Intravital Microscopy for Imaging Subcellular Structures in Live Mice Expressing Fluorescent Proteins

Here we describe a procedure to image subcellular structures in live rodents that is based on the use of confocal intravital microscopy. As a model organ, we use the salivary glands of live mice since they provide several advantages. First, they can be easily exposed to enable access to the optics, and stabilized to facilitate the reduction of the motion artifacts due to heartbeat and respiration. This significantly facilitates imaging and tracking small subcellular structures. Second, most of the cell populations of the salivary glands are accessible from the surface of the organ. This permits the use of confocal microscopy that has a higher spatial resolution than other techniques that have been used for in vivo imaging, such as two-photon microscopy. Finally, salivary glands can be easily manipulated pharmacologically and genetically, thus providing a robust system to investigate biological processes at a molecular level.In this study we focus on a protocol designed to follow the kinetics of the exocytosis of secretory granules in acinar cells and the dynamics of the apical plasma membrane where the secretory granules fuse upon stimulation of the beta-adrenergic receptors. Specifically, we used a transgenic mouse that co-expresses cytosolic GFP and a membrane-targeted peptide fused with the fluorescent protein tandem-Tomato. However, the procedures that we used to stabilize and image the salivary glands can be extended to other mouse models and coupled to other approaches to label in vivo cellular components, enabling the visualization of various subcellular structures, such as endosomes, lysosomes, mitochondria, and the actin cytoskeleton.     

Preparation of imidazoles as potent calcitonin gene-related peptide (CGRP) antagonists

Several new potent CGRP receptor antagonists have been prepared in which the amide bond of lead compound 1 has been replaced by bioisosteric imidazole moieties. Substitution at N-1 of the imidazole was optimized to afford compounds with comparable potency to that of lead 1. Conformational restraint of the imidazole to form tetrahydroimidazo[1,5-a]pyrazine 43 gave substantially improved permeability.     

Cloning and characterization of hTAFII18, hTAFII20 and hTAFII28: three subunits of the human transcription factor TFIID.

We have cloned cDNAs encoding three novel TAFIIs [TATA-binding protein (TBP)-associated factors] from the human (h) HeLa cell TFIID complexes hTAFII28, hTAFII20 and hTAFII18. hTAFII28 is a core hTAFII present in both of the previously described hTFIID species which either lack or contain hTAFII30 (hTFIID alpha and hTFIID beta respectively), and is the homologue of Drosophila (d)TAFII30 beta. hTAFII18 is a novel hTAFII which shows homology to the N-terminal region of the yeast TAFIISPT3, but has no known Drosophila counterpart. In contrast to hTAFII28, hTAFII18 is a TFIID beta-specific hTAFII. hTAFII20 is the homologue of p22, an alternatively spliced form of dTAFII30 alpha (p32). Using a combination of protein affinity chromatography and cotransfection and immunoprecipitation assays, we have identified a series of in vitro and intracellular interactions among the novel hTAFIIs and between the novel hTAFIIs and hTAFII30 or TBP. We show that hTAFII28 interacts with hTAFII18 both in vitro and intracellularly; in contrast to its Drosophila homologue, hTAFII28 also interacts directly with TBP. Deletion analysis indicates that TBP and hTAFII18 bind to distinct domains of hTAFII28. hTAFII18 also interacts with TBP, but it interacts more strongly with hTAFII28 and hTAFII30. The binding of hTAFII28 and hTAFII30 requires distinct domains of hTAFII18. As observed with the homologous Drosophila proteins, hTAFII20 interacts directly with TBP; however, additional interactions between hTAFII20 and hTAFII28 or hTAFII30 were detected. These results reveal differences not only in subunit composition, but also in the organization of dTFIID and hTFIID complexes.