Joachim Biwersi

Fluorescent chloride indicators to assess the efficacy of CFTR cDNA delivery.

Cl(-)-sensitive fluorescent indicators have been used extensively in cell culture systems to measure the Cl(-)-transporting function of the cystic fibrosis transmembrane conductance regulator protein CFTR. These indicators have been used in establishing a surrogate end point to assess the efficacy of CFTR cDNA delivery in human gene therapy trials. The ability to measure Cl- transport with high sensitivity in small and heterogeneous tissue samples makes the use of Cl- indicators potentially attractive in gene delivery studies. In this review article, the important technical aspects of Cl- transport measurements by fluorescent indicators such as SPQ are described, applications of Cl- indicators to assay CFTR function are critically evaluated, and new methodological developments are discussed. The available Cl- indicators have been effective in quantifying Cl- transport rates in cell culture models and in vitro systems such as isolated membrane vesicles and liposomes. However, the imperfect photophysical properties of existing Cl- indicators limit their utility in performing measurements in airway tissues, where gene transfer vectors are delivered in CF gene therapy trials. The low efficiency of gene transfer and the cellular heterogeneity in airway samples pose substantial obstacles to functional measurements of CFTR expression. Significant new developments in generating long-wavelength and dual-wavelength halide indicators are described, and recommendations are proposed for the use of the indicators in gene therapy trials.

A mouse model to test the in vivo efficacy of chemical chaperones.

In vitro studies in transfected cells have indicated that chemical chaperones including glycerol (0.5-1.2 M) and trimethylamine oxide (TMAO, 50-100 mM) can correct defective trafficking of some proteins, including deltaF508 CFTR in cystic fibrosis and AQP2 mutants in nephrogenic diabetes insipidus. To develop a mouse model to test the efficacy of chemical chaperones in vivo, glycerol and TMAO were administered by intraperitoneal (i.p.), subcutaneous (s.c.), and oral routes. Glycerol and TMAO assays that utilized 1-5 microL of tail vein blood were developed. Administration by the i.p. and s.c. routes gave maximum serum glycerol concentrations of approximately 100 mM, levels that were well below the effective in vitro concentrations. Single i.p. or s.c. doses of TMAO (7 g/kg, 8% solution in water) resulted in serum [TMAO] greater than 50 mM, with a long half-life (t1/2 approximately equal to 18-21 h). Sustained high serum and tissue [TMAO] > 52 mM for 3 days was achieved by s.c. administration of TMAO (7 g/kg) in water every 8 h. Although approximately 50% of the mice died with this multiple-dose regimen, the remaining mice had nearly normal liver, renal, and pancreatic function. A lower dose of TMAO (5 g/kg) given by the s.c. route every 8 h resulted in serum [TMAO] concentration of 22 mM, a level that was well tolerated by all mice for 72 h. These mice also had high [TMAO] in urine, 400 mM. These results demonstrate that potentially therapeutic concentrations of TMAO can be sustained in mice in vivo, permitting the testing of chemical chaperones in transgenic mouse models of diseases caused by defective protein trafficking.

Imaging of endosome fusion in BHK fibroblasts based on a novel fluorimetric avidin-biotin binding assay

A fluorescence assay of in vivo endosome fusion was developed and applied to define the kinetics of endosome fusion in baby hamster kidney (BHK) fibroblasts. The assay is based on an approximately 10-fold enhancement of the green fluorescence of BODIPY-avidin upon biotin binding. The BODIPY-avidin fluorescence enhancement occurred in < 25 ms, was pH-independent, and involved a BODIPY-tryptophan interaction. For endocytosis in vivo, BHK fibroblasts were pulse-labeled with BODIPY-avidin together with a red (rhodamine) fluorescent fusion-independent chromophore (TMR). After specified chase times in a nonfluorescent medium, a second cohort of endosomes was pulse-labeled with biotin-conjugated albumin, dextran, or transferrin. Fusion of biotin-containing endosomes with avidin-containing endosomes was quantified by ratio imaging of BODIPY-to-TMR fluorescence in individual endosomes, using imaging methods developed for endosome pH studies. Analysis of BODIPY-to-TMR ratio distributions in avidin-labeled endosomes exposed to zero and maximum biotin indicated > 90% sensitivity for detection of endosome fusion. In avidin pulse (10 min) -chase-biotin albumin pulse (10 min) studies, both fused and unfused endosomes were identified; the fractions of avidin-labeled endosomes that fused with biotin-labeled endosomes were 0.48, 0.21, 0.16, and 0.07 for 0-, 5-, 10-, and 20-min chase times. Fitting of fusion data to a mathematical model of in vivo endosome fusion required the existence of an intermediate fusion compartment. Pulse-chase studies performed with biotin-transferrin to label the early/recycling endosomes indicated that after a 10-min chase, avidin-labeled endosomes reached a compartment that was inaccessible to biotin-transferrin. The assay was also applied to determine whether endosome fusion was influenced by temperature, pH (bafilomycin A1), second messengers (cAMP agonists, phorbol 12-myristate 13-acetate, staurosporine), and growth-related factors (platelet-derived growth factor, genistein). The results establish a sensitive fluorescence assay to quantify the fusion of vesicular compartments in living cells.

Synthesis of cell-impermeable Cl-sensitive fluorescent indicators with improved sensitivity and optical properties

Quinolinium compounds have been used as Cl-sensitive fluorescent indicators in cells and cell-free membrane fractions. To improve Cl sensitivity and for conjugation via nucleophilic reaction, the compounds 6-methoxy-N-(n-aminoalkyl)quinolinium bromide hydrochloride (AAQ) with alkyl chain lengths (n) of 2 (AEQ), 3 (APQ), and 4 (ABQ) were synthesized. AAQ was water soluble, fluorescent, and quenched by Cl. The Stern-Volmer constants (KCl) for quenching of protonated AEQ, APQ and ABQ by Cl were 354, 322, and 272 M-1, respectively, higher than KCl for 6-methoxy-N-(3-sulfopropyl)quinolinium (SPQ; 118 M-1). To eliminate pH-dependent fluorescence, 6-methoxy-N-(3-trimethylammoniumpropyl)quinolinium dibromide (TMAPQ) was synthesized (KCl, 310 M-1). To red shift fluorescence excitation and emission spectra, 6-phenyl-N-(3-trimethylammoniumpropyl)quinolinium dibromide (phenyl-TMAPQ) (emission 475 nm) and N-(3-trimethylammoniumpropyl)phenanthridinium dibromide (TMAPP) (excitation 380 nm) were synthesized. AEQ and ABQ were conjugated with neutral dextran activated by cyanogen bromide to give indicator-to-dextran mole ratios of 5 to 20. KCl values at pH 7.4 were 132 (AEQ-dextran) and 237 M-1 (ABQ-dextran). To construct a single molecule with Cl-sensitive and insensitive moieties, the bichromophores 6-methoxy-N-(n- dansylsulfonamidoalkyl)quinolinium with alkyl chains of two and four were synthesized. The new Cl-sensitive indicators were used for measurement of intracellular Cl activity and for the labeling of endocytic vesicles in 3T3 fibroblasts and T84 cells. Our results indicate that N-substitution of quinoline with positively charged moieties gives increased Cl sensitivity, and extension of ring conjugation gives indicators with red-shifted fluorescence spectra.

Fiber optic halide sensor based on fluorescence quenching

A fiber optic sensor for halides was constructed based on the collisional quenching of quinolinium chromophores bound to porous glass beads. The halide indicators N-(4- aminobutyl)-6-methoxyquinolinium (ABQ) and N-(7-carboxyheptyl)-6-methoxyquinolinium (CHQ) were covalently attached to surface derivatized glass beads. The labeled beads were fluorescent with excitation and emission maxima at 350 and 450 nm, respectively. Halide sensitivity and kinetics were examined by epifluorescence microscopy of immobilized beads. The CHQ labeled beads had a higher sensitivity to halides than the ABQ beads. CHQ bead fluorescence was quenched at 100 mM halide concentration by 40% for Cl-, 55% for Br-, 80% for SCN-, and 85% for I-. The 10 - 90% rise time for a step change in chloride concentration was approximately 4 s. Similar results were obtained when the beads were cemented to the tip of a single quartz fiberoptic. Time-resolved microfluorimetry studies showed that nanosecond fluorescence lifetimes decreased with halide concentration.