessed by differential binding with monoclonal antibodies and partitioning studies in the detergent TX-114, no HLA-A2, -B27, or -CW1 molecules can be expressed, in a correct conformation, by beta 2m-deficient cells. These cells, however, do express low but significant amounts of free HLA-CW1 heavy chains at the cell surface. Transfection with beta 2m causes a coordinate change in the antibody reactivity of the three domains of HLA-CW1 molecules, thereby providing the first experimental demonstration that assembly with beta 2m affects the folding of not only the alpha 1 and alpha 2, but also of the alpha 3 domain. HLA-CW1 heavy chains, when free of beta 2m, are less soluble in the detergent TX-114 than free HLA-B27 heavy chains, and when associated with beta 2m share an alpha 3 domain epitope with free HLA-A2 and -B27 heavy chains. Moreover, their assembly with beta 2m is largely incomplete. Those data additionally demonstrate an impaired ability of HLA-CW1 to properly fold and establish a close similarity of HLA-CW1 to murine Db and Ld molecules. Although the functional role, if any, of free HLA-CW1 heavy chains remains to be determined, the present study demonstrates that the absence of beta 2m does not completely ablate class I expression in neoplastic cells of human origin.

In vitro and in vivo binding of a CC-1065 analogue to human gene sequences: a polymerase-chain reaction study.

In this paper we analyse the in vitro sequence selectivity of the CC-1065 analogue 2-[[5-[(1H-indol-2-yl]carbonyl)-1H-indol-2-yl] carbonyl]-7-methyl-1,2,8,8a-tetrahydrocyclopropa [c]-pyrrolo-[3,2-e]-indol-4-one (U-71184) employing the polymerase-chain reaction (PCR). In addition, we determined whether alteration of PCR by U-71184 is detected when DNA is isolated from cells cultured in the presence of this drug. As molecular model systems we employed the human estrogen receptor gene, the Ha-ras oncogene and the chromosome X-linked, (CGG)-rich fragile X mental retardation-1 gene. The first conclusion that can be drawn from the experiments reported in our paper is that U-71184 inhibits PCR in a sequence-dependent manner. A second conclusion of our experiments is that PCR performed on DNA from U-71184-treated cells is inhibited when the primers amplifying the estrogen receptor gene region are used. This approach might bring important information on both in vivo uptake of the drug by target cells and binding to DNA.

Surface plasmon resonance for real-time detection of molecular interactions between chromomycin and target DNA sequences.

DNA-binding drugs interfere with the activity of a large variety of transcription factors, leading to an alteration of transcription. This and similar effects could have important practical applications in the experimental therapy of many human pathologies, including neoplastic diseases. The analysis of sequence selectivity of DNA-binding drugs by footprinting, gel retardation studies, polymerase chain reaction and in vitro transcription does not allow an easy study of kinetics of binding and dissociation. The recent development of biosensor technologies for biospecific interaction analysis (BIA) enables the monitoring of a variety of molecular reactions in real-time by surface plasmon resonance (SPR). In this report we demonstrate that molecular interactions between the DNA-binding drug chromomycin and a biotinylated GC-rich Ha-ras oligonucleotide probe immobilized on a sensor chip is detectable by SPR technology using the BIAcore(TM) biosensor. This approach appears of interest in the development of drugs exhibiting differential affinity for target DNA sequences for the following reasons: a) results are obtained within one hour; b) unlike footprinting and gel retardation studies, this technology does not require P-32-labelled probes; c) BIA allows kinetic studies of both association and dissociation.