Bimolecular Fluorescence Complementation (BiFC) Analysis of Protein-Protein Interactions and Assessment of Subcellular Localization in Live Cells.

Bimolecular fluorescence complementation (BiFC) is a fluorescence imaging technique used to visualize protein-protein interactions (PPIs) in live cells and animals. One unique application of BiFC is to reveal subcellular localization of PPIs. The superior signal-to-noise ratio of BiFC in comparison with fluorescence resonance energy transfer or bioluminescence resonance energy transfer enables its wide applications. Here, we describe how confocal microscopy can be used to detect and quantify PPIs and their subcellular localization. We use basic leucine zipper transcription factor proteins as an example to provide a step-by-step BiFC protocol using a Nikon A1 confocal microscope and NIS-Elements imaging software. The protocol given below can be readily adapted for use with other confocal microscopes or imaging software.

Usefulness of quantitative assessment of JunB gene expression as a marker for monitoring chronic myeloid leukemia patients undergoing imatinib therapy.

JunB is a component of the activator protein 1 transcription factors and has been identified to be important in hematopoiesis. Transgenic mice lacking JunB expression develop myeloproliferative disease resembling human chronic myeloid leukemia (CML). JunB expression was significantly decreased in CML patients. We used real-time quantitative reverse transcription-polymerase chain reaction analysis to monitor both JunB and BCR-ABL expression during imatinib therapy. Nineteen patients were evaluated every 2 to 4 weeks, and their levels of JunB expression before therapy were significantly decreased compared with those of healthy individuals. After imatinib therapy, an increase in JunB expression was found in 5 patients, all of whom achieved a complete cytogenetic response (CCR) and molecular response (MR), with a decrease in BCR-ABL expression. JunB expression decreased to a very low level in 2 patients, both of whom showed progression to blast crisis. Variable JunB expression was found in the other 12 patients, and their outcomes were mostly driven by BCR-ABL levels. The patients with an increase in JunB expression were statistically more likely to achieve a major cytogenetic response (P = .045), CCR (P = .033), and MR (P = .033) than the group with no increase in JunB expression, and a durable response was observed. This study revealed that an increase in JunB expression is a good prognostic marker for predicting clinical response in CML patients treated with imatinib when such data are combined with an evaluation of BCR-ABL expression.

Assessment of the role of activator protein-1 on transcription of the mouse steroidogenic acute regulatory protein gene.

cAMP-dependent mechanisms regulate the steroidogenic acute regulatory (StAR) protein even though its promoter lacks a consensus cAMP response-element (CRE, TGACGTCA). Transcriptional regulation of the StAR gene has been demonstrated to involve combinations of DNA sequences that provide recognition motifs for sequence-specific transcription factors. We recently identified and characterized three canonical 5'-CRE half-sites within the cAMP-responsive region (-151/-1 bp) of the mouse StAR gene. Among these CRE elements, the CRE2 half-site is analogous (TGACTGA) to an activator protein-1 (AP-1) sequence [TGA(C/G)TCA]; therefore, the role of the AP-1 transcription factor was explored in StAR gene transcription. Mutation in the AP-1 element demonstrated an approximately 50% decrease in StAR reporter activity. Using EMSA, oligonucleotide probes containing an AP-1 binding site were found to specifically bind to nuclear proteins obtained from mouse MA-10 Leydig and Y-1 adrenocortical tumor cells. The integrity of the sequence-specific AP-1 element in StAR gene transcription was assessed using the AP-1 family members, Fos (c-Fos, Fra-1, Fra-2, and Fos B) and Jun (c-Jun, Jun B, and Jun D), which demonstrated the involvement of Fos and Jun in StAR gene transcription to varying degrees. Disruption of the AP-1 binding site reversed the transcriptional responses seen with Fos and Jun. EMSA studies utilizing antibodies specific to Fos and Jun demonstrated the involvement of several AP-1 family proteins. Functional assessment of Fos and Jun was further demonstrated by transfecting antisense c-Fos, Fra-1, and dominant negative forms of Fos (A-Fos) and c-Jun (TAM-67) into MA-10 cells, which significantly (P < 0.01) repressed transcription of the StAR gene. Mutation of the AP-1 site in combination with mutations in other cis-elements resulted in a further decrease of StAR promoter activity, demonstrating a functional cooperation between these factors. Mammalian two-hybrid assays revealed high-affinity protein-protein interactions between c-Fos and c-Jun with steroidogenic factor 1, GATA-4, and CCAAT/enhancer binding protein-beta. These findings demonstrate that Fos and Jun can bind to the TGACTGA element in the StAR promoter and provide novel insights into the mechanisms regulating StAR gene transcription.